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Renesas HD6417709SF100B Renesas 32-bit risc microcomputer super risc engine family/sh7700 sery Datasheet

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clicking the title page.
The revision list summarizes the locations of
revisions and additions. Details should always
be checked by referring to the relevant text.
SH7709S Group
32
Hardware Manual
Renesas 32-Bit RISC Microcomputer
SuperH RISC engine Family/SH7700 Series
Rev.5.00
2003.9.18
Renesas 32-Bit RISC Microcomputer
SuperH RISC engine Family/SH7700 Series
SH7709S Group
Hardware Manual
REJ09B0081-0500O
Cautions
Keep safety first in your circuit designs!
1. Renesas Technology Corp. puts the maximum effort into making semiconductor products
better and more reliable, but there is always the possibility that trouble may occur with them.
Trouble with semiconductors may lead to personal injury, fire or property damage.
Remember to give due consideration to safety when making your circuit designs, with
appropriate measures such as (i) placement of substitutive, auxiliary circuits, (ii) use of
nonflammable material or (iii) prevention against any malfunction or mishap.
Notes regarding these materials
1. These materials are intended as a reference to assist our customers in the selection of the
Renesas Technology Corp. product best suited to the customer's application; they do not
convey any license under any intellectual property rights, or any other rights, belonging to
Renesas Technology Corp. or a third party.
2. Renesas Technology Corp. assumes no responsibility for any damage, or infringement of any
third-party's rights, originating in the use of any product data, diagrams, charts, programs,
algorithms, or circuit application examples contained in these materials.
3. All information contained in these materials, including product data, diagrams, charts,
programs and algorithms represents information on products at the time of publication of these
materials, and are subject to change by Renesas Technology Corp. without notice due to
product improvements or other reasons. It is therefore recommended that customers contact
Renesas Technology Corp. or an authorized Renesas Technology Corp. product distributor for
the latest product information before purchasing a product listed herein.
The information described here may contain technical inaccuracies or typographical errors.
Renesas Technology Corp. assumes no responsibility for any damage, liability, or other loss
rising from these inaccuracies or errors.
Please also pay attention to information published by Renesas Technology Corp. by various
means, including the Renesas Technology Corp. Semiconductor home page
(http://www.renesas.com).
4. When using any or all of the information contained in these materials, including product data,
diagrams, charts, programs, and algorithms, please be sure to evaluate all information as a total
system before making a final decision on the applicability of the information and products.
Renesas Technology Corp. assumes no responsibility for any damage, liability or other loss
resulting from the information contained herein.
5. Renesas Technology Corp. semiconductors are not designed or manufactured for use in a
device or system that is used under circumstances in which human life is potentially at stake.
Please contact Renesas Technology Corp. or an authorized Renesas Technology Corp. product
distributor when considering the use of a product contained herein for any specific purposes,
such as apparatus or systems for transportation, vehicular, medical, aerospace, nuclear, or
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whole or in part these materials.
7. If these products or technologies are subject to the Japanese export control restrictions, they
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contained therein.
Rev. 5.00, 09/03, page iv of xliv
General Precautions on Handling of Product
1. Treatment of NC Pins
Note: Do not connect anything to the NC pins.
The NC (not connected) pins are either not connected to any of the internal circuitry or are
used as test pins or to reduce noise. If something is connected to the NC pins, the
operation of the LSI is not guaranteed.
2. Treatment of Unused Input Pins
Note: Fix all unused input pins to high or low level.
Generally, the input pins of CMOS products are high-impedance input pins. If unused pins
are in their open states, intermediate levels are induced by noise in the vicinity, a passthrough current flows internally, and a malfunction may occur.
3. Processing before Initialization
Note: When power is first supplied, the product’s state is undefined.
The states of internal circuits are undefined until full power is supplied throughout the
chip and a low level is input on the reset pin. During the period where the states are
undefined, the register settings and the output state of each pin are also undefined. Design
your system so that it does not malfunction because of processing while it is in this
undefined state. For those products which have a reset function, reset the LSI immediately
after the power supply has been turned on.
4. Prohibition of Access to Undefined or Reserved Addresses
Note: Access to undefined or reserved addresses is prohibited.
The undefined or reserved addresses may be used to expand functions, or test registers
may have been be allocated to these addresses. Do not access these registers; the system’s
operation is not guaranteed if they are accessed.
Rev. 5.00, 09/03, page v of xliv
Configuration of This Manual
This manual comprises the following items:
1. General Precautions on Handling of Product
2. Configuration of This Manual
3. Preface
4. Contents
5. Overview
6. Description of Functional Modules
•
•
CPU and System-Control Modules
On-Chip Peripheral Modules
The configuration of the functional description of each module differs according to the
module. However, the generic style includes the following items:
i) Feature
ii) Input/Output Pin
iii) Register Description
iv) Operation
v) Usage Note
When designing an application system that includes this LSI, take notes into account. Each section
includes notes in relation to the descriptions given, and usage notes are given, as required, as the
final part of each section.
7. List of Registers
8. Electrical Characteristics
9. Appendix
10. Main Revisions and Additions in this Edition (only for revised versions)
The list of revisions is a summary of points that have been revised or added to earlier versions.
This does not include all of the revised contents. For details, see the actual locations in this
manual.
11. Index
Rev. 5.00, 09/03, page vi of xliv
Preface
This LSI is a microprocessor with the 32-bit SH-3 CPU as its core and peripheral functions
necessary for configuring a user system.
This LSI is built in with a variety of peripheral functions such as cache memory, memory
management unit (MMU), interrupt controller, timer, three serial communication interfaces, realtime clock (RTC), use break controller (UBC), bus state controller (BSC) and I/O ports.
This LSI can be used as a microcomputer for devices that require both high speed and low power
consumption.
Target Readers: This manual is designed for use by people who design application systems using
the SH7709S.
To use this manual, basic knowledge of electric circuits, logic circuits and microcomputers is
required.
Purpose: This manual provides the information of the hardware functions and electrical
characteristics of the SH7709S.
The SH3, SH-3E, SH3-DSP Programming Manual contains detailed information of executable
instructions. Please read the Programming Manual together with this manual.
How to Use the Book:
• To understand general functions
 Read the manual from the beginning.
The manual explains the CPU, system control functions, peripheral functions and electrical
characteristics in that order.
• To understanding CPU functions
 Refer to the separate SH3, SH-3E, SH3-DSP Programming Manual.
Explanatory Note: Bit sequence: upper bit at left, and lower bit at right
List of Related Documents: The latest documents are available on our Web site. Please make
sure that you have the latest version.
(http://www.renesas.com/eng/)
• User manuals for SH7709S
Name of Document
Document No.
SH7709S Group Hardware Manual
This manual
SH3, SH-3E, SH3-DSP Programming Manual
ADE-602-156
Rev. 5.00, 09/03, page vii of xliv
• User manuals for development tools
Name of Document
Document No.
C/C++ Compiler, Assembler, Optimizing Linkage Editor User’s Manual
ADE-702-246
Simulator/Debugger User’s Manual
ADE-702-186
Embedded Workshop User’s Manual
ADE-702-201
Rev. 5.00, 09/03, page viii of xliv
List of Items Revised or Added for This Version
Section
Page
Description
1.2 Block Diagram
6
ASERAM deleted from figure
Figure 1.1 Block
Diagram
BRIDGE
I bus 2
UDI
INTC
CPG/WDT
External bus
interface
ASERAM deleted from legend
2.5.1 Processor States 53
Description amended
In the power-on reset state, the internal states of the CPU and the
on-chip supporting module registers are initialized. In the manual
reset state, the internal states of the CPU and registers of on-chip
supporting modules other than the bus state controller (BSC) are
Refer to
initialized.
the register configurations in the relevant sections for further
details.
5.4 Memory-Mapped
Cache
5.4.1 Address Array
113
Description amended
This operation is used to invalidate the address specification for a
cache. Write back will take place when the U bit of the entry that
received a hit is 1. Note that, when a 0 is written to the V bit, a 0
should always be written to the U bit of the same entry, too.
Rev. 5.0, 09/03, page ix of xliv
Section
Page
Description
5.4.3 Examples of
Usage
115,
116
(1) Invalidating a Specific Entry
Description amended
A specific cache entry can be invalidated by accessing the allocated
memory cache and writing a 0 to the entry’s U and V bits. The A bit is
cleared to 0, and an address is specified for the entry address and the
way. If the U bit of the way of the entry in question was set to 1, the
entry is written back and the V and U bits specified by the write data are
written to.
In the following example, the write data is specified in R0 and the
address is specified in R1.
; R0 = H'0000 0000 LRU = H'000, U = 0, V = 0
; R1 = H'F000 1080, Way = 1, Entry = H'08, A = 0
;
MOV.L R0, @R1
To invalidate all entries and ways, write 0 to the following addresses.
Addresses
F000 0000
F000 0010
F000 0020
:
F000 3FF0
This involves a total of 1,024 writes.
The above operation should be performed using a non-cacheable area.
(2) Invalidating a Specific Address
Newly added
(3) Reading Data from a Specific Entry
Description amended
; R0 = H'F100 004C; Data array access, Entry = H'04,
; Way = 0, Longword address = 3
;
MOV.L R0, @R1
; Longword 3 is read.
6.2.6 Interrupt
127
Exception Handling and
Priority
IPR (bit numbers) for SCI amended
(Before)IPRB(3-0) → (After)IPRB(7-4)
Table 6.4 Interrupt
Exception Handling
Sources and Priority
(IRQ Mode)
6.3.6 Interrupt
Request Register 0
(IRR0)
138
8.2.1 Standby Control 184
Register (STBCR)
Description amended
When clearing an IRQ5R–IRQ0R bit to 0, read the bit while bit set
to 1, and then write 0. In this case, 0 should be written only to the
bits to be cleared and 1 to the other bits. The contents of the bits
to which 1 is written do not change.
Description added
Bit 1—Module Standby 1 (MSTP1)
Before switching the RTC to module standby, access at least one
among the registers RTC, SCI, and TMU.
Rev. 5.0, 09/03, page x of xliv
Section
Page
Description
8.3.3 Precautions
when Using the Sleep
Mode
187
Newley added
8.5.1 Transition to
Module Standby
Function
191
Note *3 added to bit table
9.3 Clock Operating
Modes
210
Note: 3. Before putting the RTC into module standby status, first
access one or more of the RTC, SCI, and TMU
registers. The RTC may then be put into module standby
status.
The peripheral clock frequency should not be set higher than the
frequency of the CKIO pin, higher than 33.34 MHz.
Table 9.4 Available
Combinations of Clock
Mode and FRQCR
Values
9.5.1 Changing the
Multiplication Rate
2. under cautions amended
213
Description added
5.Supply of the clock that has been set begins at WDT count
overflow, and the processor begins operating again. The WDT
stops after it overflows.
When the following three conditions are all met, FRQCR should
not be changed while a DMAC transfer is in progress.
• Bits IFC2 to IFC0 are changed.
• STC2 to STC0 are not changed.
• The clock ratio of Iφ (on-chip clock) to Bφ (bus clock) after the
change is other than 1:1.
9.8.2 Changing the
Frequency
218,
219
Description added
5.The counter stops at a value of H'00 or H'01. The stop value
depends on the clock ratio.
When the following three conditions are all met, FRQCR should
not be changed while a DMAC transfer is in progress.
• Bits IFC2 to IFC0 are changed.
• STC2 to STC0 are not changed.
• The clock ratio of Iφ (on-chip clock) to Bφ (bus clock) after the
change is other than 1:1.
10.1.1 Features
223
Refresh function description deleted
10.2.5 Individual
Memory Control
Register (MCR)
246
Description added
Bit 7—Synchronous DRAM Bank Active (RASD): Specifies
whether synchronous DRAM is used in bank active mode or autoprecharge mode. Set auto-precharge mode when areas 2 and 3
are both designated as synchronous DRAM space.
The bank active mode should not be used unless the bus width
for all areas is 32 bits.
Rev. 5.0, 09/03, page xi of xliv
Section
Page
Description
10.2.13 MCS0 Control 258
Register (MCSCR0)
Description added
10.3.4 Synchronous
DRAM Interface
290
Bank Active description added
10.3.6 PCMCIA
Interface
310
Bit 6—CS2/CS0 Select (CS2/0)
Only 0 should be used for the CS2/0 bit in MCSCR0. Either 0 or 1
may be used for MCSCR1 to MCSCR7.
… .In bank active mode, too, all banks become inactive after a
refresh cycle or after the bus is released as the result of bus
arbitration.
The bank active mode should not be used unless the bus width
for all areas is 32 bits.
Figure amended
D15 to D0
Figure 10.32 Basic
Timing for PCMCIA
Memory Card Interface
(Write)
10.3.7 Waits between 320
Access Cycles
Figure 10.40 Waits
between Access Cycles
Figure amended
T1
T2
Twait
T1
T2
Twait
T1
T2
CKIO
A25 to A0
10.3.10 MCS[0] to
MCS[7] Pin Control
323
11.6 Usage Notes
387
Description amended
This enables 32-, 64-, 128-, or 256-Mbit memory to be connected
to area 0 or area 2. However, only CS2/0 = 0 (area 0) should be
used for MCSCR0. Table 10.15 shows MCSCR0–MCSCR7
settings and MCS[0]–MCS[7] assertion conditions.
Description added
13. DMAC transfers should not be performed in the sleep mode
under conditions other than when the clock ratio of Iφ (onchip clock) to Bφ (bus clock) is 1:1.
14. When the following three conditions are all met, the
frequency control register (FRQCR) should not be changed
while a DMAC transfer is in progress.
• Bits IFC2 to IFC0 are changed.
• STC2 to STC0 in FRQCR are not changed.
• The clock ratio of Iφ (on-chip clock) to Bφ (bus clock) after
the change is other than 1:1.
13.4.3 Precautions
when Using RTC
Module Standby
426
Rev. 5.0, 09/03, page xii of xliv
Newly added
Section
Page
Description
16.4 SCIF Interrupts
550
Description amended
When the TDFE flag in the serial status register (SCSSR) is set to
1, a TXI interrupt request is generated. The DMAC can be
activated and data transfer performed when this interrupt is
generated. When data exceeding the transmit trigger number is
written to the transmit data register (SCFTDR) by the DMAC, 1 is
read from the TDFE flag, after which 0 is written to it to clear it.
When the RDF flag in SCSSR is set to 1, an RXI interrupt request
is generated. The DMAC can be activated and data transfer
performed when the RDF flag in SCSSR is set to 1. When
receive data less than the receive trigger number is read from the
receive data register (SCFRDR) by the DMAC, 1 is read from the
RDF flag, after which 0 is written to it to clear it.
16.5 Usage Notes
551
Description amended
1. SCFTDR Writing and TDFE Flag:
However, if the number of data bytes written to SCFTDR is equal
to or less than the transmit trigger number, the TDFE flag will be
set to 1 again even after having been cleared to 0. TDFE clearing
should therefore be carried out after data exceeding the specified
transmit trigger number has been written to SCFTDR.
2. SCFRDR Reading and RDF Flag:
However, if the number of data bytes in SCFRDR exceeds the
trigger number, the RDF flag will be set to 1 again even after
having been cleared to 0. RDF should therefore be cleared to 0
after being read as 1 after all the receive data has been read.
19.13.2 SC Port Data
Register (SCPDR)
610
Title Amended
Rev. 5.0, 09/03, page xiii of xliv
Section
Page
Description
20.3 Bus Master
Interface
622
Figure amended
Upper byte read
Figure 20.2 A/D Data
Register Access
Operation (Reading
H'AA40)
CPU
receives
data H'AA
Module internal data bus
Bus
interface
TEMP
[H'40]
ADDRn H
[H'AA]
ADDRn L
[H'40]
n = A to D
Lower byte read
CPU
receives
data H'40
Module internal data bus
Bus
interface
TEMP
[H'40]
ADDRn H
[H'AA]
23.1 Absolute
Maximum Ratings
657
n = A to D
Caution added
2.Until voltage is applied to all power supplies, a low level is input
at the RESETP pin, and CKIO has operated for a maximum of 4
clock cycles, internal circuits remain unsettled, and so pin states
are also undefined. The system design must ensure that these
undefined states do not cause erroneous system operation.
Note that the RESETP pin cannot receive a low level signal while
a low level signal is being input to the CA pin.
Table 23.1 Absolute
Maximum Ratings
23.2 DC
Characteristics
ADDRn L
[H'40]
659,
662
Table 23.2 DC
Characteristics
Test conditions for in sleep mode amended
Item
Symbol Min
Sleep Icc
1
mode* IccQ
Typ Max
—
15
30
—
10
20
Unit
Test Conditions
1
* : When there is no
other external bus
cycle other than the
refresh cycle.
Vcc = 1.9 V
VccQ = 3.3 V
Bφ = 33MHz
Note * added
* If the IRL and IRLS interrupts are used, the minimum is 1.9 V.
Rev. 5.0, 09/03, page xiv of xliv
Section
Page
Description
23.3.6 Synchronous
DRAM Timing
690
Tnop cycle deleted from figure
Figure 23.31
Synchronous DRAM
Burst Read Bus Cycle
(RAS Down, Same Row
Address, CAS Latency
= 2)
Tc1
Tc2
Tc3/Td1 Tc4/Td2
Td3
Td4
CKIO
tAD
tAD
A25 to A16
Row address
tAD
tAD
Read command
A12 or A10
tAD
tAD
Column address
A15 to A0
tCSD3
tCSD3
tRWD
tRWD
CSn
RD/WR
tRASD2
RAS
tCASD2
tCASD2
CAS
tDQMD
tDQMD
DQMxx
tRDS2 tRDH2
tRDS2 tRDH2
D31 to D0
tBSD
tBSD
BS
CKE
(High)
tDAKD1
tDAKD1
DACKn
Rev. 5.0, 09/03, page xv of xliv
Section
Page
A.2 Pin Specifications 723
Table A.2 Pin
Specifications
Description
Function information amended for VCC–RTC, VCC–PLL1, VCC–
PLL2, and VCC
Pin
A.3 Treatment of
Unused Pins
724
A.4 Pin States in
Access to Each
Address Space
726 to
738
Pin No.
(FP-208C,
FP-208E)
Pin No.
(BP240A)
I/O
Function
VCC– 3
RTC
E2
Power
supply
RTC oscillator power
supply
(2.0/1.9/1.8/1.7 V)
VCC– 145
PLL1 150
VCC–
PLL2
F16,
E17
Power
supply
PLL power supply
(2.0/1.9/1.8/1.7 V)
VCC
L3, L4,
U11, T11,
J17, J16,
E18, C19,
C12, D12
Power
supply
Internal power supply
(2.0/1.9/1.8/1.7 V)
29, 81,
134, 154,
175
"When RTC is not used" and "When PLL2 is not used" amended
(Before) (1.9/1.8V) →(After) (2.0/1.9/1.8/1.7V)
Table A.3 Pin States
(Ordinary Memory/Little
Endian)
Table A.4 Pin States
(Ordinary Memory/Big
Endian)
Table A.5 Pin States
(Burst ROM/Little
Endian)
Table A.6 Pin States
(Burst ROM/Big
Endian)
Table A.9 Pin States
(PCMCIA/Little Endian)
Table A.10 Pin States
(PCMCIA/Big Endian)
Rev. 5.0, 09/03, page xvi of xliv
Note 2 amended
Note: 2. Unused data pins should be switched to the port
function, or pulled up.
Contents
Section 1 Overview and Pin Functions ..........................................................................
1.1
1.2
1.3
SH7709S Features .............................................................................................................
Block Diagram ..................................................................................................................
Pin Description ..................................................................................................................
1.3.1 Pin Assignment ....................................................................................................
1.3.2 Pin Function .........................................................................................................
1
1
6
7
7
9
Section 2 CPU ....................................................................................................................... 19
2.1
2.2
2.3
2.4
2.5
Register Configuration ......................................................................................................
2.1.1 Privileged Mode and Banks..................................................................................
2.1.2 General Registers .................................................................................................
2.1.3 System Registers ..................................................................................................
2.1.4 Control Registers..................................................................................................
Data Formats .....................................................................................................................
2.2.1 Data Format in Registers ......................................................................................
2.2.2 Data Format in Memory .......................................................................................
Instruction Features ...........................................................................................................
2.3.1 Execution Environment ........................................................................................
2.3.2 Addressing Modes................................................................................................
2.3.3 Instruction Formats...............................................................................................
Instruction Set....................................................................................................................
2.4.1 Instruction Set Classified by Function..................................................................
2.4.2 Instruction Code Map ...........................................................................................
Processor States and Processor Modes..............................................................................
2.5.1 Processor States....................................................................................................
2.5.2 Processor Modes ..................................................................................................
19
19
22
23
23
25
25
25
26
26
28
32
35
35
50
53
53
54
Section 3 Memory Management Unit (MMU) ............................................................ 55
3.1
3.2
3.3
Overview ...........................................................................................................................
3.1.1 Features ................................................................................................................
3.1.2 Role of MMU .......................................................................................................
3.1.3 SH7709S MMU....................................................................................................
3.1.4 Register Configuration .........................................................................................
Register Description ..........................................................................................................
TLB Functions...................................................................................................................
3.3.1 Configuration of the TLB .....................................................................................
3.3.2 TLB Indexing .......................................................................................................
3.3.3 TLB Address Comparison....................................................................................
3.3.4 Page Management Information ............................................................................
55
55
55
58
61
61
63
63
65
66
68
Rev. 5.00, 09/03, page xvii of xliv
3.4
3.5
3.6
3.7
MMU Functions ................................................................................................................
3.4.1 MMU Hardware Management .............................................................................
3.4.2 MMU Software Management...............................................................................
3.4.3 MMU Instruction (LDTLB) .................................................................................
3.4.4 Avoiding Synonym Problems...............................................................................
MMU Exceptions ..............................................................................................................
3.5.1 TLB Miss Exception ............................................................................................
3.5.2 TLB Protection Violation Exception....................................................................
3.5.3 TLB Invalid Exception.........................................................................................
3.5.4 Initial Page Write Exception ................................................................................
3.5.5 Processing Flow in Event of MMU Exception (Same Processing Flow
for Address Error) ................................................................................................
Configuration of Memory-Mapped TLB...........................................................................
3.6.1 Address Array ......................................................................................................
3.6.2 Data Array ............................................................................................................
3.6.3 Usage Examples ...................................................................................................
Usage Note ........................................................................................................................
69
69
69
70
72
74
74
75
76
77
79
80
80
81
83
83
Section 4 Exception Handling .......................................................................................... 85
4.1
4.2
4.3
4.4
4.5
4.6
Overview ........................................................................................................................... 85
4.1.1 Features ................................................................................................................ 85
4.1.2 Register Configuration ......................................................................................... 85
Exception Handling Function............................................................................................ 85
4.2.1 Exception Handling Flow..................................................................................... 85
4.2.2 Exception Vector Addresses................................................................................. 86
4.2.3 Acceptance of Exceptions .................................................................................... 88
4.2.4 Exception Codes................................................................................................... 90
4.2.5 Exception Request Masks .................................................................................... 91
4.2.6 Returning from Exception Handling .................................................................... 91
Register Descriptions......................................................................................................... 92
Exception Handling Operation .......................................................................................... 93
4.4.1 Reset..................................................................................................................... 93
4.4.2 Interrupts .............................................................................................................. 93
4.4.3 General Exceptions............................................................................................... 94
Individual Exception Operations ....................................................................................... 94
4.5.1 Resets ................................................................................................................... 94
4.5.2 General Exceptions............................................................................................... 95
4.5.3 Interrupts .............................................................................................................. 99
Cautions............................................................................................................................. 100
Section 5 Cache .................................................................................................................... 103
5.1
Overview ........................................................................................................................... 103
5.1.1 Features ................................................................................................................ 103
Rev. 5.00, 09/03, page xviii of xliv
5.2
5.3
5.4
5.1.2 Cache Structure .................................................................................................... 103
5.1.3 Register Configuration ......................................................................................... 105
Register Description .......................................................................................................... 105
5.2.1 Cache Control Register (CCR) ............................................................................. 105
5.2.2 Cache Control Register 2 (CCR2) ........................................................................ 106
Cache Operation ................................................................................................................ 109
5.3.1 Searching the Cache ............................................................................................. 109
5.3.2 Read Access ......................................................................................................... 111
5.3.3 Prefetch Operation................................................................................................ 111
5.3.4 Write Access ........................................................................................................ 111
5.3.5 Write-Back Buffer................................................................................................ 111
5.3.6 Coherency of Cache and External Memory.......................................................... 112
Memory-Mapped Cache.................................................................................................... 112
5.4.1 Address Array ...................................................................................................... 112
5.4.2 Data Array ............................................................................................................ 113
5.4.3 Examples of Usage ............................................................................................... 115
Section 6 Interrupt Controller (INTC) ........................................................................... 117
6.1
6.2
6.3
6.4
6.5
Overview ........................................................................................................................... 117
6.1.1 Features ................................................................................................................ 117
6.1.2 Block Diagram ..................................................................................................... 118
6.1.3 Pin Configuration ................................................................................................. 119
6.1.4 Register Configuration ......................................................................................... 120
Interrupt Sources ............................................................................................................... 121
6.2.1 NMI Interrupt ....................................................................................................... 121
6.2.2 IRQ Interrupts ...................................................................................................... 121
6.2.3 IRL Interrupts....................................................................................................... 122
6.2.4 PINT Interrupts .................................................................................................... 124
6.2.5 On-Chip Peripheral Module Interrupts................................................................. 124
6.2.6 Interrupt Exception Handling and Priority ........................................................... 125
INTC Registers.................................................................................................................. 131
6.3.1 Interrupt Priority Registers A to E (IPRA–IPRE) ................................................ 131
6.3.2 Interrupt Control Register 0 (ICR0) ..................................................................... 132
6.3.3 Interrupt Control Register 1 (ICR1) ..................................................................... 133
6.3.4 Interrupt Control Register 2 (ICR2) ..................................................................... 136
6.3.5 PINT Interrupt Enable Register (PINTER) .......................................................... 137
6.3.6 Interrupt Request Register 0 (IRR0)..................................................................... 138
6.3.7 Interrupt Request Register 1 (IRR1)..................................................................... 140
6.3.8 Interrupt Request Register 2 (IRR2)..................................................................... 141
INTC Operation................................................................................................................. 143
6.4.1 Interrupt Sequence................................................................................................ 143
6.4.2 Multiple Interrupts................................................................................................ 145
Interrupt Response Time ................................................................................................... 145
Rev. 5.00, 09/03, page xix of xliv
Section 7 User Break Controller ...................................................................................... 149
7.1
7.2
7.3
Overview ........................................................................................................................... 149
7.1.1 Features ................................................................................................................ 149
7.1.2 Block Diagram ..................................................................................................... 150
7.1.3 Register Configuration ......................................................................................... 151
Register Descriptions......................................................................................................... 152
7.2.1 Break Address Register A (BARA)...................................................................... 152
7.2.2 Break Address Mask Register A (BAMRA) ........................................................ 153
7.2.3 Break Bus Cycle Register A (BBRA) .................................................................. 154
7.2.4 Break Address Register B (BARB) ...................................................................... 156
7.2.5 Break Address Mask Register B (BAMRB)......................................................... 157
7.2.6 Break Data Register B (BDRB) ........................................................................... 158
7.2.7 Break Data Mask Register B (BDMRB) .............................................................. 159
7.2.8 Break Bus Cycle Register B (BBRB)................................................................... 160
7.2.9 Break Control Register (BRCR)........................................................................... 162
7.2.10 Execution Times Break Register (BETR) ............................................................ 166
7.2.11 Branch Source Register (BRSR) .......................................................................... 167
7.2.12 Branch Destination Register (BRDR) .................................................................. 168
7.2.13 Break ASID Register A (BASRA) ....................................................................... 169
7.2.14 Break ASID Register B (BASRB) ....................................................................... 169
Operation Description ....................................................................................................... 170
7.3.1 Flow of the User Break Operation........................................................................ 170
7.3.2 Break on Instruction Fetch Cycle ......................................................................... 170
7.3.3 Break by Data Access Cycle ................................................................................ 171
7.3.4 Sequential Break .................................................................................................. 172
7.3.5 Value of Saved Program Counter......................................................................... 172
7.3.6 PC Trace............................................................................................................... 173
7.3.7 Usage Examples ................................................................................................... 174
7.3.8 Notes .................................................................................................................... 179
Section 8 Power-Down Modes......................................................................................... 181
8.1
8.2
8.3
8.4
Overview ........................................................................................................................... 181
8.1.1 Power-Down Modes............................................................................................. 181
8.1.2 Pin Configuration ................................................................................................. 183
8.1.3 Register Configuration ......................................................................................... 183
Register Descriptions......................................................................................................... 183
8.2.1 Standby Control Register (STBCR) ..................................................................... 183
8.2.2 Standby Control Register 2 (STBCR2) ................................................................ 185
Sleep Mode........................................................................................................................ 187
8.3.1 Transition to Sleep Mode ..................................................................................... 187
8.3.2 Canceling Sleep Mode.......................................................................................... 187
8.3.3 Precautions when Using the Sleep Mode ............................................................. 187
Standby Mode.................................................................................................................... 188
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8.5
8.6
8.7
8.4.1 Transition to Standby Mode ................................................................................. 188
8.4.2 Canceling Standby Mode ..................................................................................... 189
8.4.3 Clock Pause Function........................................................................................... 190
Module Standby Function ................................................................................................. 191
8.5.1 Transition to Module Standby Function............................................................... 191
8.5.2 Clearing Module Standby Function...................................................................... 191
Timing of STATUS Pin Changes ...................................................................................... 192
8.6.1 Timing for Resets ................................................................................................. 192
8.6.2 Timing for Canceling Standby ............................................................................. 194
8.6.3 Timing for Canceling Sleep Mode ....................................................................... 196
Hardware Standby Mode................................................................................................... 199
8.7.1 Transition to Hardware Standby Mode ................................................................ 199
8.7.2 Canceling Hardware Standby Mode..................................................................... 199
8.7.3 Hardware Standby Mode Timing ......................................................................... 200
Section 9 On-Chip Oscillation Circuits ......................................................................... 203
9.1
9.2
9.3
9.4
9.5
9.6
9.7
9.8
9.9
Overview ........................................................................................................................... 203
9.1.1 Features ................................................................................................................ 203
Overview of CPG .............................................................................................................. 204
9.2.1 CPG Block Diagram............................................................................................. 204
9.2.2 CPG Pin Configuration ........................................................................................ 206
9.2.3 CPG Register Configuration................................................................................. 206
Clock Operating Modes..................................................................................................... 207
Register Descriptions......................................................................................................... 211
9.4.1 Frequency Control Register (FRQCR) ................................................................. 211
Changing the Frequency.................................................................................................... 213
9.5.1 Changing the Multiplication Rate ........................................................................ 213
9.5.2 Changing the Division Ratio ................................................................................ 213
Overview of WDT............................................................................................................. 214
9.6.1 Block Diagram of WDT ....................................................................................... 214
9.6.2 Register Configuration ......................................................................................... 214
WDT Registers .................................................................................................................. 215
9.7.1 Watchdog Timer Counter (WTCNT) ................................................................... 215
9.7.2 Watchdog Timer Control/Status Register (WTCSR) ........................................... 215
9.7.3 Notes on Register Access ..................................................................................... 217
Using the WDT ................................................................................................................. 218
9.8.1 Canceling Standby................................................................................................ 218
9.8.2 Changing the Frequency....................................................................................... 218
9.8.3 Using Watchdog Timer Mode .............................................................................. 219
9.8.4 Using Interval Timer Mode .................................................................................. 219
Notes on Board Design...................................................................................................... 220
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Section 10 Bus State Controller (BSC) ......................................................................... 223
10.1 Overview ........................................................................................................................... 223
10.1.1 Features ................................................................................................................ 223
10.1.2 Block Diagram ..................................................................................................... 225
10.1.3 Pin Configuration ................................................................................................. 226
10.1.4 Register Configuration ......................................................................................... 228
10.1.5 Area Overview ..................................................................................................... 229
10.1.6 PCMCIA Support................................................................................................. 232
10.2 BSC Registers.................................................................................................................... 235
10.2.1 Bus Control Register 1 (BCR1)............................................................................ 235
10.2.2 Bus Control Register 2 (BCR2)............................................................................ 239
10.2.3 Wait State Control Register 1 (WCR1) ................................................................ 240
10.2.4 Wait State Control Register 2 (WCR2) ................................................................ 241
10.2.5 Individual Memory Control Register (MCR) ....................................................... 245
10.2.6 PCMCIA Control Register (PCR) ........................................................................ 248
10.2.7 Synchronous DRAM Mode Register (SDMR)..................................................... 252
10.2.8 Refresh Timer Control/Status Register (RTCSR) ................................................ 253
10.2.9 Refresh Timer Counter (RTCNT) ........................................................................ 255
10.2.10 Refresh Time Constant Register (RTCOR) .......................................................... 256
10.2.11 Refresh Count Register (RFCR)........................................................................... 256
10.2.12 Cautions on Accessing Refresh Control Related Registers .................................. 257
10.2.13 MCS0 Control Register (MCSCR0)..................................................................... 258
10.2.14 MCS1 Control Register (MCSCR1)..................................................................... 259
10.2.15 MCS2 Control Register (MCSCR2)..................................................................... 259
10.2.16 MCS3 Control Register (MCSCR3)..................................................................... 259
10.2.17 MCS4 Control Register (MCSCR4)..................................................................... 259
10.2.18 MCS5 Control Register (MCSCR5)..................................................................... 259
10.2.19 MCS6 Control Register (MCSCR6)..................................................................... 259
10.2.20 MCS7 Control Register (MCSCR7)..................................................................... 259
10.3 BSC Operation .................................................................................................................. 260
10.3.1 Endian/Access Size and Data Alignment ............................................................. 260
10.3.2 Description of Areas............................................................................................. 265
10.3.3 Basic Interface...................................................................................................... 268
10.3.4 Synchronous DRAM Interface ............................................................................. 276
10.3.5 Burst ROM Interface ............................................................................................ 304
10.3.6 PCMCIA Interface ............................................................................................... 307
10.3.7 Waits between Access Cycles .............................................................................. 319
10.3.8 Bus Arbitration..................................................................................................... 320
10.3.9 Bus Pull-Up .......................................................................................................... 321
10.3.10 MCS[0] to MCS[7] Pin Control ........................................................................... 323
Section 11 Direct Memory Access Controller (DMAC) .......................................... 327
11.1 Overview ........................................................................................................................... 327
Rev. 5.00, 09/03, page xxii of xliv
11.2
11.3
11.4
11.5
11.6
11.1.1 Features ................................................................................................................ 327
11.1.2 Block Diagram ..................................................................................................... 329
11.1.3 Pin Configuration ................................................................................................. 330
11.1.4 Register Configuration ......................................................................................... 331
Register Descriptions......................................................................................................... 333
11.2.1 DMA Source Address Registers 0–3 (SAR0–SAR3)........................................... 333
11.2.2 DMA Destination Address Registers 0–3 (DAR0–DAR3) .................................. 334
11.2.3 DMA Transfer Count Registers 0–3 (DMATCR0–DMATCR3) ......................... 335
11.2.4 DMA Channel Control Registers 0–3 (CHCR0–CHCR3) ................................... 336
11.2.5 DMA Operation Register (DMAOR) ................................................................... 343
Operation........................................................................................................................... 345
11.3.1 DMA Transfer Flow............................................................................................. 345
11.3.2 DMA Transfer Requests....................................................................................... 347
11.3.3 Channel Priority ................................................................................................... 349
11.3.4 DMA Transfer Types ........................................................................................... 352
11.3.5 Number of Bus Cycle States and DREQ Pin Sampling Timing ........................... 363
11.3.6 Source Address Reload Function ......................................................................... 372
11.3.7 DMA Transfer Ending Conditions ....................................................................... 374
Compare Match Timer (CMT) .......................................................................................... 376
11.4.1 Overview .............................................................................................................. 376
11.4.2 Register Descriptions ........................................................................................... 377
11.4.3 Operation.............................................................................................................. 380
11.4.4 Compare Match .................................................................................................... 381
Examples of Use................................................................................................................ 383
11.5.1 Example of DMA Transfer between On-Chip IrDA and External Memory ........ 383
11.5.2 Example of DMA Transfer between A/D Converter and External Memory ........ 384
11.5.3 Example of DMA Transfer between External Memory and SCIF Transmitter
(Indirect Address On)........................................................................................... 385
Usage Notes....................................................................................................................... 387
Section 12 Timer (TMU) ................................................................................................... 389
12.1 Overview ........................................................................................................................... 389
12.1.1 Features ................................................................................................................ 389
12.1.2 Block Diagram ..................................................................................................... 390
12.1.3 Pin Configuration ................................................................................................. 391
12.1.4 Register Configuration ......................................................................................... 391
12.2 TMU Registers .................................................................................................................. 392
12.2.1 Timer Output Control Register (TOCR) .............................................................. 392
12.2.2 Timer Start Register (TSTR)................................................................................ 392
12.2.3 Timer Control Registers (TCR)............................................................................ 393
12.2.4 Timer Constant Registers (TCOR) ....................................................................... 397
12.2.5 Timer Counters (TCNT)....................................................................................... 397
12.2.6 Input Capture Register (TCPR2) .......................................................................... 399
Rev. 5.00, 09/03, page xxiii of xliv
12.3 TMU Operation ................................................................................................................. 400
12.3.1 General Operation ................................................................................................ 400
12.3.2 Input Capture Function......................................................................................... 403
12.4 Interrupts ........................................................................................................................... 404
12.4.1 Status Flag Setting Timing ................................................................................... 404
12.4.2 Status Flag Clearing Timing................................................................................. 405
12.4.3 Interrupt Sources and Priorities ............................................................................ 405
12.5 Usage Notes....................................................................................................................... 406
12.5.1 Writing to Registers.............................................................................................. 406
12.5.2 Reading Registers................................................................................................. 406
Section 13 Realtime Clock (RTC) .................................................................................. 407
13.1 Overview ........................................................................................................................... 407
13.1.1 Features ................................................................................................................ 407
13.1.2 Block Diagram ..................................................................................................... 408
13.1.3 Pin Configuration ................................................................................................. 409
13.1.4 RTC Register Configuration................................................................................. 410
13.2 RTC Registers ................................................................................................................... 411
13.2.1 64-Hz Counter (R64CNT).................................................................................... 411
13.2.2 Second Counter (RSECCNT)............................................................................... 411
13.2.3 Minute Counter (RMINCNT) .............................................................................. 412
13.2.4 Hour Counter (RHRCNT) .................................................................................... 412
13.2.5 Day of Week Counter (RWKCNT) ...................................................................... 413
13.2.6 Date Counter (RDAYCNT).................................................................................. 414
13.2.7 Month Counter (RMONCNT).............................................................................. 414
13.2.8 Year Counter (RYRCNT) .................................................................................... 415
13.2.9 Second Alarm Register (RSECAR)...................................................................... 415
13.2.10 Minute Alarm Register (RMINAR) ..................................................................... 416
13.2.11 Hour Alarm Register (RHRAR) ........................................................................... 416
13.2.12 Day of Week Alarm Register (RWKAR)............................................................. 417
13.2.13 Date Alarm Register (RDAYAR) ........................................................................ 418
13.2.14 Month Alarm Register (RMONAR)..................................................................... 418
13.2.15 RTC Control Register 1 (RCR1) .......................................................................... 419
13.2.16 RTC Control Register 2 (RCR2) .......................................................................... 420
13.3 RTC Operation .................................................................................................................. 422
13.3.1 Initial Settings of Registers after Power-On......................................................... 422
13.3.2 Setting the Time ................................................................................................... 422
13.3.3 Reading the Time ................................................................................................. 423
13.3.4 Alarm Function .................................................................................................... 424
13.3.5 Crystal Oscillator Circuit...................................................................................... 425
13.4 Usage Notes....................................................................................................................... 426
13.4.1 Register Writing during RTC Count .................................................................... 426
13.4.2 Use of Realtime Clock (RTC) Periodic Interrupts ............................................... 426
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13.4.3 Precautions when Using RTC Module Standby ................................................... 426
Section 14 Serial Communication Interface (SCI) ..................................................... 427
14.1 Overview ........................................................................................................................... 427
14.1.1 Features ................................................................................................................ 427
14.1.2 Block Diagram ..................................................................................................... 428
14.1.3 Pin Configuration ................................................................................................. 431
14.1.4 Register Configuration ......................................................................................... 432
14.2 Register Descriptions......................................................................................................... 432
14.2.1 Receive Shift Register (SCRSR) .......................................................................... 432
14.2.2 Receive Data Register (SCRDR).......................................................................... 433
14.2.3 Transmit Shift Register (SCTSR)......................................................................... 433
14.2.4 Transmit Data Register (SCTDR) ........................................................................ 434
14.2.5 Serial Mode Register (SCSMR) ........................................................................... 434
14.2.6 Serial Control Register (SCSCR) ......................................................................... 437
14.2.7 Serial Status Register (SCSSR) ............................................................................ 440
14.2.8 SC Port Control Register (SCPCR)/SC Port Data Register (SCPDR) ................. 444
14.2.9 Bit Rate Register (SCBRR) .................................................................................. 446
14.3 Operation........................................................................................................................... 453
14.3.1 Overview .............................................................................................................. 453
14.3.2 Operation in Asynchronous Mode........................................................................ 455
14.3.3 Multiprocessor Communication ........................................................................... 465
14.3.4 Synchronous Operation ........................................................................................ 474
14.4 SCI Interrupts .................................................................................................................... 484
14.5 Usage Notes....................................................................................................................... 485
Section 15 Smart Card Interface ...................................................................................... 489
15.1 Overview ........................................................................................................................... 489
15.1.1 Features ................................................................................................................ 489
15.1.2 Block Diagram ..................................................................................................... 490
15.1.3 Pin Configuration ................................................................................................. 491
15.1.4 Smart Card Interface Registers............................................................................. 491
15.2 Register Descriptions......................................................................................................... 492
15.2.1 Smart Card Mode Register (SCSCMR)................................................................ 492
15.2.2 Serial Status Register (SCSSR) ............................................................................ 493
15.3 Operation........................................................................................................................... 494
15.3.1 Overview .............................................................................................................. 494
15.3.2 Pin Connections.................................................................................................... 495
15.3.3 Data Format.......................................................................................................... 496
15.3.4 Register Settings................................................................................................... 497
15.3.5 Clock .................................................................................................................... 498
15.3.6 Data Transmission and Reception ........................................................................ 501
15.4 Usage Notes....................................................................................................................... 507
Rev. 5.00, 09/03, page xxv of xliv
15.4.1 Receive Data Timing and Receive Margin in Asynchronous Mode .................... 507
15.4.2 Retransmission (Receive and Transmit Modes) ................................................... 509
Section 16 Serial Communication Interface with FIFO (SCIF) ............................. 511
16.1 Overview ........................................................................................................................... 511
16.1.1 Features ................................................................................................................ 511
16.1.2 Block Diagram ..................................................................................................... 512
16.1.3 Pin Configuration ................................................................................................. 515
16.1.4 Register Configuration ......................................................................................... 516
16.2 Register Descriptions......................................................................................................... 517
16.2.1 Receive Shift Register (SCRSR) .......................................................................... 517
16.2.2 Receive FIFO Data Register (SCFRDR).............................................................. 517
16.2.3 Transmit Shift Register (SCTSR)......................................................................... 517
16.2.4 Transmit FIFO Data Register (SCFTDR) ............................................................ 518
16.2.5 Serial Mode Register (SCSMR) ........................................................................... 518
16.2.6 Serial Control Register (SCSCR) ......................................................................... 520
16.2.7 Serial Status Register (SCSSR) ............................................................................ 522
16.2.8 Bit Rate Register (SCBRR) .................................................................................. 527
16.2.9 FIFO Control Register (SCFCR).......................................................................... 534
16.2.10 FIFO Data Count Register (SCFDR) ................................................................... 536
16.3 Operation........................................................................................................................... 537
16.3.1 Overview .............................................................................................................. 537
16.3.2 Serial Operation.................................................................................................... 538
16.4 SCIF Interrupts .................................................................................................................. 550
16.5 Usage Notes....................................................................................................................... 551
Section 17 IrDA .................................................................................................................... 555
17.1 Overview ........................................................................................................................... 555
17.1.1 Features ................................................................................................................ 555
17.1.2 Block Diagram ..................................................................................................... 556
17.1.3 Pin Configuration ................................................................................................. 559
17.1.4 Register Configuration ......................................................................................... 560
17.2 Register Description .......................................................................................................... 561
17.2.1 Serial Mode Register (SCSMR) ........................................................................... 561
17.3 Operation Description ....................................................................................................... 563
17.3.1 Overview .............................................................................................................. 563
17.3.2 Transmitting ......................................................................................................... 563
17.3.3 Receiving.............................................................................................................. 564
Section 18 Pin Function Controller ................................................................................ 565
18.1 Overview ........................................................................................................................... 565
18.2 Register Configuration ...................................................................................................... 569
18.3 Register Descriptions......................................................................................................... 570
Rev. 5.00, 09/03, page xxvi of xliv
18.3.1 Port A Control Register (PACR).......................................................................... 570
18.3.2 Port B Control Register (PBCR) .......................................................................... 571
18.3.3 Port C Control Register (PCCR) .......................................................................... 572
18.3.4 Port D Control Register (PDCR) .......................................................................... 573
18.3.5 Port E Control Register (PECR)........................................................................... 574
18.3.6 Port F Control Register (PFCR) ........................................................................... 575
18.3.7 Port G Control Register (PGCR) .......................................................................... 576
18.3.8 Port H Control Register (PHCR) .......................................................................... 577
18.3.9 Port J Control Register (PJCR) ............................................................................ 579
18.3.10 Port K Control Register (PKCR) .......................................................................... 580
18.3.11 Port L Control Register (PLCR)........................................................................... 581
18.3.12 SC Port Control Register (SCPCR) ...................................................................... 582
Section 19 I/O Ports ............................................................................................................ 587
19.1 Overview ........................................................................................................................... 587
19.2 Port A ................................................................................................................................ 587
19.2.1 Register Description ............................................................................................. 587
19.2.2 Port A Data Register (PADR) .............................................................................. 588
19.3 Port B ................................................................................................................................ 589
19.3.1 Register Description ............................................................................................. 589
19.3.2 Port B Data Register (PBDR)............................................................................... 590
19.4 Port C ................................................................................................................................ 591
19.4.1 Register Description ............................................................................................. 591
19.4.2 Port C Data Register (PCDR)............................................................................... 592
19.5 Port D ................................................................................................................................ 593
19.5.1 Register Description ............................................................................................. 593
19.5.2 Port D Data Register (PDDR) .............................................................................. 594
19.6 Port E................................................................................................................................. 595
19.6.1 Register Description ............................................................................................. 595
19.6.2 Port E Data Register (PEDR) ............................................................................... 596
19.7 Port F................................................................................................................................. 597
19.7.1 Register Description ............................................................................................. 597
19.7.2 Port F Data Register (PFDR)................................................................................ 598
19.8 Port G ................................................................................................................................ 599
19.8.1 Register Description ............................................................................................. 599
19.8.2 Port G Data Register (PGDR) .............................................................................. 600
19.9 Port H ................................................................................................................................ 601
19.9.1 Register Description ............................................................................................. 601
19.9.2 Port H Data Register (PHDR) .............................................................................. 602
19.10 Port J.................................................................................................................................. 603
19.10.1 Register Description ............................................................................................. 603
19.10.2 Port J Data Register (PJDR)................................................................................. 604
19.11 Port K ................................................................................................................................ 605
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19.11.1 Register Description ............................................................................................. 605
19.11.2 Port K Data Register (PKDR) .............................................................................. 606
19.12 Port L................................................................................................................................. 607
19.12.1 Register Description ............................................................................................. 607
19.12.2 Port L Data Register (PLDR) ............................................................................... 608
19.13 SC Port .............................................................................................................................. 609
19.13.1 Register Description ............................................................................................. 609
19.13.2 SC Port Data Register (SCPDR) .......................................................................... 610
Section 20 A/D Converter ................................................................................................. 613
20.1 Overview ........................................................................................................................... 613
20.1.1 Features ................................................................................................................ 613
20.1.2 Block Diagram ..................................................................................................... 614
20.1.3 Input Pins.............................................................................................................. 615
20.1.4 Register Configuration ......................................................................................... 616
20.2 Register Descriptions......................................................................................................... 617
20.2.1 A/D Data Registers A to D (ADDRA to ADDRD) .............................................. 617
20.2.2 A/D Control/Status Register (ADCSR) ................................................................ 618
20.2.3 A/D Control Register (ADCR)............................................................................. 621
20.3 Bus Master Interface.......................................................................................................... 622
20.4 Operation........................................................................................................................... 623
20.4.1 Single Mode (MULTI = 0)................................................................................... 623
20.4.2 Multi Mode (MULTI = 1, SCN = 0) .................................................................... 625
20.4.3 Scan Mode (MULTI = 1, SCN = 1) ..................................................................... 627
20.4.4 Input Sampling and A/D Conversion Time .......................................................... 629
20.4.5 External Trigger Input Timing ............................................................................. 630
20.5 Interrupts ........................................................................................................................... 631
20.6 Definitions of A/D Conversion Accuracy ......................................................................... 631
20.7 Usage Notes....................................................................................................................... 632
20.7.1 Setting Analog Input Voltage ............................................................................... 632
20.7.2 Processing of Analog Input Pins .......................................................................... 632
20.7.3 Access Size and Read Data .................................................................................. 633
Section 21 D/A Converter ................................................................................................. 635
21.1 Overview ........................................................................................................................... 635
21.1.1 Features ................................................................................................................ 635
21.1.2 Block Diagram ..................................................................................................... 635
21.1.3 I/O Pins................................................................................................................. 636
21.1.4 Register Configuration ......................................................................................... 636
21.2 Register Descriptions......................................................................................................... 637
21.2.1 D/A Data Registers 0 and 1 (DADR0/1) .............................................................. 637
21.2.2 D/A Control Register (DACR)............................................................................. 637
21.3 Operation........................................................................................................................... 639
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Section 22 User Debugging Interface (UDI) ............................................................... 641
22.1 Overview ........................................................................................................................... 641
22.2 User Debugging Interface (UDI) ....................................................................................... 641
22.2.1 Pin Descriptions ................................................................................................... 641
22.2.2 Block Diagram ..................................................................................................... 642
22.3 Register Descriptions......................................................................................................... 642
22.3.1 Bypass Register (SDBPR).................................................................................... 643
22.3.2 Instruction Register (SDIR).................................................................................. 643
22.3.3 Boundary Scan Register (SDBSR) ....................................................................... 644
22.4 UDI Operation................................................................................................................... 651
22.4.1 TAP Controller..................................................................................................... 651
22.4.2 Reset Configuration.............................................................................................. 652
22.4.3 UDI Reset............................................................................................................. 653
22.4.4 UDI Interrupt........................................................................................................ 653
22.4.5 Bypass .................................................................................................................. 653
22.4.6 Using UDI to Recover from Sleep Mode ............................................................. 653
22.5 Boundary Scan .................................................................................................................. 654
22.5.1 Supported Instructions.......................................................................................... 654
22.5.2 Points for Attention .............................................................................................. 655
22.6 Usage Notes....................................................................................................................... 655
22.7 Advanced User Debugger (AUD) ..................................................................................... 655
Section 23 Electrical Characteristics .............................................................................. 657
23.1 Absolute Maximum Ratings.............................................................................................. 657
23.2 DC Characteristics............................................................................................................. 659
23.3 AC Characteristics............................................................................................................. 663
23.3.1 Clock Timing........................................................................................................ 664
23.3.2 Control Signal Timing.......................................................................................... 670
23.3.3 AC Bus Timing .................................................................................................... 673
23.3.4 Basic Timing ........................................................................................................ 675
23.3.5 Burst ROM Timing .............................................................................................. 678
23.3.6 Synchronous DRAM Timing ............................................................................... 681
23.3.7 PCMCIA Timing.................................................................................................. 699
23.3.8 Peripheral Module Signal Timing ........................................................................ 706
23.3.9 UDI-Related Pin Timing ...................................................................................... 709
23.3.10 AC Characteristics Measurement Conditions....................................................... 711
23.3.11 Delay Time Variation Due to Load Capacitance.................................................. 712
23.4 A/D Converter Characteristics........................................................................................... 713
23.5 D/A Converter Characteristics........................................................................................... 713
Appendix A Pin Functions ................................................................................................ 715
A.1
A.2
Pin States ........................................................................................................................... 715
Pin Specifications .............................................................................................................. 719
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A.3
A.4
Treatment of Unused Pins ................................................................................................. 724
Pin States in Access to Each Address Space ..................................................................... 725
Appendix B Memory-Mapped Control Registers....................................................... 739
B.1
B.2
Register Address Map ....................................................................................................... 739
Register Bits ...................................................................................................................... 745
Appendix C Product Lineup ............................................................................................. 757
Appendix D Package Dimensions ................................................................................... 758
Rev. 5.00, 09/03, page xxx of xliv
Figures
Figure 1.1
Figure 1.2
Figure 1.3
Figure 2.1
Figure 2.2
Figure 2.3
Figure 2.4
Figure 2.5
Figure 2.6
Figure 2.7
Figure 2.8
Figure 3.1
Figure 3.2
Figure 3.3
Figure 3.4
Figure 3.5
Figure 3.6
Figure 3.7
Figure 3.8
Figure 3.9
Figure 3.10
Figure 3.11
Figure 3.12
Figure 3.13
Figure 3.14
Figure 4.1
Figure 4.2
Figure 4.3
Figure 5.1
Figure 5.2
Figure 5.3
Figure 5.4
Figure 5.5
Figure 5.6
Figure 6.1
Figure 6.2
Figure 6.3
Figure 6.4
Figure 7.1
Figure 8.1
Figure 8.2
Block Diagram ..................................................................................................... 6
Pin Assignment (FP-208C, FP-208E) .................................................................. 7
Pin Assignment (BP-240A).................................................................................. 8
User Mode Register Configuration ...................................................................... 20
Privileged Mode Register Configuration.............................................................. 21
General Registers ................................................................................................. 22
System Registers .................................................................................................. 23
Register Set Overview, Control Registers ............................................................ 24
Longword ............................................................................................................. 25
Data Format in Memory ....................................................................................... 25
Processor State Transitions................................................................................... 54
MMU Functions ................................................................................................... 57
Virtual Address Space Mapping........................................................................... 59
MMU Register Contents ...................................................................................... 62
Overall Configuration of the TLB ........................................................................ 63
Virtual Address and TLB Structure...................................................................... 64
TLB Indexing (IX = 1) ......................................................................................... 65
TLB Indexing (IX = 0) ......................................................................................... 66
Objects of Address Comparison ........................................................................... 67
Operation of LDTLB Instruction.......................................................................... 71
Synonym Problem ................................................................................................ 73
MMU Exception Generation Flowchart ............................................................... 78
MMU Exception Signals in Instruction Fetch ...................................................... 79
MMU Exception Signals in Data Access ............................................................. 80
Specifying Address and Data for Memory-Mapped TLB Access ........................ 82
Vector Table......................................................................................................... 86
Example of Acceptance Order of General Exceptions ......................................... 89
Bit Configurations of EXPEVT, INTEVT, INTEVT2, and TRA Registers......... 92
Cache Structure .................................................................................................... 104
CCR Register Configuration ................................................................................ 106
CCR2 Register Configuration .............................................................................. 107
Cache Search Scheme (Normal Mode) ................................................................ 110
Write-Back Buffer Configuration......................................................................... 112
Specifying Address and Data for Memory-Mapped Cache Access...................... 114
Block Diagram of INTC....................................................................................... 118
Example of IRL Interrupt Connection.................................................................. 122
Interrupt Operation Flowchart .............................................................................. 144
Example of Pipeline Operations when IRL Interrupt is Accepted ....................... 148
Block Diagram of User Break Controller............................................................. 150
Canceling Standby Mode with STBCR.STBY..................................................... 189
Power-On Reset (Clock Modes 0, 1, 2, and 7) STATUS Output ......................... 192
Rev. 5.00, 09/03, page xxxi of xliv
Figure 8.3
Figure 8.4
Figure 8.5
Figure 8.6
Figure 8.7
Figure 8.8
Figure 8.9
Figure 8.10
Figure 8.11
Figure 9.1
Figure 9.2
Figure 9.3
Figure 9.4
Figure 9.5
Figure 10.1
Figure 10.2
Figure 10.3
Figure 10.4
Figure 10.5
Figure 10.6
Figure 10.7
Figure 10.8
Figure 10.9
Figure 10.10
Figure 10.11
Figure 10.12
Figure 10.13
Figure 10.14
Figure 10.15
Figure 10.16
Figure 10.17
Figure 10.18
Figure 10.19
Figure 10.20
Figure 10.21
Figure 10.22
Figure 10.23
Figure 10.24
Figure 10.25
Figure 10.26
Figure 10.27
Manual Reset STATUS Output............................................................................ 193
Standby to Interrupt STATUS Output.................................................................. 194
Standby to Power-On Reset STATUS Output...................................................... 195
Standby to Manual Reset STATUS Output.......................................................... 196
Sleep to Interrupt STATUS Output ...................................................................... 196
Sleep to Power-On Reset STATUS Output.......................................................... 197
Sleep to Manual Reset STATUS Output.............................................................. 198
Hardware Standby Mode (When CA Goes Low in Normal Operation)............... 200
Hardware Standby Mode Timing (When CA Goes Low during WDT Operation
on Standby Mode Cancellation) ........................................................................... 201
Block Diagram of Clock Pulse Generator ............................................................ 204
Block Diagram of WDT ....................................................................................... 214
Writing to WTCNT and WTCSR......................................................................... 217
Points for Attention when Using Crystal Resonator............................................. 220
Points for Attention when Using PLL Oscillator Circuit ..................................... 221
Block Diagram of Bus State Controller................................................................ 225
Correspondence between Logical Address Space and Physical Address Space .. 229
Physical Space Allocation .................................................................................... 231
PCMCIA Space Allocation .................................................................................. 232
Writing to RFCR, RTCSR, RTCNT, and RTCOR............................................... 257
Basic Timing of Basic Interface ........................................................................... 269
Example of 32-Bit Data-Width Static RAM Connection ..................................... 270
Example of 16-Bit Data-Width Static RAM Connection ..................................... 271
Example of 8-Bit Data-Width Static RAM Connection ....................................... 272
Basic Interface Wait Timing (Software Wait Only)............................................. 273
Basic Interface Wait State Timing (Wait State Insertion by WAIT Signal
WAITSEL = 1)..................................................................................................... 275
Example of 64-Mbit Synchronous DRAM Connection (32-Bit Bus Width)........ 277
Example of 64-Mbit Synchronous DRAM Connection (16-Bit Bus Width)........ 278
Basic Timing for Synchronous DRAM Burst Read ............................................. 282
Synchronous DRAM Burst Read Wait Specification Timing .............................. 283
Basic Timing for Synchronous DRAM Single Read............................................ 284
Basic Timing for Synchronous DRAM Burst Write ............................................ 286
Basic Timing for Synchronous DRAM Single Write........................................... 288
Burst Read Timing (No Precharge) ...................................................................... 291
Burst Read Timing (Same Row Address) ............................................................ 292
Burst Read Timing (Different Row Addresses) ................................................... 293
Burst Write Timing (No Precharge) ..................................................................... 294
Burst Write Timing (Same Row Address) ........................................................... 295
Burst Write Timing (Different Row Addresses) .................................................. 296
Auto-Refresh Operation ....................................................................................... 298
Synchronous DRAM Auto-Refresh Timing......................................................... 299
Synchronous DRAM Self-Refresh Timing .......................................................... 301
Rev. 5.00, 09/03, page xxxii of xliv
Figure 10.28
Figure 10.29
Figure 10.30
Figure 10.31
Figure 10.32
Figure 10.33
Figure 10.34
Figure 10.35
Figure 10.36
Figure 10.37
Figure 10.38
Figure 10.39
Figure 10.40
Figure 10.41
Figure 10.42
Figure 10.43
Figure 11.1
Figure 11.2
Figure 11.3
Figure 11.4
Figure 11.5
Figure 11.6
Figure 11.7
Figure 11.8
Figure 11.9
Figure 11.10
Figure 11.11
Figure 11.12
Figure 11.13
Figure 11.14
Figure 11.15
Figure 11.16
Figure 11.17
Figure 11.18
Figure 11.19
Figure 11.20
Figure 11.21
Figure 11.22
Synchronous DRAM Mode Write Timing ........................................................... 303
Burst ROM Wait Access Timing ......................................................................... 305
Burst ROM Basic Access Timing ........................................................................ 306
Example of PCMCIA Interface ............................................................................ 308
Basic Timing for PCMCIA Memory Card Interface ............................................ 310
Wait Timing for PCMCIA Memory Card Interface ............................................. 311
Basic Timing for PCMCIA Memory Card Interface Burst Access ...................... 312
Wait Timing for PCMCIA Memory Card Interface Burst Access ....................... 313
PCMCIA Space Allocation .................................................................................. 314
Basic Timing for PCMCIA I/O Card Interface .................................................... 316
Wait Timing for PCMCIA I/O Card Interface ..................................................... 317
Dynamic Bus Sizing Timing for PCMCIA I/O Card Interface ............................ 318
Waits between Access Cycles .............................................................................. 320
Pull-Up Timing for Pins A25 to A0 ..................................................................... 321
Pull-Up Timing for Pins D31 to D0 (Read Cycle) ............................................... 322
Pull-Up Timing for Pins D31 to D0 (Write Cycle) .............................................. 322
Block Diagram of DMAC .................................................................................... 329
DMAC Transfer Flowchart .................................................................................. 346
Round-Robin Mode.............................................................................................. 350
Changes in Channel Priority in Round-Robin Mode............................................ 351
Operation of Direct Address Mode in Dual Address Mode ................................. 353
Example of DMA Transfer Timing in the Direct Address Mode in Dual Mode
(Transfer Source: Ordinary Memory, Transfer Destination: Ordinary Memory). 354
Indirect Address Operation in Dual Address Mode (When External Memory
Space has a 16-Bit Width).................................................................................... 355
Example of Transfer Timing in the Indirect Address Mode in Dual Address
Mode .................................................................................................................... 356
Data Flow in Single Address Mode...................................................................... 357
Example of DMA Transfer Timing in Single Address Mode .............................. 358
Example of DMA Transfer Timing in Single Address Mode (16-byte Transfer,
External Memory Space (Ordinary Memory) → External Device with DACK) . 359
Example of DMA Transfer in Cycle-Steal Mode................................................. 360
Example of Transfer in Burst Mode ..................................................................... 360
Bus State when Multiple Channels Are Operating............................................... 362
Cycle-Steal Mode, Level Input (CPU Access: 2 Cycles) ..................................... 365
Cycle-Steal Mode, Level Input (CPU Access: 3 Cycles) ..................................... 366
Cycle-Steal Mode, Level input (CPU Access: 2 Cycles, DMA RD Access:
4 Cycles)............................................................................................................... 367
Cycle-Steal Mode, Level input (CPU Access: 2 Cycles, DREQ Input Delayed) . 368
Cycle-Steal Mode, Edge input (CPU Access: 2 Cycles) ...................................... 369
Burst Mode, Level Input ...................................................................................... 370
Burst Mode, Edge Input ....................................................................................... 371
Source Address Reload Function Diagram........................................................... 372
Rev. 5.00, 09/03, page xxxiii of xliv
Figure 11.23
Figure 11.24
Figure 11.25
Figure 11.26
Figure 11.27
Figure 11.28
Figure 12.1
Figure 12.2
Figure 12.3
Figure 12.4
Figure 12.5
Figure 12.6
Figure 12.7
Figure 12.8
Figure 12.9
Figure 13.1
Figure 13.2
Figure 13.3
Figure 13.4
Figure 13.5
Figure 13.6
Figure 14.1
Figure 14.2
Figure 14.3
Figure 14.4
Figure 14.5
Figure 14.6
Figure 14.7
Figure 14.8
Figure 14.9
Figure 14.10
Figure 14.11
Figure 14.12
Figure 14.13
Figure 14.14
Figure 14.15
Figure 14.16
Timing Chart of Source Address Reload Function............................................... 373
Block Diagram of CMT ....................................................................................... 376
Counter Operation ................................................................................................ 380
Count Timing ....................................................................................................... 381
CMF Setting Timing ............................................................................................ 382
Timing of CMF Clearing by the CPU .................................................................. 382
Block Diagram of TMU ....................................................................................... 390
Setting the Count Operation ................................................................................. 401
Auto-Reload Count Operation.............................................................................. 402
Count Timing when Operating on Internal Clock ................................................ 402
Count Timing when Operating on External Clock (Both Edges Detected) .......... 403
Count Timing when Operating on On-Chip RTC Clock ...................................... 403
Operation Timing when Using Input Capture Function (Using TCLK Rising
Edge) .................................................................................................................... 404
UNF Setting Timing............................................................................................. 404
Status Flag Clearing Timing................................................................................. 405
Block Diagram of RTC ........................................................................................ 408
Setting the Time ................................................................................................... 422
Reading the Time ................................................................................................. 423
Using the Alarm Function .................................................................................... 424
Example of Crystal Oscillator Circuit Connection............................................... 425
Using Periodic Interrupt Function ........................................................................ 426
Block Diagram of SCI .......................................................................................... 428
SCPT[1]/SCK0 Pin .............................................................................................. 429
SCPT[0]/TxD0 Pin............................................................................................... 430
SCPT[0]/RxD0 Pin............................................................................................... 431
Example of Data Format in Asynchronous Communication (8-Bit Data
with Parity and Two Stop Bits) ............................................................................ 455
Output Clock and Serial Data Timing (Asynchronous Mode) ............................. 457
Sample Flowchart for SCI Initialization............................................................... 458
Sample Flowchart for Transmitting Serial Data ................................................... 459
Example of SCI Transmit Operation in Asynchronous Mode (8-Bit Data
with Parity and One Stop Bit) .............................................................................. 461
Sample Flowchart for Receiving Serial Data ....................................................... 462
Example of SCI Receive Operation (8-Bit Data with Parity and One Stop Bit) .. 465
Communication Among Processors Using Multiprocessor Format
(Sending Data H'AA to Receiving Processor A) .................................................. 466
Sample Flowchart for Transmitting Multiprocessor Serial Data .......................... 467
Example of SCI Multiprocessor Transmit Operation (8-Bit Data with
Multiprocessor Bit and One Stop Bit) .................................................................. 468
Sample Flowchart for Receiving Multiprocessor Serial Data .............................. 470
Example of SCI Receive Operation (8-Bit Data with Multiprocessor Bit and
One Stop Bit)........................................................................................................ 472
Rev. 5.00, 09/03, page xxxiv of xliv
Figure 14.17
Figure 14.18
Figure 14.19
Figure 14.20
Figure 14.21
Figure 14.22
Figure 14.23
Figure 14.24
Figure 15.1
Figure 15.2
Figure 15.3
Figure 15.4
Figure 15.5
Figure 15.6
Figure 15.7
Figure 15.8
Figure 15.9
Figure 15.10
Figure 16.1
Figure 16.2
Figure 16.3
Figure 16.4
Figure 16.5
Figure 16.6
Figure 16.7
Figure 16.8
Figure 16.9
Figure 16.10
Figure 16.11
Figure 16.12
Figure 16.13
Figure 17.1
Figure 17.2
Figure 17.3
Figure 17.4
Figure 17.5
Figure 19.1
Figure 19.2
Figure 19.3
Figure 19.4
Figure 19.5
Figure 19.6
Figure 19.7
Data Format in Synchronous Communication ..................................................... 474
Sample Flowchart for SCI Initialization............................................................... 476
Sample Flowchart for Transmitting Serial Data ................................................... 477
Example of SCI Transmit Operation .................................................................... 478
Sample Flowchart for Receiving Serial Data ....................................................... 480
Example of SCI Receive Operation...................................................................... 482
Sample Flowchart for Transmitting/Receiving Serial Data.................................. 483
Receive Data Sampling Timing in Asynchronous Mode ..................................... 486
Block Diagram of Smart Card Interface............................................................... 490
Pin Connection Diagram for Smart Card Interface .............................................. 495
Data Format for Smart Card Interface.................................................................. 496
Waveform of Start Character................................................................................ 498
Initialization Flowchart (Example)....................................................................... 502
Transmission Flowchart ....................................................................................... 504
Reception Flowchart (Example)........................................................................... 506
Receive Data Sampling Timing in Smart Card Mode .......................................... 508
Retransmission in SCI Receive Mode .................................................................. 509
Retransmission in SCI Transmit Mode ................................................................ 510
Block Diagram of SCIF........................................................................................ 512
SCPT[5]/SCK2 Pin .............................................................................................. 513
SCPT[4]/TxD2 Pin............................................................................................... 514
SCPT[4]/RxD2 Pin............................................................................................... 515
Sample Flowchart for SCIF Initialization ............................................................ 540
Sample Flowchart for Transmitting Serial Data ................................................... 542
Example of Transmit Operation (8-Bit Data, Parity, One Stop Bit)..................... 544
Example of Operation Using Modem Control (CTS)........................................... 544
Sample Flowchart for Receiving Serial Data ....................................................... 546
Sample Flowchart for Receiving Serial Data (cont)............................................. 547
Example of SCIF Receive Operation (8-Bit Data, Parity, One Stop Bit)............. 549
Example of Operation Using Modem Control (RTS)........................................... 549
Receive Data Sampling Timing in Asynchronous Mode ..................................... 552
Block Diagram of IrDA........................................................................................ 556
SCPT[3]/SCK1 Pin .............................................................................................. 557
SCPT[2]/TxD1 Pin............................................................................................... 558
SCPT[2]/RxD1 Pin............................................................................................... 559
Transmit/Receive Operation................................................................................. 564
Port A ................................................................................................................... 587
Port B ................................................................................................................... 589
Port C ................................................................................................................... 591
Port D ................................................................................................................... 593
Port E.................................................................................................................... 595
Port F.................................................................................................................... 597
Port G ................................................................................................................... 599
Rev. 5.00, 09/03, page xxxv of xliv
Figure 19.8
Figure 19.9
Figure 19.10
Figure 19.11
Figure 19.12
Figure 20.1
Figure 20.2
Figure 20.3
Figure 20.4
Figure 20.5
Figure 20.6
Figure 20.7
Figure 20.8
Figure 20.9
Figure 20.10
Figure 21.1
Figure 21.2
Figure 22.1
Figure 22.2
Figure 22.3
Figure 23.1
Figure 23.2
Figure 23.3
Figure 23.4
Figure 23.5
Figure 23.6
Figure 23.7
Figure 23.8
Figure 23.9
Figure 23.10
Figure 23.11
Figure 23.12
Figure 23.13
Figure 23.14
Figure 23.15
Figure 23.16
Figure 23.17
Figure 23.18
Port H ................................................................................................................... 601
Port J .................................................................................................................... 603
Port K ................................................................................................................... 605
Port L.................................................................................................................... 607
SC Port ................................................................................................................. 609
Block Diagram of A/D Converter ........................................................................ 614
A/D Data Register Access Operation (Reading H'AA40) .................................... 622
Example of A/D Converter Operation (Single Mode, Channel 1 Selected) ......... 624
Example of A/D Converter Operation (Multi Mode, Channels AN0 to AN2
Selected) ............................................................................................................... 626
Example of A/D Converter Operation (Scan Mode, Channels AN0 to AN2
Selected) ............................................................................................................... 628
A/D Conversion Timing ....................................................................................... 629
External Trigger Input Timing ............................................................................. 630
Definitions of A/D Conversion Accuracy ............................................................ 632
Example of Analog Input Protection Circuit ........................................................ 633
Analog Input Pin Equivalent Circuit .................................................................... 633
Block Diagram of D/A Converter ........................................................................ 635
Example of D/A Converter Operation.................................................................. 639
Block Diagram of UDI ......................................................................................... 642
TAP Controller State Transitions ......................................................................... 651
UDI Reset............................................................................................................. 653
EXTAL Clock Input Timing ................................................................................ 665
CKIO Clock Input Timing ................................................................................... 665
CKIO Clock Output Timing................................................................................. 665
Power-on Oscillation Settling Time ..................................................................... 666
Oscillation Settling Time at Standby Return (Return by Reset)........................... 666
Oscillation Settling Time at Standby Return (Return by NMI)............................ 667
Oscillation Settling Time at Standby Return (Return by IRQ4 to IRQ0,
PINT0/1, IRL3 to IRL0)....................................................................................... 667
PLL Synchronization Settling Time during Standby Recovery (Reset or NMI) .. 668
PLL Synchronization Settling Time during Standby Recovery (IRQ/IRL or
PINT0/PINT1 Interrupt)....................................................................................... 668
PLL Synchronization Settling Time when Frequency Multiplication Rate
Modified ............................................................................................................... 669
Reset Input Timing............................................................................................... 671
Interrupt Signal Input Timing............................................................................... 671
IRQOUT Timing .................................................................................................. 671
Bus Release Timing.............................................................................................. 672
Pin Drive Timing at Standby................................................................................ 672
Basic Bus Cycle (No Wait) .................................................................................. 675
Basic Bus Cycle (One Wait)................................................................................. 676
Basic Bus Cycle (External Wait, WAITSEL = 1) ................................................ 677
Rev. 5.00, 09/03, page xxxvi of xliv
Figure 23.19
Figure 23.20
Figure 23.21
Figure 23.22
Figure 23.23
Figure 23.24
Figure 23.25
Figure 23.26
Figure 23.27
Figure 23.28
Figure 23.29
Figure 23.30
Figure 23.31
Figure 23.32
Figure 23.33
Figure 23.34
Figure 23.35
Figure 23.36
Figure 23.37
Figure 23.38
Figure 23.39
Figure 23.40
Figure 23.41
Figure 23.42
Figure 23.43
Figure 23.44
Figure 23.45
Figure 23.46
Burst ROM Bus Cycle (No Wait) ........................................................................ 678
Burst ROM Bus Cycle (Two Waits) .................................................................... 679
Burst ROM Bus Cycle (External Wait, WAITSEL = 1) ...................................... 680
Synchronous DRAM Read Bus Cycle (RCD = 0, CAS Latency = 1, TPC = 0) .. 681
Synchronous DRAM Read Bus Cycle (RCD = 2, CAS Latency = 2, TPC = 1) .. 682
Synchronous DRAM Read Bus Cycle (Burst Read (Single Read × 4),
RCD = 0, CAS Latency = 1, TPC = 1) ................................................................. 683
Synchronous DRAM Read Bus Cycle (Burst Read (Single Read × 4),
RCD = 1, CAS Latency = 3, TPC = 0) ................................................................. 684
Synchronous DRAM Write Bus Cycle (RCD = 0, TPC = 0, TRWL = 0)............ 685
Synchronous DRAM Write Bus Cycle (RCD = 2, TPC = 1, TRWL = 1)............ 686
Synchronous DRAM Write Bus Cycle (Burst Mode (Single Write × 4),
RCD = 0, TPC = 1, TRWL = 0) ........................................................................... 687
Synchronous DRAM Write Bus Cycle (Burst Mode (Single Write × 4),
RCD = 1, TPC = 0, TRWL = 0) ........................................................................... 688
Synchronous DRAM Burst Read Bus Cycle (RAS Down, Same Row
Address, CAS Latency = 1).................................................................................. 689
Synchronous DRAM Burst Read Bus Cycle (RAS Down, Same Row
Address, CAS Latency = 2).................................................................................. 690
Synchronous DRAM Burst Read Bus Cycle (RAS Down, Different Row
Address, TPC = 0, RCD = 0, CAS Latency = 1) .................................................. 691
Synchronous DRAM Burst Read Bus Cycle (RAS Down, Different Row
Address, TPC = 1, RCD = 0, CAS Latency = 1) .................................................. 692
Synchronous DRAM Burst Write Bus Cycle (RAS Down, Same Row
Address) ............................................................................................................... 693
Synchronous DRAM Burst Write Bus Cycle (RAS Down, Different Row
Address, TPC = 0, RCD = 0) ............................................................................... 694
Synchronous DRAM Burst Write Bus Cycle (RAS Down, Different Row
Address, TPC = 1, RCD = 1) ............................................................................... 695
Synchronous DRAM Auto-Refresh Timing (TRAS = 1, TPC = 1) ..................... 696
Synchronous DRAM Self-Refresh Cycle (TRAS = 1, TPC = 1) ......................... 697
Synchronous DRAM Mode Register Write Cycle ............................................... 698
PCMCIA Memory Bus Cycle (TED = 0, TEH = 0, No Wait) ............................. 699
PCMCIA Memory Bus Cycle (TED = 2, TEH = 1, One Wait, External Wait,
WAITSEL = 1)..................................................................................................... 700
PCMCIA Memory Bus Cycle (Burst Read, TED = 0, TEH = 0, No Wait).......... 701
PCMCIA Memory Bus Cycle (Burst Read, TED = 1, TEH = 1, Two Waits,
Burst Pitch = 3, WAITSEL = 1)........................................................................... 702
PCMCIA I/O Bus Cycle (TED = 0, TEH = 0, No Wait)...................................... 703
PCMCIA I/O Bus Cycle (TED = 2, TEH = 1, One Wait, External Wait,
WAITSEL = 1)..................................................................................................... 704
PCMCIA I/O Bus Cycle (TED = 1, TEH = 1, One Wait, Bus Sizing,
WAITSEL = 1)..................................................................................................... 705
Rev. 5.00, 09/03, page xxxvii of xliv
Figure 23.47
Figure 23.48
Figure 23.49
Figure 23.50
Figure 23.51
Figure 23.52
Figure 23.53
Figure 23.54
Figure 23.55
Figure 23.56
Figure 23.57
Figure 23.58
Figure 23.59
Figure 23.60
Figure D.1
Figure D.2
Figure D.3
TCLK Input Timing ............................................................................................. 707
TCLK Clock Input Timing................................................................................... 707
Oscillation Settling Time at RTC Crystal Oscillator Power-on............................ 707
SCK Input Clock Timing ..................................................................................... 707
SCI I/O Timing in Clock Synchronous Mode ...................................................... 708
I/O Port Timing .................................................................................................... 708
DREQ Input Timing............................................................................................. 708
DRAK Output Timing.......................................................................................... 709
TCK Input Timing................................................................................................ 709
TRST Input Timing (Reset Hold)......................................................................... 710
UDI Data Transfer Timing ................................................................................... 710
ASEMD0 Input Timing........................................................................................ 710
Output Load Circuit.............................................................................................. 711
Load Capacitance vs. Delay Time........................................................................ 712
Package Dimensions (FP-208C)........................................................................... 758
Package Dimensions (FP-208E)........................................................................... 759
Package Dimensions (BP-240A).......................................................................... 760
Rev. 5.00, 09/03, page xxxviii of xliv
Tables
Table 1.1
Table 1.2
Table 1.3
Table 2.1
Table 2.2
Table 2.3
Table 2.4
Table 2.5
Table 2.6
Table 2.7
Table 2.8
Table 2.9
Table 2.10
Table 2.11
Table 2.12
Table 3.1
Table 3.2
Table 4.1
Table 4.2
Table 4.3
Table 4.4
Table 5.1
Table 5.2
Table 5.3
Table 5.4
Table 5.5
Table 5.6
Table 5.7
Table 5.8
Table 6.1
Table 6.2
Table 6.3
Table 6.4
Table 6.5
Table 6.6
Table 6.7
Table 6.8
Table 7.1
Table 7.2
Table 8.1
SH7709S Features .................................................................................................. 2
Characteristics......................................................................................................... 5
SH7709S Pin Function ........................................................................................... 9
Initial Register Values ............................................................................................ 22
Addressing Modes and Effective Addresses........................................................... 28
Instruction Formats ................................................................................................. 32
Classification of Instructions .................................................................................. 35
Instruction Code Format ......................................................................................... 38
Data Transfer Instructions ...................................................................................... 39
Arithmetic Instructions ........................................................................................... 41
Logic Operation Instructions .................................................................................. 44
Shift Instructions..................................................................................................... 45
Branch Instructions ................................................................................................. 46
System Control Instructions.................................................................................... 47
Instruction Code Map ............................................................................................. 50
Register Configuration............................................................................................ 61
Access States Designated by D, C, and PR Bits ..................................................... 68
Register Configuration............................................................................................ 85
Exception Event Vectors ........................................................................................ 87
Exception Codes ..................................................................................................... 90
Types of Reset ........................................................................................................ 95
Cache Specifications............................................................................................... 103
LRU and Way Replacement (When the cache lock function is not used) .............. 105
Register Configuration............................................................................................ 105
Way Replacement when PREF Instruction Ended Up in a Cache Miss ................. 107
Way Replacement when Instructions Except for PREF Instruction Ended Up
in a Cache Miss....................................................................................................... 108
LRU and Way Replacement (when W2LOCK=1) ................................................. 108
LRU and Way Replacement (when W3LOCK=1) ................................................. 108
LRU and Way Replacement (when W2LOCK=1 and W3LOCK=1)..................... 108
INTC Pins ............................................................................................................... 119
INTC Registers ....................................................................................................... 120
IRL3–IRL0/IRLS3–IRLS0 Pins and Interrupt Levels ............................................ 123
Interrupt Exception Handling Sources and Priority (IRQ Mode) ........................... 126
Interrupt Exception Handling Sources and Priority (IRL Mode)............................ 128
Interrupt Levels and INTEVT Codes...................................................................... 130
Interrupt Request Sources and IPRA–IPRE............................................................ 131
Interrupt Response Time......................................................................................... 146
Register Configuration............................................................................................ 151
Data Access Cycle Addresses and Operand Size Comparison Conditions............. 171
Power-Down Modes ............................................................................................... 182
Rev. 5.00, 09/03, page xxxix of xliv
Table 8.2
Table 8.3
Table 8.4
Table 9.1
Table 9.2
Table 9.3
Table 9.4
Table 9.5
Table 10.1
Table 10.2
Table 10.3
Table 10.4
Table 10.5
Table 10.6
Table 10.7
Table 10.8
Table 10.9
Table 10.10
Table 10.11
Table 10.12
Table 10.13
Table 10.14
Pin Configuration.................................................................................................... 183
Register Configuration............................................................................................ 183
Register States in Standby Mode ............................................................................ 188
CPG Pins and Functions ......................................................................................... 206
CPG Register .......................................................................................................... 206
Clock Operating Modes .......................................................................................... 207
Available Combinations of Clock Mode and FRQCR Values................................ 208
Register Configuration............................................................................................ 214
BSC Pins................................................................................................................. 226
BSC Registers......................................................................................................... 228
Physical Address Space Map.................................................................................. 230
Correspondence between External Pins (MD4 and MD3) and Memory Size......... 231
PCMCIA Interface Characteristics ......................................................................... 232
PCMCIA Support Interface .................................................................................... 233
32-Bit External Device/Big-Endian Access and Data Alignment .......................... 260
16-Bit External Device/Big-Endian Access and Data Alignment .......................... 261
8-Bit External Device/Big-Endian Access and Data Alignment ............................ 262
32-Bit External Device/Little-Endian Access and Data Alignment........................ 263
16-Bit External Device/Little-Endian Access and Data Alignment........................ 263
8-Bit External Device/Little-Endian Access and Data Alignment.......................... 264
Relationship between Bus Width, AMX Bits, and Address Multiplex Output ....... 279
Example of Correspondence between SH7709S and Synchronous DRAM
Address Pins (AMX [3:0] = 0100 (32-Bit Bus Width)).......................................... 281
Table 10.15 MCSCRx Settings and MCS[x] Assertion Conditions (x: 0–7).............................. 324
Table 11.1 DMAC Pins ............................................................................................................ 330
Table 11.2 DMAC Registers .................................................................................................... 331
Table 11.3 Selecting External Request Modes with RS Bits .................................................... 347
Table 11.4 Selecting On-Chip Peripheral Module Request Modes with RS3-0 Bits................ 348
Table 11.5 Supported DMA Transfers...................................................................................... 352
Table 11.6 Relationship between Request Modes and Bus Modes by DMA Transfer
Category ................................................................................................................. 361
Table 11.7 Register Configuration............................................................................................ 377
Table 11.8 Transfer Conditions and Register Settings for Transfer between On-Chip SCI
and External Memory ............................................................................................. 383
Table 11.9 Transfer Conditions and Register Settings for Transfer between On-Chip A/D
Converter and External Memory ............................................................................ 384
Table 11.10 Values in DMAC after End of Fourth Transfer ...................................................... 385
Table 11.11 Transfer Conditions and Register Settings for Transfer between External
Memory and SCIF Transmitter............................................................................... 386
Table 12.1 TMU Pin................................................................................................................. 391
Table 12.2 TMU Registers........................................................................................................ 391
Table 12.3 TMU Interrupt Sources........................................................................................... 405
Table 13.1 RTC Pins................................................................................................................. 409
Rev. 5.00, 09/03, page xl of xliv
Table 13.2
Table 13.3
Table 13.4
Table 13.5
Table 14.1
Table 14.2
Table 14.3
Table 14.4
Table 14.5
Table 14.6
Table 14.7
Table 14.8
Table 14.9
Table 14.10
Table 14.11
Table 14.12
Table 14.13
Table 14.14
Table 15.1
Table 15.2
Table 15.3
Table 15.4
Table 15.5
Table 15.6
Table 15.7
Table 15.8
Table 15.9
Table 16.1
Table 16.2
Table 16.3
Table 16.4
Table 16.5
Table 16.6
Table 16.7
Table 16.8
Table 16.9
Table 16.10
Table 17.1
Table 17.2
Table 18.1
Table 18.2
RTC Registers......................................................................................................... 410
Day-of-Week Codes (RWKCNT) .......................................................................... 413
Day-of-Week Codes (RWKAR) ............................................................................. 417
Recommended Oscillator Circuit Constants (Recommended Values).................... 425
SCI Pins ................................................................................................................. 431
SCI Registers .......................................................................................................... 432
SCSMR Settings ..................................................................................................... 446
Bit Rates and SCBRR Settings in Asynchronous Mode ......................................... 447
Bit Rates and SCBRR Settings in Synchronous Mode ........................................... 450
Maximum Bit Rates for Various Frequencies with Baud Rate Generator
(Asynchronous Mode) ............................................................................................ 451
Maximum Bit Rates with External Clock Input (Asynchronous Mode)................. 452
Maximum Bit Rates with External Clock Input (Synchronous Mode) ................... 452
Serial Mode Register Settings and SCI Communication Formats .......................... 454
SCSMR and SCSCR Settings and SCI Clock Source Selection ............................. 454
Serial Communication Formats (Asynchronous Mode) ......................................... 456
Receive Error Conditions and SCI Operation......................................................... 464
SCI Interrupt Sources ............................................................................................. 484
SCSSR Status Flags and Transfer of Receive Data ................................................ 485
Smart Card Interface Pins ....................................................................................... 491
Registers ................................................................................................................. 491
Register Settings for Smart Card Interface ............................................................. 497
Relationship of n to CKS1 and CKS0..................................................................... 499
Examples of Bit Rate B (Bits/s) for SCBRR Settings (n = 0)................................. 499
Examples of SCBRR Settings for Bit Rate B (Bits/s) (n = 0)................................. 499
Maximum Bit Rates for Frequencies (Smart Card Interface Mode) ....................... 500
Register Set Values and SCK Pin ........................................................................... 500
Smart Card Mode Operating State and Interrupt Sources....................................... 507
SCIF Pins................................................................................................................ 515
SCIF Registers ........................................................................................................ 516
SCSMR Settings ..................................................................................................... 528
Bit Rates and SCBRR Settings ............................................................................... 528
Maximum Bit Rates for Various Frequencies with Baud Rate Generator
(Asynchronous Mode) ............................................................................................ 532
Maximum Bit Rates with External Clock Input (Asynchronous Mode)................. 533
SCSMR Settings and SCIF Communication Formats ............................................ 537
SCSCR Settings and SCIF Clock Source Selection................................................ 538
Serial Communication Formats .............................................................................. 538
SCIF Interrupt Sources ........................................................................................... 550
IrDA Pins................................................................................................................ 559
IrDA Registers ........................................................................................................ 560
List of Multiplexed Pins ......................................................................................... 565
Pin Function Controller Registers........................................................................... 569
Rev. 5.00, 09/03, page xli of xliv
Table 19.1
Table 19.2
Table 19.3
Table 19.4
Table 19.5
Table 19.6
Table 19.7
Table 19.8
Table 19.9
Table 19.10
Table 19.11
Table 19.12
Table 19.13
Table 19.14
Table 19.15
Table 19.16
Table 19.17
Table 19.18
Table 19.19
Table 19.20
Table 19.21
Table 19.22
Table 19.23
Table 19.24
Table 20.1
Table 20.2
Table 20.3
Table 20.4
Table 20.5
Table 20.6
Table 21.1
Table 21.2
Table 22.1
Table 22.2
Table 22.3
Table 22.4
Table 23.1
Table 23.2
Table 23.3
Table 23.4
Table 23.5
Table 23.6
Table 23.7
Port A Register ....................................................................................................... 587
Port A Data Register (PADR) Read/Write Operations ........................................... 588
Port B Register........................................................................................................ 589
Port B Data Register (PBDR) Read/Write Operations ........................................... 590
Port C Register........................................................................................................ 591
Port C Data Register (PCDR) Read/Write Operations ........................................... 592
Port D Register ....................................................................................................... 593
Port D Data Register (PDDR) Read/Write Operations ........................................... 594
Port E Register........................................................................................................ 595
Port E Data Register (PEDR) Read/Write Operations ............................................ 596
Port F Register ........................................................................................................ 597
Port F Data Register (PFDR) Read/Write Operations ............................................ 598
Port G Register ....................................................................................................... 599
Port G Data Register (PGDR) Read/Write Operations ........................................... 600
Port H Register ....................................................................................................... 601
Port H Data Register (PHDR) Read/Write Operations ........................................... 602
Port J Register......................................................................................................... 603
Port J Data Register (PJDR) Read/Write Operations.............................................. 604
Port K Register ....................................................................................................... 605
Port K Data Register (PKDR) Read/Write Operations ........................................... 606
Port L Register ........................................................................................................ 607
Port L Data Register (PLDR) Read/Write Operation ............................................. 608
SC Port Register ..................................................................................................... 609
Read/Write Operation of the SC Port Data Register (SCPDR) .............................. 611
A/D Converter Pins................................................................................................. 615
A/D Converter Registers......................................................................................... 616
Analog Input Channels and A/D Data Registers .................................................... 617
A/D Conversion Time (Single Mode)..................................................................... 630
Analog Input Pin Ratings........................................................................................ 634
Relationship between Access Size and Read Data ................................................. 634
D/A Converter Pins................................................................................................. 636
D/A Converter Registers......................................................................................... 636
UDI Registers ......................................................................................................... 643
UDI Commands ...................................................................................................... 644
Pins of this LSI and Boundary Scan Register Bits.................................................. 645
Reset Configuration ................................................................................................ 652
Absolute Maximum Ratings ................................................................................... 657
DC Characteristics .................................................................................................. 659
Permitted Output Current Values............................................................................ 662
Operating Frequency Range ................................................................................... 663
Clock Timing .......................................................................................................... 664
Control Signal Timing ............................................................................................ 670
Bus Timing ............................................................................................................. 673
Rev. 5.00, 09/03, page xlii of xliv
Table 23.8
Table 23.9
Table 23.10
Table 23.11
Table A.1
Table A.2
Table A.3
Table A.4
Table A.5
Table A.6
Table A.7
Table A.8
Table A.9
Table A.10
Table B.1
Table B.2
Table C.1
Peripheral Module Signal Timing........................................................................... 706
UDI-Related Pin Timing......................................................................................... 709
A/D Converter Characteristics................................................................................ 713
D/A Converter Characteristics................................................................................ 713
Pin States during Resets, Power-Down States, and Bus-Released State................. 715
Pin Specifications ................................................................................................... 719
Pin States (Ordinary Memory/Little Endian).......................................................... 725
Pin States (Ordinary Memory/Big Endian)............................................................. 727
Pin States (Burst ROM/Little Endian) .................................................................... 729
Pin States (Burst ROM/Big Endian) ....................................................................... 731
Pin States (Synchronous DRAM/Little Endian) ..................................................... 733
Pin States (Synchronous DRAM/Big Endian) ........................................................ 734
Pin States (PCMCIA/Little Endian)........................................................................ 735
Pin States (PCMCIA/Big Endian) .......................................................................... 737
Memory-Mapped Control Registers ....................................................................... 739
Register Bits ........................................................................................................... 745
SH7709S Models.................................................................................................... 757
Rev. 5.00, 09/03, page xliii of xliv
Rev. 5.00, 09/03, page xliv of xliv
Section 1 Overview and Pin Functions
1.1
SH7709S Features
This LSI is a single-chip RISC microprocessor that integrates a Renesas Technology-original
RISC-type SuperHTM architecture CPU as its core that has an on-chip multiplier, cache memory,
and a memory management unit (MMU) as well as peripheral functions required for system
configuration such as a timer, a realtime clock, an interrupt controller, and a serial communication
interface. This LSI includes data protection, virtual memory, and other functions provided by
incorporating an MMU into a SuperH Series microprocessor (SH-1 or SH-2).
High-speed data transfers can be performed by an on-chip direct memory access controller
(DMAC) and an external memory access support function enables direct connection to different
types of memory. The SH7709S microprocessor also supports an infrared communication
function, an A/D converter, and a D/A converter.
A powerful built-in power management function keeps power consumption low, even during highspeed operation. This LSI can run at six times the frequency of the system bus operating speed,
making it optimum for electrical devices such as PDAs that require both high speed and low
power.
The features of this LSI is listed in table 1.1. The specifications are shown in table 1.2.
Note: SuperH is a trademark of Renesas Technology, Corp.
Rev. 5.00, 09/03, page 1 of 760
Table 1.1
SH7709S Features
Item
Features
CPU
•
Original Renesas Technology SuperH architecture
•
Object code level with SH-1, SH-2, and SH-3 Series
•
32-bit internal data bus
•
General-register files
 Sixteen 32-bit general registers (eight 32-bit shadow registers)
 Eight 32-bit control registers
 Four 32-bit system registers
•
RISC-type instruction set
 Instruction length: 16-bit fixed length for improved code efficiency
 Load-store architecture
 Delayed branch instructions
 Instruction set based on C language
Clock pulse
generator (CPG)
•
Instruction execution time: one instruction/cycle for basic instructions
•
Logical address space: 4 Gbytes
•
Space identifier ASID: 8 bits, 256 logical address space
•
Five-stage pipeline
•
Clock mode: An input clock can be selected from the external input (EXTAL
or CKIO) or crystal oscillator.
•
Three types of clocks generated:
 CPU clock: 1–24 times the input clock, maximum 200 MHz
 Bus clock: 1–4 times the input clock, maximum 66.67 MHz
 Peripheral clock: 1/4–4 times the input clock, maximum 33.34 MHz
•
Power-down modes:
 Sleep mode
 Standby mode
 Module standby mode
Memory
management
unit (MMU)
•
One-channel watchdog timer
•
4 Gbytes of address space, 256 address spaces (ASID 8 bits)
•
Page unit sharing
•
Supports multiple page sizes: 1, 4 kbytes
•
128-entry, 4-way set associative TLB
•
Supports software selection of replacement method and random-replacement
algorithms
Rev. 5.00, 09/03, page 2 of 760
Item
Features
Cache memory
•
16-kbyte cache, mixed instruction/data
•
256 entries, 4-way set associative, 16-byte block length
•
Write-back, write-through, LRU replacement algorithm
•
1-stage write-back buffer
•
Maximum 2 ways of the cache can be locked
Interrupt
controller (INTC)
•
23 external interrupt pins (NMI, IRQ5–IRQ0, PINT15 to PINT0)
•
On-chip peripheral interrupts: set priority levels for each module
User break
controller (UBC)
•
2 break channels
•
Addresses, data values, type of access, and data size can all be set as break
conditions
•
Supports a sequential break function
•
Physical address space divided into six areas (area 0, areas 2 to 6), each a
maximum of 64 Mbytes, with the following features settable for each area:
Bus state
controller (BSC)
 Bus size (8, 16, or 32 bits)
 Number of wait cycles (also supports a hardware wait function)
 Setting the type of space enables direct connection to SRAM,
Synchronous DRAM, and burst ROM
 Supports PCMCIA interface (2 channels)
 Outputs chip select signal (CS0, CS2–CS6) for corresponding area
•
Synchronous DRAM refresh function
 Programmable refresh interval
 Support self-refresh mode
User-debugging
Interface (UDI)
Timer (TMU)
Realtime clock
(RTC)
•
Synchronous DRAM burst access function
•
Usable as either big or little endian machine
•
E10A emulator support
•
JTAG-compliant
•
Realtime branch address trace
•
1-kB on-chip RAM for fast emulation program execution
•
3-channel auto-reload-type 32-bit timer
•
Input capture function
•
6 types of counter input clocks can be selected
•
Maximum resolution: 2 MHz
•
Built-in clock, calendar functions, and alarm functions
•
On-chip 32-kHz crystal oscillator circuit with a maximum resolution (interrupt
cycle) of 1/256 second
Rev. 5.00, 09/03, page 3 of 760
Item
Features
Serial communi- •
cation interface 0
•
(SCI0/SCI)
•
Asynchronous mode or clock synchronous mode can be selected
Serial communi- •
cation interface 1
•
(SCI1/IrDA)
•
16-byte FIFO for transmission/reception
Serial communi- •
cation interface 2
•
(SCI2/SCIF)
•
16-byte FIFO for transmission/reception
Direct memory
•
access controller
•
(DMAC)
•
4 channels
Full-duplex communication
Supports smart card interface
DMA can be transferred
IrDA: interface based on 1.0
DMA can be transferred
Hardware flow control
Burst mode and cycle-steal mode
Data transfer size: 8-/16-/32-bit and 16-byte
I/O port
•
Twelve 8-bit ports
A/D converter
(ADC)
•
10 bits ± 4 LSB, 8 channels
•
Conversion time: 16 µs
•
Input range: 0–AVcc (max. 3.6 V)
•
8 bits ± 4 LSB, 2 channels
•
Conversion time: 10 µs
•
Output range: 0–AVcc (max. 3.6 V)
D/A converter
(DAC)
Product lineup
Power Supply Voltage
Abbr.
I/O
Internal
Operating
Frequency Model Name
SH7709S 3.3±0.3 V 2.0±0.15 V* 200 MHz
1.9±0.15 V
167 MHz
Package
HD6417709SHF200B 208-pin plastic
HQFP (FP-208E)
HD6417709SF167B
208-pin plastic
LQFP (FP-208C)
HD6417709SBP167B 240-pin CSP
(BP-240A)
1.8+0.25 V
1.8–0.15 V
133 MHz
HD6417709SF133B
208-pin plastic
LQFP (FP-208C)
HD6417709SBP133B 240-pin CSP
(BP-240A)
1.7+0.25 V
1.7–0.15 V
100 MHz
HD6417709SF100B
208-pin plastic
LQFP (FP-208C)
HD6417709SBP100B 240-pin CSP
(BP-240A)
Note: * 2.0 (+0.15, –0.1) V when an IRL or IRLS interrupt is used.
Rev. 5.00, 09/03, page 4 of 760
Table 1.2
Characteristics
Item
Characteristics
Power supply voltage
•
I/O: 3.3 ±0.3 V
Internal: 2.0 ±0.15 V (200 MHz model)*, 1.9±0.15 V (167 MHz model),
1.8 (+0.25, –0.15) V (133 MHz model), 1.7(+0.25, –0.15) V (100 MHz
model)
Operating frequency
•
Internal frequency: maximum 200 MHz(200 MHz model), 167 MHz
(167 MHz model) 133.34 MHz (133 MHz model), 100 MHz (100 MHz
model); external frequency: maximum 66.67 MHz
Process
•
0.25-µm CMOS/5-layer metal
Note: * 2.0 (+0.15, –0.1) V when an IRL or IRLS interrupt is used.
Rev. 5.00, 09/03, page 5 of 760
1.2
Block Diagram
SH-3
CPU
TLB
L bus
I bus 1
MMU
CCN
UBC
Peripheral bus 1
AUD
CACHE
SCI
TMU
BRIDGE
RTC
BSC
UDI
I bus 2
IrDA
SCIF
DMAC
CPG/WDT
CMT
Peripheral bus 2
INTC
ADC
DAC
I/O port
External bus
interface
Legend:
ADC:
AUD:
BSC:
CACHE:
CCN:
CMT:
CPG/WDT:
CPU:
DAC:
DMAC:
UDI:
A/D converter
Advanced user debugger
Bus state controller
Cache memory
Cache memory controller
Compare match timer
Clock pulse generator/watchdog timer
Central processing unit
D/A converter
Direct memory access controller
User debugging interface
INTC:
IrDA:
MMU:
RTC:
SCI:
SCIF:
TLB:
TMU:
UBC:
Interrupt controller
Serial communicatiion interface (with IrDA)
Memory management unit
Realtime clock
Serial communication interface (with smart card interface)
Serial communication interface (with FIFO)
Address translation buffer
Timer unit
User break controller
Figure 1.1 Block Diagram
Rev. 5.00, 09/03, page 6 of 760
Pin Description
1.3.1
Pin Assignment
156
155
154
153
152
151
150
149
148
147
146
145
144
143
142
141
140
139
138
137
136
135
134
133
132
131
130
129
128
127
126
125
124
123
122
121
120
119
118
117
116
115
114
113
112
111
110
109
108
107
106
105
EXTAL
XTAL
VCC
VSS
VSS
AUDCK/PTH[6]
VCC-PLL2
CAP2
VSS-PLL2
VSS-PLL1
CAP1
VCC-PLL1
MD0
IRLS0/PTF[0]/PINT[8]
IRLS1/PTF[1]/PINT[9]
IRLS2/PTF[2]/PINT[10]
IRLS3/PTF[3]/PINT[11]
TCK/PTF[4]/PINT[12]
TDI/PTF[5]/PINT[13]
TMS/PTF[6]/PINT[14]
TRST/PTF[7]/PINT[15]
AUDATA[0]/PTG[0]
VCC
AUDATA[1]/PTG[1]
VSS
AUDATA[2]/PTG[2]
AUDATA[3]/PTG[3]
PTG[4]/CKIO2
ASEBRKAK/PTG[5]
ASEMD0/PTG[6]
IOIS16/PTG[7]
ADTRG/PTH[5]
RESETM
WAIT
BREQ
BACK
TDO/PTE[0]
PTE[1]
RAS3U/PTE[2]
PTE[3]
PTE[6]
DACK1/PTD[7]
DACK0/PTD[5]
PTJ[5]
PTJ[4]
VCCQ
CASU/PTJ[3]
VSSQ
CASL/PTJ[2]
PTJ[1]
RAS3L/PTJ[0]
CKE/PTK[5]
1.3
104
103
102
101
100
99
98
97
96
95
94
93
92
91
90
89
88
87
86
85
84
83
82
81
80
79
78
77
76
75
74
73
72
71
70
69
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
SH7709S
FP-208C
FP-208E
(Top view)
INDEX MARK
CE2B/PTE[5]
CE2A/PTE[4]
CS6/CE1B
CS5/CE1A/PTK[3]
CS4/PTK[2]
CS3/PTK[1]
CS2/PTK[0]
VCCQ
CS0/MCS0
VSSQ
AUDSYNC/PTE[7]
RD/WR
WE3/DQMUU/ICIOWR/PTK[7]
WE2/DQMUL/ICIORD/PTK[6]
WE1/DOMLU/WE
WE0/DQMLL
RD
BS/PTK[4]
A25
VCCQ
A24
VSSQ
A23
VCC
A22
VSS
A21
A20
A19
A18
A17
A16
A15
VCCQ
A14
VSSQ
A13
A12
A11
A10
A9
A8
A7
A6
A5
VCCQ
A4
VSSQ
A3
A2
A1
A0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
MD1
MD2
VCC-RTC
XTAL2
EXTAL2
VSS-RTC
NMI
IRQ0/IRL0/PTH[0]
IRQ1/IRL1/PTH[1]
IRQ2/IRL2/PTH[2]
IRQ3/IRL3/PTH[3]
IRQ4/PTH[4]
D31/PTB[7]
D30/PTB[6]
D29/PTB[5]
D28/PTB[4]
D27/PTB[3]
D26/PTB[2]
VSSQ
D25/PTB[1]
VCCQ
D24/PTB[0]
D23/PTA[7]
D22/PTA[6]
D21/PTA[5]
D20/PTA[4]
VSS
D19/PTA[3]
VCC
D18/PTA[2]
D17/PTA[1]
D16/PTA[0]
VSSQ
D15
VCCQ
D14
D13
D12
D11
D10
D9
D8
D7
D6
VSSQ
D5
VCCQ
D4
D3
D2
D1
D0
STATUS0/PTJ[6]
STATUS1/PTJ[7]
TCLK/PTH[7]
IRQOUT
VSSQ
CKIO
VCCQ
TxD0/SCPT[0]
SCK0/SCPT[1]
TxD1/SCPT[2]
SCK1/SCPT[3]
TxD2/SCPT[4]
SCK2/SCPT[5]
RTS2/SCPT[6]
RxD0/SCPT[0]
RxD1/SCPT[2]
VSS
RXD2/SCPT[4]
VCC
CTS2/IRQ5/SCPT[7]
MCS[7]/PTC[7]/PINT[7]
MCS[6]/PTC[6]/PINT[6]
MCS[5]/PTC[5]/PINT[5]
MCS[4]/PTC[4]/PINT[4]
VSSQ
WAKEUP/PTD[3]
VCCQ
RESETOUT/PTD[2]
MCS[3]/PTC[3]/PINT[3]
MCS[2]/PTC[2]/PINT[2]
MCS[1]/PTC[1]/PINT[1]
MCS[0]/PTC[0]/PINT[0]
DRAK0/PTD[1]
DRAK1/PTD[0]
DREQ0/PTD[4]
DREQ1/PTD[6]
RESETP
CA
MD3
MD4
MD5
AVSS
AN[0]/PTL[0]
AN[1]/PTL[1]
AN[2]/PTL[2]
AN[3]/PTL[3]
AN[4]/PTL[4]
AN[5]/PTL[5]
AVCC
AN[6]/DA[1]/PTL[6]
AN[7]/DA[0]/PTL[7]
AVSS
Figure 1.2 Pin Assignment (FP-208C, FP-208E)
Rev. 5.00, 09/03, page 7 of 760
A
B
C D
E
F
G H
J
K
L
M N
P
R
T
U
V W
19
19
18
18
17
17
16
16
15
15
14
14
13
13
12
12
11
SH7709S
11
10
BP-240A
10
9
(Top view)
9
8
8
7
7
6
6
5
5
4
4
3
3
2
2
1
1
A
B
C D
E
F
G H
J
K
L
M N
P
R
T
U
Note: The pin area enclosed in broken lines is an inner view.
Figure 1.3 Pin Assignment (BP-240A)
Rev. 5.00, 09/03, page 8 of 760
V W
1.3.2
Table 1.3
Pin Function
SH7709S Pin Function
Number of Pins
FP-208C
FP-208E
BP-240A
Pin Name
I/O
Description
1
D2
MD1
I
Clock mode setting
2
C2
MD2
I
Clock mode setting
3
E2
1
Vcc-RTC*
—
RTC power supply (* )
4
D1
XTAL2
O
On-chip RTC crystal oscillator pin
5
D3
EXTAL2
I
On-chip RTC crystal oscillator
6
pin*
6
E1
Vss-RTC*
—
RTC power supply (0 V)
7
C3
NMI
I
Nonmaskable interrupt request
8
E3
IRQ0/IRL0/PTH[0]
I
External interrupt request/input
port H
9
E4
IRQ1/IRL1/PTH[1]
I
External interrupt request/input
port H
10
F1
IRQ2/IRL2/PTH[2]
I
External interrupt request/input
port H
11
F2
IRQ3/IRL3/PTH[3]
I
External interrupt request/input
port H
12
F3
IRQ4/PTH[4]
I
External interrupt request/input
port H
13
F4
D31/PTB[7]
I/O
Data bus / input/output port B
14
G1
D30/PTB[6]
I/O
Data bus / input/output port B
15
G2
D29/PTB[5]
I/O
Data bus / input/output port B
16
G3
D28/PTB[4]
I/O
Data bus / input/output port B
17
G4
D27/PTB[3]
I/O
Data bus / input/output port B
18
H1
D26/PTB[2]
I/O
Data bus / input/output port B
19
H2
VssQ
—
Input/output power supply (0 V)
20
H3
D25/PTB[1]
I/O
Data bus / input/output port B
21
H4
VccQ
—
Input/output power supply (3.3 V)
22
J1
D24/PTB[0]
I/O
Data bus / input/output port B
23
J2
D23/PTA[7]
I/O
Data bus / input/output port A
24
J4
D22/PTA[6]
I/O
Data bus / input/output port A
25
J3
D21/PTA[5]
I/O
Data bus / input/output port A
26
K2
D20/PTA[4]
I/O
Data bus / input/output port A
1
3
Rev. 5.00, 09/03, page 9 of 760
Number of Pins
FP-208C
FP-208E
BP-240A
Pin Name
I/O
Description
27
K3
Vss
—
Power supply (0 V)
—
K4
Vss
—
Power supply (0 V)
28
K1
D19/PTA[3]
I/O
29
L3
Vcc
—
Data bus / input/output port A
3
Power supply (1.9 V/1.8 V* )
—
L4
Vcc
—
Power supply (* )
30
L2
D18/PTA[2]
I/O
Data bus / input/output port A
31
L1
D17/PTA[1]
I/O
Data bus / input/output port A
32
M4
D16/PTA[0]
I/O
Data bus / input/output port A
33
M3
VssQ
—
Input/output power supply (0 V)
34
M2
D15
I/O
Data bus
35
M1
VccQ
—
Input/output power supply (3.3 V)
36
N4
D14
I/O
Data bus
37
N3
D13
I/O
Data bus
38
N2
D12
I/O
Data bus
3
39
N1
D11
I/O
Data bus
40
P4
D10
I/O
Data bus
41
P3
D9
I/O
Data bus
42
P2
D8
I/O
Data bus
43
P1
D7
I/O
Data bus
44
R4
D6
I/O
Data bus
45
R3
VssQ
—
Input/output power supply (0 V)
46
T4
D5
I/O
Data bus
47
R1
VccQ
—
Input/output power supply (3.3 V)
48
T3
D4
I/O
Data bus
49
T1
D3
I/O
Data bus
50
R2
D2
I/O
Data bus
51
U2
D1
I/O
Data bus
52
T2
D0
I/O
Data bus
53
V4
A0
O
Address bus
54
V3
A1
O
Address bus
55
V5
A2
O
Address bus
56
W4
A3
O
Address bus
Rev. 5.00, 09/03, page 10 of 760
Number of Pins
FP-208C
FP-208E
BP-240A
Pin Name
I/O
Description
57
U4
VssQ
—
Input/output power supply (0 V)
58
W5
A4
O
Address bus
59
U3
VccQ
—
Input/output power supply (3.3 V)
60
U5
A5
O
Address bus
61
T5
A6
O
Address bus
62
W6
A7
O
Address bus
63
V6
A8
O
Address bus
64
U6
A9
O
Address bus
65
T6
A10
O
Address bus
66
W7
A11
O
Address bus
67
V7
A12
O
Address bus
68
U7
A13
O
Address bus
69
T7
VssQ
—
Input/output power supply (0 V)
70
W8
A14
O
Address bus
71
V8
VccQ
—
Input/output power supply (3.3 V)
72
U8
A15
O
Address bus
73
T8
A16
O
Address bus
74
W9
A17
O
Address bus
75
V9
A18
O
Address bus
76
T9
A19
O
Address bus
77
U9
A20
O
Address bus
78
V10
A21
O
Address bus
79
U10
Vss
—
Power supply (0 V)
—
T10
Vss
O
Power supply (0 V)
80
W10
A22
O
Address bus
81
U11
Vcc
—
—
T11
Vcc
—
Power supply (* )
3
Power supply (* )
3
82
V11
A23
O
Address bus
83
W11
VssQ
—
Input/output power supply (0 V)
84
T12
A24
O
Address bus
85
U12
VccQ
—
Input/output power supply (3.3 V)
86
V12
A25
O
Address bus
Rev. 5.00, 09/03, page 11 of 760
Number of Pins
FP-208C
FP-208E
BP-240A
Pin Name
I/O
Description
87
W12
BS/PTK[4]
O / I/O
Bus cycle start signal / input/output
port K
88
T13
RD
O
Read strobe
89
U13
WE0/DQMLL
O
D7–D0 select signal / DQM
(SDRAM)
90
V13
WE1/DQMLU/WE
O
D15–D8 select signal / DQM
(SDRAM)
91
W13
WE2/DQMUL/ICIORD/
PTK[6]
O / I/O
D23–D16 select signal / DQM
(SDRAM) / PCMCIA I/O read /
input/output port K
92
T14
WE3/DQMUU/ICIOWR/ O / I/O
PTK[7]
D31–D24 select signal / DQM
(SDRAM) / PCMCIA I/O write /
input/output port K
93
U14
RD/WR
O
Read/write
94
V14
AUDSYNC/PTE[7]
O / I/O
AUD synchronous / input/output
port E
95
W14
VssQ
—
Input/output power supply (0 V)
96
T15
CS0/MCS[0]
O
Chip select 0/mask ROM chip
select 0
97
U15
VccQ
—
Input/output power supply (3.3 V)
98
T16
CS2/PTK[0]
O / I/O
Chip select 2 / input/output port K
99
W15
CS3/PTK[1]
O / I/O
Chip select 3 / input/output port K
100
U16
CS4/PTK[2]
O / I/O
Chip select 4 / input/output port K
101
W16
CS5/CE1A/PTK[3]
O / I/O
Chip select 5/CE1 (area 5
PCMCIA) / input/output port K
102
V15
CS6/CE1B
O
Chip select 6/CE1 (area 6
PCMCIA)
103
V17
CE2A/PTE[4]
O / I/O
CE2 (area 5 PCMCIA) /
input/output port E
104
V16
CE2B/PTE[5]
O / I/O
CE2 (area 6 PCMCIA) /
input/output port E
105
T18
CKE/PTK[5]
O / I/O
CK enable (SDRAM) / input/output
port K
Rev. 5.00, 09/03, page 12 of 760
Number of Pins
FP-208C
FP-208E
BP-240A
Pin Name
I/O
Description
106
U18
RAS3L/PTJ[0]
O / I/O
107
U19
PTJ[1]
O / I/O
Lower 32 M / 64 Mbytes address
(SDRAM) RAS / input/output port J
5
Input/output port J*
108
R18
CASL/PTJ[2]
O / I/O
Lower 32 M / 64 Mbytes address
(SDRAM) CAS / input/output port J
109
T19
VssQ
—
Input/output power supply (0 V)
110
T17
CASU/PTJ[3]
O / I/O
Lower 32 Mbytes address
(SDRAM) CAS / input/output port J
111
R19
VccQ
—
Input/output power supply (3.3 V)
112
U17
PTJ[4]
I/O
Input/output port J
113
R17
PTJ[5]
I/O
Input/output port J
114
R16
DACK0/PTD[5]
O / I/O
DMA acknowledge 0 / input/output
port D
115
P19
DACK1/PTD[7]
O / I/O
DMA acknowledge 1 / input/output
port D
116
P18
PTE[6]
I/O
Input/output port E
117
P17
PTE[3]
I/O
Input/output port E
118
P16
RAS3U/PTE[2]
O / I/O
Upper 32 Mbytes address
(SDRAM) RAS / input/output port
E
119
N19
PTE[1]
I/O
Input/output port E
120
N18
TDO/PTE[0]
O / I/O
Test data output / input/output
port E
121
N17
BACK
O
Bus acknowledge
122
N16
BREQ
I
Bus request
123
M19
WAIT
I
Hardware wait request
124
M18
RESETM
I
Manual reset request
125
M17
ADTRG/PTH[5]
I
Analog trigger / input port H
126
M16
IOIS16/PTG[7]
I
127
L19
ASEMD0/PTG[6]
I
IOIS16 (PCMCIA) / input port G
4
ASE mode* / input port G
128
L18
ASEBRKAK/PTG[5]
O/I
ASE break acknowledge / input
port G
129
L16
PTG[4]/CK102
I
Input port G / clock output
Rev. 5.00, 09/03, page 13 of 760
Number of Pins
FP-208C
FP-208E
BP-240A
Pin Name
I/O
Description
130
L17
AUDATA[3]/PTG[3]
I/O / I
AUD data / input port G
131
K18
AUDATA[2]/PTG[2]
I/O/I
AUD data / input port G
132
K17
Vss
—
Power supply (0 V)
—
K16
Vss
—
Power supply (0 V)
133
K19
AUDATA[1]/PTG[1]
I/O / I
134
J17
Vcc
—
AUD data / input port G
3
Power supply (* )
—
J16
Vcc
—
Power supply (* )
135
J18
AUDATA[0]/PTG[0]
I/O / I
AUD data / input port G
136
J19
TRST/PTF[7]/PINT[15]
I
Test reset / input port F / port
interrupt
137
H16
TMS/PTF[6]/PINT[14]
I
Test mode switch / input port F /
port interrupt
138
H17
TDI/PTF[5]/PINT[13]
I
Test data input / input port F / port
interrupt
139
H18
TCK/PTF[4]/PNT[12]
I
Test clock / input port F / port
interrupt
140
H19
IRLS3/PTF[3]/
PINT[11]
I
External interrupt request / input
port F / port interrupt
141
G16
IRLS2/PTF[2]/
PINT[10]
I
External interrupt request / input
port F / port interrupt
142
G17
IRLS1/PTF[1]/PINT[9]
I
External interrupt request / input
port F / port interrupt
143
G18
IRLS0/PTF[0]/PINT[8]
I
External interrupt request / input
port F / port interrupt
144
G19
MD0
I
Clock mode setting
145
F16
2
Vcc-PLL1*
—
PLL1 power supply (* )
146
F17
CAP1
3
3
—
PLL1 external capacitance pin
F18
Vss-PLL1
*2
—
PLL1 power supply (0 V)
148
F19
2
Vss-PLL2*
—
PLL2 power supply (0 V)
149
E16
CAP2
—
150
E17
2
Vcc-PLL2*
—
PLL2 external capacitance pin
3
PLL2 power supply (* )
151
D16
AUDCK/PTH[6]
I
AUD clock / input port H
152
E19
Vss
—
Power supply (0 V)
153
D17
Vss
—
Power supply (0 V)
147
Rev. 5.00, 09/03, page 14 of 760
Number of Pins
FP-208C
FP-208E
BP-240A
Pin Name
I/O
Description
—
D19
Vss
—
154
E18
Vcc
—
Power supply (0 V)
3
Power supply (* )
—
C19
Vcc
—
Power supply (* )
155
C18
XTAL
O
Clock oscillator pin
156
D18
EXTAL
I
External clock / crystal oscillator
pin
157
B16
STATUS0/PTJ[6]
O / I/O
Processor status / input/output
port J
158
B17
STATUS1/PTJ[7]
O / I/O
Processor status / input/output
port J
159
B15
TCLK/PTH[7]
I/O
TMU or RTC clock input/output /
input/output port H
160
A16
IRQOUT
O
Interrupt request notification
161
C16
VssQ
—
Input/output power supply (0 V)
162
A15
CKIO
I/O
System clock input/output
3
163
C17
VccQ
—
Power supply (3.3 V)
164
C15
TxD0/SCPT[0]
O
Transmit data 0 / SCI output port
165
D15
SCK0/SCPT[1]
I/O
Serial clock 0 / SCI input/output
port
166
A14
TxD1/SCPT[2]
O
Transmit data 1 / SCI output port
167
B14
SCK1/SCPT[3]
I/O
Serial clock 1 / SCI input/output
port
168
C14
TxD2/SCPT[4]
O
Transmit data 2 / SCI output port
169
D14
SCK2/SCPT[5]
I/O
Serial clock 2 / SCI input/output
port
170
A13
RTS2/SCPT[6]
O / I/O
Transmit request 2 / SCI
input/output port
171
B13
RxD0/SCPT[0]
I
Transmit data 0 / SCI output port
172
C13
RxD1/SCPT[2]
I
Transmit data 1 / SCI output port
173
D13
Vss
—
Power supply (0 V)
—
A12
Vss
—
Power supply (0 V)
174
B12
RxD2/SCPT[4]
I
175
C12
Vcc
—
Transmit data 2 / SCI output port
3
Power supply (* )
—
D12
Vcc
—
Power supply (* )
3
Rev. 5.00, 09/03, page 15 of 760
Number of Pins
FP-208C
FP-208E
BP-240A
Pin Name
I/O
Description
176
A11
CTS2/IRQ5/SCPT[7]
I
Transmit clear 2 / external interrupt
request / SCI input port
177
B11
MCS[7]/PTC[7]/PINT[7]
O / I/O / I Mask ROM chip select /
input/output port C / port interrupt
178
D11
MCS[6]/PTC[6]/PINT[6]
O / I/O / I Mask ROM chip select /
input/output port C / port interrupt
179
C11
MCS[5]/PTC[5]/PINT[5]
O / I/O / I Mask ROM chip select /
input/output port C / port interrupt
180
B10
MCS[4]/PTC[4]/PINT[4]
O / I/O / I Mask ROM chip select /
input/output port C / port interrupt
181
C10
VssQ
—
Input/output power supply (0 V)
182
D10
WAKEUP/PTD[3]
O / I/O
Standby mode interrupt request
notification / input/output port D
183
A10
VccQ
—
Input/output power supply (3.3 V)
184
C9
RESETOUT/PTD[2]
O / I/O
Reset output / input/output port D
185
D9
MCS[3]/PTC[3]/PINT[3]
O / I/O / I Mask ROM chip select /
input/output port C / port interrupt
186
B9
MCS[2]/PTC[2]/PINT[2]
O / I/O / I Mask ROM chip select /
input/output port C / port interrupt
187
A9
MCS[1]/PTC[1]/PINT[1]
O / I/O / I Mask ROM chip select /
input/output port C / port interrupt
188
D8
MCS[0]/PTC[0]/PINT[0]
O / I/O / I Mask ROM chip select /
input/output port C / port interrupt
189
C8
DRAK0/PTD[1]
O / I/O
DMA request acknowledge /
input/output port D
190
B8
DRAK1/PTD[0]
O / I/O
DMA request acknowledge /
input/output port D
191
A8
DREQ0/PTD[4]
I
DMA request / input port D
192
D7
DREQ1/PTD[6]
I
DMA request / input port D
193
C7
RESETP
I
Power-on reset request
194
B7
CA
I
Chip activate (hardware standby
request signal)
195
A7
MD3
I
Area 0 bus width setting
196
D6
MD4
I
Area 0 bus width setting
197
C6
MD5
I
Endian setting
Rev. 5.00, 09/03, page 16 of 760
Number of Pins
FP-208C
FP-208E
BP-240A
Pin Name
I/O
Description
198
B6
AVss
—
Analog power supply (0 V)
199
A6
AN[0]/PTL[0]
I
A/D converter input / input port L
200
D5
AN[1]/PTL[1]
I
A/D converter input / input port L
201
C5
AN[2]/PTL[2]
I
A/D converter input / input port L
202
D4
AN[3]/PTL[3]
I
A/D converter input / input port L
203
A5
AN[4]/PTL[4]
I
A/D converter input / input port L
204
C4
AN[5]/PTL[5]
I
A/D converter input / input port L
205
A4
AVcc
—
Analog power supply (3.3 V)
206
B5
AN[6]/DA[1]/PTL[6]
I
A/D converter input /
D/A converter output / input port L
207
B3
AN[7]/DA[0]/PTL[7]
I
A/D converter input /
D/A converter output / input port L
208
B4
AVss
—
Analog power supply (0 V)
Notes: 1. Must be connected to the power supply even when the RTC is not used.
2. Except in hardware standby mode, all of the power supply pins must be connected to
the system power supply. (Supply power constantly.) In hardware standby mode, power
must be supplied at least to VCC –RTC and VSS –RTC. If power is not being supplied to
any of the power supply pins other than VCC –RTC and VSS –RTC, hold the CA pin low.
3. 2.0 V for the 200 MHz model, 1.9 V for the 167 MHz model, 1.8 V for the 133 MHz
model, 1.7 V for the 100 MHz model.
4. When this LSI is used on the user system alone, without an emulator and the UDI, hold
this pin at high level. When this pin is low or open, RESETP may be masked (see
section 22, User Debugging Interface (UDI)).
5. B2, B1, C1, U1, V1, W1, V2, W2, W3, W17, W18, W19, V18, V19, B19, A19, B18, A18,
A17, A3, A2, and A1 are NC pins. Do not connect anything to these pins.
6. If EXTAL2 is not used, pull this pin up to the Vcc-RTC level.
Rev. 5.00, 09/03, page 17 of 760
Rev. 5.00, 09/03, page 18 of 760
Section 2 CPU
2.1
Register Configuration
2.1.1
Privileged Mode and Banks
Processor Modes: There are two processor modes: user mode and privileged mode. The
SH7709S normally operates in user mode, and enters privileged mode when an exception occurs
or an interrupt is accepted. There are three kinds of registers—general registers, system registers,
and control registers—and the registers that can be accessed differ in the two processor modes.
General Registers: There are 16 general registers, designated R0 to R15. General registers R0 to
R7 are banked registers which are switched by a processor mode change. In privileged mode, the
register bank bit (RB) in the status register (SR) defines which banked register set is accessed as
general registers, and which set is accessed only through the load control register (LDC) and store
control register (STC) instructions.
When the RB bit is 1, the 16 registers comprising BANK1 general registers R0_BANK1–
R7_BANK1 and non-banked general registers R8–R15 function as the general register set, with
the 8 registers comprising BANK0 general registers R0_BANK0–R7_BANK0 accessed only by
the LDC/STC instructions.
When the RB bit is 0, BANK0 general registers R0_BANK0–R7_BANK0 and nonbanked general
registers R8–R15 function as the general register set, with BANK1 general registers R0_BANK1–
R7_BANK1 accessed only by the LDC/STC instructions. In user mode, the 16 registers
comprising bank 0 general registers R0_BANK0–R7_BANK0 and non-banked registers R8–R15
can be accessed as general registers R0–R15, and bank 1 general registers R0_BANK1–
R7_BANK1 cannot be accessed.
Control Registers: Control registers comprise the global base register (GBR) and status register
(SR) which can be accessed in both processor modes, and the saved status register (SSR), saved
program counter (SPC), and vector base register (VBR) which can only be accessed in privileged
mode. Some bits of the status register (such as the RB bit) can only be accessed in privileged
mode.
System Registers: System registers comprise the multiply and accumulate registers
(MACL/MACH), the procedure register (PR), and the program counter (PC). Access to these
registers does not depend on the processor mode.
The register configuration in each mode is shown in figures 2.1 and 2.2.
Switching between user mode and privileged mode is controlled by the processor mode bit (MD)
in the status register.
Rev. 5.00, 09/03, page 19 of 760
31
R0_BANK0*1 *2
R1_BANK0*2
R2_BANK0*2
R3_BANK0*2
R4_BANK0*2
R5_BANK0*2
R6_BANK0*2
R7_BANK0*2
R8
R9
R10
R11
R12
R13
R14
R15
0
SR
GBR
MACH
MACL
PR
PC
User mode register configuration
Notes: 1. R0 functions as an index register in the indexed register-indirect addressing
mode and indexed GBR-indirect addressing mode.
2. Banked register.
Figure 2.1 User Mode Register Configuration
Rev. 5.00, 09/03, page 20 of 760
31
0
31
0
R0_BANK1*1 *2
R1_BANK1*2
R2_BANK1*2
R3_BANK1*2
R4_BANK1*2
R5_BANK1*2
R6_BANK1*2
R7_BANK1*2
R8
R9
R10
R11
R12
R13
R14
R15
R0_BANK0*1 *3
R1_BANK0*3
R2_BANK0*3
R3_BANK0*3
R4_BANK0*3
R5_BANK0*3
R6_BANK0*3
R7_BANK0*3
R8
R9
R10
R11
R12
R13
R14
R15
SR
SSR
SR
SSR
GBR
MACH
MACL
PR
VBR
GBR
MACH
MACL
PR
VBR
PC
SPC
PC
SPC
R0_BANK0*1 *3
R1_BANK0*3
R2_BANK0*3
R3_BANK0*3
R4_BANK0*3
R5_BANK0*3
R6_BANK0*3
R7_BANK0*3
R0_BANK1*1 *2
R1_BANK1*2
R2_BANK1*2
R3_BANK1*2
R4_BANK1*2
R5_BANK1*2
R6_BANK1*2
R7_BANK1*2
a. Privileged mode
register configuration
(RB = 1)
Notes: 1. R0 functions as an index
register in the indexed
register-indirect addressing
mode and indexed GBRindirect addressing mode.
2. Banked register
When the RB bit of the SR
register is 1, the register can
be accessed for general use.
When the RB bit is 0, it can
only be accessed with the
LDC/STC instruction.
3. Banked register
When the RB bit of the SR
register is 0, the register can
be accessed for general use.
When the RB bit is 1, it can
only be accessed with the
LDC/STC instruction.
b. Privileged mode
register configuration
(RB = 0)
Figure 2.2 Privileged Mode Register Configuration
Rev. 5.00, 09/03, page 21 of 760
Register values after a reset are shown in table 2.1.
Table 2.1
Initial Register Values
Type
Registers
Initial Value*
General registers
R0 to R15
Undefined
Control registers
SR
MD bit = 1, RB bit = 1, BL bit = 1,
I3–I0 = 1111 (H'F), reserved bits =
0, others undefined
GBR, SSR, SPC
Undefined
VBR
H'00000000
MACH, MACL, PR
Undefined
PC
H'A0000000
System registers
Note: * Register values are initialized at power-on reset or manual reset.
2.1.2
General Registers
There are 16 general registers, designated R0 to R15 (figure 2.3). General registers R0 to R7 are
banked registers, with a different R0–R7 register bank (R0_BANK0–R7_BANK0 or
R0_BANK1–R7_BANK1) being accessed according to the processor mode. For details, see
figures 2.1 and 2.2.
The general register configuration is shown in figure 2.3.
General Registers
31
0
R0*1 *2
R1*2
R2*2
R3*2
R4*2
R5*2
R6*2
R7*2
R8
R9
R10
R11
R12
R13
R14
R15
Notes:
1. R0 functions as an index register in the indexed
register-indirect addressing mode and indexed
GBR-indirect addressing mode. In some instructions,
only R0 can be used as the source register or
destination register.
2. R0–R7 are banked registers.
In privileged mode, SR.RB specifies which banked
registers are accessed as general registers
(R0_BANK0−R7_BANK0 or R0_BANK1−R7_BANK1).
Figure 2.3 General Registers
Rev. 5.00, 09/03, page 22 of 760
2.1.3
System Registers
System registers can be accessed by the LDS and STS instructions. When an exception occurs, the
contents of the program counter (PC) are saved in the saved program counter (SPC). The SPC
contents are restored to the PC by the RTE instruction used at the end of the exception handling.
There are four system registers, as follows.
• Multiply and accumulate high register (MACH)
• Multiply and accumulate low register (MACL)
• Procedure register (PR)
• Program counter (PC)
The system register configuration is shown in figure 2.4.
System Registers
31
0
Multiply and Accumulate High and Low Registers
(MACH/L)
Store the results of multiply-and-accumulate operations.
MACH
MACL
31
0
PR
31
Procedure Register (PR)
Stores the return address for exiting a subroutine
procedure.
0
PC
Program Counter (PC)
Indicates the address four addresses (two instructions)
ahead of the currently executing instruction. Initialized
to H'A0000000 by a reset.
Figure 2.4 System Registers
2.1.4
Control Registers
Control registers can be accessed in privileged mode using the LDC and STC instructions. The
GBR register can also be accessed in user mode. There are five control registers, as follows:
• Status register (SR)
• Saved status register (SSR)
• Saved program counter (SPC)
• Global base register (GBR)
• Vector base register (VBR)
Rev. 5.00, 09/03, page 23 of 760
SSR
0 Saved Status Register (SSR)
Stores current SR value at time of exception to
indicate processor status in return to instruction
stream from exception handler.
SPC
0 Saved Program Counter (SPC)
Stores current PC value at time of exception to
indicate return address at completion of exception
handling.
31
31
31
GBR
31
VBR
0 Global Base Register (GBR)
Stores base address of GBR-indirect
addressing mode. The GBR-indirect addressing mode
is used for on-chip supporting module register area
data transfers and logic operations.
The GBR register can also be accessed in user mode.
Its contents are undefined after a reset.
0 Vector Base Register (VBR)
Stores base address of exception handling vector area.
Initialized to H'0000000 by a reset.
13 12 11 10 9 8 7
3
1 0 Status
0 MD RB BL 0−−−−−−−−−−−−−−−−−−−−−−0 CL 0 0 M Q I3 I2 I1 I0 0 0 S T register
(SR)
31 30 29 28 27
MD: Processor operation mode bit: Indicates the processor operation mode as follows:
MD =1: Privileged mode; MD = 0: User mode
MD is set to 1 on generation of an exception or interrupt , and is initialized to 1 by a reset.
RB: Register bank bit: Determines the bank of general registers R0–R7 used in processing mode.
RB = 1: R0_BANK1−R7_BANK1 and R8−R15 are general registers, and R0_BANK0−
R7_BANK0 can be accessed by LDC/STC instructions.
RB = 0: R0_BANK0−R7_BANK0 and R8−R15 are general registers, and R0_BANK1−
R7_BANK1 can be accessed by LDC/STC instructions.
RB is set to 1 on generation of an exception or interrupt , and is initialized to 1 by a reset.
BL: Block bit
BL = 1: Exceptions and interrupts are suppressed. See section 4, Exception
Handling, for details.
BL = 0: Exceptions and interrupts are accepted.
BL is set to 1 on generation of an exception or interrupt , and is initialized to 1 by a reset.
CL: Cache lock bit
When set to 1, the cache lock function can be used.
M and Q bits: Used by the DIV0S/U and DIV1 instructions.
I3−I0 bits: Interrupt mask bits: 4-bit field indicating the interrupt request mask level.
I3−I0 do not change to the interrupt acceptance level when an interrupt is generated.
Initialized to B'1111 by a reset.
S bit: Used by the MAC instruction.
T bit: Used by the MOVT, CMP/cond, TAS, TST, BT, BF, SETT, CLRT, and DT instructions to
indicate true (1) or false (0).
Used by the ADDV/C, SUBV/C, DIV0U/S, DIV1, NEGC, SHAR/L, SHLR/L, ROTR/L, and
ROTCR/L instructions to indicate a carry, borrow, overflow, or underflow.
0 bits: These bits always read 0, and the write value should always be 0.
Note: The M, Q, S, and T bits can be set or cleared by special instructions in user mode.
Their values are undefined after a reset. All other bits can be read or written in privileged mode.
Figure 2.5 Register Set Overview, Control Registers
Rev. 5.00, 09/03, page 24 of 760
2.2
Data Formats
2.2.1
Data Format in Registers
Register operands are always longwords (32 bits, figure 2.6). When a memory operand is only a
byte (8 bits) or a word (16 bits), it is sign-extended into a longword when loaded into a register.
31
0
Longword
Figure 2.6 Longword
2.2.2
Data Format in Memory
Memory data formats are classified into bytes, words, and longwords. Memory can be accessed in
8-bit byte, 16-bit word, or 32-bit longword form. A memory operand less than 32 bits in length is
sign-extended before being stored in a register.
A word operand must be accessed starting from a word boundary (even address of a 2-byte unit:
address 2n), and a longword operand starting from a longword boundary (even address of a 4-byte
unit: address 4n). An address error will result if this rule is not observed. A byte operand can be
accessed from any address.
Big-endian or little-endian byte order can be selected for the data format. The endian mode should
be set with the MD5 external pin in a power-on reset. Big-endian mode is selected when the MD5
pin is low, and little-endian when high. The endian mode cannot be changed dynamically. Bit
positions are numbered left to right from most-significant to least-significant. Thus, in a 32-bit
longword, the leftmost bit, bit 31, is the most significant bit and the rightmost bit, bit 0, is the least
significant bit.
The data format in memory is shown in figure 2.7.
Address A + 1 Address A + 3
Address A + 10 Address A + 8
Address A Address A + 2 Address A + 11 Address A + 9
23
7 0
23
7 0
31
15
31
15
Address A Byte0 Byte1 Byte2 Byte3
Byte3 Byte2 Byte1 Byte0
Address A + 4
Word0
Word1
Word1
Word0
Address A + 8
Longword
Longword
Big-endian mode
Address A + 8
Address A + 4
Address A
Little-endian mode
Figure 2.7 Data Format in Memory
Rev. 5.00, 09/03, page 25 of 760
2.3
Instruction Features
2.3.1
Execution Environment
Data Length: The SH7709S instruction set is implemented with fixed-length 16-bit wide
instructions executed in a pipelined sequence with single-cycle execution for most instructions.
All operations are executed in 32-bit longword units. Memory can be accessed in 8-bit byte, 16-bit
word, or 32-bit longword units, with byte or word units sign-extended into 32-bit longwords.
Literals are sign-extended in arithmetic operations (MOV, ADD, and CMP/EQ instructions) and
zero-extended in logical operations (TST, AND, OR, and XOR instructions).
Load/Store Architecture: The SH7709S features a load-store architecture in which basic
operations are executed in registers. Operations requiring memory access are executed in registers
following register loading, except for bit-manipulation operations such as logical AND functions,
which are executed directly in memory.
Delayed Branching: Unconditional branching is implemented as delayed branch operations.
Pipeline disruptions due to branching are minimized by the execution of the instruction following
the delayed branch instruction prior to branching. Conditional branch instructions are of two
kinds, delayed and normal.
BRA
TRGET
ADD
R1, R0
;ADD is executed prior to branching to TRGET
Rev. 5.00, 09/03, page 26 of 760
T bit: The T bit in the status register (SR) is used to indicate the result of compare operations, and
is read as a TRUE/FALSE condition determining if a conditional branch is taken or not. To
improve processing speed, the T bit logic state is modified only by specific operations. An
example of how the T bit may be used in a sequence of operations is shown below.
ADD
#1, R0
;T bit not modified by ADD operation
CMP/EQ
R1, R0
;T bit set to 1 when R0 = 0
BT
TRGET
;branch taken to TRGET when T bit = 1 (R0 = 0)
Literals: Byte-length literals are inserted directly into the instruction code as immediate data. To
maintain the 16-bit fixed-length instruction code, word or longword literals are stored in a table in
main memory rather than inserted directly into the instruction code. The memory table is accessed
by the MOV instruction using PC-relative addressing with displacement, as follows:
MOV.W
@(disp, PC), R0
Absolute Addresses: As with word and longword literals, absolute addresses must also be stored
in a table in main memory. The value of the absolute address is transferred to a register and the
operand access is specified by indexed register-indirect addressing, with the absolute address
loaded (like word and longword immediate data) during instruction execution.
16-Bit and 32-Bit Displacements: In the same way, 16-bit and 32-bit displacements also must be
stored in a table in main memory. Exactly like absolute addresses, the displacement value is
transferred to a register and the operand access is specified by indexed register-indirect addressing,
loading the displacement (like word and longword immediate data) during instruction execution.
Rev. 5.00, 09/03, page 27 of 760
2.3.2
Addressing Modes
Addressing modes and effective address calculation methods are shown in table 2.2.
Table 2.2
Addressing
Mode
Addressing Modes and Effective Addresses
Instruction
Format
Effective Address Calculation Method
Calculation Formula
Register direct Rn
Effective address is register Rn. (Operand is
register Rn contents.)
—
Register
indirect
Effective address is register Rn contents.
Rn
@Rn
Register
@Rn+
indirect with
post-increment
Rn
Rn
Effective address is register Rn contents. A
constant is added to Rn after instruction
execution: 1 for a byte operand, 2 for a word
operand, 4 for a longword operand.
Rn
Rn
Rn + 1/2/4
Rn
After instruction
execution
Byte: Rn + 1 → Rn
Word: Rn + 2 → Rn
Longword: Rn + 4 → Rn
+
1/2/4
Register
@–Rn
indirect with
pre-decrement
Effective address is register Rn contents,
decremented by a constant beforehand: 1 for
a byte operand, 2 for a word operand, 4 for a
longword operand.
Rn
Rn − 1/2/4
1/2/4
Rev. 5.00, 09/03, page 28 of 760
−
Rn − 1/2/4
Byte: Rn – 1 → Rn
Word: Rn – 2 → Rn
Longword: Rn – 4 → Rn
(Instruction executed
with Rn after
calculation)
Addressing
Mode
Instruction
Format
Effective Address Calculation Method
Register
indirect with
displacement
@(disp:4,
Rn)
Effective address is register Rn contents with
4-bit displacement disp added. After disp is
zero-extended, it is multiplied by 1 (byte), 2
(word), or 4 (longword), according to the
operand size.
Calculation Formula
Byte: Rn + disp
Word: Rn + disp × 2
Longword: Rn + disp ×
4
Rn
disp
(zero-extended)
+
Rn
+ disp × 1/2/4
×
1/2/4
Indexed
@(R0, Rn) Effective address is sum of register Rn and
register indirect
R0 contents.
Rn + R0
Rn
+
Rn + R0
R0
GBR indirect
with
displacement
@(disp:8,
GBR)
Effective address is register GBR contents
with 8-bit displacement disp added. After
disp is zero-extended, it is multiplied by 1
(byte), 2 (word), or 4 (longword), according
to the operand size.
Byte: GBR + disp
Word: GBR + disp × 2
Longword: GBR + disp
×4
GBR
disp
(zero-extended)
+
GBR
+ disp × 1/2/4
×
1/2/4
Indexed GBR @(R0,
indirect
GBR)
Effective address is sum of register GBR and
R0 contents.
GBR + R0
GBR
+
GBR + R0
R0
Rev. 5.00, 09/03, page 29 of 760
Addressing
Mode
Instruction
Format
Effective Address Calculation Method
PC-relative
with
displacement
@(disp:8,
PC)
Effective address is register PC contents
with 8-bit displacement disp added. After
disp is zero-extended, it is multiplied by 2
(word), or 4 (longword), according to the
operand size. With a longword operand, the
lower 2 bits of PC are masked.
Calculation Formula
Word: PC + disp × 2
Longword:
PC & H'FFFF FFFC +
disp × 4
PC
(for longword)
&
PC + disp × 2
or
PC&H'FFFFFFFC
+ disp × 4
H'FFFFFFFC
+
disp
(zero-extended)
x
2/4
PC-relative
disp:8
Effective address is register PC contents
with 8-bit displacement disp added after
being sign-extended and multiplied by 2.
PC + disp × 2
PC
disp
(sign-extended)
+
PC + disp × 2
×
2
disp:12
Effective address is register PC contents
with 12-bit displacement disp added after
being sign-extended and multiplied by 2.
PC
disp
(sign-extended)
+
×
2
Rev. 5.00, 09/03, page 30 of 760
PC + disp × 2
PC + disp × 2
Addressing
Mode
Instruction
Format
Effective Address Calculation Method
Calculation Formula
PC-relative
Rn
PC + Rn
Effective address is sum of register PC and
Rn contents.
PC
+
PC + R0
R0
Immediate
#imm:8
8-bit immediate data imm of TST, AND, OR,
or XOR instruction is zero-extended.
—
#imm:8
8-bit immediate data imm of MOV, ADD, or
CMP/EQ instruction is sign-extended.
—
#imm:8
8-bit immediate data imm of TRAPA
—
instruction is zero-extended and multiplied by
4.
Note: For the addressing modes below that use a displacement (disp), the assembler descriptions
in this manual show the value before scaling (×1, ×2, or ×4) is performed according to the
operand size. This is done to clarify the operation of the IC. Refer to the relevant assembler
notation rules for the actual assembler descriptions.
@ (disp:4, Rn) ; Register indirect with displacement
@ (disp:8, Rn) ; GBR indirect with displacement
@ (disp:8, PC) ; PC-relative with displacement
disp:8, disp:12; PC-relative
Rev. 5.00, 09/03, page 31 of 760
2.3.3
Instruction Formats
Table 2.3 explains the meaning of instruction formats and source and destination operands. The
meaning of the operands depends on the operation code. The following symbols are used.
xxxx:
mmmm:
nnnn:
iiii:
dddd:
Table 2.3
Operation code
Source register
Destination register
Immediate data
Displacement
Instruction Formats
Source
Operand
Destination
Operand
Instruction
Example
0
—
—
NOP
0
—
nnnn: register
direct
MOVT Rn
Control register or
system register
nnnn: register
direct
STS
MACH,Rn
Control register or
system register
nnnn: register
indirect with
pre-decrement
STC.L
SR,@–Rn
mmmm: register
direct
Control register
or system
register
LDC
Rm,SR
mmmm: register
indirect with postincrement
Control register
or system
register
LDC.L
@Rm+,SR
mmmm: register
indirect
—
JMP
@Rm
mmmm: PCrelative using Rm
—
BRAF
Rm
Instruction Format
0 format 15
xxxx
xxxx
xxxx
xxxx
xxxx
nnnn
xxxx
xxxx
n format 15
m format 15
0
xxxx mmmm xxxx
Rev. 5.00, 09/03, page 32 of 760
xxxx
Source
Operand
Instruction Format
nm format 15
xxxx
nnnn mmmm xxxx
md format 15
xxxx
xxxx mmmm dddd
xxxx
dddd
nd4 format 15
xxxx
nnnn
Destination
Operand
Instruction
Example
0 mmmm: register
direct
nnnn: register
direct
ADD
mmmm: register
indirect
nnnn: register
indirect
MOV.L
Rm,@Rn
mmmm: register
indirect with postincrement
(multiply-andaccumulate
operation)
nnnn: * register
indirect with postincrement
(multiply-andaccumulate
operation)
MACH,MACL
MAC.W
@Rm+,@Rn+
mmmm: register
indirect with postincrement
nnnn: register
direct
MOV.L
@Rm+,Rn
mmmm: register
direct
nnnn: register
indirect with
pre-decrement
MOV.L
Rm,@–Rn
mmmm: register
direct
nnnn: indexed
register indirect
MOV.L
Rm,@(R0,Rn)
0 mmmmdddd:
register indirect
with displacement
R0 (register
direct)
MOV.B
@(disp,Rm),R0
0 R0 (register
direct)
nnnndddd:
register indirect
with
displacement
MOV.B
R0,@(disp,Rn)
Rm,Rn
Rev. 5.00, 09/03, page 33 of 760
Source
Operand
Instruction Format
nmd
format
15
xxxx
nnnn mmmm dddd
Destination
Operand
Instruction
Example
nnnndddd:
register
indirect with
displacement
MOV.L
Rm,@(disp,Rn)
nnnn: register
direct
MOV.L
@(disp,Rm),Rn
R0 (register
direct)
MOV.L
@(disp,GBR),R
0
R0 (register
direct)
dddddddd:
GBR indirect
with
displacement
MOV.L
R0,@(disp,GBR
)
dddddddd:
PC-relative with
displacement
R0 (register
direct)
MOVA
@(disp,PC),R0
dddddddd:
PC-relative
—
BF
—
BRA
label
(label = disp +
PC)
0 dddddddd:
PC-relative with
displacement
nnnn: register
direct
MOV.L
@(disp,PC),Rn
0 iiiiiiii: immediate
Indexed GBR
indirect
AND.B
#imm,
@(R0,GBR)
iiiiiiii: immediate
R0 (register
direct)
AND
#imm,R0
iiiiiiii: immediate
—
TRAPA #imm
nnnn: register
direct
ADD
#imm,Rn
0 mmmm: register
direct
mmmmdddd:
register indirect
with displacement
d format
15
xxxx
xxxx
dddd
d12 format 15
dddd
xxxx
dddd
dddd
0 dddddddddddd:
PC-relative
dddd
xxxx
nnnn
dddd
dddd
xxxx
xxxx
iiii
iiii
nd8 format 15
i format
ni format
0 dddddddd: GBR
indirect with
displacement
15
0 iiiiiiii: immediate
15
xxxx
nnnn
iiii
iiii
Note: * In a multiply-and-accumulate instruction, nnnn is the source register.
Rev. 5.00, 09/03, page 34 of 760
label
2.4
Instruction Set
2.4.1
Instruction Set Classified by Function
The SH7709S instruction set includes 68 basic instruction types, as listed in table 2.4.
Table 2.4
Classification of Instructions
Classification Types
Operation
Code
Function
No. of
Instructions
Data transfer
MOV
Data transfer
39
Arithmetic
operations
5
21
MOVA
Effective address transfer
MOVT
T bit transfer
SWAP
Swap of upper and lower bytes
XTRCT
Extraction of middle of linked registers
ADD
Binary addition
33
ADDC
Binary addition with carry
ADDV
Binary addition with overflow check
CMP/cond
Comparison
DIV1
Division
DIV0S
Initialization of signed division
DIV0U
Initialization of unsigned division
DMULS
Signed double-precision multiplication
DMULU
Unsigned double-precision multiplication
DT
Decrement and test
EXTS
Sign extension
EXTU
Zero extension
MAC
Multiply-and-accumulate operation,
double-precision multiply-and-accumulate
operation
Rev. 5.00, 09/03, page 35 of 760
Classification Types
Arithmetic
operations
(cont)
Logic
operations
Shift
21
6
12
Operation
Code
Function
MUL
Double-precision multiplication (32 × 32
bits)
MULS
Signed multiplication (16 × 16 bits)
MULU
Unsigned multiplication (16 × 16 bits)
NEG
Negation
NEGC
Negation with borrow
SUB
Binary subtraction
SUBC
Binary subtraction with borrow
SUBV
Binary subtraction with underflow check
AND
Logical AND
NOT
Bit inversion
OR
Logical OR
TAS
Memory test and bit set
TST
Logical AND and T bit set
XOR
Exclusive OR
ROTL
One-bit left rotation
ROTR
One-bit right rotation
ROTCL
One-bit left rotation with T bit
ROTCR
One-bit right rotation with T bit
SHAL
One-bit arithmetic left shift
SHAR
One-bit arithmetic right shift
SHLL
One-bit logical left shift
SHLLn
n-bit logical left shift
SHLR
One-bit logical right shift
SHLRn
n-bit logical right shift
SHAD
Dynamic arithmetic shift
SHLD
Dynamic logical shift
Rev. 5.00, 09/03, page 36 of 760
No. of
Instructions
33
14
16
Classification Types
Operation
Code
Branch
BF
Conditional branch, delayed conditional
branch (T = 0)
BT
Conditional branch, delayed conditional
branch (T = 1)
BRA
Unconditional branch
BRAF
Unconditional branch
BSR
Branch to subroutine procedure
BSRF
Branch to subroutine procedure
JMP
Unconditional branch
JSR
Branch to subroutine procedure
RTS
Return from subroutine procedure
System
control
9
15
Total: 68
No. of
Instructions
Function
CLRMAC
MAC register clear
CLRT
Clear T bit
CLRS
Clear S bit
LDC
Load to control register
LDS
Load to system register
LDTLB
Load PTE to TLB
NOP
No operation
PREF
Prefetch data to cache
RTE
Return from exception handling
SETS
Set S bit
SETT
Set T bit
SLEEP
Shift to power-down mode
STC
Store from control register
STS
Store from system register
TRAPA
Trap exception handling
11
75
188
Rev. 5.00, 09/03, page 37 of 760
Table 2.5 lists the SH7709S instruction code formats.
Table 2.5
Instruction Code Format
Item
Format
Explanation
Instruction
mnemonic
OP.Sz SRC,DEST
OP: Operation code
Sz: Size
SRC: Source
DEST: Destination
Rm: Source register
Rn: Destination register
imm: Immediate data
disp: Displacement
Instruction
code
MSB ↔ LSB
mmmm: Source register
nnnn: Destination register
0000: R0
0001: R1
...........
1111: R15
iiii: Immediate data
dddd: Displacement*
Operation
summary
→, ←
(xx)
M/Q/T
&
|
^
~
<<n, >>n
Direction of transfer
Memory operand
Flag bits in SR
Logical AND of each bit
Logical OR of each bit
Exclusive OR of each bit
Logical NOT of each bit
n-bit shift
Privileged
mode
Indicates whether privileged mode applies
Execution
cycles
Value when no wait states are inserted
The execution cycles listed in the table are minimums. The
actual number of cycles may be increased in cases such as
the followsing:
1. When contention occurs between instruction fetches and
data access
2. When the destination register of the load instruction
(memory → register) and the register used by the next
instruction are the same
T bit
Value of T bit after instruction is executed
—: No change
Note: * Scaling (×1, ×2, ×4) is performed according to the instruction operand size.
Rev. 5.00, 09/03, page 38 of 760
Table 2.6 lists the SH7709S data transfer instructions
Table 2.6
Data Transfer Instructions
Instruction
Operation
Code
Privileged
Mode
Cycles T Bit
MOV
#imm,Rn
imm → Sign extension
→ Rn
1110nnnniiiiiiii
—
1
—
MOV.W
@(disp,PC),Rn
(disp × 2 + PC) → Sign
extension → Rn
1001nnnndddddddd
—
1
—
MOV.L
@(disp,PC),Rn
(disp × 4 + PC) → Rn
1101nnnndddddddd
—
1
—
MOV
Rm,Rn
Rm → Rn
0110nnnnmmmm0011
—
1
—
MOV.B
Rm,@Rn
Rm → (Rn)
0010nnnnmmmm0000
—
1
—
MOV.W
Rm,@Rn
Rm → (Rn)
0010nnnnmmmm0001
—
1
—
MOV.L
Rm,@Rn
Rm → (Rn)
0010nnnnmmmm0010
—
1
—
MOV.B
@Rm,Rn
(Rm) → Sign extension
→ Rn
0110nnnnmmmm0000
—
1
—
MOV.W
@Rm,Rn
(Rm) → Sign extension
→ Rn
0110nnnnmmmm0001
—
1
—
MOV.L
@Rm,Rn
(Rm) → Rn
0110nnnnmmmm0010
—
1
—
MOV.B
Rm,@–Rn
Rn–1 → Rn, Rm → (Rn)
0010nnnnmmmm0100
—
1
—
MOV.W
Rm,@–Rn
Rn–2 → Rn, Rm → (Rn)
0010nnnnmmmm0101
—
1
—
MOV.L
Rm,@–Rn
Rn–4 → Rn, Rm → (Rn)
0010nnnnmmmm0110
—
1
—
MOV.B
@Rm+,Rn
(Rm) → Sign extension
→ Rn, Rm + 1 → Rm
0110nnnnmmmm0100
—
1
—
MOV.W
@Rm+,Rn
(Rm) → Sign extension
→ Rn, Rm + 2 → Rm
0110nnnnmmmm0101
—
1
—
MOV.L
@Rm+,Rn
(Rm) → Rn,Rm + 4 → Rm 0110nnnnmmmm0110
—
1
—
MOV.B
R0,@(disp,Rn)
R0 → (disp + Rn)
10000000nnnndddd
—
1
—
MOV.W
R0,@(disp,Rn)
R0 → (disp × 2 + Rn)
10000001nnnndddd
—
1
—
MOV.L
Rm,@(disp,Rn)
Rm → (disp × 4 + Rn)
0001nnnnmmmmdddd
—
1
—
MOV.B
@(disp,Rm),R0
(disp + Rm) → Sign
extension → R0
10000100mmmmdddd
—
1
—
MOV.W
@(disp,Rm),R0
(disp × 2 + Rm) → Sign
extension → R0
10000101mmmmdddd
—
1
—
MOV.L
@(disp,Rm),Rn
(disp × 4 + Rm) → Rn
0101nnnnmmmmdddd
—
1
—
MOV.B
Rm,@(R0,Rn)
Rm → (R0 + Rn)
0000nnnnmmmm0100
—
1
—
Rev. 5.00, 09/03, page 39 of 760
Instruction
Operation
Code
Privileged
Mode
Cycles T Bit
MOV.W
Rm,@(R0,Rn)
Rm → (R0 + Rn)
0000nnnnmmmm0101
—
MOV.L
Rm,@(R0,Rn)
Rm → (R0 + Rn)
0000nnnnmmmm0110
—
1
—
MOV.B
@(R0,Rm),Rn
(R0 + Rm) → Sign
extension → Rn
0000nnnnmmmm1100
—
1
—
MOV.W
@(R0,Rm),Rn
(R0 + Rm) → Sign
extension → Rn
0000nnnnmmmm1101
—
1
—
MOV.L
@(R0,Rm),Rn
(R0 + Rm) → Rn
0000nnnnmmmm1110
—
1
—
MOV.B
R0,@(disp,GBR) R0 → (disp + GBR)
11000000dddddddd
—
1
—
MOV.W
R0,@(disp,GBR) R0 → (disp × 2 + GBR)
11000001dddddddd
—
1
—
MOV.L
R0,@(disp,GBR) R0 → (disp × 4 + GBR)
11000010dddddddd
—
1
—
MOV.B
@(disp,GBR),R0 (disp + GBR) → Sign
extension → R0
11000100dddddddd
—
1
—
MOV.W
@(disp,GBR),R0 (disp × 2 + GBR) →
Sign extension → R0
11000101dddddddd
—
1
—
MOV.L
@(disp,GBR),R0 (disp × 4 + GBR) → R0
11000110dddddddd
—
1
—
MOVA
@(disp,PC),R0
disp × 4 + PC → R0
11000111dddddddd
—
1
—
MOVT
Rn
T → Rn
0000nnnn00101001
—
1
—
SWAP.B Rm,Rn
Rm → Swap the bottom
two bytes → Rn
0110nnnnmmmm1000
—
1
—
SWAP.W Rm,Rn
Rm → Swap two
consecutive words → Rn
0110nnnnmmmm1001
—
1
—
XTRCT
Rm: Middle 32 bits of
Rn → Rn
0010nnnnmmmm1101
—
1
—
Rm,Rn
Rev. 5.00, 09/03, page 40 of 760
1
—
Table 2.7 lists the SH7709S arithmetic instructions.
Table 2.7
Arithmetic Instructions
Instruction
Operation
Code
Privileged
Mode
Cycles T Bit
ADD
Rm,Rn
Rn + Rm → Rn
0011nnnnmmmm1100
—
ADD
#imm,Rn
Rn + imm → Rn
0111nnnniiiiiiii
—
1
—
ADDC
Rm,Rn
Rn + Rm + T → Rn,
Carry → T
0011nnnnmmmm1110
—
1
Carry
ADDV
Rm,Rn
Rn + Rm → Rn,
Overflow → T
0011nnnnmmmm1111
—
1
Overflow
CMP/EQ
#imm,R0
If R0 = imm, 1 → T
10001000iiiiiiii
—
1
Comparison
result
CMP/EQ
Rm,Rn
If Rn = Rm, 1 → T
0011nnnnmmmm0000
—
1
Comparison
result
CMP/HS
Rm,Rn
If Rn ≥ Rm with
unsigned data, 1 → T
0011nnnnmmmm0010
—
1
Comparison
result
CMP/GE
Rm,Rn
If Rn ≥ Rm with signed
data, 1 → T
0011nnnnmmmm0011
—
1
Comparison
result
CMP/HI
Rm,Rn
If Rn > Rm with
unsigned data, 1 → T
0011nnnnmmmm0110
—
1
Comparison
result
CMP/GT
Rm,Rn
If Rn > Rm with signed
data, 1 → T
0011nnnnmmmm0111
—
1
Comparison
result
CMP/PZ
Rn
If Rn ≥ 0, 1 → T
0100nnnn00010001
—
1
Comparison
result
CMP/PL
Rn
If Rn > 0, 1 → T
0100nnnn00010101
—
1
Comparison
result
CMP/STR Rm,Rn
If Rn and Rm have an
equivalent byte, 1 → T
0010nnnnmmmm1100
—
1
Comparison
result
DIV1
Rm,Rn
Single-step division
(Rn/Rm)
0011nnnnmmmm0100
—
1
Calculation
result
DIV0S
Rm,Rn
MSB of Rn → Q, MSB
of Rm → M, M ^ Q → T
0010nnnnmmmm0111
—
1
Calculation
result
0 → M/Q/T
0000000000011001
—
1
0
DIV0U
1
—
Rev. 5.00, 09/03, page 41 of 760
Instruction
Operation
Code
Privileged
Mode
Cycles T Bit
DMULS.L Rm,Rn
Signed operation of
Rn × Rm → MACH,
MACL 32 × 32 → 64 bits
0011nnnnmmmm1101
—
2(to 5)* —
DMULU.L Rm,Rn
Unsigned operation of
Rn × Rm → MACH,
MACL 32 × 32 → 64 bits
0011nnnnmmmm0101
—
2(to 5)* —
DT
Rn – 1 → Rn, if Rn =
0, 1 → T, else 0 → T
0100nnnn00010000
—
1
Comparison
result
EXTS.B Rm,Rn
A byte in Rm is signextended → Rn
0110nnnnmmmm1110
—
1
—
EXTS.W Rm,Rn
A word in Rm is signextended → Rn
0110nnnnmmmm1111
—
1
—
EXTU.B Rm,Rn
A byte in Rm is zeroextended → Rn
0110nnnnmmmm1100
—
1
—
EXTU.W Rm,Rn
A word in Rm is zeroextended → Rn
0110nnnnmmmm1101
—
1
—
MAC.L
@Rm+,@Rn+
Signed operation of (Rn) 0000nnnnmmmm1111
× (Rm) + MAC → MAC,
Rn + 4 → Rn,
Rm + 4 → Rm,
32 × 32 + 64 → 64 bits
—
2(to 5)* —
MAC.W
@Rm+,@Rn+
Signed operation of (Rn) 0100nnnnmmmm1111
× (Rm) + MAC → MAC,
Rn + 2 → Rn,
Rm + 2 → Rm,
16 × 16 + 64 → 64 bits
—
2(to 5)* —
MUL.L
Rm,Rn
Rn × Rm → MACL,
32 × 32 → 32 bits
0000nnnnmmmm0111
—
2(to 5)* —
MULS.W Rm,Rn
Signed operation of Rn
× Rm → MACL,
16 × 16 → 32 bits
0010nnnnmmmm1111
—
1(to 3)* —
MULU.W Rm,Rn
Unsigned operation of
Rn × Rm → MACL,
16 × 16 → 32 bits
0010nnnnmmmm1110
—
1(to 3)* —
Rn
Rev. 5.00, 09/03, page 42 of 760
Instruction
Operation
Code
Privileged
Mode
Cycles T Bit
NEG
Rm,Rn
0–Rm → Rn
0110nnnnmmmm1011
—
1
—
NEGC
Rm,Rn
0–Rm–T → Rn,
Borrow → T
0110nnnnmmmm1010
—
1
Borrow
SUB
Rm,Rn
Rn–Rm → Rn
0011nnnnmmmm1000
—
1
—
SUBC
Rm,Rn
Rn–Rm–T → Rn,
Borrow → T
0011nnnnmmmm1010
—
1
Borrow
SUBV
Rm,Rn
Rn–Rm → Rn,
Underflow → T
0011nnnnmmmm1011
—
1
Underflow
Note: * The normal number of execution cycles is shown. The value in parentheses is the number
of cycles required in case of contention with the preceding or following instruction.
Rev. 5.00, 09/03, page 43 of 760
Table 2.8 lists the SH7709S logic operation instructions.
Table 2.8
Logic Operation Instructions
Instruction
Operation
Code
Privileged
Mode
Cycles T Bit
AND
Rm,Rn
Rn & Rm → Rn
0010nnnnmmmm1001
—
1
—
AND
#imm,R0
R0 & imm → R0
11001001iiiiiiii
—
1
—
AND.B #imm,@(R0,GBR)
(R0 + GBR) & imm →
(R0 + GBR)
11001101iiiiiiii
—
3
—
NOT
Rm,Rn
~Rm → Rn
0110nnnnmmmm0111
—
1
—
OR
Rm,Rn
Rn | Rm → Rn
0010nnnnmmmm1011
—
1
—
OR
#imm,R0
R0 | imm → R0
11001011iiiiiiii
—
1
—
OR.B
#imm,@(R0,GBR)
(R0 + GBR) | imm →
(R0 + GBR)
11001111iiiiiiii
—
3
—
TAS.B @Rn
If (Rn) is 0, 1 → T;
1 → MSB of (Rn)
0100nnnn00011011
—
3
Test
result
TST
Rm,Rn
Rn & Rm; if the result
is 0, 1 → T
0010nnnnmmmm1000
—
1
Test
result
TST
#imm,R0
R0 & imm; if the result
is 0, 1 → T
11001000iiiiiiii
—
1
Test
result
TST.B #imm,@(R0,GBR)
(R0 + GBR) & imm;
if the result is 0, 1 → T
11001100iiiiiiii
—
3
Test
result
XOR
Rm,Rn
Rn ^ Rm → Rn
0010nnnnmmmm1010
—
1
—
XOR
#imm,R0
R0 ^ imm → R0
11001010iiiiiiii
—
1
—
(R0 + GBR) ^ imm →
(R0 + GBR)
11001110iiiiiiii
—
3
—
XOR.B #imm,@(R0,GBR)
Rev. 5.00, 09/03, page 44 of 760
Table 2.9 lists the SH7709S shift instructions.
Table 2.9
Shift Instructions
Instruction
Operation
Code
Privileged
Mode
Cycles T Bit
ROTL
Rn
T ← Rn ← MSB
0100nnnn00000100
—
ROTR
Rn
LSB → Rn → T
0100nnnn00000101
—
1
LSB
ROTCL
Rn
T ← Rn ← T
0100nnnn00100100
—
1
MSB
ROTCR
Rn
T → Rn → T
0100nnnn00100101
—
1
LSB
SHAD
Rm,Rn
Rn ≥ 0: Rn << Rm → Rn
Rn < 0: Rn >> Rm →
[MSB → Rn]
0100nnnnmmmm1100
—
1
—
SHAL
Rn
T ← Rn ← 0
0100nnnn00100000
—
1
MSB
SHAR
Rn
MSB → Rn → T
0100nnnn00100001
—
1
LSB
SHLD
Rm,Rn
Rn ≥ 0: Rn << Rm → Rn
Rn < 0: Rn >> Rm →
[0 → Rn]
0100nnnnmmmm1101
—
1
—
SHLL
Rn
T ← Rn ← 0
0100nnnn00000000
—
1
MSB
SHLR
Rn
0 → Rn → T
0100nnnn00000001
—
1
LSB
SHLL2
Rn
Rn << 2 → Rn
0100nnnn00001000
—
1
—
SHLR2
Rn
Rn >> 2 → Rn
0100nnnn00001001
—
1
—
SHLL8
Rn
Rn << 8 → Rn
0100nnnn00011000
—
1
—
SHLR8
Rn
Rn >> 8 → Rn
0100nnnn00011001
—
1
—
SHLL16 Rn
Rn << 16 → Rn
0100nnnn00101000
—
1
—
SHLR16 Rn
Rn >> 16 → Rn
0100nnnn00101001
—
1
—
1
MSB
Rev. 5.00, 09/03, page 45 of 760
Table 2.10 lists the SH7709S branch instructions.
Table 2.10 Branch Instructions
Privileged
Mode
Cycles
T Bit
10001011dddddddd
—
3/1*
—
Delayed branch, if T = 0,
disp × 2 + PC → PC;
if T = 1, nop
10001111dddddddd
—
2/1*
—
label
if T = 1,
disp × 2 + PC → PC;
if T = 0, nop
10001001dddddddd
—
3/1*
—
BT/S
label
Delayed branch,
If T = 1, disp × 2 + PC → PC;
if T = 0, nop
10001101dddddddd
—
2/1*
—
BRA
label
Delayed branch,
disp × 2 + PC → PC
1010dddddddddddd
—
2
—
BRAF
Rm
Delayed branch,
Rm + PC → PC
0000mmmm00100011
—
2
—
BSR
label
Delayed branch, PC → PR,
disp × 2 + PC → PC
1011dddddddddddd
—
2
—
BSRF
Rm
Delayed branch, PC → PR,
Rm + PC → PC
0000mmmm00000011
—
2
—
JMP
@Rm
Delayed branch, Rm → PC
0100mmmm00101011
—
2
—
JSR
@Rm
Delayed branch, PC → PR,
Rm → PC
0100mmmm00001011
—
2
—
Delayed branch, PR → PC
0000000000001011
—
2
—
Instruction
Operation
BF
label
If T = 0, disp × 2 + PC → PC;
if T = 1, nop
BF/S
label
BT
RTS
Note: * One state when there is no branch.
Rev. 5.00, 09/03, page 46 of 760
Code
Table 2.11 lists the SH7709S system control instructions.
Table 2.11 System Control Instructions
Instruction
Operation
Code
Privileged
Mode
Cycles T Bit
CLRMAC
0 → MACH, MACL
0000000000101000
—
1
—
CLRS
0→S
0000000001001000
—
1
—
CLRT
0→T
0000000000001000
—
1
0
LDC
Rm,SR
Rm → SR
0100mmmm00001110
√
5
LSB
LDC
Rm,GBR
Rm → GBR
0100mmmm00011110
—
3
—
LDC
Rm,VBR
Rm → VBR
0100mmmm00101110
√
3
—
LDC
Rm,SSR
Rm → SSR
0100mmmm00111110
√
3
—
LDC
Rm,SPC
Rm → SPC
0100mmmm01001110
√
3
—
LDC
Rm,R0_BANK
Rm → R0_BANK
0100mmmm10001110
√
3
—
LDC
Rm,R1_BANK
Rm → R1_BANK
0100mmmm10011110
√
3
—
LDC
Rm,R2_BANK
Rm → R2_BANK
0100mmmm10101110
√
3
—
LDC
Rm,R3_BANK
Rm → R3_BANK
0100mmmm10111110
√
3
—
LDC
Rm,R4_BANK
Rm → R4_BANK
0100mmmm11001110
√
3
—
LDC
Rm,R5_BANK
Rm → R5_BANK
0100mmmm11011110
√
3
—
LDC
Rm,R6_BANK
Rm → R6_BANK
0100mmmm11101110
√
3
—
LDC
Rm,R7_BANK
Rm → R7_BANK
0100mmmm11111110
√
3
—
LDC.L @Rm+,SR
(Rm) → SR, Rm + 4 → Rm
0100mmmm00000111
√
7
LSB
LDC.L @Rm+,GBR
(Rm) → GBR, Rm + 4 → Rm
0100mmmm00010111
—
5
—
LDC.L @Rm+,VBR
(Rm) → VBR, Rm + 4 → Rm
0100mmmm00100111
√
5
—
LDC.L @Rm+,SSR
(Rm) → SSR, Rm + 4 → Rm
0100mmmm00110111
√
5
—
LDC.L @Rm+,SPC
(Rm) → SPC, Rm + 4 → Rm
0100mmmm01000111
√
5
—
LDC.L @Rm+,
R0_BANK
(Rm) → R0_BANK,
Rm + 4 → Rm
0100mmmm10000111
√
5
—
LDC.L @Rm+,
R1_BANK
(Rm) → R1_BANK,
Rm + 4 → Rm
0100mmmm10010111
√
5
—
LDC.L @Rm+,
R2_BANK
(Rm) → R2_BANK,
Rm + 4 → Rm
0100mmmm10100111
√
5
—
LDC.L @Rm+,
R3_BANK
(Rm) → R3_BANK,
Rm + 4 → Rm
0100mmmm10110111
√
5
—
LDC.L @Rm+,
R4_BANK
(Rm) → R4_BANK,
Rm + 4 → Rm
0100mmmm11000111
√
5
—
LDC.L @Rm+,
R5_BANK
(Rm) → R5_BANK,
Rm + 4 → Rm
0100mmmm11010111
√
5
—
Rev. 5.00, 09/03, page 47 of 760
Instruction
Operation
Code
Privileged
Mode
Cycles T Bit
LDC.L @Rm+,
R6_BANK
(Rm) → R6_BANK,
Rm + 4 → Rm
0100mmmm11100111
√
5
—
LDC.L @Rm+,
R7_BANK
(Rm) → R7_BANK,
Rm + 4 → Rm
0100mmmm11110111
√
5
—
LDS
Rm,MACH
Rm → MACH
0100mmmm00001010
—
1
—
LDS
Rm,MACL
Rm → MACL
0100mmmm00011010
—
1
—
LDS
Rm,PR
Rm → PR
0100mmmm00101010
—
1
—
LDS.L @Rm+,MACH
(Rm) → MACH, Rm + 4 → Rm
0100mmmm00000110
—
1
—
LDS.L @Rm+,MACL
(Rm) → MACL, Rm + 4 → Rm
0100mmmm00010110
—
1
—
LDS.L @Rm+,PR
(Rm) → PR, Rm + 4 → Rm
0100mmmm00100110
—
1
—
LDTLB
PTEH/PTEL → TLB
0000000000111000
√
1
—
No operation
0000000000001001
—
1
—
(Rm) → cache
0000mmmm10000011
—
2
—
RTE
Delayed branch,
SSR → SR, SPC → PC
0000000000101011
√
4
—
SETS
1→S
0000000001011000
—
1
—
SETT
1→T
0000000000011000
—
1
1
SLEEP
Sleep
0000000000011011
√
4*
—
NOP
PREF
@Rm
STC
SR,Rn
SR → Rn
0000nnnn00000010
√
1
—
STC
GBR,Rn
GBR → Rn
0000nnnn00010010
—
1
—
STC
VBR,Rn
VBR → Rn
0000nnnn00100010
√
1
—
STC
SSR,Rn
SSR → Rn
0000nnnn00110010
√
1
—
STC
SPC,Rn
SPC → Rn
0000nnnn01000010
√
1
—
STC
R0_BANK,Rn
R0_BANK→ Rn
0000nnnn10000010
√
1
—
STC
R1_BANK,Rn
R1_BANK→ Rn
0000nnnn10010010
√
1
—
STC
R2_BANK,Rn
R2_BANK→ Rn
0000nnnn10100010
√
1
—
STC
R3_BANK,Rn
R3_BANK→ Rn
0000nnnn10110010
√
1
—
STC
R4_BANK,Rn
R4_BANK→ Rn
0000nnnn11000010
√
1
—
STC
R5_BANK,Rn
R5_BANK→ Rn
0000nnnn11010010
√
1
—
STC
R6_BANK,Rn
R6_BANK→ Rn
0000nnnn11100010
√
1
—
STC
R7_BANK,Rn
R7_BANK→ Rn
0000nnnn11110010
√
1
—
STC.L SR,@–Rn
Rn–4 → Rn, SR → (Rn)
0100nnnn00000011
√
2
—
STC.L GBR,@–Rn
Rn–4 → Rn, GBR → (Rn)
0100nnnn00010011
—
2
—
STC.L VBR,@–Rn
Rn–4 → Rn, VBR → (Rn)
0100nnnn00100011
√
2
—
Note: * The number of cycles until the sleep state is entered.
Rev. 5.00, 09/03, page 48 of 760
Instruction
Operation
Code
Privileged
Mode
Cycles T Bit
STC.L SSR,@–Rn
Rn–4 → Rn, SSR → (Rn)
0100nnnn00110011
√
2
—
STC.L SPC,@–Rn
Rn–4 → Rn, SPC → (Rn)
0100nnnn01000011
√
2
—
STC.L R0_BANK,
@–Rn
Rn–4 → Rn, R0_BANK → (Rn)
0100nnnn10000011
√
2
—
STC.L R1_BANK,
@–Rn
Rn–4 → Rn, R1_BANK → (Rn)
0100nnnn10010011
√
2
—
STC.L R2_BANK,
@–Rn
Rn–4 → Rn, R2_BANK → (Rn)
0100nnnn10100011
√
2
—
STC.L R3_BANK,
@–Rn
Rn–4 → Rn, R3_BANK → (Rn)
0100nnnn10110011
√
2
—
STC.L R4_BANK,
@–Rn
Rn–4 → Rn, R4_BANK → (Rn)
0100nnnn11000011
√
2
—
STC.L R5_BANK,
@–Rn
Rn–4 → Rn, R5_BANK → (Rn)
0100nnnn11010011
√
2
—
STC.L R6_BANK,
@–Rn
Rn–4 → Rn, R6_BANK → (Rn)
0100nnnn11100011
√
2
—
STC.L R7_BANK,
@–Rn
Rn–4 → Rn, R7_BANK → (Rn)
0100nnnn11110011
√
2
—
STS
MACH,Rn
MACH → Rn
0000nnnn00001010
—
1
—
STS
MACL,Rn
MACL → Rn
0000nnnn00011010
—
1
—
STS
PR,Rn
PR → Rn
0000nnnn00101010
—
1
—
STS.L MACH,@–Rn
Rn–4 → Rn, MACH → (Rn)
0100nnnn00000010
—
1
—
STS.L MACL,@–Rn
Rn–4 → Rn, MACL → (Rn)
0100nnnn00010010
—
1
—
STS.L PR,@–Rn
Rn–4 → Rn, PR → (Rn)
0100nnnn00100010
—
1
—
TRAPA #imm
PC → SPC, SR → SSR,
imm → TRA
11000011iiiiiiii
—
8
—
Notes: 1. The table shows the minimum number of execution cycles. The actual number of
instruction execution cycles will increase in cases such as the following:
• When there is contention between an instruction fetch and data access
• When the destination register in a load (memory-to-register) instruction is also used
by the next instruction
2. With the addressing modes using displacement (disp) listed below, the assembler
descriptions in this manual show the value before scaling (×1, ×2, or ×4) is performed.
This is done to clarify the operation of the chip. For the actual assembler descriptions,
refer to the individual assembler notation rules.
@ (disp:4, Rn) ; Register-indirect with displacement
@ (disp:8, Rn) ; GBR-indirect with displacement
@ (disp:8, PC) ; PC-relative with displacement
disp:8, disp:12 ; PC-relative
Rev. 5.00, 09/03, page 49 of 760
2.4.2
Instruction Code Map
Table 2.12 shows the instruction code map.
Table 2.12 Instruction Code Map
Instruction Code
MSB
LSB
0000 Rn
Fx
0000
0000 Rn
Fx
0001
0000 Rn 00MD 0010 STC
Fx: 0000
MD: 00
SR,Rn
Fx: 0001
MD: 01
Fx: 0010
MD: 10
Fx: 0011 to 1111
MD: 11
STC GBR,Rn
STC VBR,Rn
STC SSR,Rn
0000 Rn 01MD 0010 STC
SPC,Rn
0000 Rn 10MD 0010 STC
R0_BANK,Rn
STC
R1_BANK,Rn
STC
R2_BANK,Rn
STC
R3_BANK,Rn
0000 Rn 11MD 0010 STC
R4_BANK,Rn
STC
R5_BANK,Rn
STC
R6_BANK,Rn
STC
R7_BANK,Rn
0000 Rm 00MD 0011 BSRF
Rm
BRAF
Rm
0000 Rn 10MD 0011 PREF
@Rn
0000 Rn
Rm,@(R0,Rn) MOV.W Rm,@(R0,Rn)
MOV.L
Rm,@(R0,Rn)
MUL.L
Rm,Rn
Rm 01MD MOV.B
0000 0000 00MD 1000 CLRT
SETT
0000 0000 01MD 1000 CLRS
SETS
0000 0000
Fx
1001 NOP
DIV0U
0000 0000
Fx
1010
0000 0000
Fx
1011 RTS
0000 Rn
Fx
1000
CLRMAC
SLEEP
RTE
0000 Rn
Fx
1001
0000 Rn
Fx
1010 STS
0000 Rn
Fx
1011
0000 Rn
Rm 11MD MOV.B
@(R0,Rm),Rn MOV.W @(R0,Rm),Rn
0001 Rn
Rm
Rm,@(disp:4,Rn)
0010 Rn
Rm 00MD MOV.B
Rm,@Rn
0010 Rn
Rm 01MD MOV.B
0010 Rn
Rm 10MD TST
0010 Rn
Rm 11MD CMP/STR Rm,Rn
disp MOV.L
LDTLB
MOVT
Rn
STS
PR,Rn
MOV.L
@(R0,Rm),Rn
MOV.W Rm,@Rn
MOV.L
Rm,@Rn
Rm,@-Rn
MOV.W Rm,@-Rn
MOV.L
Rm,@-Rn
Rm,Rn
AND
Rm,Rn
XOR
Rm,Rn
XTRCT
Rm,Rn
MULU.W Rm,Rn
CMP/HS Rm,Rn
CMP/GE Rm,Rn
DMULU.LRm,Rn
CMP/HI Rm,Rn
CMP/GT Rm,Rn
SUBC
Rm,Rn
SUBV
Rm,Rn
DMULS.L Rm,Rn
ADDC
Rm,Rn
ADDV
Rm,Rn
MACH,Rn
0011 Rn
Rm 00MD CMP/EQ Rm,Rn
0011 Rn
Rm 01MD DIV1
0011 Rn
Rm 10MD SUB
Rm,Rn
0011 Rn
Rm 11MD ADD
Rm,Rn
Rm,Rn
Rev. 5.00, 09/03, page 50 of 760
STS
MACL,Rn
MAC.L
@Rm+,@Rn+
DIV0S
Rm,Rn
OR
Rm,Rn
MULSW Rm,Rn
Instruction Code
MSB
0100 Rn
Fx: 0000
MD: 00
LSB
Fx
0000 SHLL
Rn
Fx: 0001
MD: 01
DT
Rn
Fx: 0010
MD: 10
SHAL
Fx: 0011 to 1111
MD: 11
Rn
0100 Rn
Fx
0001 SHLR
Rn
CMP/PZ Rn
SHAR
Rn
0100 Rn
Fx
0010 STS.L
MACH,@-Rn
STS.L
MACL,@-Rn
STS.L
PR,@-Rn
0100 Rn 00MD 0011 STC.L
SR,@-Rn
STC.L
GBR,@-Rn
STC.L
VBR,@-Rn
STC.L
SSR,@-Rn
0100 Rn 01MD 0011 STC.L
SPC,@-Rn
0100 Rn 10MD 0011 STC.L
R0_BANK,@-Rn
STC.L
R1_BANK,@-Rn
STC.L
R2_BANK,@-Rn
STC.L
R3_BANK,@-Rn
0100 Rn 11MD 0011 STC.L
R4_BANK,@-Rn
STC.L
R5_BANK,@-Rn
STC.L
R6_BANK,@-Rn
STC.L
R7_BANK,@-Rn
0100 Rn
Fx
0100 ROTL
Rn
ROTCL
Rn
0100 Rn
Fx
0101 ROTR
Rn
0100 Rm
Fx
0110 LDS.L
@Rm+,MACH LDS.L
@Rm+,MACL
LDS.L
@Rm+,PR
0100 Rm 00MD 0111 LDC.L
@Rm+,SR
@Rm+,GBR
LDC.L
@Rm+,VBR
LDC.L
@Rm+,SSR
0100 Rm 01MD 0111 LDC.L
@Rm+,SPC
CMP/PL Rn
LDC.L
ROTCR Rn
0100 Rm 10MD 0111 LDC.L
@Rm+,R0_BANK LDC.L
@Rm+,R1_BANK
LDC.L
@Rm+,R2_BANK LDC.L
@Rm+,R3_BANK
0100 Rm 11MD 0111 LDC.L
@Rm+,R4_BANK LDC.L
@Rm+,R5_BANK LDC.L
@Rm+,R6_BANK LDC.L
@Rm+,R7_BANK
0100 Rn
Fx
1000 SHLL2
Rn
SHLL8
Rn
SHLL16 Rn
0100 Rn
Fx
1001 SHLR2
Rn
SHLR8
Rn
SHLR16 Rn
0100 Rm
Fx
1010 LDS
Rm,MACH
LDS
Rm,MACL
LDS
Rm,PR
0100 Rm/
Rn
Fx
1011 JSR
@Rm
TAS.B
@Rn
JMP
@Rm
0100 Rn
Rm 1100 SHAD
Rm,Rn
0100 Rn
Rm 1101 SHLD
Rm,Rn
LDC
Rm,GBR
LDC
Rm,VBR
LDC
Rm,SSR
0100 Rm 00MD 1110 LDC
Rm,SR
0100 Rm 01MD 1110 LDC
Rm,SPC
0100 Rm 10MD 1110 LDC
Rm,R0_BANK LDC
Rm,R1_BANK
LDC
Rm,R2_BANK
LDC
Rm,R3_BANK
0100 Rm 11MD 1110 LDC
Rm,R4_BANK LDC
Rm,R5_BANK
LDC
Rm,R6_BANK
LDC
Rm,R7_BANK
MOV.L
@Rm,Rn
MOV
Rm,Rn
0100 Rn
Rm 1111 MAC.W
0101 Rn
Rm
0110 Rn
Rm 00MD MOV.B
@Rm,Rn
0110 Rn
Rm 01MD MOV.B
@Rm+,Rn
MOV.W @Rm+,Rn
MOV.L
@Rm+,Rn
NOT
Rm,Rn
0110 Rn
Rm 10MD SWAP.B Rm,Rn
SWAP.W Rm,Rn
NEGC
Rm,Rn
NEG
Rm,Rn
0110 Rn
Rm 11MD EXTU.B Rm,Rn
EXTU.W Rm,Rn
EXTS.B Rm,Rn
0111 Rn
disp MOV.L
@Rm+,@Rn+
imm
ADD
@(disp:4,Rm),Rn
MOV.W @Rm,Rn
EXTS.W Rm,Rn
#imm:8,Rn
Rev. 5.00, 09/03, page 51 of 760
Instruction Code
MSB
Fx: 0000
MD: 00
LSB
Fx: 0001
MD: 01
1000 00MD Rn
disp MOV.B
R0,@(disp:4,Rn)
MOV.W
R0,@(disp:4,Rn)
1000 01MD Rm
disp MOV.B
@(disp:4,Rm),R0
MOV.W
@(disp:4,Rm),R0
1000 10MD imm/disp
CMP/EQ #imm:8,R0
1000 11MD imm/disp
1001 Rn
disp
Fx: 0010
MD: 10
Fx: 0011 to 1111
MD: 11
BT
label:8
BF
label:8
BT/S
label:8
BF/S
label:8
#imm:8
MOV.W @(DISP:8,PC),RN
1010
disp
BRA
label:12
1011
disp
BSR
label:12
1100 00MD imm/disp
MOV.B
R0,@(disp:8,GBR)
MOV.W
R0,@(disp:8,GBR)
MOV.L
R0,@(disp:8,GBR)
TRAPA
1100 01MD
disp
MOV.B
@(disp:8,GBR),R0
MOV.W
@(disp:8,GBR),R0
MOV.L
@(disp:8,GBR),R0
MOVA
@(disp:8,PC),R0
1100 10MD
imm
TST
AND
XOR
OR
1100 11MD
imm
TST.B
#imm:8,@(R0,GBR)
#imm:8,R0
#imm:8,R0
AND.B
#imm:8,@(R0,GBR)
1101 Rn
disp
MOV.L
@(disp:8,PC),Rn
1110 Rn
imm
MOV
#imm:8,Rn
1111
************
Note:
See the SH-3/SH-3E/SH3-DSP Programming Manual for details.
Rev. 5.00, 09/03, page 52 of 760
#imm:8,R0
XOR.B
#imm:8,@(R0,GBR)
#imm:8,R0
OR.B
#imm:8,@(R0,GBR)
2.5
Processor States and Processor Modes
2.5.1
Processor States
The SH7709S has five processor states: the reset state, exception-handling state, bus-released
state, program execution state, and power-down state.
Reset State: In this state the CPU is reset. The CPU enters the power-on reset state if the RESETP
pin is low, or the manual reset state if the RESETM pin is low. See section 4, Exception Handling,
for more information on resets.
In the power-on reset state, the internal states of the CPU and the on-chip supporting module
registers are initialized. In the manual reset state, the internal states of the CPU and registers of onchip supporting modules other than the bus state controller (BSC) are initialized. Refer to the
register configurations in the relevant sections for further details.
Exception-Handling State: This is a transient state during which the CPU’s processor state flow
is altered by a reset, general exception, or interrupt exception handling.
In the case of a reset, the CPU branches to address H'A0000000 and starts executing the usercoded exception handling program.
In the case of a general exception or interrupt, the program counter (PC) contents are saved in the
saved program counter (SPC) and the status register (SR) contents are saved in the saved status
register (SSR). The CPU branches to the start address of the user-coded exception service routine
found from the sum of the contents of the vector base address and the vector offset. See section 4,
Exception Processing, for more information on resets, general exceptions, and interrupts.
Program Execution State: In this state the CPU executes program instructions in sequence.
Power-Down State: In the power-down state, CPU operation halts and power consumption is
reduced. There are two modes in the power-down state: sleep mode, and standby mode. See
section 8, Power-Down Modes, for more information.
Bus-Released State: In this state the CPU has released the bus to a device that requested it.
Transitions between the states are shown in figure 2.8.
Rev. 5.00, 09/03, page 53 of 760
From any state when
RESETP = 0
From any state but hardware standby
mode when RESETM = 0
RESETP = 0
Power-on reset
state
Manual reset
state
Reset state
RESETP = 1
RESETM = 1
Exception-handling state
Interrupt
Bu
sr
eq
st
ue
u
eq
sr
Bu
Bus-released state
Bus
request
ce
ran
ea
cl
est
Exception
interrupt
End of exception
transition
processing
Bu
cle s requ
ara
nce est
Bus
req
Program execution state
ues
t
Bus
request
clearance
SLEEP
instruction
with STBY
bit cleared
Interrupt
SLEEP
instruction
with STBY
bit set
Sleep mode
Standby mode
Hardware standby mode*
CA = 1,RESETP=0
Power-down state
Note: * The hardware standby mode is entered when the CA pin goes low from any state.
Figure 2.8 Processor State Transitions
2.5.2
Processor Modes
There are two processor modes: privileged mode and user mode. The processor mode is
determined by the processor mode bit (MD) in the status register (SR). User mode is selected
when the MD bit is 0, and privileged mode when the MD bit is 1. When the reset state or
exception state is entered, the MD bit is set to 1. When exception handling ends, the MD bit is
cleared to 0 and user mode is entered. There are certain registers and bits which can only be
accessed in privileged mode.
Rev. 5.00, 09/03, page 54 of 760
Section 3 Memory Management Unit (MMU)
3.1
Overview
3.1.1
Features
The SH7709S has an on-chip memory management unit (MMU) that implements address
translation. The SH7709S features a resident translation look-aside buffer (TLB) that caches
information for user-created address translation tables located in external memory. It enables highspeed translation of virtual addresses into physical addresses. Address translation uses the paging
system and supports two page sizes (1 kbytes and 4 kbytes). The access right to virtual address
space can be set for privileged and user modes to provide memory protection.
3.1.2
Role of MMU
The MMU is a feature designed to make efficient use of physical memory. As shown in figure 3.1,
if a process is smaller in size than the physical memory, the entire process can be mapped onto
physical memory. However, if the process increases in size to the extent that it no longer fits into
physical memory, it becomes necessary to partition the process and to map those parts requiring
execution onto memory as occasion demands ((1)). Having the process itself consider this
mapping onto physical memory would impose a large burden on the process. To lighten this
burden, the idea of virtual memory was born as a means of performing en bloc mapping onto
physical memory ((2)). In a virtual memory system, substantially more virtual memory than
physical memory is provided, and the process is mapped onto this virtual memory. Thus a process
only has to consider operation in virtual memory. Mapping from virtual memory to physical
memory is handled by the MMU. The MMU is normally controlled by the operating system,
switching physical memory to allow the virtual memory required by a process to be mapped onto
physical memory in a smooth fashion. Switching of physical memory is carried out via secondary
storage, etc.
The virtual memory system that came into being in this way is particularly effective in a timesharing system (TSS) in which a number of processes are running simultaneously ((3)). If
processes running in a TSS had to take mapping onto virtual memory into consideration while
running, it would not be possible to increase efficiency. Virtual memory is thus used to reduce this
load on the individual processes and so improve efficiency ((4)). In the virtual memory system,
virtual memory is allocated to each process. The task of the MMU is to perform efficient mapping
of these virtual memory areas onto physical memory. It also has a memory protection feature that
prevents one process from inadvertently accessing another process’s physical memory.
When address translation from virtual memory to physical memory is performed using the MMU,
it may occur that the relevant translation information is not recorded in the MMU, with the result
that one process may inadvertently access the virtual memory allocated to another process. In this
Rev. 5.00, 09/03, page 55 of 760
case, the MMU will generate an exception, change the physical memory mapping, and record the
new address translation information.
Although the functions of the MMU could also be implemented by software alone, the need for
translation to be performed by software each time a process accesses physical memory would
result in poor efficiency. For this reason, a buffer for address translation (translation look-aside
buffer: TLB) is provided in hardware to hold frequently used address translation information. The
TLB can be described as a cache for storing address translation information. Unlike cache
memory, however, if address translation fails, that is, if an exception is generated, switching of
address translation information is normally performed by software. This makes it possible for
memory management to be performed flexibly by software.
The MMU has two methods of mapping from virtual memory to physical memory: a paging
method using fixed-length address translation, and a segment method using variable-length
address translation. With the paging method, the unit of translation is a fixed-size address space
(usually of 1 to 64 kbytes) called a page. This LSI uses the paging method.
In the following text, the SH7709S address space in virtual memory is referred to as virtual
address space, and address space in physical memory as physical memory space.
Rev. 5.00, 09/03, page 56 of 760
Virtual
memory
Process 1
Physical
memory
Process 1
MMU
Physical
memory
Physical
memory
Process 1
(2)
(1)
Process 1
Process 1
Virtual
memory
MMU
Physical
memory
Physical
memory
Process 2
Process 2
Process 3
Process 3
(3)
(4)
Figure 3.1 MMU Functions
Rev. 5.00, 09/03, page 57 of 760
3.1.3
SH7709S MMU
Virtual Address Space: The SH7709S uses 32-bit virtual addresses to access a 4-Gbyte virtual
address space that is divided into several areas. Address space mapping is shown in figure 3.2.
• Privileged Mode
In privileged mode, there are five areas, P0–P4. The P0 and P3 areas are mapped onto physical
address space in page units, in accordance with address translation table information. Writeback or write-through can be selected for write access by means of a cache control register
(CCR) setting.
Mapping of the P1 area is fixed in physical address space (H'00000000 to H'1FFFFFFF). In
the P1 area, setting a virtual address MSB (bit 31) to 0 generates the corresponding physical
address. P1 area accesses can be cached, and the cache control register (CCR) is set to indicate
whether to cache or not. Write-back or write-through mode can be selected.
Mapping of the P2 area is fixed in physical address space (H'00000000 to H'1FFFFFFF). In the
P2 area, setting the top three virtual address bits (bits 31, 30, and 29) to 0 generates the
corresponding physical address. P2 area access cannot be cached.
The P1 and P2 areas are not mapped by the address translation table, so the TLB is not used
and no exceptions such as TLB misses occur. Initialization of MMU control registers,
exception handling routines, and the like should be located in the P1 and P2 areas. Routines
that require high-speed processing should be placed in the P1 area, since it can be cached.
Some peripheral module control registers are located in area 1 of the physical address space.
When the physical address space is not used for address translation, these registers should be
located in the P2 area. When address translation is to be used, set no caching.
The P4 area is used for mapping peripheral module register addresses, etc.
• User Mode
In user mode, 2 Gbytes of the virtual address space from H'00000000 to H'7FFFFFFF (area
U0) can be accessed. U0 is mapped onto physical address space in page units, in accordance
with address translation table information.
Rev. 5.00, 09/03, page 58 of 760
H'00000000
H'00000000
2-Gbyte virtual space,
cacheable
(write-back/write-through)
H'80000000
H'A0000000
H'C0000000
H'E0000000
Area U0
H'80000000
0.5-Gbyte fixed physical
space, cacheable
(write-back/write-through)
Area P1
0.5-Gbyte fixed
physical space,
non-cacheable
Area P2
0.5-Gbyte virtual space,
cacheable
(write-back/write-through)
Area P3
0.5-Gbyte control space,
non-cacheable
2-Gbyte virtual space,
cacheable
(write-back/write-through)
Area P0
Address error
Area P4
H'FFFFFFFF
H'FFFFFFFF
Privileged mode
User mode
Figure 3.2 Virtual Address Space Mapping
Physical Address Space: The SH7709S supports a 32-bit physical address space, but the upper 3
bits are actually ignored and treated as a shadow. See section 10, Bus State Controller (BSC), for
details.
Address Translation: When the MMU is enabled, the virtual address space is divided into units
called pages. Physical addresses are translated in page units. Address translation tables in external
memory hold information such as the physical address that corresponds to the virtual address and
memory protection codes. When an access to an area other than P4 occurs, if the accessed virtual
address belongs to area P1 or P2 there is no TLB access and the physical address is uniquely
defined. If it belongs to area P0, P3, or U0, the TLB is searched by virtual address and, if that
virtual address is registered in the TLB, the access hits the TLB. The corresponding physical
address and the page control information are read from the TLB and the physical address is
determined.
Rev. 5.00, 09/03, page 59 of 760
If the virtual address is not registered in the TLB, a TLB miss exception occurs and processing
will shift to the TLB miss handler. In the TLB miss handler, the TLB address translation table in
external memory is searched and the corresponding physical address and the page control
information are registered in the TLB. After returning from the handler, the instruction that caused
the TLB miss is re-executed. When the MMU is enabled, address translation information that
results in a physical address space of H'80000000–H'FFFFFFFF should not be registered in the
TLB.
When the MMU is disabled, the virtual address is used directly as the physical address. As the
SH7709S supports a 29-bit address space as the physical address space, the top 3 bits of the
physical address are ignored, and constitute a shadow space (see section 10, Bus State Controller
(BSC)). For example, addresses H'00001000 in the P0 area, H'80001000 in the P1 area,
H'A0001000 in the P2 area, and H'C0001000 in the P3 area are all mapped onto the same physical
address. When access to these addresses is performed with the cache enabled, an address with the
top 3 bits of the physical address masked to 0 is stored in the cache address array to ensure data
congruity.
Single Virtual Memory Mode and Multiple Virtual Memory Mode: There are two virtual
memory modes: single virtual memory mode and multiple virtual memory mode. In single virtual
memory mode, multiple processes run in parallel using the virtual address space exclusively and
the physical address corresponding to a given virtual address is specified uniquely. In multiple
virtual memory mode, multiple processes run in parallel sharing the virtual address space, so a
given virtual address may be translated into different physical addresses depending on the process.
Single or multiple virtual mode is selected by a value set in the MMU control register (MMUCR).
In terms of operation, the only difference between single virtual memory mode and multiple
virtual memory mode is in the TLB address comparison method (see section 3.3.3, TLB Address
Comparison).
Address Space Identifier (ASID): In multiple virtual memory mode, the address space identifier
(ASID) is used to differentiate between processes running in parallel and sharing virtual address
space. The ASID is 8 bits in length and can be set by software setting of the ASID of the currently
running process in the page table entry register high (PTEH) within the MMU. When the process
is switched using the ASID, the TLB does not have to be purged.
In single virtual memory mode, the ASID is used to provide memory protection for processes
running simultaneously and using the virtual address space exclusively (see section 3.4.2, MMU
Software Management).
Rev. 5.00, 09/03, page 60 of 760
3.1.4
Register Configuration
A register that has an undefined initial value must be initialized by software. Table 3.1 shows the
configuration of the MMU control registers.
Table 3.1
Register Configuration
Name
Abbreviation
R/W
Size
Initial
Value*1
Address
Page table entry register high
PTEH
R/W
Longword
Undefined
H'FFFFFFF0
Page table entry register low
PTEL
R/W
Longword
Undefined
H'FFFFFFF4
Translation table base register
TTB
R/W
Longword
Undefined
H'FFFFFFF8
TLB exception address register
TEA
R/W
Longword
MMUCR
R/W
Longword
Undefined
*2
H'FFFFFFFC
MMU control register
H'FFFFFFE0
Notes: 1. Initialized by a power-on reset or manual reset.
2. SV bit: undefined
Other bits: 0
3.2
Register Description
There are five registers for MMU processing. These registers are located in address space area P4
and can only be accessed from privileged mode by specifying the address.
1. The page table entry register high (PTEH) register residing at address H'FFFFFFF0, which
consists of a virtual page number (VPN) and ASID. The VPN set is the VPN of the virtual
address at which the exception is generated in case of an MMU exception or address error
exception. When the page size is 4 kbytes, the VPN is the upper 20 bits of the virtual address,
but in this case the upper 22 bits of the virtual address are set. The VPN can also be modified
by software. As the ASID, software sets the number of the currently executing process. The
VPN and ASID are recorded in the TLB by the LDTLB instruction.
2. The page table entry register low (PTEL) register residing at address H'FFFFFFF4, and used to
store the physical page number and page management information to be recorded in the TLB
by the LDTLB instruction. The contents of this register are only modified in response to a
software command. (Refer to section 3.4.3, MMU Instruction (LDTLB), and section 3.5,
MMU Exceptions.)
3. The translation table base register (TTB) residing at address H'FFFFFFF8, which points to the
base address of the current page table. The hardware does not set any value in TTB
automatically. TTB is available to software for general purposes.
4. The TLB exception address register (TEA) residing at address H'FFFFFFFC, which stores the
virtual address corresponding to a TLB or address error exception. This value remains valid
until the next exception or interrupt.
Rev. 5.00, 09/03, page 61 of 760
5. The MMU control register (MMUCR) residing at address H'FFFFFFE0, which makes the
MMU settings described in figure 3.3. Any program that modifies MMUCR should reside in
the P1 or P2 area.
The MMU registers are shown in figure 3.3.
31
10
VPN
7
0
0
ASID
PTEH
31 29 28
10 9 8 7 6
000
PPN
0
V* 0
4 3 2 1 0
PR* SZ* C* D* SH* 0
PTEL
31
0
TTB
TTB
31
0
Virtual address causing TLB-related
or address error exception
TEA
31
8
0
7 6543 2 1
0
SV 00 RC 0 TF IX AT
MMUCR
0: Reserved bits. Always read as 0. Writing is ignored. However, 0 should also be
specified in a write to MMUCR only.
SV: Single virtual memory mode bit. 0: Multiple virtual memory mode
1: Single virtual memory mode
RC: A 2-bit random counter, automatically updated by hardware according to the
following rules in the event of an MMU exception. When a TLB miss exception
occurs, all TLB entry ways corresponding to the virtual address at which the
exception occurred are checked, and if all ways are valid, 1 is added to RC; if
there is one or more invalid way, they are set by priority from way 0, in the order:
way 0, way 1, way 2, way 3. In the event of an MMU exception other than a TLB
miss exception, the way which caused the exception is set in RC.
TF: TLB flush bit. Write 1 to flush the TLB (clear all valid bits of the TLB to 0). Always
reads 0.
IX: Index mode bit. When 0, VPN bits 16−12 are used as the TLB index number.
When 1, the value obtained by EX-ORing ASID bits 4−0 in PTEH and VPN bits
16−12 are used as the TLB index number.
AT: Address translation bit. Enables/disables the MMU.
0: MMU disabled
1: MMU enabled
Note: * Refer to section 3.3, TLB Functions.
Figure 3.3 MMU Register Contents
Rev. 5.00, 09/03, page 62 of 760
3.3
TLB Functions
3.3.1
Configuration of the TLB
The TLB caches address translation table information located in the external memory. The address
translation table stores the physical page number translated from the virtual page number and the
control information for the page, which is the unit of address translation. Figure 3.4 shows the
overall TLB configuration. The TLB is 4-way set associative with 128 entries. There are 32 entries
for each way. Figure 3.5 shows the configuration of virtual addresses and TLB entries.
Ways 0−3
Entry 0
VPN(31−17)
VPN(11−10) ASID(7−0)
Ways 0−3
V
Entry 0 PPN(28−10) PR(1−0) SZ C D SH
Entry 1
Entry 1
Entry 31
Entry 31
Address array
Data array
Figure 3.4 Overall Configuration of the TLB
Rev. 5.00, 09/03, page 63 of 760
31
10 9
VPN
0
Offset
Virtual address (1-kbyte page)
12 11
31
VPN
0
Offset
Virtual address (4-kbyte page)
(15)
(2)
(8)
VPN (31–17) VPN (11–10) ASID
(1)
(19)
(2) (1) (1) (1) (1)
V
PPN
PR SZ C SH D
TLB entry
Legend:
VPN: Virtual page number. Top 22 bits of virtual address for a 1-kbyte page, or top 20 bits of
virtual address for a 4-kbyte page. Since VPN bits 16-12 are used as the index number, they
are not stored in the TLB entry.
ASID: Address space identifier. Indicates the process that can access a virtual page. In single
virtual memory mode and user mode, or in multiple virtual memory mode, if the SH bit is 0,
the address is compared with the ASID in PTEH when address comparison is performed.
SH: Share status bit
0 = Page not shared between processes
1 = Page shared between processes
SZ: Page-size bit
0 = 1-kbyte page
1 = 4-kbyte page
V: Valid bit. Indicates whether entry is valid.
0 = Invalid
1 = Valid
Cleared to 0 by a power-on reset. Not affected by a manual reset.
PPN: Physical page number. Top 29 bits of physical address. PPN bits 11-10 are not used in case
of a 4-kbyte page. Attention must be paid to the synonym problem in case of a 1-kbyte page
(see section 3.4.4, Avoiding Synonym Problems).
PR: Set the most significant bit to 0.
Protection key field. 2-bit field encoded to define the access rights to the page.
00: Reading only is possible in privileged mode.
01: Reading/writing is possible in privileged mode.
10: Reading only is possible in privileged/user mode.
11: Reading/writing is possible in privileged/user mode.
C: Cacheable bit. Indicates whether the page is cacheable.
0: Non-cacheable
1: Cacheable
D: Dirty bit. Indicates whether the page has been written to.
0 = Not written to
1 = Written to
Figure 3.5 Virtual Address and TLB Structure
Rev. 5.00, 09/03, page 64 of 760
3.3.2
TLB Indexing
The TLB uses a 4-way set associative scheme, so entries must be selected by index. VPN bits 16
to 12 and ASID bits 4 to 0 in PTEH are used as the index number regardless of the page size. The
index number can be generated in two different ways depending on the setting of the IX bit in
MMUCR.
1. When IX = 0, VPN bits 16–12 alone are used as the index number
2. When IX = 1, VPN bits 16–12 are EX-ORed with ASID bits 4–0 to generate a 5-bit index
number
The second method is used to prevent lowered TLB efficiency that results when multiple
processes run simultaneously in the same virtual address space (multiple virtual memory) and a
specific entry is selected by generating an index number for each process. Figures 3.6 and 3.7
show the indexing schemes.
Virtual address
31
17 16 12 11
PTEH register
31
0
10
VPN
7
0
0
ASID
ASID(4−0)
Exclusive-OR
Index
Ways 0−3
0
VPN(31−17)
VPN(11−10)
ASID(7−0)
V
PPN(28−10) PR(1−0) SZ C
D
SH
31
Address array
Data array
Figure 3.6 TLB Indexing (IX = 1)
Rev. 5.00, 09/03, page 65 of 760
Virtual address
31
17 16 12 11
0
Index
Ways 0−3
0
VPN(31−17)
VPN(11−10)
ASID(7−0)
V
PPN(28−10) PR(1−0) SZ C
D SH
31
Address array
Data array
Figure 3.7 TLB Indexing (IX = 0)
3.3.3
TLB Address Comparison
The results of address comparison determine whether a specific virtual page number is registered
in the TLB. The virtual page number of the virtual address that accesses external memory is
compared to the virtual page number of the indexed TLB entry. The ASID within the PTEH is
compared to the ASID of the indexed TLB entry. All four ways are searched simultaneously. If the
compared values match, and the indexed TLB entry is valid (V bit = 1), the hit is registered.
It is necessary to have software ensure that TLB hits do not occur simultaneously in more than one
way, as hardware operation is not guaranteed if this occurs. For example, if there are two identical
TLB entries with the same VPN and a setting is made such that a TLB hit is made only by a
process with ASID = H'FF when one is in the shared state (SH = 1) and the other in the non-shared
state (SH = 0), then if the ASID in PTEH is set to H'FF, there is a possibility of simultaneous TLB
hits in both these ways. It is therefore necessary to ensure that this kind of setting is not made by
software.
The object compared varies depending on the page management information (SZ, SH) in the TLB
entry. It also varies depending on whether the system supports multiple virtual memory or single
virtual memory.
The page-size information determines whether VPN (11–10) is compared. VPN (11–10) is
compared for 1-kbyte pages (SZ = 0) but not for 4-kbyte pages (SZ = 1).
Rev. 5.00, 09/03, page 66 of 760
The sharing information (SH) determines whether the PTEH.ASID and the ASID in the TLB entry
are compared. ASIDs are compared when there is no sharing between processes (SH = 0) but not
when there is sharing (SH = 1).
When single virtual memory is supported (MMUCR.SV = 1) and privileged mode is engaged
(SR.MD = 1), all process resources can be accessed. This means that ASIDs are not compared
when single virtual memory is supported and privileged mode is engaged. The objects of address
comparison are shown in figure 3.8.
SH = 1 or
(SR.MD = 1 and
MMUCR.SV = 1)?
No
Yes
No (4 kbytes)
No (4 kbytes)
SZ = 0?
SZ = 0?
Yes (1 kbyte)
Bits compared:
VPN (31−17)
VPN (11−10)
Bits compared:
VPN (31−17)
Yes (1 kbyte)
Bits compared:
VPN (31−17)
VPN (11−10)
ASID (7−0)
Bits compared:
VPN (31−17)
ASID (7−0)
Figure 3.8 Objects of Address Comparison
Rev. 5.00, 09/03, page 67 of 760
3.3.4
Page Management Information
In addition to the SH and SZ bits, the page management information of TLB entries also includes
D, C, and PR bits.
The D bit of a TLB entry indicates whether the page is dirty (i.e., has been written to). If the D bit
is 0, an attempt to write to the page results in an initial page write exception. For physical page
swapping between secondary memory and main memory, for example, pages are controlled so that
a dirty page is paged out of main memory only after that page is written back to secondary
memory.
The C bit in the entry indicates whether the referenced page resides in a cacheable or noncacheable area of memory. When the control register in area 1 is mapped, set the C bit to 0. The
PR field specifies the access rights for the page in privileged and user modes and is used to protect
memory. Attempts at nonpermitted accesses result in TLB protection violation exceptions.
Access states designated by the D, C, and PR bits are shown in table 3.2.
Table 3.2
Access States Designated by D, C, and PR Bits
Privileged Mode
D bit
C bit
PR bit
User Mode
Reading
Writing
Reading
Writing
0
Permitted
Initial page write
exception
Permitted
Initial page write
exception
1
Permitted
Permitted
Permitted
Permitted
0
Permitted
(no caching)
Permitted
(no caching)
Permitted
(no caching)
Permitted
(no caching)
1
Permitted
(with caching)
Permitted
(with caching)
Permitted
(with caching)
Permitted
(with caching)
00
Permitted
TLB protection
violation exception
TLB protection
violation
exception
TLB protection
violation exception
01
Permitted
Permitted
TLB protection
violation
exception
TLB protection
violation exception
10
Permitted
TLB protection
violation exception
Permitted
TLB protection
violation exception
11
Permitted
Permitted
Permitted
Permitted
Rev. 5.00, 09/03, page 68 of 760
3.4
MMU Functions
3.4.1
MMU Hardware Management
There are two kinds of MMU hardware management as follows:
1. The MMU decodes the virtual address accessed by a process and performs address translation
by controlling the TLB in accordance with the MMUCR settings.
2. In address translation, the MMU receives page management information from the TLB, and
determines the MMU exception and whether the cache is to be accessed (using the C bit). For
details of the determination method and the hardware processing, see section 3.5, MMU
Exceptions.
3.4.2
MMU Software Management
There are three kinds of MMU software management, as follows.
1. MMU register setting. MMUCR setting, in particular, should be performed in areas P1 and P2
for which address translation is not performed. Also, since SV and IX bit changes constitute
address translation system changes, in this case, TLB flushing should be performed by
simultaneously writing 1 to the TF bit also. Since MMU exceptions are not generated in the
MMU disabled state with the AT bit cleared to 0, use in the disabled state must be avoided
with software that does not use the MMU.
2. TLB entry recording, deletion, and reading. TLB entry recording can be done in two ways by
using the LDTLB instruction, or by writing directly to the memory-mapped TLB. For TLB
entry deletion and reading, the memory allocation TLB can be accessed. See section 3.4.3,
MMU Instruction (LDTLB), for details of the LDTLB instruction, and section 3.6,
Configuration of Memory-Mapped TLB, for details of the memory-mapped TLB.
3. MMU exception processing. When an MMU exception is generated, it is handled on the basis
of information set from the hardware side. See section 3.5, MMU Exceptions, for details.
When single virtual memory mode is used, it is possible to create a state in which physical
memory access is enabled in the privileged mode only by clearing the share status bit (SH) to 0 to
specify recording of all TLB entries. This strengthens inter-process memory protection, and
enables special access levels to be created in the privileged mode only.
Recording a 1-kbyte page TLB entry may result in a synonym problem. See section 3.4.4,
Avoiding Synonym Problems.
Rev. 5.00, 09/03, page 69 of 760
3.4.3
MMU Instruction (LDTLB)
The load TLB instruction (LDTLB) is used to record TLB entries. When the IX bit in MMUCR is
0, the LDTLB instruction changes the TLB entry in the way specified by the RC bit in MMUCR
to the value specified by PTEH and PTEL, using VPN bits 16–12 specified in PTEH as the index
number. When the IX bit in MMUCR is 1, the EX-OR of VPN bits 16–12 specified in PTEH and
ASID bits 4–0 in PTEH are used as the index number.
Figure 3.9 shows the case where the IX bit in MMUCR is 0.
When an MMU exception occurs, the virtual page number of the virtual address that caused the
exception is set in PTEH by hardware. The way is set in the RC bit of MMUCR for each
exception (see figure 3.3). Consequently, if the LDTLB instruction is issued after setting only
PTEL in the MMU exception handling routine, TLB entry recording is possible. Any TLB entry
can be updated by software rewriting of PTEH and the RC bits in MMUCR.
As the LDTLB instruction changes address translation information, there is a risk of destroying
address translation information if this instruction is issued in the P0, U0, or P3 area. Make sure,
therefore, that this instruction is issued in the P1 or P2 area. Also, an instruction associated with an
access to the P0, U0, or P3 area (such as the RTE instruction) should be issued at least two
instructions after the LDTLB instruction.
Rev. 5.00, 09/03, page 70 of 760
MMUCR
31
9
0
0
SV 0 0 RC 0 TF IX AT
Way selection
Index
PTEH register
31
17
VPN
12
10
VPN
8
0
PTEL register
31 29 28
10
0
000
ASID
PPN
0
0 V 0 PR SZ C D SH 0
Write
Write
Ways 0 to 3
0
VPN(31−17)
VPN(11−10)
ASID(7−0)
V
PPN(28−10) PR(1−0) SZ C
D SH
31
Address array
Data array
Figure 3.9 Operation of LDTLB Instruction
Rev. 5.00, 09/03, page 71 of 760
3.4.4
Avoiding Synonym Problems
When a 1-kbyte page is recorded in a TLB entry, a synonym problem may arise. If a number of
virtual addresses are mapped onto a single physical address, the same physical address data will be
recorded in a number of cache entries, and it will not be possible to guarantee data congruity. The
reason why this problem only occurs when using a 1-kbyte page is explained below with reference
to figure 3.10.
To achieve high-speed operation of the SH7709S cache, an index number is created using virtual
address bits 11–4. When a 4-kbyte page is used, virtual address bits 11–4 are included in the
offset, and since they are not subject to address translation, they are the same as physical address
bits 11–4. In cache-based address comparison and recording in the address array, since the cache
tag address is a physical address, physical address bits 28–10 are recorded.
When a 1-kbyte page is used, also, a cache index number is created using virtual address bits 11-4.
However, in case of a 1-kbyte page, virtual address bit (11, 10) is subject to address translation
and therefore may not be the same as physical address bit (11, 10). Consequently, the physical
address is recorded in a different entry from that of the index number indicated by the physical
address in the cache address array.
For example, assume that, with 1-kbyte page TLB entries, TLB entries for which the following
translation has been performed are recorded in two TLBs:
Virtual address 1 H'00000000 → physical address
Virtual address 2 H'00000400 → physical address
H'00000400
H'00000400
Virtual address 1 is recorded in cache entry H'00, and virtual address 2 in cache entry H'C0. Since
two virtual addresses are recorded in different cache entries despite the fact that the physical
addresses are the same, memory inconsistency will occur as soon as a write is performed to either
virtual address. Therefore, when recording a 1-kbyte TLB entry, if the physical address is the same
as a physical address already used in another TLB entry, it should be recorded in such a way that
physical address bit (11, 10) is the same.
Note: In readiness for the future expansion of the SuperH RISC engine family, we recommend
that, when multiple sets of address translation information are mapped onto the same
physical area of memory, you set the VPN numbers so that each VPN [20:10] is equal to
the others. We also recommend that you do not map multiple sets of address-translation
information that include 1- and 4-kbyte pages to a single physical area.
Rev. 5.00, 09/03, page 72 of 760
When using a 4-kbyte page
Virtual address
0
12 11 10
31
VPN
Offset
Virtual address (11−4)
Physical address
31 29 28
PPN
000
0
12 11 10
Cache address
array
Offset
Physical address (28−10)
When using a 1-kbyte page
Virtual address
11 10 9
31
VPN
Virtual address (11−4)
Physical address
31 29 28
000
PPN
0
Offset
11 10 9
0
Cache address
array
Offset
Physical address (28−10)
Figure 3.10 Synonym Problem
Rev. 5.00, 09/03, page 73 of 760
3.5
MMU Exceptions
There are four MMU exceptions: TLB miss, TLB protection violation, TLB invalid, and initial
page write.
3.5.1
TLB Miss Exception
A TLB miss results when the virtual address and the address array of the selected TLB entry are
compared and no match is found. TLB miss exception processing includes both hardware and
software operations.
Hardware Operations: In a TLB miss, the SH7709S hardware executes a set of prescribed
operations, as follows:
1. The VPN field of the virtual address causing the exception is written to the PTEH register.
2. The virtual address causing the exception is written to the TEA register.
3. Either exception code H'040 for a load access, or H'060 for a store access, is written to the
EXPEVT register.
4. The PC value indicating the address of the instruction in which the exception occurred is
written to the save program counter (SPC). If the exception occurred in a delay slot, the PC
value indicating the address of the related delayed branch instruction is written to the SPC.
5. The contents of the status register (SR) at the time of the exception are written to the save
status register (SSR).
6. The mode (MD) bit in SR is set to 1 to place the SH7709S in the privileged mode.
7. The block (BL) bit in SR is set to 1 to mask any further exception requests.
8. The register bank (RB) bit in SR is set to 1.
9. The random counter (RC) field in the MMU control register (MMUCR) is incremented by 1
when all ways are checked for the TLB entry corresponding to the logical address at which the
exception occurred, and all ways are valid. If one or more ways are invalid, those ways are set
in RC in prioritized order from way 0 through way 1, way 2, and way 3.
10. Execution branches to the address obtained by adding the value of the VBR contents and
H'00000400 to invoke the user-written TLB miss exception handler.
Software (TLB Miss Handler) Operations: The software searches the page tables in external
memory and allocates the required page table entry. Upon retrieving the required page table entry,
software must execute the following operations:
1. Write the value of the physical page number (PPN) field and the protection key (PR), page size
(SZ), cacheable (C), dirty (D), share status (SH), and valid (V) bits of the page table entry
recorded in the address translation table in the external memory into the PTEL register in the
SH7709S.
Rev. 5.00, 09/03, page 74 of 760
2. If using software for way selection for entry replacement, write the desired value to the RC
field in MMUCR.
3. Issue the LDTLB instruction to load the contents of PTEH and PTEL into the TLB.
4. Issue the return from exception handler (RTE) instruction to terminate the handler routine and
return to the instruction stream.
3.5.2
TLB Protection Violation Exception
A TLB protection violation exception results when the virtual address and the address array of the
selected TLB entry are compared and a valid entry is found to match, but the type of access is not
permitted by the access rights specified in the PR field. TLB protection violation exception
processing includes both hardware and software operations.
Hardware Operations: In a TLB protection violation exception, the SH7709S hardware executes
a set of prescribed operations, as follows:
1. The VPN field of the virtual address causing the exception is written to the PTEH register.
2. The virtual address causing the exception is written to the TEA register.
3. Either exception code H'0A0 for a load access, or H'0C0 for a store access, is written to the
EXPEVT register.
4. The PC value indicating the address of the instruction in which the exception occurred is
written into SPC (if the exception occurred in a delay slot, the PC value indicating the address
of the related delayed branch instruction is written into SPC).
5. The contents of SR at the time of the exception are written to SSR.
6. The MD bit in SR is set to 1 to place the SH7709S in the privileged mode.
7. The BL bit in SR is set to 1 to mask any further exception requests.
8. The register bank (RB) bit in SR is set to 1.
9. The way that generated the exception is set in the RC field in MMUCR.
10. Execution branches to the address obtained by adding the value of the VBR contents and
H'00000100 to invoke the TLB protection violation exception handler.
Software (TLB Protection Violation Handler) Operations: Software resolves the TLB
protection violation and issues the RTE (return from exception handler) instruction to terminate
the handler and return to the instruction stream.
Rev. 5.00, 09/03, page 75 of 760
3.5.3
TLB Invalid Exception
A TLB invalid exception results when the virtual address is compared to a selected TLB entry
address array and a match is found but the entry is not valid (the V bit is 0). TLB invalid exception
processing includes both hardware and software operations.
Hardware Operations: In a TLB invalid exception, the SH7709S hardware executes a set of
prescribed operations, as follows:
1. The VPN number of the virtual address causing the exception is written to the PTEH register.
2. The virtual address causing the exception is written to the TEA register.
3. The way number causing the exception is written to RC in MMUCR.
4. Either exception code H'040 for a load access, or H'060 for a store access, is written to the
EXPEVT register.
5. The PC value indicating the address of the instruction in which the exception occurred is
written to the SPC. If the exception occurred in a delay slot, the PC value indicating the
address of the delayed branch instruction is written to the SPC.
6. The contents of SR at the time of the exception are written into SSR.
7. The mode (MD) bit in SR is set to 1 to place the SH7709S in the privileged mode.
8. The block (BL) bit in SR is set to 1 to mask any further exception requests.
9. The register bank (RB) bit in SR is set to 1.
10. Execution branches to the address obtained by adding the value of the VBR contents and
H'00000100, and the TLB protection violation exception handler starts.
Software (TLB Invalid Exception Handler) Operations: The software searches the page tables
in external memory and assigns the required page table entry. Upon retrieving the required page
table entry, software must execute the following operations:
1. Write the values of the physical page number (PPN) field and the values of the protection key
(PR), page size (SZ), cacheable (C), dirty (D), share status (SH), and valid (V) bits of the page
table entry recorded in the external memory to the PTEL register.
2. If using software for way selection for entry replacement, write the desired value to the RC
field in MMUCR.
3. Issue the LDTLB instruction to load the contents of PTEH and PTEL into the TLB.
4. Issue the RTE instruction to terminate the handler and return to the instruction stream. The
RTE instruction should be issued after two LDTLB instructions.
Rev. 5.00, 09/03, page 76 of 760
3.5.4
Initial Page Write Exception
An initial page write exception results in a write access when the virtual address and the address
array of the selected TLB entry are compared and a valid entry with the appropriate access rights
is found to match, but the D (dirty) bit of the entry is 0 (the page has not been written to). Initial
page write exception processing includes both hardware and software operations.
Hardware Operations: In an initial page write exception, the SH7709S hardware executes a set
of prescribed operations, as follows:
1. The VPN field of the virtual address causing the exception is written to the PTEH register.
2. The virtual address causing the exception is written to the TEA register.
3. Exception code H'080 is written to the EXPEVT register.
4. The PC value indicating the address of the instruction in which the exception occurred is
written to the SPC. If the exception occurred in a delay slot, the PC value indicating the
address of the related delayed branch instruction is written to the SPC.
5. The contents of SR at the time of the exception are written to SSR.
6. The MD bit in SR is set to 1 to place the SH7709S in the privileged mode.
7. The BL bit in SR is set to 1 to mask any further exception requests.
8. The register bank (RB) bit in SR is set to 1.
9. The way that caused the exception is set in the RC field in MMUCR.
10. Execution branches to the address obtained by adding the value of the VBR contents and
H'00000100 to invoke the user-written initial page write exception handler.
Software (Initial Page Write Handler) Operations: The software must execute the following
operations:
1. Retrieve the required page table entry from external memory.
2. Set the D bit of the page table entry in the external memory to 1.
3. Write the value of the PPN field and the PR, SZ, C, D, SH, and V bits of the page table entry
in the external memory to the PTEL register.
4. If using software for way selection for entry replacement, write the desired value to the RC
field in MMUCR.
5. Issue the LDTLB instruction to load the contents of PTEH and PTEL into the TLB.
6. Issue the RTE instruction to terminate the handler and return to the instruction stream. The
RTE instruction should be issued after two LDTLB instructions.
Figure 3.11 shows the flowchart for MMU exceptions.
Rev. 5.00, 09/03, page 77 of 760
Start
SH = 0
and (MMUCR.SV = 0
or SR.MD = 0)?
No
No
Yes
VPNs match?
VPNs
and ASIDs
match?
No
Yes
Yes
No
V = 1?
TLB miss
exception
TLB invalid
exception
Yes
User mode
Privileged mode
User or
privileged?
PR check
00/01
W
10
R/W?
R
PR check
11
R/W?
01/11
W
W
R
No
R/W?
00/10
W
R/W?
R
R
D = 1?
Yes
TLB protection
violation
exception
Initial page
write
exception
No (noncacheable)
Memory
access
TLB protection
violation
C = 1?
Yes (cacheable)
Cache
access
Figure 3.11 MMU Exception Generation Flowchart
Rev. 5.00, 09/03, page 78 of 760
3.5.5
Processing Flow in Event of MMU Exception (Same Processing Flow for Address
Error)
Figure 3.12 shows the MMU exception signals in the instruction fetch mode.
IF
ID
EX
MA
WB
ID
EX
MA
ID
EX
Handler transition
processing
WB
MA
WB
NOP
NOP
MMU exception handler
IF
ID
EX
MA
WB
: Exception source stage
IF
ID
EX
MA
WB
NOP
= Instruction fetch
= Instruction decode
= Instruction execution
= Memory access
= Write back
= No operation
Figure 3.12 MMU Exception Signals in Instruction Fetch
Rev. 5.00, 09/03, page 79 of 760
Figure 3.13 shows the MMU exception signals in the data access mode.
IF
ID
EX
MA
WB
IF
ID
EX
MA
WB
IF
ID
EX
MA
WB
ID
EX
MA
WB
ID
EX
MA
WB
ID
EX
MA WB
Handler transition
processing
NOP
NOP
MMU exception handler
IF
ID
EX
MA WB
: Exception source stage
: Stage cancellation for instruction
that has begun execution
IF
ID
EX
MA
WB
NOP
= Instruction fetch
= Instruction decode
= Instruction execution
= Memory access
= Write back
= No operation
Figure 3.13 MMU Exception Signals in Data Access
3.6
Configuration of Memory-Mapped TLB
To allow the management of TLB operations by software, the MOV instruction can be used, in the
privileged mode, to read and write TLB contents. The TLB is mapped to the P4 area of the virtual
address space. The TLB address array (VPN, V bit, and ASID) is mapped to H'F2000000 to
H'F2FFFFFF, and the TLB data array (PPN, PR, SZ, CD, S, and H bits) is mapped to H'F3000000
to H'F3FFFFFF. It is also possible to access the V bits in the address array from the data array.
Only longword access is possible, for both the address and data arrays.
3.6.1
Address Array
The address array is mapped to H'F2000000 to H'F2FFFFFF. To access the address array, the 32bit address field (for read/write access) and 32-bit data field (for write access) must be specified.
The address field has the information that selects the entry to be accessed; the data field specifies
the VPN, the V bit, and the ASID to be written to the address array (figure 3.14 (1)).
Rev. 5.00, 09/03, page 80 of 760
In the address field, specify VPN in bits 16-12 as the index address that selects the entry, W in bits
9-8 to select the way, and H'F2 in bits 31-24 to indicate access to the address array. Selection of
the index address depends on the MMUCR.IX setting.
The following 2 types of operations on the address array are possible.
(1) Address Array Read
Reads VPN, V bit, and ASID from the entry that corresponds to the entry address and way that
were specified in the address field.
(2) Address Array Write
Writes the data set in the data field to the entry that corresponds to the entry address and way
that were specified in the address field.
3.6.2
Data Array
The data array is assigned to H'F3000000 to H'F3FFFFFF. To access a data array, the 32-bit
address field (for read/write operations), and 32-bit data field (for write operations) must be
specified. These are specified in the general register. The address section specifies information for
selecting the entry to be accessed; the data section specifies the longword data to be written to the
data array (figure 3.14 (2)).
In the address section, specify the entry address for selecting the entry (bits 16–12), W for
selecting the way (bits 9–8: 00 is way 0, 01 is way 1, 10 is way 2, 11 is way 3), and H'F3 to
indicate data array access (bits 31–24). The IX bit in MMUCR indicates whether an EX-OR is
taken of the entry address and ASID.
Both reading and writing use the longword of the data array specified by the index address and
way number. The access size of the data array is fixed at longword.
Rev. 5.00, 09/03, page 81 of 760
(1) TLB Address Array Access
Read access
17 16
24 23
31
Address field
11110010
*
*
17 16
31
Data field
VPN
12 11 10 9 8 7 6
VPN
* * W
0
0 *
*
12 11 10 9 8 7
0
0 VPN 0 V
0
ASID
Write access
31
Address field
24 23
11110010
17 16
*
*
17 16
31
Data field
* * W
0
0 *
*
12 11 10 9 8 7
*
VPN
VPN:
V:
W:
12 11 10 9 8 7 6
VPN
* VPN * V
0
ASID
Virtual page number
ASID: Address space identifier
Valid bit
* : Don't care bit
Way (00: Way 0, 01: Way 1, 10: Way 2, 11: Way 3)
(2) TLB Data Array Access
Read/write access
31
Address field
31
Data field
17 16
24 23
11110011
*
29 28
12 11 10 9 8 7
0
* * W *
*
VPN
10 9 8 7 6 5 4
PPN
000
PPN:
PR:
C:
SH:
VPN:
X:
W:
*
3 2
1
0
X V X PR SZ C D SH X
Physical page number
V: Valid bit
Protection key field
SZ: Page-size bit
Cacheable bit
D: Dirty bit
* : Don't care bit
Share status bit
Virtual page number
0 for read, don’t care bit for write
Way (00: Way 0, 01: Way 1, 10: Way 2, 11: Way 3)
Figure 3.14 Specifying Address and Data for Memory-Mapped TLB Access
Rev. 5.00, 09/03, page 82 of 760
3.6.3
Usage Examples
Invalidating Specific Entries: Specific TLB entries can be invalidated by writing 0 to the entry’s
V bit. When the A bit is 1, the VPN and ASID specified by the write data is compared to the VPN
and ASID within the TLB entry selected by the entry address and data is written to the matching
way. If no match is found, there is no operation. R0 specifies the write data and R1 specifies the
address.
; R0=H'1547 381C
R1=H'F201 3000
; MMUCR.IX=0
; VPN(31–17)=B'0001 0101 0100 011
VPN(11–10)=B'10
ASID=B'0001 1100
; corresponding entry association is made from the entry selected by
; the VPN(16–12)=B'1 0011 index, the V bit of the hit way is cleared to
; 0,achieving invalidation.
MOV.L
R0,@R1
Reading the Data of a Specific Entry: This example reads the data section of a specific TLB
entry. The bit order indicated in the data field in figure 3.14 (2) is read. R0 specifies the address
and the data section of a selected entry is read to R1.
; R1=H'F300 4300
VPN(16-12)=B'00100
Way 3
MOV.L @R0,R1
3.7
Usage Note
The operations listed below must only be performed when the TLB is disabled or in the P1 or P2
area. Any subsequent operation that accesses the P0, P3, or U0 area must take place two or more
instructions after any of the below operations.
1. Change SR.MD or SR.BL
2. Execute the LDTLB instruction
3. Write to the memory-mapped TLB
4. Change MMUCR.
Rev. 5.00, 09/03, page 83 of 760
Rev. 5.00, 09/03, page 84 of 760
Section 4 Exception Handling
4.1
Overview
4.1.1
Features
Exception handling is separate from normal program processing, and is performed by a routine
separate from the normal program. In response to an exception handling request due to abnormal
termination of the executing instruction, control is passed to a user-written exception handler.
However, in response to an interrupt request, normal program execution continues until the end of
the executing instruction. Here, all exceptions other than resets and interrupts will be called
general exceptions. There are thus three types of exceptions: resets, general exceptions, and
interrupts.
4.1.2
Register Configuration
Table 4.1 lists the registers used for exception handling. A register with an undefined initial value
should be initialized by software.
Table 4.1
Register Configuration
Register
Abbr.
R/W
Size
Initial Value
Address
TRAPA exception register
TRA
R/W
Longword
Undefined
H'FFFFFFD0
Exception event register
EXPEVT
R/W
Longword
Power-on reset: H'000 H'FFFFFFD4
1
Manual reset: H'020*
Interrupt event register
INTEVT
R/W
Longword
Undefined
H'FFFFFFD8
Interrupt event register2
INTEVT2 R
Longword
Undefined
H'04000000
2
(H'A4000000)*
Notes: 1. H'000 is set in a power-on reset, and H'020 in a manual reset.
2. When address translation by the MMU does not apply, the address in parentheses
should be used.
4.2
Exception Handling Function
4.2.1
Exception Handling Flow
In exception handling, the contents of the program counter (PC) and status register (SR) are saved
in the saved program counter (SPC) and saved status register (SSR), respectively, and execution of
the exception handler is invoked from a vector address. The return from exception handler (RTE)
instruction is issued by the exception handler routine on completion of the routine, restoring the
Rev. 5.00, 09/03, page 85 of 760
contents of PC and SR to return to the processor state at the point of interruption and the address
where the exception occurred.
A basic exception handling sequence consists of the following operations:
1. The contents of PC and SR are saved in SPC and SSR, respectively.
2. The block (BL) bit in SR is set to 1, masking any subsequent exceptions.
3. The mode (MD) bit in SR is set to 1 to place the SH7709S in privileged mode.
4. The register bank (RB) bit in SR is set to 1.
5. An exception code identifying the exception event is written to bits 11–0 of the exception
event (EXPEVT) or interrupt event (INTEVT or INTEVT2) register.
6. Instruction execution jumps to the designated exception vector address to invoke the handler
routine.
4.2.2
Exception Vector Addresses
The reset vector address is fixed at H'A0000000. The other three events are assigned offsets from
the vector base address by software. Translation look-aside buffer (TLB) miss exceptions have an
offset from the vector base address of H'00000400. The vector address offset for general exception
events other than TLB miss exceptions is H'00000100. The interrupt vector address offset is
H'00000600. The vector base address is loaded into the vector base register (VBR) by software.
The vector base address should reside in P1 or P2 fixed physical address space. Figure 4.1 shows
the relationship between the vector base address, the vector offset, and the vector table.
VBR
+ Vector offset
(Vector base address)
H'A000 0000
Vector table
Figure 4.1 Vector Table
In table 4.2, exceptions and their vector addresses are listed by exception type, instruction
completion state, relative acceptance priority, relative order of occurrence within an instruction
execution sequence and vector address for exceptions and their vector addresses.
Rev. 5.00, 09/03, page 86 of 760
Table 4.2
Exception Event Vectors
Exception Current
Type
Instruction Exception Event
Exception Vector
1
Priority* Order
Address
Reset
Power-on reset
1
—
H'A00000000 —
Manual reset
1
—
H'A00000000 —
Aborted
UDI reset
General
exception
events
General
interrupt
requests
Vector
Offset
1
—
H'A00000000 —
2
1
—
H'00000100
TLB miss
2
2
—
H'00000400
TLB invalid
(instruction access)
2
3
—
H'00000100
TLB protection
violation (instruction
access)
2
4
—
H'00000100
General illegal
instruction exception
2
5
—
H'00000100
Illegal slot instruction
exception
2
5
—
H'00000100
CPU address error
(data access)
2
6
—
H'00000100
TLB miss (data access 2
not in repeat loop)
7
—
H'00000400
TLB invalid (data
access)
2
8
—
H'00000100
TLB protection
2
violation (data access)
9
—
H'00000100
Initial page write
2
10
—
H'00000100
Completed Unconditional trap
(TRAPA instruction)
2
5
—
H'00000100
User breakpoint trap
2
n*
—
H'00000100
DMA address error
2
—
—
H'00000100
Completed Nonmaskable interrupt 3
Aborted
CPU address error
and retried (instruction access)
2
—
—
H'00000600
External hardware
interrupt
3
4*
—
—
H'00000600
UDI interrupt
4*
3
—
—
H'00000600
Notes: 1. Priorities are indicated from high to low, 1 being the highest and 4 the lowest.
2. The user defines the break point traps. 1 is a break point before instruction execution
and 11 is a break point after instruction execution. For an operand break point, use 11.
3. Use software to specify relative priorities of external hardware interrupts and peripheral
module interrupts (see section 6, Interrupt Controller (INTC)).
Rev. 5.00, 09/03, page 87 of 760
4.2.3
Acceptance of Exceptions
Processor resets and interrupts are asynchronous events unrelated to the instruction stream. All
exception events are prioritized to establish an acceptance order whenever two or more exception
events occur simultaneously.
All general exception events occur in a relative order in the execution sequence of an instruction
(i.e. execution order), but are handled at priority level 2 in instruction-stream order (i.e. program
order), where an exception detected in a preceding instruction is accepted prior to an exception
detected in a subsequent instruction.
Three general exception events (reserved instruction code exception, unconditional trap, and slot
illegal instruction exception) are detected in the decode stage (ID stage) of different instructions
and are mutually exclusive events in the instruction pipeline. They have the same execution
priority. Figure 4.2 shows the order of general exception acceptance.
Rev. 5.00, 09/03, page 88 of 760
Pipeline Sequence:
Instruction n
IF
ID
EX
MA
WB
TLB miss (data access)
Instruction n + 1
IF
ID
EX
MA
WB
TLB miss (instruction access)
Instruction n + 2
IF
ID
EX
MA
WB
RIE (reserved instruction exception)
Detection Order:
TLB miss (instruction n+1)
TLB miss (instruction n) and general illegal instruction exception (instruction n + 2)
= simultaneous detection
Handling Order:
Program Order:
TLB miss (instruction n)
1
Re-execution of instruction n
TLB miss (instruction n + 1)
2
Re-execution of instruction n + 1
RIE (instruction n + 2)
IF
ID
EX
MA
WB
3
= Instruction fetch
= Instruction decode
= Instruction execution
= Memory access
= Write back
Figure 4.2 Example of Acceptance Order of General Exceptions
All exceptions other than a reset are detected in the pipeline ID stage, and accepted at instruction
boundaries. However, an exception is not accepted between a delayed branch instruction and the
delay slot. A re-execution type exception detected in a delay slot is accepted before execution of
the delayed branch instruction. A completion type exception detected in a delayed branch
Rev. 5.00, 09/03, page 89 of 760
instruction or delay slot is accepted after execution of the delayed branch instruction. The delay
slot here refers either to the next instruction after a delayed unconditional branch instruction or to
the next instruction when a delayed conditional branch instruction is true.
4.2.4
Exception Codes
Table 4.3 lists the exception codes written to the EXPEVT register (for reset or general
exceptions) or the INTEVT and INTEVT2 registers (for general interrupt requests) to identify
each specific exception event.
Table 4.3
Exception Codes
Exception Type
Exception Event
Exception Code
Reset
Power-on reset
H'000
Manual reset
H'020
UDI reset
H'000
TLB miss/invalid (read)
H'040
TLB miss/invalid (write)
H'060
General exception events
General interrupt requests
Initial page write
H'080
TLB protection violation (read)
H'0A0
TLB protection violation (write)
H'0C0
CPU address error (read)
H'0E0
CPU address error (write)
H'100
Unconditional trap (TRAPA instruction)
H'160
Illegal general instruction exception
H'180
Illegal slot instruction exception
H'1A0
User breakpoint trap
H'1E0
DMA address error
H'5C0
Nonmaskable interrupt
H'1C0
UDI interrupt
H'5E0
External hardware interrupts:
Rev. 5.00, 09/03, page 90 of 760
IRL3–IRL0 = 0000
H'200
IRL3–IRL0 = 0001
H'220
Exception Type
Exception Event
General interrupt requests
(cont)
External hardware interrupts (cont):
4.2.5
Exception Code
IRL3–IRL0 = 0010
H'240
IRL3–IRL0 = 0011
H'260
IRL3–IRL0 = 0100
H'280
IRL3–IRL0 = 0101
H'2A0
IRL3–IRL0 = 0110
H'2C0
IRL3–IRL0 = 0111
H'2E0
IRL3–IRL0 = 1000
H'300
IRL3–IRL0 = 1001
H'320
IRL3–IRL0 = 1010
H'340
IRL3–IRL0 = 1011
H'360
IRL3–IRL0 = 1100
H'380
IRL3–IRL0 = 1101
H'3A0
IRL3–IRL0 = 1110
H'3C0
Exception Request Masks
When the BL bit in SR is 0, exceptions and interrupts are accepted.
If a general exception event occurs when the BL bit in SR is 1, the CPU’s internal registers are set
to their post-reset state, other module registers retain their contents prior to the general exception,
and a branch is made to the same address (H'A0000000) as for a reset.
If a general interrupt occurs when BL = 1, the request is masked (held pending) and not accepted
until the BL bit is cleared to 0 by software. For reentrant exception handling, SPC and SSR must
be saved and the BL bit in SR cleared to 0.
4.2.6
Returning from Exception Handling
The RTE instruction is used to return from exception handling. When RTE is executed, the SPC
value is set in PC, and the SSR value in SR, and the return from exception handling is performed
by branching to the SPC address.
If SPC and SSR have been saved in external memory, set the BL bit in SR to 1, then restore SPC
and SSR, and issue an RTE instruction.
Rev. 5.00, 09/03, page 91 of 760
4.3
Register Descriptions
There are four registers related to exception handling. These are peripheral module registers, and
therefore reside in area P4. They can be accessed by specifying the address in privileged mode
only.
1. The exception event register (EXPEVT) resides at address H'FFFFFFD4, and contains a 12-bit
exception code. The exception code set in EXPEVT is that for a reset or general exception
event. The exception code is set automatically by hardware when an exception occurs.
EXPEVT can also be modified by software.
2. The interrupt event register (INTEVT) resides at address H'FFFFFFD8, and contains a 12-bit
interrupt exception code or a code indicating the interrupt priority. Which is set when an
interrupt occurs depends on the interrupt source (see tables 6.4 and 6.5). The exception code or
interrupt priority code is set automatically by hardware when an exception occurs. INTEVT
can also be modified by software.
3. Interrupt event register 2 (INTEVT2) resides at address H'04000000, and contains a 12-bit
exception code. The exception code set in INTEVT2 is that for an interrupt request. The
exception code is set automatically by hardware when an exception occurs.
4. The TRAPA exception register (TRA) resides at address H'FFFFFFD0, and contains 8-bit
immediate data (imm) for the TRAPA instruction. TRA is set automatically by hardware when
a TRAPA instruction is executed. TRA can also be modified by software.
The bit configurations of the EXPEVT, INTEVT, INTEVT2, and TRA registers are shown in
figure 4.3.
EXPEVT, INTEVT, and INTEVT2 registers
TRA register
31
0
31
0 Exception code
0
0
0:
11
9
0
2 0
imm
00
Reserved bits, always read as 0
imm: 8-bit immediate data in TRAPA instruction
Figure 4.3 Bit Configurations of EXPEVT, INTEVT, INTEVT2, and TRA Registers
Rev. 5.00, 09/03, page 92 of 760
4.4
Exception Handling Operation
4.4.1
Reset
The reset sequence is used to power up or restart the SH7709S from the initialization state. The
RESETP and RESETM signals are sampled every clock cycle, and in the case of a power-on reset,
all processing being executed (excluding the RTC) is suspended, all unfinished events are
canceled, and reset processing is executed immediately. In the case of a manual reset, however,
reset processing is executed after completion of any memory access being executed. The reset
sequence consists of the following operations:
1. The MD bit in SR is set to 1 to place the SH7709S in privileged mode.
2. The BL bit in SR is set to 1, masking any subsequent exceptions (except the NMI interrupt
when the BLMSK bit is 1).
3. The RB bit in SR is set to 1.
4. An encoded value of H'000 in a power-on reset or H'020 in a manual reset is written to bits 11–
0 of the EXPEVT register to identify the exception event.
5. Instruction execution jumps to the user-written exception handler at address H'A0000000.
4.4.2
Interrupts
An interrupt handling request is accepted on completion of the current instruction. The interrupt
acceptance sequence consists of the following operations:
1. The contents of PC and SR are saved to SPC and SSR, respectively.
2. The BL bit in SR is set to 1, masking any subsequent exceptions (except the NMI interrupt
when the BLMSK bit is 1).
3. The MD bit in SR is set to 1 to place the SH7709S in privileged mode.
4. The RB bit in SR is set to 1.
5. An encoded value identifying the exception event is written to bits 11–0 of the INTEVT and
INTEVT2 registers.
6. Instruction execution jumps to the vector location designated by the sum of the value of the
contents of the vector base register (VBR) and H'00000600 to invoke the exception handler.
Rev. 5.00, 09/03, page 93 of 760
4.4.3
General Exceptions
When the SH7709S encounters any exception condition other than a reset or interrupt request, it
executes the following operations:
1. The contents of PC and SR are saved to SPC and SSR, respectively.
2. The BL bit in SR is set to 1, masking any subsequent exceptions (except the NMI interrupt
when the BLMSK bit is 1).
3. The MD bit in SR is set to 1 to place the SH7709S in privileged mode.
4. The RB bit in SR is set to 1.
5. Instruction execution jumps to the vector location designated by either the sum of the vector
base address and offset H'00000400 in the vector table in a TLB miss trap, or by the sum of the
vector base address and offset H'00000100 for exceptions other than TLB miss traps, to invoke
the exception handler.
4.5
Individual Exception Operations
This section describes the conditions for specific exception handling, and this LSI operations.
4.5.1
Resets
• Power-On Reset
 Conditions: RESETP low
 Operations: EXPEVT set to H'000, VBR and SR initialized, branch to PC = H'A0000000.
Initialization sets the VBR register to H'0000000. In SR, the MD, RB and BL bits are set to
1 and the interrupt mask bits (I3 to I0) are set to B'1111. The CPU and on-chip peripheral
modules are initialized. See the register descriptions in the relevant sections for details. A
power-on reset must always be performed when powering on. A low level is output from
the RESETOUT pin, and a high level is output from the STATUS0 and STATUS1 pins.
• Manual Reset
 Conditions: RESETM low
 Operations: EXPEVT set to H'020, VBR and SR initialized, branch to PC = H'A0000000.
Initialization sets the VBR register to H'0000000. In SR, the MD, RB, and BL bits are set
to 1 and the interrupt mask bits (I3 to I0) are set to B'1111. The CPU and on-chip
peripheral modules are initialized. See the register descriptions in the relevant sections for
details. A low level is output from the RESETOUT pin, and a high level is output from the
STATUS0 and STATUS1 pins.
Rev. 5.00, 09/03, page 94 of 760
• UDI Reset
 Conditions: UDI reset command input (see section 22.4.3, UDI Reset)
 Operations: EXPEVT set to H'000, VBR and SR initialized, branch to PC = H'A0000000.
Initialization sets the VBR register to H'0000000. In SR, the MD, RB and BL bits are set to
1 and the interrupt mask bits (I3 to I0) are set to B'1111. The CPU and on-chip peripheral
modules are initialized. See the register descriptions in the relevant sections for details.
Table 4.4
Types of Reset
Internal State
Conditions for Transition
to Reset State
CPU
On-Chip Peripheral Modules
Power-on
reset
RESETP = Low
Initialized
(See register configuration in
relevant sections)
Manual
reset
RESETM = Low
Initialized
UDI
reset
UDI reset command input
Initialized
Type
4.5.2
General Exceptions
• TLB miss exception
 Conditions: Comparison of TLB addresses shows no address match.
 Operations: The virtual address (32 bits) that caused the exception is set in TEA and the
corresponding virtual page number (22 bits) is set in PTEH (31–10). The ASID of PTEH
indicates the ASID at the time the exception occurred. If all ways are valid, 1 is added to
the RC bit in MMUCR. If there is one or more invalid way, they are set by priority starting
with way 0.
PC and SR of the instruction that generated the exception are saved to SPC and SSR,
respectively. If the exception occurred during a read, H'040 is set in EXPEVT; if the exception
occurred during a write, H'060 is set in EXPEVT. The BL, MD and RB bits in SR are set to 1
and a branch occurs to PC = VBR + H'0400.
To speed up TLB miss processing, the offset differs from other exceptions.
Rev. 5.00, 09/03, page 95 of 760
• TLB invalid exception
 Conditions: Comparison of TLB addresses shows address match but the TLB entry valid
bit (V) is 0.
 Operations: The virtual address (32 bits) that caused the exception is set in TEA and the
corresponding virtual page number (22 bits) is set in PTEH (31–10). The ASID of PTEH
indicates the ASID at the time the exception occurred. The way that generated the
exception is set in the RC bits in MMUCR.
PC and SR of the instruction that generated the exception are saved to SPC and SSR,
respectively. If the exception occurred during a read, H'040 is set in EXPEVT; if the exception
occurred during a write, H'060 is set in EXPEVT. The BL, MD, and RB bits in SR are set to 1
and a branch occurs to PC = VBR + H'0100.
• Initial page write exception
 Conditions: A hit occurred to the TLB for a store access, but the TLB entry data bit (D) is
0.
This occurs for initial writes to the page registered by the load.
 Operations: The virtual address (32 bits) that caused the exception is set in TEA and the
corresponding virtual page number (22 bits) is set in PTEH (31–10). The ASID of PTEH
indicates the ASID at the time the exception occurred. The way that generated the
exception is set in the RC bit in MMUCR.
PC and SR of the instruction that generated the exception are saved to SPC and SSR,
respectively. H'080 is set in EXPEVT. The BL, MD, and RB bits in SR are set to 1 and a
branch occurs to PC = VBR + H'0100.
• TLB protection exception
 Conditions: When a hit access violates the TLB protection information (PR bits) shown
below:
PR
Privileged mode
User mode
00
Only read enabled
No access
01
Read/write enabled
No access
10
Only read enabled
Only read enabled
11
Read/write enabled
Read/write enabled
 Operations: The virtual address (32 bits) that caused the exception is set in TEA and the
corresponding virtual page number (22 bits) is set in PTEH (31–10). The ASID of PTEH
indicates the ASID at the time the exception occurred. The way that generated the
exception is set in the RC bits in MMUCR.
PC and SR of the instruction that generated the exception are saved to SPC and SSR,
respectively. If the exception occurred during a read, H'0A0 is set in EXPEVT; if the exception
occurred during a write, H'0C0 is set in EXPEVT. The BL, MD, and RB bits in SR are set to 1
and a branch occurs to PC = VBR + H'0100.
Rev. 5.00, 09/03, page 96 of 760
• CPU address error
 Conditions:
a. Instruction fetch from odd address (4n + 1, 4n + 3)
b. Word data accessed from addresses other than word boundaries (4n + 1, 4n + 3)
c. Longword accessed from addresses other than longword boundaries (4n + 1, 4n + 2,
4n + 3)
d. Virtual space accessed in user mode in the area H'80000000 to H'FFFFFFFF
 Operations: The virtual address (32 bits) that caused the exception is set in TEA. PC and
SR of the instruction that generated the exception are saved to SPC and SSR, respectively.
If the exception occurred during a read, H'0E0 is set in EXPEVT; if the exception occurred
during a write, H'100 is set in EXPEVT. The BL, MD, and RB bits in SR are set to 1 and a
branch occurs to PC = VBR + H'0100. See section 3.5.5, Processing Flow in Event of
MMU Exception, for more information.
• Unconditional trap
 Conditions: TRAPA instruction executed
 Operations: The exception is a processing-completion type, so PC of the instruction after
the TRAPA instruction is saved to SPC. SR from the time when the TRAPA instruction
was executing is saved to SSR. The 8-bit immediate value in the TRAPA instruction is
quadrupled and set in TRA (9–0). H'160 is set in EXPEVT. The BL, MD, and RB bits in
SR are set to 1 and a branch occurs to PC = VBR + H'0100.
• Illegal general instruction exception
 Conditions:
a. When undefined code not in a delay slot is decoded
Delay branch instructions: JMP, JSR, BRA, BRAF, BSR, BSRF, RTS, RTE, BT/S,
BF/S
Undefined instruction: H'Fxxx
b. When a privileged instruction not in a delay slot is decoded in user mode
Privileged instructions: LDC, STC, RTE, LDTLB, SLEEP; Instructions that access
GBR with LDC/STC are not privileged instructions and therefore do not apply.
 Operations: PC and SR of the instruction that generated this instruction are saved to SPC
and SSR, respectively. H'180 is set in EXPEVT. The BL, MD, and RB bits in SR are set to
1 and a branch occurs to PC = VBR + H'100. When an undefined code other than H'Fxxx is
decoded, operation cannot be guaranteed.
Rev. 5.00, 09/03, page 97 of 760
• Illegal slot instruction
 Conditions:
a. When undefined code in a delay slot is decoded
Delay branch instructions: JMP, JSR, BRA, BRAF, BSR, BSRF, RTS, RTE, BT/S,
BF/S
b. When an instruction that rewrites PC in a delay slot is decoded
Instructions that rewrite PC: JMP, JSR, BRA, BRAF, BSR, BSRF, RTS, RTE, BT, BF,
BT/S, BF/S, TRAPA, LDC Rm, SR, LDC.L @Rm+, SR
c. When a privileged instruction in a delay slot is decoded in user mode
Privileged instructions: LDC, STC, RTE, LDTLB, SLEEP; Instructions that access
GBR with LDC/STC are not privileged instructions and therefore do not apply.
 Operations: PC of the immediately preceding delay branch instruction is saved to SPC. SR
of the instruction that generated the exception is saved to SSR. H'1A0 is set in EXPEVT.
The BL, MD, and RB bits in SR are set to 1 and a branch occurs to PC = VBR + H'0100.
When an undefined instruction other than H'Fxxx is decoded, operation cannot be
guaranteed.
• User break point trap
 Conditions: When a break condition set in the user break controller is satisfied
 Operations: When a post-execution break occurs, PC of the instruction immediately after
the instruction that set the break point is set in SPC. If a pre-execution break occurs, PC of
the instruction that set the break point is set in SPC. SR when the break occurs is set in
SSR. H'1E0 is set in EXPEVT. The BL, MD, and RB bits in SR are set to 1 and a branch
occurs to PC = VBR + H'0100. See section 7, User Break Controller, for more information.
• DMA address error
 Conditions:
a. Word data accessed from addresses other than word boundaries (4n + 1, 4n + 3)
b. Longword accessed from addresses other than longword boundaries (4n + 1, 4n + 2,
4n + 3)
 Operations: PC of the instruction immediately after the instruction executed before the
exception occurs is saved to SPC. SR when the exception occurs is saved to SSR. H'5C0 is
set in EXPEVT. The BL, MD, and RB bits in SR are set to 1 and a branch occurs to PC =
VBR + H'0100.
Rev. 5.00, 09/03, page 98 of 760
4.5.3
Interrupts
1. NMI
— Conditions: NMI pin edge detection
— Operations: PC after the instruction that receives the interrupt is saved to SPC, and SR at
the point the interrupt is accepted is saved to SSR. H'01C0 is set to INTEVT and
INTEVT2. The BL, MD, and RB bits of the SR are set to 1 and a branch occurs to PC =
VBR + H'0600. This interrupt is not masked by SR.IMASK and is accepted with top
priority when the BL bit in SR is 0. When the BL bit is 1, the interrupt is masked. See
section 6, Interrupt Controller (INTC), for more information.
2. IRL Interrupts
— Conditions: The value of the interrupt mask bits in SR is lower than the IRL3–IRL0 level
and the BL bit in SR is 0. The interrupt is accepted at an instruction boundary.
— Operations: The PC value after the instruction at which the interrupt is accepted is saved to
SPC. SR at the time the interrupt is accepted is saved to SSR. The code corresponding to
the IRL3–IRL0 level is set in INTEVT and INTEVT2. The corresponding code is given as
H'200 + [IRL3–IRL0] × H'20. See table 6.5, for the corresponding codes. The BL, MD, and
RB bits in SR are set to 1 and a branch occurs to VBR + H'0600. The received level is not
set in SR.IMASK. See section 6, Interrupt Controller (INTC), for more information.
3. IRQ Pin Interrupts
— Conditions: The IRQ pin is asserted, SR.IMASK is lower than the IRQ priority level, and
the BL bit in SR is 0. The interrupt is accepted at an instruction boundary.
— Operations: The PC value after the instruction at which the interrupt is accepted is saved to
SPC. SR at the point the interrupt is accepted is saved to SSR. The code corresponding to
the interrupt source is set in INTEVT and INTEVT2. The BL, MD, and RB bits in SR are
set to 1 and a branch occurs to VBR + H'0600. The received level is not set in the interrupt
mask bits in SR. See section 6, Interrupt Controller (INTC), for more information.
4. PINT Pin Interrupts
— Conditions: The PINT pin is asserted, the interrupt mask bits in SR. is lower than the PINT
priority level, and the BL bit in SR is 0. The interrupt is accepted at an instruction
boundary.
— Operations: The PC value after the instruction at which the interrupt is accepted is saved to
SPC. SR at the point the interrupt is accepted is saved to SSR. The code corresponding to
the interrupt source is set in INTEVT and INTEVT2. The BL, MD, and RB bits of SR are
set to 1 and a branch occurs to VBR + H'0600. The received level is not set in the interrupt
mask bits in SR. See section 6, Interrupt Controller (INTC), for more information.
Rev. 5.00, 09/03, page 99 of 760
5. On-Chip Peripheral Interrupts
— Conditions: The interrupt mask bits in SR are lower than the on-chip module (TMU, RTC,
SCI, IrDA, SCIF, A/D, DMAC, WDT, REF) interrupt level and the BL bit in SR is 0. The
interrupt is accepted at an instruction boundary.
— Operations: The PC value after the instruction at which the interrupt is accepted is saved to
SPC. SR at the point the interrupt is accepted is saved to SSR. The code corresponding to
the interrupt source is set in INTEVT and INTEVT2. The BL, MD, and RB bits in SR are
set to 1 and a branch occurs to VBR + H'0600. See section 6, Interrupt Controller (INTC),
for more information.
6. UDI Interrupt
— Conditions: An UDI interrupt command is input (see section 22.4.4, UDI Interrupt),
SR.IMASK is lower than 15, and the BL bit in SR is 0. The interrupt is accepted at an
instruction boundary.
— Operations: The PC value after the instruction that accepts the interrupt is saved to SPC.
SR at the point the interrupt is accepted is saved to SSR. H'5E0 is set to INTEVT and
INTEVT2. The BL, MD, and RB bits in SR are set to 1 and a branch occurs to VBR +
H'0600. See section 6, Interrupt Controller (INTC), for more information.
4.6
Cautions
• Return from exception handling
 Check the BL bit in SR with software. When SPC and SSR have been saved to external
memory, set the BL bit in SR to 1 before restoring them.
 Issue an RTE instruction, which sets SPC in PC and SSR in SR, and causes a branch to the
SPC address, and return from exception handling.
• Operation when exception or interrupt occurs while SR.BL = 1
 Interrupt: Acceptance is suppressed until the BL bit in SR is cleared to 0. If there is an
interrupt request and the reception conditions are satisfied, the interrupt is accepted after
the execution of the instruction that clears the BL bit in SR to 0. In sleep or standby mode,
however, the interrupt will be accepted even when the BL bit in SR is 1.
 Exception: No user break point trap will occur even when the break conditions are met.
When one of the other exceptions occurs, a branch is made to the fixed address of the reset
(H'A0000000). In this case, the values of the EXPEVT, SPC, and SSR registers are
undefined. Differently from general reset processing, the RESETOUT pin is not asserted,
and reset status is output from the STATUS0 and STATUS1 pins.
Rev. 5.00, 09/03, page 100 of 760
• SPC when exception occurs: The PC saved to SPC when an exception occurs is as shown
below:
 Re-executing-type exceptions: PC of the instruction that caused the exception is set in SPC
and re-executed after return from exception handling. If the exception occurred in a delay
slot, however, PC of the immediately prior delayed branch instruction is set in SPC. If the
condition of the conditional delayed branch instruction is not satisfied, the delay slot PC is
set in SPC.
 Completed-type exceptions and interrupts: PC of the instruction after the one that caused
the exception is set in SPC. If the exception was caused by a conditional delayed branch
instruction, however, the branch destination PC is set in SPC. If the condition of the
conditional delayed branch instruction is not satisfied, the delay slot PC is set in SPC.
• Initial register values after reset
 Undefined registers
R0_BANK0/1–R7_BANK0/1, R8–R15, GBR, SPC, SSR, MACH, MACL, PR
 Initialized registers
VBR = H'00000000
SR.MD = 1, SR.BL = 1, SR.RB = 1, SR.I3–SR.I0 = H'F. Other SR bits are undefined.
PC = H'A0000000
• Ensure that an exception is not generated at an RTE instruction delay slot, as operation is not
guaranteed in this case.
• When the BL bit in the SR register is set to 1, ensure that a TLB-related exception or address
error does not occur at an LDC instruction that updates the SR register and the following
instruction. This will be identified as the occurrence of multiple exceptions, and may initiate
reset processing.
Rev. 5.00, 09/03, page 101 of 760
Rev. 5.00, 09/03, page 102 of 760
Section 5 Cache
5.1
Overview
5.1.1
Features
The cache specifications are listed in table 5.1.
Table 5.1
Cache Specifications
Parameter
Specification
Capacity
16 kbytes
Structure
Instruction/data mixed, 4-way set associative
Locking
Way 2 and way 3 are lockable
Line size
16 bytes
Number of entries
256 entries/way
Write system
P0, P1, P3, U0: Write-back/write-through selectable
Replacement method
Least-recently-used (LRU) algorithm
5.1.2
Cache Structure
The cache mixes data and instructions and uses a 4-way set associative system. It is composed of
four ways (banks), each of which is divided into an address section and a data section. Each of the
address and data sections is divided into 256 entries. The data section of the entry is called a line.
Each line consists of 16 bytes (4 bytes × 4). The data capacity per way is 4 kbytes (16 bytes × 256
entries), with a total of 16 kbytes in the cache as a whole (4 ways). Figure 5.1 shows the cache
structure.
Rev. 5.00, 09/03, page 103 of 760
Address array (ways 0−3)
Entry 0 V U Tag address
Entry 1
Data array (ways 0−3)
0
LW0
LW1
LW2
LW3
LRU
0
1
1
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
.
Entry 255
255
255
24 (1 + 1 + 22) bits
128 (32 × 4) bits
6 bits
LW0−LW3: Longword data 0−3
Figure 5.1 Cache Structure
Address Array: The V bit indicates whether the entry data is valid. When the V bit is 1, data is
valid; when 0, data is not valid. The U bit indicates whether the entry has been written to in writeback mode. When the U bit is 1, the entry has been written to; when 0, it has not. The address tag
holds the physical address used in the external memory access. It is composed of 22 bits (address
bits 31–10) used for comparison during cache searches.
In the SH7709S, the top three of 32 physical address bits are used as shadow bits (see section 10,
Bus State Controller (BSC)), and therefore in a normal replace operation the top three bits of the
tag address are cleared to 0.
The V and U bits are initialized to 0 by a power-on reset, but are not initialized by a manual reset.
The tag address is not initialized by either a power-on or manual reset.
Data Array: Holds a 16-byte instruction or data. Entries are registered in the cache in line units
(16 bytes). The data array is not initialized by a power-on or manual reset.
LRU: With the 4-way set associative system, up to four instructions or data with the same entry
address (address bits 11–4) can be registered in the cache. When an entry is registered, the LRU
shows which of the four ways it is recorded in. There are six LRU bits, controlled by hardware. A
least-recently-used (LRU) algorithm is used to select the way.
The way that is to be replaced on a cache miss is determined by the 6-bit LRU. Table 5.2 shows
the correspondence between the LRU bits and the way to be replaced when the cache-lock
function is not used (when the cache-lock function is used, refer to section 5.2.2, Cache Control
Register 2 (CCR2)). If a bit pattern other than those listed in table 5.2 is set in the LRU bits by
software, the cache will not function correctly. When modifying the LRU bits by software, set one
of the patterns listed in table 5.2.
Rev. 5.00, 09/03, page 104 of 760
The LRU bits are initialized to 000000 by a power-on reset, but are not initialized by a manual
reset.
Table 5.2
LRU and Way Replacement (When the cache lock function is not used)
LRU (5–0)
Way to be Replaced
000000, 000100, 010100, 100000, 110000, 110100
3
000001, 000011, 001011, 100001, 101001, 101011
2
000110, 000111, 001111, 010110, 011110, 011111
1
111000, 111001, 111011, 111100, 111110, 111111
0
5.1.3
Register Configuration
Table 5.3 shows details of the cache control register.
Table 5.3
Register Configuration
Register
Abbr.
R/W
Initial Value
Address
Access Size
Cache control register
CCR
R/W
H'00000000
H'FFFFFFEC
32-bit
Cache control register 2
CCR2
R/W
H'00000000
H'040000B0
32-bit
(H’A40000B0)*
Note: * When address translation by the MMU does not apply, the address in parentheses should
be used.
5.2
Register Description
5.2.1
Cache Control Register (CCR)
The cache is enabled or disabled using the CE bit of the cache control register (CCR). CCR also
has a CF bit (which invalidates all cache entries), and a WT and CB bits (which select either writethrough mode or write-back mode). Programs that change the contents of the CCR register should
be placed in address space that is not cached. When updating the contents of the CCR register,
always set bits 4 to 0. Figure 5.2 shows the configuration of the CCR register.
Rev. 5.00, 09/03, page 105 of 760
31
…
…
…
…
…
…
…
…
6
5
4
3
2
1
0
CF
CB
WT
CE
:
Reserved bits. Always 0 when reading. Data written here is also always 0.
CF:
Cache flush bit. Writing 1 flushes all cache entries (clears the V, U, and LRU bits of all
cache entries to 0). Always reads 0. Write-back to external memory is not performed when
the cache is flushed.
CB:
Write-back/write-through switchover bit. Indicates the cache’s operating mode for area P1.
1 = write-back mode, 0 = write-through mode.
WT:
Write-through bit. Indicates the cache’s operating mode for area P0, U0, and P3.
1 = write-through mode, 0 = write-back mode.
CE:
Cache enable bit. Indicates whether the cache function is used.
1 = cache used, 0 = cache not used.
Figure 5.2 CCR Register Configuration
5.2.2
Cache Control Register 2 (CCR2)
CCR2 is used to control the cache-lock function and is valid only in cache locking mode. Cache
locking mode means that the cache lock bit (bit 12) in SR (status register) is set to 1. The cachelock function is invalid in non-cache locking mode (the cache-lock bit is 0).
When a prefetch instruction (PREF) is executed in cache locking mode and a cache miss occurs,
one line size of data pointed to by Rn is brought to cache according to the setting of bits 9 and 8
(W3LOAD and W3LOCK) and bits 1 and 0 (W2LOAD and W2LOCK) in CCR2. Table 5.4
shows the relationship between the bit setting and way to be replaced when a prefetch instruction
is executed. When a prefetch instruction is executed and there is a cache hit, new data is not
fetched and an entry which has already been valid is retained. For example, when the cache-lock,
W3LOAD, and W3LOCK bits are set to 1 and a prefetch instruction is executed while one line
size of data pointed to by Rn is already in way 0, a cache hit occurs and data is not fetched to way
3.
When cache is accessed by means of instructions except for a prefetch instruction in cache locking
mode, a way that is replaced by the W3LOCK and W2LOCK bits is restricted. Table 5.5 shows
the relationship between the bit setting of CCR2 and way to be replaced.
The program which modifies the contents of CCR2 must be placed in an address space which does
not cache.
Figure 5.3 shows the configuration of CCR2.
CCR2 is a write-only register; if read, an undefined value will be returned.
Rev. 5.00, 09/03, page 106 of 760
31
9
8
7
W3
W3
LOAD LOCK
2
1
0
W2 W2
LOAD LOCK
W2LOCK: Way 2 lock bit. W2LOAD: Way 2 load bit.
When W2LOCK = 1 & W2LOAD = 1 & SR, CL = 1, the prefetched data will always be
loaded into Way2. In all other conditions the prefetched data will be loaded into the way
pointed by LRU.
W3LOCK: Way 3 lock bit. W3LOAD: Way 3 load bit.
When W3LOCK = 1 & W3LOAD = 1 & SR, CL = 1, the prefetched data will always be
loaded into Way3. In all other conditions the prefetched data will be loaded into the way
pointed by LRU.
Note: W2LOAD and W3LOAD should not be set to high at the same time.
—: Reserved bits.
Figure 5.3 CCR2 Register Configuration
Whenever CCR2 bit 8 (W3LOCK) or bit 0 (W2LOCK) is high the cache is locked. The locked
data will not be overwritten unless W3LOCK bit and W2LOCK bit are reset or the PREF
condition during DSP mode matched. During cache locking mode, the LRU in table 5.2 will be
replaced by tables 5.4 to 5.8.
Table 5.4
Way Replacement when PREF Instruction Ended Up in a Cache Miss
DSP bit
W3LOAD
W3LOCK
W2LOAD
W2LOCK
Way to be replaced
0
*
*
*
*
Depends on LRU (table 5.2)
1
*
0
*
0
Depends on LRU (table 5.2)
1
*
0
0
1
Depends on LRU (table 5.6)
1
0
1
*
0
Depends on LRU (table 5.7)
1
0
1
0
1
Depends on LRU (table 5.8)
1
0
*
1
1
Way 2
1
1
1
0
*
Way 3
*: Don't care
Do not set as W3LOAD=1 and also W2LOAD=1
Rev. 5.00, 09/03, page 107 of 760
Table 5.5
Way Replacement when Instructions Except for PREF Instruction Ended Up in
a Cache Miss
DSP bit
W3LOAD
W3LOCK
W2LOAD
W2LOCK
Way to be replaced
0
*
*
*
*
Depends on LRU (table 5.2)
1
*
0
*
0
Depends on LRU (table 5.2)
1
*
0
*
1
Depends on LRU (table 5.6)
1
*
1
*
0
Depends on LRU (table 5.7)
1
*
1
*
1
Depends on LRU (table 5.8)
*: Don't care
Do not set as W3LOAD=1 and also W2LOAD=1
Table 5.6
LRU and Way Replacement (when W2LOCK=1)
LRU (5–0)
Way to be Replaced
000000, 000001, 000100, 010100, 100000, 100001, 110000, 110100
3
000011, 000110, 000111, 001011, 001111, 010110, 011110, 011111
1
101001, 101011, 111000, 111001, 111011, 111100, 111110, 111111
0
Table 5.7
LRU and Way Replacement (when W3LOCK=1)
LRU (5–0)
Way to be Replaced
000000, 000001, 000011, 001011, 100000, 100001, 101001, 101011
2
000100, 000110, 000111, 001111, 010100, 010110, 011110, 011111
1
110000, 110100, 111000, 111001, 111011, 111100, 111110, 111111
0
Table 5.8
LRU and Way Replacement (when W2LOCK=1 and W3LOCK=1)
LRU (5–0)
Way to be Replaced
000000, 000001, 000011, 000100, 000110, 000111, 001011, 001111,
010100, 010110, 011110, 011111
1
100000, 100001, 101001, 101011, 110000, 110100, 111000, 111001,
111011, 111100, 111110, 111111
0
Rev. 5.00, 09/03, page 108 of 760
5.3
Cache Operation
5.3.1
Searching the Cache
If the cache is enabled, whenever instructions or data in memory are accessed the cache will be
searched to see if the desired instruction or data is in the cache. Figure 5.4 illustrates the method
by which the cache is searched. The cache is a physical cache and holds physical addresses in its
address section.
Entries are selected using bits 11–4 of the address (virtual) of the access to memory and the
address tag of that entry is read. In parallel to reading of the address tag, the virtual address is
translated to a physical address in the MMU. The physical address after translation and the
physical address read from the address section are compared. The address comparison uses all four
ways. When the comparison shows a match and the selected entry is valid (V = 1), a cache hit
occurs. When the comparison does not show a match or the selected entry is not valid (V = 0), a
cache miss occurs. Figure 5.4 shows a hit on way 1.
Rev. 5.00, 09/03, page 109 of 760
Virtual address
31
12 11
4 3 21 0
Entry selection
Longword (LW) selection
Ways 0−3
Ways 0−3
0
MMU
V U Tag address
LW0
LW1
LW2
1
255
Physical address
CMP0 CMP1 CMP2 CMP3
Hit signal 1
CMP0: Comparison circuit 0
CMP1: Comparison circuit 1
CMP2: Comparison circuit 2
CMP3: Comparison circuit 3
Figure 5.4 Cache Search Scheme (Normal Mode)
Rev. 5.00, 09/03, page 110 of 760
LW3
5.3.2
Read Access
Read Hit: In a read access, instructions and data are transferred from the cache to the CPU. The
transfer unit is 32 bits. The LRU is updated.
Read Miss: An external bus cycle starts and the entry is updated. The way replaced is the one
least recently used. Entries are updated in 16-byte units. When the desired instruction or data that
caused the miss is loaded from external memory to the cache, the instruction or data is transferred
to the CPU in parallel with being loaded to the cache. When it is loaded in the cache, the U bit is
cleared to 0 and the V bit is set to 1.
5.3.3
Prefetch Operation
Prefetch Hit: The LRU will be updated to correctly indicate the latest way to have been hit. Other
contents of the cache will remain unchanged. Neither instructions nor data are transferred to the
CPU.
Prefetch Miss: Neither instructions nor data are transferred to the CPU, and way replacement
takes place as shown in table 5.4. All other action is the same as for a read miss.
5.3.4
Write Access
Write Hit: In a write access in the write-back mode, the data is written to the cache and the U bit
of the entry written is set to 1. Writing occurs only to the cache; no external memory write cycle is
issued. In the write-through mode, the data is written to the cache and an external memory write
cycle is issued.
Write Miss: In the write-back mode, an external write cycle starts when a write miss occurs, and
the entry is updated. The way to be replaced is shown in table 5.5. When the U bit of the entry to
be replaced is 1, the cache fill cycle starts after the entry is transferred to the write-back buffer.
The write-back unit is 16 bytes. Data is written to the cache and the U bit is set to 1. After the
cache completes its fill cycle, the write-back buffer writes back the entry to the memory. In the
write-through mode, no write to cache occurs in a write miss; the write is only to the external
memory.
5.3.5
Write-Back Buffer
When the U bit of the entry to be replaced in the write-back mode is 1, it must be written back to
the external memory. To increase performance, the entry to be replaced is first transferred to the
write-back buffer and fetching of new entries to the cache takes priority over writing back to the
external memory. During the write back cycles, the cache can be accessed. The write-back buffer
can hold one line of the cache data (16 bytes) and its physical address. Figure 5.5 shows the
configuration of the write-back buffer.
Rev. 5.00, 09/03, page 111 of 760
PA (31−4) Longword 0 Longword 1 Longword 2 Longword 3
PA (31−4):
Physical address written to external memory
Longword 0−3: The line of cache data to be written to
external memory
Figure 5.5 Write-Back Buffer Configuration
5.3.6
Coherency of Cache and External Memory
Use software to ensure coherency between the cache and the external memory. When memory
shared by this LSI and another device is placed in an address space to be cached, the memory
allocation cache is manipulated if necessary and a write back should be performed by invalidating
the entry. This is also applied to memory shared by the CPU and DMAC in this LSI.
5.4
Memory-Mapped Cache
To allow software management of the cache, cache contents can be read and written by means of
MOV instructions in the privileged mode. The cache is mapped onto the P4 area in virtual address
space. The address array is mapped onto addresses H'F0000000 to H'F0FFFFFF, and the data
array onto addresses H'F1000000 to H'F1FFFFFF. Only longword can be used as the access size
for the address array and data array, and instruction fetches cannot be performed.
5.4.1
Address Array
The address array is mapped to H'F0000000 to H'F0FFFFFF. The 32-bit address field (for
read/write accessed) and 32-bit data field (for write access) must be specified to access an element
of the address array. The address field specifies information that selects the entry to be accessed;
the data field specifies the tag address, V bit, U bit, and LRU bits to be written to the address array
(figure 5.6 (1)).
In the address field, specify the entry's address in bits 11-4 to select the entry, W in bits 13-12 to
select the way, the A bit (bit 3) to specify an associative operation, and H'F0 in bits 31-24 to
indicate access to the address array. Settings for the W bits (13-12) are as follows: 00 is way 0, 01
is way 1, 10 is way 2, and 11 is way 3.
In the data field, specify the tag address in bits 31-10, LRU in bits 9-4, U bit in bit 1, and V bit in
bit 0. The upper 3 bits (bit 31-29) of the tag address must always be 0.
Rev. 5.00, 09/03, page 112 of 760
The following three operations on the address array are possible.
(1) Address Array Read
Reads the tag address, LRU, U bit, and V bit from the entry that corresponds to the entry address
and w`ay that were specified in the address field. No associative operation will be performed,
regardless of the value of the associative bit (the A bit).
(2) Address Array Write (without Associative Operation)
Writes the tag address, LRU, U bit, and V bit specified in the data field to the entry that
corresponds to the entry address and way that were specified in the address field. The associative
bit (A bit) of the address field must be set to 0. An attempt to write to a cache line for which both
the U bit and V bit are set results in a write-back for that cache line. The tag address, LRU, U bit,
and V bit specified in the data field are then written. Note that, when a 0 is written to the V bit, a 0
should always be written to the U bit of the same entry, too.
(3) Address Array Write (with Associative Operation)
The associative bit (A bit) in the address field indicates whether the addresses are compared
during writing. With the A bit set to 1, all 4 ways for the entry specified in the address field will be
compared to the tag address specified in the data field for a match. The values of the U bit and V
bit specified in the data field will be written to the way that has a hit. However, the tag address and
the LRU will not be changed. If no way receives a hit, writing does not take place and the result is
no operation.
This operation is used to invalidate the address specification for a cache. Write back will take
place when the U bit of the entry that received a hit is 1. Note that, when a 0 is written to the V bit,
a 0 should always be written to the U bit of the same entry, too.
5.4.2
Data Array
The address array is mapped to H'F1000000 to H'F1FFFFFF. To access an element of the data
array, the 32-bit address field (for read/write access) and 32-bit data field (for write access) must
be specified. The address field specifies the information that selects the entry to be accessed; the
data field specifies the longword data to be written to the data array.
In the address field, specify the entry's address in bits 11-4, L in bits 3-2 to indicate the longword's
position within a line (which consists of 16 bytes), W in bits 13-12 to select the way, and H'F1 in
bits 31-24 to indicate access to the data array. The L bits (3-2) specification is in the following
form: 00 is longword 0, 01 is longword 1, 10 is longword 2, and 11 is longword 3. Settings for the
W bits (13-12) are as follows: 00 is way 0, 01 is way 1, 10 is way 2, and 11 is way 3. Since access
is not allowed crossing longword boundaries, always set 00 in bits 1-0 of the address field.
Rev. 5.00, 09/03, page 113 of 760
The following two operations on the data array are possible. Note that these operations will not
change the information in the address array.
(1) Data Array Read
Reads the data at the position selected by the L bits (3-2) of the address field from the entry that
corresponds to the entry address and way that were specified in the address field.
(2) Data Array Write
Writes the longword data set in the data field into the entry that corresponds to the entry address
and way that were specified in the address field. The longword data will be written to the entry at
the position selected by the L bits (3-2) of the address field.
1. Address array access
Address specification
Read access
31
24
23
14
13
*…………*
1111 0000
12
11
W
4
Entry address
3
2
0
*
0
*
*
Write access
31
24
23
14
13
*…………*
1111 0000
12
11
W
4
Entry address
3
2
A
*
*
*
0
2
1
0
X
U
V
0
0
Data specification (both read and write accesses)
31 30 29
10
0 0 0
Address tag (28−10)
9
4
3
LRU
X
2. Data array access (both read and write accesses)
Address specification
31
24
1111 0001
23
14
*…………*
13
12
W
11
4
Entry address
3
2
L
1
0
Data specification
31
0
Longword
X: 0 for read, don't care for write
*: Don't care bit
Figure 5.6 Specifying Address and Data for Memory-Mapped Cache Access
Rev. 5.00, 09/03, page 114 of 760
5.4.3
Examples of Usage
(1) Invalidating a Specific Entry
A specific cache entry can be invalidated by accessing the allocated memory cache and writing a 0
to the entry’s U and V bits. The A bit is cleared to 0, and an address is specified for the entry
address and the way. If the U bit of the way of the entry in question was set to 1, the entry is
written back and the V and U bits specified by the write data are written to.
In the following example, the write data is specified in R0 and the address is specified in R1.
; R0 = H'0000 0000 LRU = H'000, U = 0, V = 0
; R1 = H'F000 1080, Way = 1, Entry = H'08, A = 0
;
MOV.L
R0, @R1
To invalidate all entries and ways, write 0 to the following addresses.
Addresses
F000 0000
F000 0010
F000 0020
:
F000 3FF0
This involves a total of 1,024 writes.
The above operation should be performed using a non-cacheable area.
(2) Invalidating a Specific Address
A specific address can be invalidated by writing a 0 to the entry’s U and V bits. When the A bit is
1, the tag address specified by the write data is compared to the tag address within the cache
selected by the entry address. If the tag addresses match, data is written to the memory at that
address. If no match is found, no operation is carried out. If the entry’s U bit is 1 at that time, the
entry is written back.
; R0 = H'0110 0010; Tag address = B'0000 0001 0001 0000 0000 00, U = 0,
V = 0
; R1 = H'F000 0088; Address array access, Entry = H'08, A = 1
;
MOV.L
R0, @R1
Rev. 5.00, 09/03, page 115 of 760
In the following example, an address (32-bit) to be purged is specified in R0.
MOV.L #H'00000FF0, R1
;
AND
; The entry address is fetched.
R0, R1
MOV.L #H'F0000008, R2
;
OR
; The start is set to H'F0 and the A bit
R1, R2
to 1.
MOV.L #H'1FFFFC00, R3
;
AND
; The tag address is fetched. U = V = 0.
R0, R3
MOV.L R3, @R2
; Associative purge.
The above operation should be performed using a non-cacheable area.
(3) Reading Data from a Specific Entry
This example reads the data section of a specific entry. The longword in the data field of the data
array in figure 5.6 is read to the register.
; R0 = H'F100 004C; Data array access, Entry = H'04,
; Way = 0, Longword address = 3
;
MOV.L
R0, @R1
; Longword 3 is read.
Rev. 5.00, 09/03, page 116 of 760
Section 6 Interrupt Controller (INTC)
6.1
Overview
The interrupt controller (INTC) ascertains the priority of interrupt sources and controls interrupt
requests to the CPU. The INTC registers set the order of priority of each interrupt, allowing the
user to process interrupt requests according to the user-set priority.
6.1.1
Features
The INTC has the following features:
• 16 levels of interrupt priority can be set: By setting the five interrupt-priority registers, the
priorities of on-chip peripheral module, IRQ, and PINT interrupts can be selected from 16
levels for individual request sources.
• NMI noise canceler function: An NMI input-level bit indicates the NMI pin state. By reading
this bit in the interrupt exception service routine, the pin state can be checked, enabling it to be
used as a noise canceler.
• External devices can be notified that an interrupt has been received (IRQOUT): When the
SH7709S has released the bus, the external bus master can be notified that an external
interrupt, an on-chip peripheral module interrupt, or a memory refresh request has occurred,
enabling the bus to be requested.
Rev. 5.00, 09/03, page 117 of 760
6.1.2
Block Diagram
Figure 6.1 shows a block diagram of the INTC.
IRQOUT
NMI
IRL3–IRL0
IRLS3–IRLS0
IRQ0–IRQ5
PINT0–PINT15
DMAC
IrDA
SCIF
SCI
ADC
TMU
RTC
WDT
REF
UDI
4
4
6
16
Input/output
control
(Interrupt request)
(Interrupt request)
(Interrupt request)
(Interrupt request)
Comparator
Interrupt
request
SR
Priority
identifier
3 2 1 0
(Interrupt request)
CPU
(Interrupt request)
(Interrupt request)
(Interrupt request)
(Interrupt request/
refresh request)
(Interrupt request)
ICR
IPR
Bus
interface
Legend
: Timer unit
TMU
: Realtime clock unit
RTC
: Serial communication interface
SCI
: Serial communication interface (with IrDA)
IrDA
: Serial communication interface (with FIFO)
SCIF
: Watchdog timer
WDT
: Refresh requests in the bus state controller
REF
: Interrupt control register
ICR
IPRA–IPRE : Interrupt priority registers A−E
: Status register
SR
: Direct memory access controller
DMAC
ADC
: Analog-to-digital converter
UDI
: User-debugging interface
Figure 6.1 Block Diagram of INTC
Rev. 5.00, 09/03, page 118 of 760
INTC
Internal bus
IPRA–IPRE
6.1.3
Pin Configuration
Table 6.1 shows the INTC pin configuration.
Table 6.1
INTC Pins
Name
Abbreviation
I/O
Description
Nonmaskable interrupt
input pin
NMI
I
Input of interrupt request signal, not
maskable by the interrupt mask bits in
SR.
Interrupt input pins
IRQ5–IRQ0
IRL3–IRL0
I
Input of interrupt request signals,
maskable by the interrupt mask bits in
SR.
IRLS3-IRLS0
Port interrupt input pins
PINT0–PINT15
I
Input of port interrupt request signals,
maskable by the interrupt mask bits in
SR.
Bus request output pin
IRQOUT
O
Output of signal that notifies external
devices that an interrupt source or
memory refresh has occurred
Rev. 5.00, 09/03, page 119 of 760
6.1.4
Register Configuration
The INTC has the 12 registers listed in table 6.2.
Table 6.2
INTC Registers
Name
Abbr.
R/W
Initial Value*
Address
Access
Size
Interrupt control register 0
ICR0
R/W
*2
H'FFFFFEE0
16
Interrupt control register 1
ICR1
R/W
H'0000
H'04000010
16
3
(H'A4000010)*
Interrupt control register 2
ICR2
R/W
H'0000
H'04000012
16
3
(H'A4000012)*
PINT interrupt enable register
PINTER
R/W
H'0000
H'04000014
16
3
(H'A4000014)*
Interrupt priority register A
IPRA
R/W
H'0000
H'FFFFFEE2
16
Interrupt priority register B
IPRB
R/W
H'0000
H'FFFFFEE4
16
Interrupt priority register C
IPRC
R/W
H'0000
H'04000016
16
3
(H'A4000016)*
Interrupt priority register D
IPRD
R/W
H'0000
H'04000018
16
3
(H'A4000018)*
Interrupt priority register E
IPRE
R/W
H'0000
H'0400001A
16
3
(H'A400001A)*
Interrupt request register 0
IRR0
R/W
H'00
H'04000004
8
3
(H'A4000004)*
Interrupt request register 1
IRR1
R
H'00
H'04000006
8
3
(H'A4000006)*
Interrupt request register 2
IRR2
R
H'00
H'04000008
8
3
(H'A4000008)*
1
Notes: 1. Initialized by a power-on or manual reset.
2. H'8000 when the NMI pin is high, H'0000 when the NMI pin is low.
3. When address translation by the MMU does not apply, the address in parentheses
should be used.
Rev. 5.00, 09/03, page 120 of 760
6.2
Interrupt Sources
There are five types of interrupt sources: NMI, IRQ, IRL,PINT, and on-chip peripheral modules.
Each interrupt has a priority level (0–16), with 0 the lowest and 16 the highest. Priority level 0
masks an interrupt.
6.2.1
NMI Interrupt
The NMI interrupt has the highest priority level of 16. When the BLMSK bit in the interrupt
control register (ICR1) is 1 or the BL bit in the status register (SR) is 0, NMI interrupts are
accepted when the MAI bit in the ICR1 register is 0. NMI interrupts are edge-detected. In sleep or
standby mode, the interrupt is accepted regardless of the BL setting. The NMI edge select bit
(NMIE) in the interrupt control register 0 (ICR0) is used to select either rising or falling edge
detection. When the NMIE bit in the ICR0 register is changed, an NMI interrupt is not detected for
20 cycles after changing ICR0. NMIE to avoid a false detection of NMI. NMI interrupt exception
handling does not affect the interrupt mask level bits (I3–I0) in the status register (SR).
When the BL bit is land the BLMSK bit in the ICR1 register is set to 1 and only NMI interrupts
are accepted, the SPC register and SSR register are updated by the NMI interrupt handler, making
it impossible to return to the original processing from exception handling initiated prior to the
NMI interrupt. Use should therefore be restricted to cases where return is not necessary.
It is possible to wake the chip up from the standby state with an NMI interrupt (except when the
MAI bit in the ICR1 register is set to 1).
6.2.2
IRQ Interrupts
IRQ interrupts are input by level or edge from pins IRQ0–IRQ5. The priority level can be set by
interrupt priority registers C–D (IPRC–IPRD) in a range from 0 to 15.
When using edge-sensing for IRQ interrupts, clear the interrupt source by having software read 1
from the corresponding bit in IRR0, then write 0 to the bit.
When the ICR1 register is rewritten, IRQ interrupts may be mistakenly detected, depending on the
pin states. To prevent this, rewrite the register while interrupts are masked, then release the mask
after clearing the illegal interrupt by writing 0 to interrupt request register 0 (IRR0).
Edge input interrupt detection requires input of a pulse width of more than two cycles on a
peripheral clock (Pφ) basis.
The interrupt mask bits (I3–I0) in the status register (SR) are not affected by IRQ interrupt
handling.
Rev. 5.00, 09/03, page 121 of 760
Interrupts IRQ4–IRQ0 can wake the chip up from the standby state when the relevant interrupt
level is higher than the setting of I3–I0 in the SR register (but only when the RTC 32-kHz
oscillator is used).
If the IRQ edge is input immediately before the CPU enters the standby mode (during the period
between when the CPU executes a SLEEP instruction and when STATUS0 becomes high level),
the interrupt may not be detected. However, the interrupt will be accepted correctly if the IRQ
edge is re-input after the CPU has entered the standby mode (when STATUS0 is high level). In
addition, the interrupt may not be detected if the IRQ edge is input during frequency change
processing (WDT count).
6.2.3
IRL Interrupts
IRL interrupts are input by level at pins IRL3–IRL0 and IRLS3–IRLS0. IRLS3–IRLS0 are
enabled when the IRQLVL bit and IRLSEN bit in interrupt control register 1 (ICR1) are both 1.
The priority level is the higher level indicated by pins IRL3–IRL0 and IRLS3–IRLS0. An IRL3–
IRL0/IRLS3–IRLS0 value of 0 (0000) indicates the highest-level interrupt request (interrupt
priority level 15). A value of 15 (1111) indicates no interrupt request (interrupt priority level 0).
Figure 6.2 shows an example of IRL interrupt connection. Table 6.3 shows IRL/IRLS pins and
interrupt levels.
SH7709S
Interrupt
request
Priority
encoder
Interrupt
request
Priority
encoder
4
IRL3 to IRL0
IRL3 to IRL0
4
IRLS3 to IRLS0
IRLS3 to IRLS0
Figure 6.2 Example of IRL Interrupt Connection
Rev. 5.00, 09/03, page 122 of 760
IRL3–IIRL0/IIRLS3–IIRLS0 Pins and Interrupt Levels
Table 6.3
IRL3/
L3/
IRLS3
IRL2/
L2/
IRLS2
IRL1/
L1/
IRLS1
IRL0/
L0/
IRLS0
Interrupt Priority Level
Interrupt Request
0
0
0
0
15
Level 15 interrupt request
0
0
0
1
14
Level 14 interrupt request
0
0
1
0
13
Level 13 interrupt request
0
0
1
1
12
Level 12 interrupt request
0
1
0
0
11
Level 11 interrupt request
0
1
0
1
10
Level 10 interrupt request
0
1
1
0
9
Level 9 interrupt request
0
1
1
1
8
Level 8 interrupt request
1
0
0
0
7
Level 7 interrupt request
1
0
0
1
6
Level 6 interrupt request
1
0
1
0
5
Level 5 interrupt request
1
0
1
1
4
Level 4 interrupt request
1
1
0
0
3
Level 3 interrupt request
1
1
0
1
2
Level 2 interrupt request
1
1
1
0
1
Level 1 interrupt request
1
1
1
1
0
No interrupt request
A noise-cancellation feature is built in, and the IRL interrupt is not detected unless the levels
sampled at every peripheral module clock cycle remain unchanged for two consecutive cycles, so
that no transient level on the IRL/IRLS pin change is detected. In standby mode, as the peripheral
clock is stopped, noise cancellation is performed using the 32-kHz clock for the RTC instead.
Therefore when the RTC is not used, interruption by means of IRL interrupts cannot be performed
in standby mode.
The priority level of the IRL interrupt must not be lowered until the interrupt is accepted and
interrupt handling starts. Correct operation cannot be guaranteed if the level is not maintained.
However, the priority level can be changed to a higher one.
The interrupt mask bits (I3–I0) in the status register (SR) are not affected by IRL/IRLS interrupt
handling.
When the interrupt level of the IRL interrupt is higher than the level set by the I3-I0 bits in the SR,
the IRL interrupt can be used to recover from standby mode (however, this only applies when the
RTC is used for 32-kHz oscillator).
Rev. 5.00, 09/03, page 123 of 760
6.2.4
PINT Interrupts
PINT interrupts are input by level from pins PINT0–PINT15. The priority level can be set by
interrupt priority register D (IPRD) in a range from 0 to 15, in groups of PINT0–PINT7 and
PINT8–PINT15.
The PINT0/1 interrupt level should be held until the interrupt is accepted and interrupt handling is
started. Correct operation cannot be guaranteed if the level is not maintained.
The interrupt mask bits (I3–I0) in the status register (SR) are not affected by PINT interrupt
handling.
PINT0/1 interrupts can wake the chip up from the standby state when the relevant interrupt level is
higher than the setting of I3–I0 in the SR register (but only when the RTC 32-kHz oscillator is
used).
6.2.5
On-Chip Peripheral Module Interrupts
On-chip peripheral module interrupts are generated by the following ten modules:
• Timer unit (TMU)
• Realtime clock (RTC)
• Serial communication interfaces (SCI, IrDA, SCIF)
• Bus state controller (BSC)
• Watchdog timer (WDT)
• Direct memory access controller (DMAC)
• Analog-to-digital converter (ADC)
• User-debugging interface (UDI)
Not every interrupt source is assigned a different interrupt vector. Sources are reflected in the
interrupt event registers (INTEVT and INTEVT2). It is easy to identify sources by using the value
of the INTEVT or INTEVT2 register as a branch offset.
A priority level (from 0 to 15) can be set for each module except UDI by writing to interrupt
priority registers A, B, and E (IPRA, IPRB, and IPRE). The priority level of the UDI interrupt is
15 (fixed).
The interrupt mask bits (I3–I0) in the status register are not affected by on-chip peripheral module
interrupt handling.
TMU and RTC interrupts can wake the chip up from the standby state when the relevant interrupt
level is higher than the setting of I3–I0 in the SR register (but only when the RTC 32-kHz
oscillator is used).
Rev. 5.00, 09/03, page 124 of 760
6.2.6
Interrupt Exception Handling and Priority
Tables 6.4 and 6.5 list the codes for the interrupt event registers (INTEVT and INTEVT2), and the
order of interrupt priority. Each interrupt source is assigned a unique code. The start address of the
interrupt service routine is common to each interrupt source. This is why, for instance, the value of
INTEVT or INTEVT2 is used as offset at the start of the interrupt service routine and branched to
in order to identify the interrupt source.
The priority of the on-chip peripheral module, IRQ, and PINT interrupts is set within priority
levels 0–15 as required by using interrupt priority registers A–E (IPRA–IPRE). The priority of the
on-chip peripheral module, IRQ, and PINT interrupts is set to 0 by a reset.
When the priorities of multiple interrupt sources are set to the same level and such interrupts are
generated simultaneously, they are handled according to the default order shown in tables 6.4 and
6.5.
Rev. 5.00, 09/03, page 125 of 760
Table 6.4
Interrupt Exception Handling Sources and Priority (IRQ Mode)
Interrupt Source
INTEVT Code
(INTEVT2 Code)
Interrupt
Priority
IPR (Bit
(Initial Value) Numbers)
Priority
within IPR Default
Setting Unit Priority
NMI
H'1C0 (H'1C0)
16
—
H'5E0 (H'5E0)
H'200–3C0* (H'600)
15
—
—
0–15 (0)
IPRC (3–0)
—
0–15 (0)
IPRC (7–4)
—
IRQ2
H'200–3C0* (H'620)
H'200–3C0* (H'640)
0–15 (0)
IPRC (11–8)
—
IRQ3
H'200–3C0* (H'660)
0–15 (0)
IPRC (15–12) —
IRQ4
H'200–3C0* (H'680)
0–15 (0)
IPRD (3–0)
—
IRQ5
H'200–3C0* (H'6A0)
H'200–3C0* (H'700)
0–15 (0)
IPRD (7–4)
—
0–15 (0)
IPRD (15–12) —
0–15 (0)
IPRD (11–8)
0–15 (0)
IPRE (15–12) High
UDI
IRQ
IRQ0
IRQ1
PINT
PINT0–7
DEI0
H'200–3C0* (H'720)
H'200–3C0* (H'800)
DEI1
H'200–3C0* (H'820)
DEI2
H'200–3C0* (H'840)
H'200–3C0* (H'860)
PINT8–15
DMAC
DEI3
IrDA
ERI1
RXI1
BRI1
TXI1
SCIF
ERI2
RXI2
H'200–3C0* (H'880)
H'200–3C0* (H'8A0)
—
—
Low
0–15 (0)
IPRE (11–8)
High
0–15 (0)
IPRE (7–4)
High
H'200–3C0* (H'8C0)
H'200–3C0* (H'8E0)
H'200–3C0* (H'900)
H'200–3C0* (H'920)
Low
TXI2
H'200–3C0* (H'940)
H'200–3C0* (H'960)
ADC
ADI
H'200–3C0* (H'980)
0–15 (0)
IPRE (3–0)
TMU0
TUNI0
H'400 (H'400)
0–15 (0)
IPRA (15–12) —
TMU1
TUNI1
H'420 (H'420)
0–15 (0)
IPRA (11–8)
—
TMU2
TUNI2
H'440 (H'440)
0–15 (0)
IPRA (7–4)
High
TICPI2
H'460 (H'460)
BRI2
Rev. 5.00, 09/03, page 126 of 760
High
Low
—
Low
Low
Interrupt Source
INTEVT Code
(INTEVT2 Code)
Interrupt
Priority
IPR (Bit
(Initial Value) Numbers)
Priority
within IPR Default
Setting Unit Priority
RTC
ATI
H'480 (H'480)
0–15 (0)
High
PRI
H'4A0 (H'4A0)
CUI
H'4C0 (H'4C0)
ERI
H'4E0 (H'4E0)
RXI
H'500 (H'500)
TXI
H'520 (H'520)
TEI
H'540 (H'540)
WDT
ITI
H'560 (H'560)
0–15 (0)
IPRB (15–12) —
REF
RCMI
H'580 (H'580)
0–15 (0)
IPRB (11–8)
ROVI
H'5A0 (H'5A0)
SCI
IPRA (3–0)
High
Low
0–15 (0)
IPRB (7–4)
High
Low
High
Low
Low
Note: * The code corresponding to an interrupt level shown in table 6.6 is set.
Rev. 5.00, 09/03, page 127 of 760
Table 6.5
Interrupt Exception Handling Sources and Priority (IRL Mode)
Interrupt Source
INTEVT Code
(INTEVT2 Code)
Interrupt
Priority
IPR (Bit
(Initial Value) Numbers)
Priority
within IPR Default
Setting Unit Priority
NMI
H'1C0 (H'1C0)
16
—
UDI
H'5E0 (H'5E0)
2
IRL(3:0)* = 0000 H'200 (H'200)
2
IRL(3:0)* = 0001 H'220 (H'220)
2
IRL(3:0)* = 0010 H'240 (H'240)
IRL
2
IRL(3:0)* = 0011 H'260 (H'260)
2
IRL(3:0)* = 0100 H'280 (H'280)
2
IRL(3:0)* = 0101 H'2A0 (H'2A0)
IRL(3:0) = 0110 H'2C0 (H'2C0)
2
IRL(3:0)* = 0111 H'2E0 (H'2E0)
2
IRL(3:0)* = 1000 H'300 (H'300)
*2
2
IRL(3:0)* = 1001 H'320 (H'320)
2
IRL(3:0)* = 1010 H'340 (H'340)
2
IRL(3:0)* = 1011 H'360 (H'360)
IRL(3:0) = 1100 H'380 (H'380)
2
IRL(3:0)* = 1101 H'3A0 (H'3A0)
2
IRL(3:0)* = 1110 H'3C0 (H'3C0)
*2
IRQ
IRQ4
IRQ5
PINT
PINT0–7
PINT8–15
DMAC DEI0
IrDA
DEI2
H'200–3C0* (H'840)
1
H'200–3C0* (H'860)
RXI1
BRI1
TXI1
—
—
14
—
—
13
—
—
12
—
—
11
—
—
10
—
—
9
—
—
8
—
—
7
—
—
6
—
—
5
—
—
4
—
—
3
—
—
2
—
—
—
—
IPRD (3–0)
—
IPRD (7–4)
—
(H'700) 0–15 (0)
1
*
H'200–3C0 (H'720) 0–15 (0)
1
H'200–3C0* (H'800) 0–15 (0)
DEI1
ERI1
—
—
*1
1
H'200–3C0* (H'820)
DEI3
15
15
1
1
*
H'200–3C0 (H'680) 0–15 (0)
1
H'200–3C0* (H'6A0) 0–15 (0)
H'200–3C0
—
High
IPRD (15–12) —
IPRD (11–8) —
IPRE (15–12) High
1
H'200–3C0
*1
(H'880) 0–15 (0)
1
*
H'200–3C0 (H'8A0)
IPRE (11–8) High
1
H'200–3C0* (H'8C0)
1
H'200–3C0* (H'8E0)
Rev. 5.00, 09/03, page 128 of 760
Low
Low
Low
Interrupt Source
SCIF
ERI2
RXI2
Interrupt
Priority
IPR (Bit
(Initial Value) Numbers)
1
H'200–3C0* (H'900) 0–15 (0)
1
H'200–3C0* (H'920)
IPRE (7–4)
Priority
within IPR Default
Setting Unit Priority
High
TXI2
ADI
1
H'200–3C0* (H'980) 0–15 (0)
Low
IPRE (3–0)
—
TMU0 TUNI0
H'400 (H'400)
0–15 (0)
IPRA (15–12) —
TMU1 TUNI1
H'420 (H'420)
0–15 (0)
IPRA (11–8) —
TMU2 TUNI2
H'440 (H'440)
0–15 (0)
IPRA (7–4)
TICPI2
H'460 (H'460)
ATI
H'480 (H'480)
RTC
SCI
High
1
H'200–3C0* (H'940)
1
H'200–3C0* (H'960)
BRI2
ADC
INTEVT Code
(INTEVT2 Code)
PRI
H'4A0 (H'4A0)
CUI
H'4C0 (H'4C0)
ERI
H'4E0 (H'4E0)
RXI
H'500 (H'500)
TXI
H'520 (H'520)
High
Low
0–15 (0)
IPRA (3–0)
High
Low
0–15 (0)
IPRB (7–4)
High
TEI
H'540 (H'540)
WDT
ITI
H'560 (H'560)
0–15 (0)
IPRB (15–12) —
Low
REF
RCMI
H'580 (H'580)
0–15 (0)
IPRB (11–8) High
ROVI
H'5A0 (H'5A0)
Low
Low
Notes: 1. The code corresponding to an interrupt level shown in table 6.6 is set.
2. When IRLS3–IRLS0 are enabled, IRL is the higher level of IRL3–IRL0 and IRLS3–
IRLS0.
Rev. 5.00, 09/03, page 129 of 760
Table 6.6
Interrupt Levels and INTEVT Codes
Interrupt level
INTEVT Code
15
H'200
14
H'220
13
H'240
12
H'260
11
H'280
10
H'2A0
9
H'2C0
8
H'2E0
7
H'300
6
H'320
5
H'340
4
H'360
3
H'380
2
H'3A0
1
H'3C0
Rev. 5.00, 09/03, page 130 of 760
6.3
INTC Registers
6.3.1
Interrupt Priority Registers A to E (IPRA–IPRE)
Interrupt priority registers A to E (IPRA to IPRE) are 16-bit readable/writable registers in which
priority levels from 0 to 15 are set for on-chip peripheral module, IRQ, and PINT interrupts. These
registers are initialized to H'0000 by a power-on reset or manual reset, but are not initialized in
standby mode.
Bit:
Initial value:
15
14
13
12
11
10
9
8
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Bit:
7
6
5
4
3
2
1
0
Initial value:
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W:
R/W:
Table 6.7 lists the relationship between the interrupt sources and the IPRA—IPRE bits.
Table 6.7
Interrupt Request Sources and IPRA–IPRE
Register
Bits 15 to 12
Bits 11 to 8
Bits 7 to 4
Bits 3 to 0
IPRA
TMU0
TMU1
TMU2
RTC
IPRB
WDT
REF
SCI0
Reserved*
IPRC
IRQ3
IRQ2
IRQ1
IRQ0
IPRD
PINT0 to PINT7
PINT8 to PINT15
IRQ5
IRQ4
IPRE
DMAC
IrDA
SCIF
ADC
Note: * Always read as 0. Only 0 should be written.
As shown in table 6.7, on-chip peripheral module, IRQ, or PINT interrupts are assigned to four 4bit groups in each register. These 4-bit groups (bits 15 to 12, bits 11 to 8, bits 7 to 4, and bits 3 to
0) are set with values from H'0 (0000) to H'F (1111). Setting H'0 means priority level 0 (masking
is requested); H'F is priority level 15 (the highest level). A reset initializes IPRA–IPRE to H'0000.
Rev. 5.00, 09/03, page 131 of 760
6.3.2
Interrupt Control Register 0 (ICR0)
ICR0 is a register that sets the input signal detection mode of external interrupt input pin NMI, and
indicates the input signal level at the NMI pin. This register is initialized to H'0000 or H'8000 by a
power-on reset or manual reset, but is not initialized in standby mode.
Bit:
15
14
13
12
11
10
9
8
NMIL
0/1*
—
—
—
—
—
—
NMIE
0
0
0
0
0
0
0
R/W:
R
R
R
R
R
R
R
R/W
Bit:
7
6
5
4
3
2
1
0
—
—
—
—
—
—
—
—
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R
R
R
R
R
R
R
Initial value:
Note: * 1 when NMI input is high, 0 when NMI input is low.
Bit 15—NMI Input Level (NMIL): Sets the level of the signal input at the NMI pin. This bit can
be read to determine the NMI pin level. This bit cannot be modified.
Bit 15: NMIL
Description
0
NMI input level is low
1
NMI input level is high
Bit 8—NMI Edge Select (NMIE): Selects whether the falling or rising edge of the interrupt
request signal at the NMI pin is detected.
Bit 8: NMIE
Description
0
Interrupt request is detected on falling edge of NMI input
1
Interrupt request is detected on rising edge of NMI input
Bits 14 to 9 and 7 to 0—Reserved: These bits are always read as 0. The write value should
always be 0.
Rev. 5.00, 09/03, page 132 of 760
6.3.3
Interrupt Control Register 1 (ICR1)
ICR1 is a 16-bit register that specifies the detection mode for external interrupt input pins IRQ0 to
IRQ5 individually: rising edge, falling edge, or low level. This register is initialized to H'4000 by a
power-on reset or manual reset, but is not initialized in standby mode.
Bit:
15
MAI
Initial value:
R/W:
Bit:
14
13
12
11
10
9
8
IRQLVL BLMSK IRLSEN IRQ51S IRQ50S IRQ41S IRQ40S
0
1
0
0
0
0
0
0
R/W
R/W
R/W
RW
R/W
R/W
R/W
R/W
7
6
5
4
3
2
1
0
IRQ31S IRQ30S IRQ21S IRQ20S IRQ11S IRQ10S IRQ01S IRQ00S
Initial value:
R/W:
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Bit 15—Mask All Interrupts (MAI): When set to 1, all interrupt requests are masked while a
low level is being input to the NMI pin. Masks NMI interrupts in standby mode.
Bit 15: MAI
Description
0
All interrupt requests are not masked when NMI pin is low level
1
All interrupt requests are masked when NMI pin is low level
(Initial value)
Bit 14—Interrupt Request Level Detect (IRQLVL): Selects whether the IRQ3–IRQ0 pins are
used as four independent interrupt pins or as 15-level interrupt pins encoded as IRL3–IRL0.
Bit 14: IRQLVL Description
0
Used as four independent interrupt request pins IRQ3–IRQ0
1
Used as 15-level interrupt pins encoded as IRL3–IRL0
(Initial value)
Bit 13—BL Bit Mask (BLMSK): Specifies whether NMI interrupts are masked when the BL bit
in the SR register is 1.
Bit 13: BLMSK Description
0
NMI interrupts are masked when BL bit is 1
(Initial value)
1
NMI interrupts are accepted regardless of BL bit setting
Rev. 5.00, 09/03, page 133 of 760
Bit 12—IIRLS Enable (IRLSEN): Enables pins IRLS3–IRLS0. This bit is valid only when the
IRQLVL bit is 1.
Bit 12: IRLSEN Description
0
Pins IRLS3–IRLS0 disabled
1
Pins IRLS3–IRLS0 enabled
(Initial value)
Bits 11 and 10—IRQ5 Sense Select (IRQ51S, IRQ50S): Select whether the interrupt signal to
the IRQ5 pin is detected at the rising edge, at the falling edge, or at the low level.
Bit 11: IRQ51S Bit 10: IRQ50S Description
0
1
0
An interrupt request is detected at IRQ5 input falling edge
(Initial value)
1
An interrupt request is detected at IRQ5 input rising edge
0
An interrupt request is detected at IRQ5 input low level
1
Reserved
Bits 9 and 8—IRQ4 Sense Select (IRQ41S, IRQ40S): Select whether the interrupt signal to the
IRQ4 pin is detected at the rising edge, at the falling edge, or at the low level.
Bit 9: IRQ41S
Bit 8: IRQ40S
Description
0
0
An interrupt request is detected at IRQ4 input falling edge
(Initial value)
1
An interrupt request is detected at IRQ4 input rising edge
0
An interrupt request is detected at IRQ4 input low level
1
Reserved
1
Bits 7 and 6—IRQ3 Sense Select (IRQ31S, IRQ30S): Select whether the interrupt signal to the
IRQ3 pin is detected at the rising edge, at the falling edge, or at the low level.
Bit 7: IRQ31S
Bit 6: IRQ30S
Description
0
0
An interrupt request is detected at IRQ3 input falling edge
(Initial value)
1
An interrupt request is detected at IRQ3 input rising edge
0
An interrupt request is detected at IRQ3 input low level
1
Reserved
1
Rev. 5.00, 09/03, page 134 of 760
Bits 5 and 4—IRQ2 Sense Select (IRQ21S, IRQ20S): Select whether the interrupt signal to the
IRQ2 pin is detected at the rising edge, at the falling edge, or at the low level.
Bit 5: IRQ21S
Bit 4: IRQ20S
Description
0
0
An interrupt request is detected at IRQ2 input falling edge
(Initial value)
1
An interrupt request is detected at IRQ2 input rising edge
1
0
An interrupt request is detected at IRQ2 input low level
1
Reserved
Bits 3 and 2—IRQ1 Sense Select (IRQ11S, IRQ10S): Select whether the interrupt signal to the
IRQ1 pin is detected at the rising edge, at the falling edge, or at the low level.
Bit 3: IRQ11S
Bit 2: IRQ10S
Description
0
0
An interrupt request is detected at IRQ1 input falling edge
(Initial value)
1
An interrupt request is detected at IRQ1 input rising edge
0
An interrupt request is detected at IRQ1 input low level
1
Reserved
1
Bits 1 and 0—IRQ0 Sense Select (IRQ01S, IRQ00S): Select whether the interrupt signal to the
IRQ0 pin is detected at the rising edge, at the falling edge, or at the low level.
Bit 1: IRQ01S
Bit 0: IRQ00S
Description
0
0
An interrupt request is detected at IRQ0 input falling edge
(Initial value)
1
An interrupt request is detected at IRQ0 input rising edge
0
An interrupt request is detected at IRQ0 input low level
1
Reserved
1
Rev. 5.00, 09/03, page 135 of 760
6.3.4
Interrupt Control Register 2 (ICR2)
ICR2 is a 16-bit readable/writable register that sets the detection mode for external interrupt input
pins PINT0 to PINT15. This register is initialized to H'0000 by a power-on reset or manual reset,
but is not initialized in standby mode.
Bit:
15
14
13
12
11
10
9
8
PINT15S PINT14S PINT13S PINT14S PINT11S PINT10S PINT9S PINT8S
Initial value:
R/W:
Bit:
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
7
6
5
4
3
2
1
0
PINT7S PINT6S PINT5S PINT4S PINT3S PINT2S PINT1S PINT0S
Initial value:
R/W:
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Bits 15 to 0—PINT15 to PINT0 Sense Select (PINT15S to PINT0S): Select whether interrupt
request signals to PINT15 to PINT0 are detected at the low level or high level.
Bits 15–0:
PINT15S to PINT0S
Description
0
Interrupt requests are detected at low level input to the PINT pin
(Initial value)
1
Interrupt requests are detected at high level input to the PINT pin
Rev. 5.00, 09/03, page 136 of 760
6.3.5
PINT Interrupt Enable Register (PINTER)
PINTER is a 16-bit readable/writable register that enables interrupt requests input to external
interrupt input pins PINT0 to PINT15. This register is initialized to H'0000 by a power-on reset or
manual reset, but is not initialized in standby mode.
Bit:
15
14
13
12
11
10
9
8
PINT15E PINT14E PINT13E PINT12E PINT11E PINT10E PINT9E PINT8E
Initial value:
R/W:
Bit:
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
7
6
5
4
3
2
1
0
PINT7E PINT6E PINT5E PINT4E PINT3E PINT2E PINT1E PINT0E
Initial value:
R/W:
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Bits 15 to 0—PINT15 to PINT0 Interrupt Enable (PINT15E to PINT0E): Enable or diable
interrupt request input to pins PINT15 to PINT0.
Bits 15–0:
PINT15E to PINT0E
Description
0
PINT input interrupt requests disabled
1
PINT input interrupt requests enabled
(Initial value)
When all or some of pins PINT0–PINT15 are not used for interrupt input, bits corresponding to
pins not used as interrupt request pins should be cleared to 0.
Rev. 5.00, 09/03, page 137 of 760
6.3.6
Interrupt Request Register 0 (IRR0)
IRR0 is an 8-bit register that indicates interrupt requests from external input pins IRQ0 to IRQ5
and PINT0 to PINT15. This register is initialized to H'00 by a power-on reset or manual reset, but
is not initialized in standby mode.
Bit:
7
6
PINT0R PINT1R
5
4
3
2
1
0
IRQ5R
IRQ4R
IRQ3R
IRQ2R
IRQ1R
IRQ0R
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R
R/W
R/W
R/W
R/W
R/W
R/W
When clearing an IRQ5R–IRQ0R bit to 0, read the bit while bit set to 1, and then write 0. In this
case, 0 should be written only to the bits to be cleared and 1 to the other bits. The contents of the
bits to which 1 is written do not change.
Bit 7—PINT0 to PINT7 Interrupt Request (PINT0R): Indicates whether there is interrupt
request input to pins PINT0 to PINT7.
Bit 7: PINT0R
Description
0
No interrupt request to pins PINT0 to PINT7
1
Interrupt to pins PINT0 to PINT7
(Initial value)
Bit 6—PINT8 to PINT15 Interrupt Request (PINT1R): Indicates whether there is interrupt
request input to pins PINT8 to PINT15.
Bit 6: PINT1R
Description
0
No interrupt request input to pins PINT8 to PINT15
1
Interrupt request input to pins PINT8 to PINT15
(Initial value)
Bit 5—IRQ5 Interrupt Request (IRQ5R): Indicates whether there is interrupt request input to
the IRQ5 pin. When edge detection mode is set for IRQ5, an interrupt request is cleared by
clearing the IRQ5R bit.
Bit 5: IRQ5R
Description
0
No interrupt request input to IRQ5 pin
1
Interrupt request input to IRQ5 pin
Rev. 5.00, 09/03, page 138 of 760
(Initial value)
Bit 4—IRQ4 Interrupt Request (IRQ4R): Indicates whether there is interrupt request input to
the IRQ4 pin. When edge detection mode is set for IRQ4, an interrupt request is cleared by
clearing the IRQ4R bit.
Bit 4: IRQ4R
Description
0
No interrupt request input to IRQ4 pin
1
Interrupt request input to IRQ4 pin
(Initial value)
Bit 3—IRQ3 Interrupt Request (IRQ3R): Indicates whether there is interrupt request input to
the IRQ3 pin. When edge detection mode is set for IRQ3, an interrupt request is cleared by
clearing the IRQ3R bit.
Bit 3: IRQ3R
Description
0
No interrupt request input to IRQ3 pin
1
Interrupt request input to IRQ3 pin
(Initial value)
Bit 2—IRQ2 Interrupt Request (IRQ2R): Indicates whether there is interrupt request input to
the IRQ2 pin. When edge detection mode is set for IRQ2, an interrupt request is cleared by
clearing the IRQ2R bit.
Bit 2: IRQ2R
Description
0
No interrupt request input to IRQ2 pin
1
Interrupt request input to IRQ2 pin
(Initial value)
Bit 1—IRQ1 Interrupt Request (IRQ1R): Indicates whether there is interrupt request input to
the IRQ1 pin. When edge detection mode is set for IRQ1, an interrupt request is cleared by
clearing the IRQ1R bit.
Bit 1: IRQ1R
Description
0
No interrupt request input to IRQ1 pin
1
Interrupt request input to IRQ1 pin
(Initial value)
Bit 0—IRQ0 Interrupt Request (IRQ0R): Indicates whether there is interrupt request input to
the IRQ0 pin. When edge detection mode is set for IRQ0, an interrupt request is cleared by
clearing the IRQ0R bit.
Bit 0: IRQ0R
Description
0
No interrupt request input to IRQ0 pin
1
Interrupt request input to IRQ0 pin
(Initial value)
Rev. 5.00, 09/03, page 139 of 760
6.3.7
Interrupt Request Register 1 (IRR1)
IRR1 is an 8-bit read-only register that indicates whether DMAC or IrDA interrupt requests have
been generated. This register is initialized to H'00 by a power-on reset or manual reset, but is not
initialized in standby mode.
Bit:
7
6
5
4
3
2
1
0
TXI1R
BRI1R
RXI1R
ERI1R
DEI3R
DEI2R
DEI1R
DEI0R
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R
R
R
R
R
R
R
Bit 7—TXI1 Interrupt Request (TXI1R): Indicates whether a TXI1 (IrDA) interrupt request has
been generated.
Bit 7: TXI1
Description
0
TXI1 interrupt request not generated
1
TXI1 interrupt request generated
(Initial value)
Bit 6—BRI1 Interrupt Request (BRI1R): Indicates whether a BRI1 (IrDA) interrupt request has
been generated.
Bit 6: BRI1R
Description
0
BRI1 interrupt request not generated
1
BRI1 interrupt request generated
(Initial value)
Bit 5—RXI1 Interrupt Request (RXI1R): Indicates whether an RXI1 (IrDA) interrupt request
has been generated.
Bit 5: RXI1R
Description
0
RXI1 interrupt request not generated
1
RXI1 interrupt request generated
(Initial value)
Bit 4—ERI1 Interrupt Request (ERI1R): Indicates whether an ERI1 (IrDA) interrupt request
has been generated.
Bit 4: ERI1R
Description
0
ERI1 interrupt request not generated
1
ERI1 interrupt request generated
Rev. 5.00, 09/03, page 140 of 760
(Initial value)
Bit 3—DEI3 Interrupt Request (DEI3R): Indicates whether a DEI3 (DMAC) interrupt request
has been generated.
Bit 3: DEI3R
Description
0
DEI3 interrupt request not generated
1
DEI3 interrupt request generated
(Initial value)
Bit 2—DEI2 Interrupt Request (DEI2R): Indicates whether a DEI2 (DMAC) interrupt request
has been generated.
Bit 2: DEI2R
Description
0
DEI2 interrupt request not generated
1
DEI2 interrupt request generated
(Initial value)
Bit 1—DEI1 Interrupt Request (DEI1R): Indicates whether a DEI1 (DMAC) interrupt request
has been generated.
Bit 1: DEI1R
Description
0
DEI1 interrupt request not generated
1
DEI1 interrupt request generated
(Initial value)
Bit 0—DEI0 Interrupt Request (DEI0R): Indicates whether a DEI0 (DMAC) interrupt request
has been generated.
Bit 0: DEI0R
Description
0
DEI0 interrupt request not generated
1
DEI0 interrupt request generated
6.3.8
(Initial value)
Interrupt Request Register 2 (IRR2)
IRR2 is an 8-bit read-only register that indicates whether an A/D converter or SCIF interrupt
request has been generated. This register is initialized to H'00 by a power-on reset or manual reset,
but is not initialized in standby mode.
Bit:
7
6
5
4
3
2
1
0
—
—
—
ADIR
TXI2R
BRI2R
RXI2R
ERI2R
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R
R
R
R
R
R
R
Rev. 5.00, 09/03, page 141 of 760
Bits 7 to 5—Reserved: These bits are always read as 0. The write value should always be 0.
Bit 4—ADI Interrupt Request (ADIR): Indicates whether an ADI (ADC) interrupt request has
been generated.
Bit 4: ADIR
Description
0
ADI interrupt request not generated
1
ADI interrupt request generated
(Initial value)
Bit 3—TXI2 Interrupt Request (TXI2R): Indicates whether a TXI2 (SCIF) interrupt request has
been generated.
Bit 3: TXI2R
Description
0
TXI2 interrupt request not generated
1
TXI2 interrupt request generated
(Initial value)
Bit 2—BRI2 Interrupt Request (BRI2R): Indicates whether a BRI2 (SCIF) interrupt request has
been generated.
Bit 2: BRI2R
Description
0
BRI2 interrupt request not generated
1
BRI2 interrupt request generated
(Initial value)
Bit 1—RXI2 Interrupt Request (RXI2R): Indicates whether an RXI2 (SCIF) interrupt request
has been generated.
Bit 1: RXI2R
Description
0
RXI2 interrupt request not generated
1
RXI2 interrupt request generated
(Initial value)
Bit 0—ERI2 Interrupt Request (ERI2R): Indicates whether an ERI2 (SCIF) interrupt request
has been generated.
Bit 0: ERI2R
Description
0
ERI2 interrupt request not generated
1
ERI2 interrupt request generated
Rev. 5.00, 09/03, page 142 of 760
(Initial value)
6.4
INTC Operation
6.4.1
Interrupt Sequence
The sequence of interrupt operations is described below. Figure 6.3 is a flowchart of the
operations.
1. The interrupt request sources send interrupt request signals to the interrupt controller.
2. The interrupt controller selects the highest-priority interrupt from the interrupt requests sent,
following the priority levels set in interrupt priority registers A to E (IPRA to IPRE). Lower
priority interrupts are held pending. If two of these interrupts have the same priority level or if
multiple interrupts occur within a single module, the interrupt with the highest default priority
or the highest priority within its IPR setting unit (as indicated in tables 6.4 and 6.5) is selected.
3. The priority level of the interrupt selected by the interrupt controller is compared with the
interrupt mask bits (I3–I0) in the status register (SR) of the CPU. If the request priority level is
higher than the level in bits I3–I0, the interrupt controller accepts the interrupt and sends an
interrupt request signal to the CPU. When the interrupt controller receives an interrupt, a low
level is output from the IRQOUT pin.
4. Detection timing: The INTC operates, and notifies the CPU of interrupt requests, in
synchronization with the peripheral clock (Pφ). The CPU receives an interrupt at a break in
instructions.
5. The interrupt source code is set in the interrupt event registers (INTEVT and INTEVT2).
6. The status register (SR) and program counter (PC) are saved to SSR and SPC, respectively.
7. The block bit (BL), mode bit (MD), and register bank bit (RB) in SR are set to 1.
8. The CPU jumps to the start address of the interrupt handler (the sum of the value set in the
vector base register (VBR) and H'00000600). This jump is not a delayed branch. The interrupt
handler may branch with the INTEVT and INTEVT2 register value as its offset in order to
identify the interrupt source. This enables it to branch to the handling routine for the individual
interrupt source.
Notes: 1. The interrupt mask bits (I3–I0) in the status register (SR) are not changed by
acceptance of an interrupt in the SH7709S.
2. IRQOUT outputs a low level until the interrupt request is cleared. However, if the
interrupt source is masked by an interrupt mask bit, the IRQOUT pin returns to the
high level. The level is output without regard to the BL bit.
3. The interrupt source flag should be cleared in the interrupt handler. To ensure that an
interrupt request that should have been cleared is not inadvertently accepted again, read
the interrupt source flag after it has been cleared, then wait for the interval shown in
table 6.8 (Time for priority decision and SR mask bit comparison) before clearing the
BL bit or executing an RTE instruction.
Rev. 5.00, 09/03, page 143 of 760
Program
execution state
ICR1.MAI = 1?
No
No
Interrupt
generated?
Yes
NMI = low?
Yes
No
Yes
No
ICR1.BLMSK = 1?
No
SR.BL= 0
or sleep mode?
Yes
Yes
No
NMI?
Yes
NMI?
Yes
No
Level 15
interrupt?
Yes
IRQOUT = low
Yes
I3−I0 level
14 or lower?
Set interrupt cause in
INTEVT, INTEVT2
No
Yes
Save SR to SSR;
save PC to SPC
No
Level 14
interrupt?
Yes
I3−I0 level
13 or lower?
No
Yes
No
Level 1
interrupt?
Yes
I3−I0
level 0?
No
Set BL/MD/RB
bits in SR to 1
Branch to exception
handler
I3−I0: Interrupt mask bits in status register (SR)
Figure 6.3 Interrupt Operation Flowchart
Rev. 5.00, 09/03, page 144 of 760
No
6.4.2
Multiple Interrupts
When handling multiple interrupts, an interrupt handler should include the following procedures:
1. Branch to a specific interrupt handler corresponding to a code set in INTEVT and INTEVT2.
The code in INTEVT and INTEVT2 can be used as a branch-offset for branching to the
specific handler.
2. Clear the cause of the interrupt in each specific handler.
3. Save SSR and SPC to memory.
4. Clear the BL bit in SR, and set the accepted interrupt level in the interrupt mask bits in SR.
5. Handle the interrupt.
6. Execute the RTE instruction.
When these procedures are followed in order, an interrupt of higher priority than the one being
handled can be accepted after clearing BL in step 4. Figure 6.3 shows a sample interrupt operation
flowchart.
6.5
Interrupt Response Time
The time from generation of an interrupt request until interrupt exception handling is performed
and fetching of the first instruction of the exception handler is started (the interrupt response time)
is shown in table 6.8. Figure 6.4 shows an example of pipeline operation when an IRL interrupt is
accepted. When SR.BL is 1, interrupt exception handling is masked, and is kept waiting until
completion of an instruction that clears BL to 0.
Rev. 5.00, 09/03, page 145 of 760
Table 6.8
Interrupt Response Time
Number of States
Item
NMI
IRQ
Time for priority
decision and SR
mask bit comparison
0.5 × Icyc
0.5 × Icyc
+ 0.5 × Bcyc + 1 × Bcyc
+ 0.5 × Pcyc + 4.5 ×
4
Pcyc*
PINT
Peripheral
Modules
Notes
0.5 × Icyc
0.5 × Icyc
+ 3.5 × Pcyc + 1.5 ×
5
Pcyc*
0.5 × Icyc
6
+ 3 × Pcyc*
Wait time until end
of sequence being
executed by CPU
X (≥ 0) × Icyc X (≥ 0) × Icyc X (≥ 0) × Icyc X (≥ 0) × Icyc Interrupt exception
handling is kept
waiting until the
executing instruction ends. If the
number of instruction execution
states is S*1, the
maximum wait
time is: X = S – 1.
However, if BL is
set to 1 by instruction execution or
by an exception,
interrupt exception
handling is
deferred until
completion of an
instruction that
clears BL to 0. If
the following
instruction masks
interrupt exception
handling, the
handling may be
further deferred.
Time from interrupt
exception handling
(save of SR and PC)
until fetch of first
instruction of
exception handler is
started
5 × Icyc
Rev. 5.00, 09/03, page 146 of 760
5 × Icyc
5 × Icyc
5 × Icyc
Number of States
Item
NMI
IRQ
PINT
Peripheral
Modules
Response Total
time
(5.5 + X)
× Icyc
+ 0.5 × Bcyc
+ 0.5 × Pcyc
(5.5 + X)
× Icyc
+ 1 × Bcyc
+ 4.5 ×
4
Pcyc*
(5.5 + X)
× Icyc
+ 3.5 ×
5
Pcyc*
(5.5 + X)
× Icyc
+ 1.5
5
× Pcyc*
Minimum 7.5
2
case*
16.5
12.5
Maximum 8.5 + S
3
case*
26.5 + S
18.5 + S
Notes
(5.5 + X)
× Icyc
6
+ 3 × Pcyc*
5
6
8.5* /11.5* At 60-MHz (CKIO
= 30) operation:
0.13–0.28 µs
5
10.5 + S*
At 60-MHz (CKIO
6
= 15) operation:
16.5 + S*
0.26–0.56 µs (in
case of operand
cache-hit)
At 60-MHz (CKIO
= 15) operation:
0.29–0.59 µs
(when external
memory access is
performed with
wait = 0)
Icyc: Duration of one cycle of internal clock supplied to CPU.
Bcyc: Duration of one CKIO cycle.
Pcyc: Duration of one cycle of peripheral clock supplied to peripheral modules.
Notes: 1. S also includes the memory access wait time.
The processing requiring the maximum execution time is LDC.L @Rm+, SR. When the
memory access is a cache-hit, this requires seven instruction execution cycles. When
the external access is performed, the corresponding number of cycles must be added.
There are also instructions that perform two external memory accesses; if the external
memory access is slow, the number of instruction execution cycles will increase
accordingly.
2. The internal clock:CKIO:peripheral clock ratio is 2:1:1.
3. The internal clock:CKIO:peripheral clock ratio is 4:1:1.
4. IRQ mode
5. Modules: TMU, RTC, SCI, WDT, REFC
6. Modules: DMAC, ADC, IrDA, SCIF
Rev. 5.00, 09/03, page 147 of 760
Interrupt
acceptance
Start of interrupt
handling
0.5 × Icyc
+ 0.5 × Bcyc
+ 2 × Pcyc
5 × Icyc
IRL
Instruction (instruction
replaced by interrupt
exception handling)
IF
Overrun fetch
First instruction of interrupt
handler
ID
EX
EX
EX
EX
IF
IF
ID
EX
IF: Instruction fetch: Instruction is fetched from memory in which program is stored.
ID: Instruction decode: Fetched instruction is decoded.
EX: Instruction execution: Data operation and address calculation are performed.
Figure 6.4 Example of Pipeline Operations when IRL Interrupt is Accepted
Rev. 5.00, 09/03, page 148 of 760
Section 7 User Break Controller
7.1
Overview
The user break controller (UBC) provides functions that simplify program debugging. This
function makes it easy to design an effective self-monitoring debugger, enabling the chip to debug
programs without using an in-circuit emulator. Break conditions that can be set in the UBC are
instruction fetch or data read/write, data size, data content, address value, and stop timing during
instruction fetches.
7.1.1
Features
The user break controller has the following features:
• The following break comparison conditions can be set.
Number of break channels: two channels (channels A and B)
User break can be requested as either the independent or sequential condition on channels A
and B (sequential break setting: channel A and, then channel B match with logical AND, but
not in the same bus cycle).
Address (Compares 40 bits comprised of a 32-bit logical address prefixed with an ASID
address. Comparison bits are maskable in 32-bit units, user can easily program it to mask
addresses at bottom 12 bits (4-k page), bottom 10 bits (1-k page), or any size of page, etc.
One of two address buses (CPU address bus (LAB), cache address bus (IAB)) can be
selected.
 Data (only on channel B, 32-bit maskable)
 One of the two data buses (CPU data bus (LDB), cache data bus (IDB)) can be selected.
 Bus master: CPU cycle or DMAC cycle
 Bus cycle: instruction fetch or data access
 Read/write
 Operand size: byte, word, or longword
• User break is generated upon satisfying break conditions. A user-designed user-break
condition exception processing routine can be run.
• In an instruction fetch cycle, it can be selected that a break is set before or after an instruction
is executed.
• Maximum repeat times for the break condition: 212 – 1 times.
• Eight pairs of branch source/destination buffers.
Rev. 5.00, 09/03, page 149 of 760
7.1.2
Block Diagram
Figure 7.1 shows a block diagram of the UBC.
Access
Control
IAB
LAB
MDB
Access
comparator
BBRA
BARA
Address
comparator
BAMRA
ASID
comparator
BASRA
Channel A
Access
comparator
BBRB
BARB
Address
comparator
BAMRB
ASID
comparator
BASRB
BDRB
Data
comparator
Channel B
BDMRB
BETR
BRSR
PC Trace
BRDR
BRCR
CONTROL
LDB/IDB/
XDB/YDB
User break request
CPU state
signals
UBC Location
Legend
BBRA:
BARA:
BAMRA:
BASRA:
BBRB:
BARB:
BAMRB:
Break bus cycle register A
Break address register A
Break address mask register A
Break ASID register A
Break bus cycle register B
Break address register B
Break address mask register B
BASRB:
BDRB:
BDMRB:
BETR:
BRSR:
BRDR:
BRCR:
CCN Location
Break ASID register B
Break data register B
Break data mask register B
Break execution times register
Branch source register
Branch destination register
Break control register
Figure 7.1 Block Diagram of User Break Controller
Rev. 5.00, 09/03, page 150 of 760
7.1.3
Table 7.1
Register Configuration
Register Configuration
Name
Abbr.
R/W
Initial Value*
Address
Access
Size
Location
Break address register A
BARA
R/W
H'00000000
H'FFFFFFB0
32
UBC
Break address mask
register A
BAMRA R/W
H'00000000
H'FFFFFFB4
32
UBC
Break bus cycle register A
BBRA
R/W
H'0000
H'FFFFFFB8
16
UBC
Break address register B
BARB
R/W
H'00000000
H'FFFFFFA0
32
UBC
Break address mask
register B
BAMRB R/W
H'00000000
H'FFFFFFA4
32
UBC
Break bus cycle register B
BBRB
R/W
H'0000
H'FFFFFFA8
16
UBC
Break data register B
BDRB
R/W
H'00000000
H'FFFFFF90
32
UBC
Break data mask register B
BDMRB R/W
H'00000000
H'FFFFFF94
32
UBC
Break control register
BRCR
R/W
H'00000000
H'FFFFFF98
32
UBC
Execution count break
register
BETR
R/W
H'0000
H'FFFFFF9C
16
UBC
Branch source register
BRSR
R
H'FFFFFFAC
32
UBC
Branch destination register
BRDR
R
Undefined*
2
Undefined*
H'FFFFFFBC
32
UBC
Break ASID register A
BASRA
R/W
Undefined
H'FFFFFFE4
16
CCN
Break ASID register B
BASRB
R/W
Undefined
H'FFFFFFE8
16
CCN
1
2
Notes: 1. Initialized by power-on reset. Values held in standby state and undefined by manual
resets.
2. Bit 31 of BRSR and BRDR (valid flag) is initialized by power-on resets. But other bits
are not initialized.
Rev. 5.00, 09/03, page 151 of 760
7.2
Register Descriptions
7.2.1
Break Address Register A (BARA)
BARA is a 32-bit read/write register. BARA specifies the address used as a break condition in
channel A. A power-on reset initializes BARA to H'00000000.
Bit:
Initial value:
R/W:
Bit:
Initial value:
R/W:
Bit:
Initial value:
R/W:
Bit:
Initial value:
R/W:
31
30
29
28
27
26
25
24
BAA31
BAA30
BAA29
BAA28
BAA27
BAA26
BAA25
BAA24
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
23
22
21
20
19
18
17
16
BAA23
BAA22
BAA21
BAA20
BAA19
BAA18
BAA17
BAA16
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
15
14
13
12
11
10
9
8
BAA15
BAA14
BAA13
BAA12
BAA11
BAA10
BAA9
BAA8
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
7
6
5
4
3
2
1
0
BAA7
BAA6
BAA5
BAA4
BAA3
BAA2
BAA1
BAA0
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Bits 31 to 0—Break Address A31 to A0 (BAA31 to BAA0): Stores the address on the LAB or
IAB specifying break conditions of channel A.
Rev. 5.00, 09/03, page 152 of 760
7.2.2
Break Address Mask Register A (BAMRA)
BAMRA is a 32-bit read/write register. BAMRA specifies bits masked in the break address
specified by BARA. A power-on reset initializes BAMRA to H'00000000.
Bit:
31
30
29
28
27
26
25
24
BAMA31 BAMA30 BAMA29 BAMA28 BAMA27 BAMA26 BAMA25 BAMA24
Initial value:
R/W:
Bit:
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
23
22
21
20
19
18
17
16
BAMA23 BAMA22 BAMA21 BAMA20 BAMA19 BAMA18 BAMA17 BAMA16
Initial value:
R/W:
Bit:
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
15
14
13
12
11
10
9
8
BAMA15 BAMA14 BAMA13 BAMA12 BAMA11 BAMA10 BAMA9
Initial value:
R/W:
Bit:
Initial value:
R/W:
BAMA8
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
7
6
5
4
3
2
1
0
BAMA7
BAMA6
BAMA5
BAMA4
BAMA3
BAMA2
BAMA1
BAMA0
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Bits 31 to 0—Break Address Mask Register A31 to A0 (BAMA31 to BAMA0): Specifies bits
masked in the channel A break address bits specified by BARA (BAA31–BAA0).
Bits 31 to 0:
BAMAn
Description
0
Break address bit BAAn of channel A is included in the break condition
(Initial value)
1
Break address bit BAAn of channel A is masked and is not included in the break
condition
n = 31 to 0
Rev. 5.00, 09/03, page 153 of 760
7.2.3
Break Bus Cycle Register A (BBRA)
Break bus cycle register A (BBRA) is a 16-bit read/write register, which specifies (1) CPU cycle
or DMAC cycle, (2) instruction fetch or data access, (3) read or write, and (4) operand size in the
break conditions of channel A. A power-on reset initializes BBRA to H'0000.
Bit:
15
14
13
12
11
10
9
8
—
—
—
—
—
—
—
—
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R
R
R
R
R
R
R
Bit:
7
6
5
4
3
2
1
0
CDA1
CDA0
IDA1
IDA0
RWA1
RWA0
SZA1
SZA0
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Initial value:
R/W:
Bits 15 to 8—Reserved: These bits are always read as 0. The write value should always be 0.
Bits 7 and 6—CPU Cycle/DMAC Cycle Select A (CDA1, CDA0): Selects the CPU cycle or
DMAC cycle as the bus cycle of the channel A break condition.
Bit 7: CDA1
Bit 6: CDA0
Description
0
0
Condition comparison is not performed
*
1
The break condition is the CPU cycle
1
0
The break condition is the DMAC cycle
(Initial value)
*: Don’t care
Bits 5 and 4—Instruction Fetch/Data Access Select A (IDA1, IDA0): Selects the instruction
fetch cycle or data access cycle as the bus cycle of the channel A break condition.
Bit 5: IDA1
Bit 4: IDA0
Description
0
0
Condition comparison is not performed
1
The break condition is the instruction fetch cycle
0
The break condition is the data access cycle
1
The break condition is the instruction fetch cycle or data access
cycle
1
Rev. 5.00, 09/03, page 154 of 760
(Initial value)
Bits 3 and 2—Read/Write Select A (RWA1, RWA0): Selects the read cycle or write cycle as the
bus cycle of the channel A break condition.
Bit 3: RWA1
Bit 2: RWA0
Description
0
0
Condition comparison is not performed
1
The break condition is the read cycle
1
(Initial value)
0
The break condition is the write cycle
1
The break condition is the read cycle or write cycle
Bits 1 and 0—Operand Size Select A (SZA1, SZA0): Selects the operand size of the bus cycle
for the channel A break condition.
Bit 1: SZA1
Bit 0: SZA0
Description
0
0
The break condition does not include operand size
(Initial value)
1
The break condition is byte access
0
The break condition is word access
1
The break condition is longword access
1
Rev. 5.00, 09/03, page 155 of 760
7.2.4
Break Address Register B (BARB)
BARB is a 32-bit read/write register. BARB specifies the address used as a break condition in
channel B. A power-on reset initializes BARB to H'00000000.
Bit:
Initial value:
R/W:
Bit:
Initial value:
R/W:
Bit:
Initial value:
R/W:
Bit:
Initial value:
R/W:
31
30
29
28
27
26
25
24
BAB31
BAB30
BAB29
BAB28
BAB27
BAB26
BAB25
BAB24
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
23
22
21
20
19
18
17
16
BAB23
BAB22
BAB21
BAB20
BAB19
BAB18
BAB17
BAB16
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
15
14
13
12
11
10
9
8
BAB15
BAB14
BAB13
BAB12
BAB11
BAB10
BAB9
BAB8
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
7
6
5
4
3
2
1
0
BAB7
BAB6
BAB5
BAB4
BAB3
BAB2
BAB1
BAB0
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Rev. 5.00, 09/03, page 156 of 760
7.2.5
Break Address Mask Register B (BAMRB)
BAMRB is a 32-bit read/write register. BAMRB specifies bits masked in the break address
specified by BARB. A power-on reset initializes BAMRB to H'00000000.
Bit:
31
30
29
28
27
26
25
24
BAMB31 BAMB30 BAMB29 BAMB28 BAMB27 BAMB26 BAMB25 BAMB24
Initial value:
R/W:
Bit:
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
23
22
21
20
19
18
17
16
BAMB23 BAMB22 BAMB21 BAMB20 BAMB19 BAMB18 BAMB17 BAMB16
Initial value:
R/W:
Bit:
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
15
14
13
12
11
10
9
8
BAMB15 BAMB14 BAMB13 BAMB12 BAMB11 BAMB10 BAMB9
Initial value:
R/W:
Bit:
Initial value:
R/W:
BAMB8
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
7
6
5
4
3
2
1
0
BAMB7
BAMB6
BAMB5
BAMB4
BAMB3
BAMB2
BAMB1
BAMB0
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Bits 31 to 0—Break Address Mask Register B31 to B0 (BAMB31 to BAMB0): Specifies bits
masked in the channel B break address bits specified by BARB (BAB31—BAB0).
Bits 31 to 0:
BAMBn
Description
0
Break address BABn of channel B is included in the break condition (Initial value)
1
Break address BABn of channel B is masked and is not included in the break
condition
n = 31 to 0
Rev. 5.00, 09/03, page 157 of 760
7.2.6
Break Data Register B (BDRB)
BDRB is a 32-bit read/write register. A power-on reset initializes BDRB to H'00000000.
Bit:
Initial value:
R/W:
Bit:
Initial value:
R/W:
Bit:
Initial value:
R/W:
Bit:
Initial value:
31
30
29
28
27
26
25
24
BDB31
BDB30
BDB29
BDB28
BDB27
BDB26
BDB25
BDB24
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
23
22
21
20
19
18
17
16
BDB23
BDB22
BDB21
BDB20
BDB19
BDB18
BDB17
BDB16
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
15
14
13
12
11
10
9
8
BDB15
BDB14
BDB13
BDB12
BDB11
BDB10
BDB9
BDB8
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
7
6
5
4
3
2
1
0
BDB7
BDB6
BDB5
BDB4
BDB3
BDB2
BDB1
BDB0
0
0
0
0
0
0
0
0
Rev. 5.00, 09/03, page 158 of 760
7.2.7
Break Data Mask Register B (BDMRB)
BDMRB is a 32-bit read/write register. BDMRB specifies bits masked in the break data specified
by BDRB. A power-on reset initializes BDMRB to H'00000000.
Bit:
31
30
29
28
27
26
25
24
BDMB31 BDMB30 BDMB29 BDMB28 BDMB27 BDMB26 BDMB25 BDMB24
Initial value:
R/W:
Bit:
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
23
22
21
20
19
18
17
16
BDMB23 BDMB22 BDMB21 BDMB20 BDMB19 BDMB18 BDMB17 BDMB16
Initial value:
R/W:
Bit:
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
15
14
13
12
11
10
9
8
BDMB15 BDMB14 BDMB13 BDMB12 BDMB11 BDMB10 BDMB9 BDMB8
Initial value:
R/W:
Bit:
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
7
6
5
4
3
2
1
0
BDMB7 BDMB6 BDMB5 BDMB4 BDMB3 BDMB2 BDMB1 BDMB0
Initial value:
R/W:
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Bits 31 to 0—Break Data Mask Register B31 to B0 (BDMB31 to BDMB0): Specifies bits in
the channel B break data bits specified by BDRB (BDB31—BDB0).
Bits 31 to 0:
BDMBn
Description
0
Break data BDBn of channel B is included in the break condition
1
Break data BDBn of channel B is masked and is not included in the break
condition
(Initial value)
n = 31 to 0
Notes: 1. Specify an operand size when including the value of the data bus in the break condition.
2. When a byte size is specified as a break condition, the same-byte data must be set in
bits 15 to 8 and bits 7 to 0 in BDRB for the break data.
Rev. 5.00, 09/03, page 159 of 760
7.2.8
Break Bus Cycle Register B (BBRB)
Break bus cycle register B (BBRB) is a 16-bit read/write register, which specifies, (1) CPU cycle
or DMAC cycle, (2) instruction fetch or data access, (3) read/write, and (4) operand size in the
break conditions of channel B. A power-on reset initializes BBRB to H'0000.
Bit:
15
14
13
12
11
10
9
8
—
—
—
—
—
—
—
—
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R
R
R
R
R
R
R
Bit:
7
6
5
4
3
2
1
0
CDB1
CDB0
IDB1
IDB0
RWB1
RWB0
SZB1
SZB0
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Initial value:
R/W:
Bits 15 to 8—Reserved: These bits are always read as 0. These bits are always read as 0.
Bits 7 and 6—CPU Cycle/DMAC Cycle Select B (CDB1, CDB0): Select the CPU cycle or
DMAC cycle as the bus cycle of the channel B break condition.
Bit 7: CDB1
Bit 6: CDB0
Description
0
0
Condition comparison is not performed
*
1
The break condition is the CPU cycle
1
0
The break condition is the DMAC cycle
(Initial value)
*: Don’t care
Bits 5 and 4—Instruction Fetch/Data Access Select B (IDB1, IDB0): Select the instruction
fetch cycle or data access cycle as the bus cycle of the channel B break condition.
Bit 5: IDB1
Bit 4: IDB0
Description
0
0
Condition comparison is not performed
1
The break condition is the instruction fetch cycle
1
0
The break condition is the data access cycle
1
The break condition is the instruction fetch cycle or data access
cycle
Rev. 5.00, 09/03, page 160 of 760
(Initial value)
Bits 3 and 2—Read/Write Select B (RWB1, RWB0): Select the read cycle or write cycle as the
bus cycle of the channel B break condition.
Bit 3: RWB1
Bit 2: RWB0
Description
0
0
Condition comparison is not performed
1
The break condition is the read cycle
1
(Initial value)
0
The break condition is the write cycle
1
The break condition is the read cycle or write cycle
Bits 1 and 0—Operand Size Select B (SZB1, SZB0): Select the operand size of the bus cycle for
the channel B break condition.
Bit 1: SZB1
Bit 0: SZB0
Description
0
0
The break condition does not include operand size
(Initial value)
1
The break condition is byte access
0
The break condition is word access
1
The break condition is longword access
1
Rev. 5.00, 09/03, page 161 of 760
7.2.9
Break Control Register (BRCR)
BRCR sets the following conditions:
1. Channels A and B are used in two independent channels condition or under the sequential
condition.
2. A break is set before or after instruction execution.
3. A break is set by the number of execution times.
4. Determine whether to include data bus on channel B in comparison conditions.
5. Enable PC trace.
6. Enable the ASID check.
The break control register (BRCR) is a 32-bit read/write register that has break conditions match
flags and bits for setting a variety of break conditions. A power-on reset initializes BRCR to
H'00000000.
Bit:
31
30
29
28
27
26
25
24
—
—
—
—
—
—
—
—
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R
R
R
R
R
R
R
Bit:
23
22
21
20
19
18
17
16
—
—
—
—
—
—
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R
R/W
R/W
R
R
R
R
Bit:
15
14
13
12
11
10
9
8
PCBA
—
—
BASMA BASMB
SCMFCA SCMFCB SCMFDA SCMFDB PCTE
Initial value:
R/W:
Bit:
Initial value:
R/W:
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R
R
7
6
5
4
3
2
1
0
DBEB
PCBB
—
—
SEQ
—
—
ETBE
0
0
0
0
0
0
0
0
R/W
R/W
R
R
R/W
R
R
R/W
Bits 31 to 22—Reserved: These bits are always read as 0. The write value should always be 0.
Rev. 5.00, 09/03, page 162 of 760
Bit 21—Break ASID Mask A (BASMA): Specifies whether the bits of the channel A break
ASID7-ASID0 (BASA7 to BASA0) set in BASRA are masked or not.
Bit 21: BASMA Description
0
All BASRA bits are included in break condition, ASID is checked
(Initial value)
1
No BASRA bits are included in break condition, ASID is not checked
Bit 20—Break ASID Mask B (BASMB): Specifies whether the bits of channel B break ASID7ASID0 (BASB7 to BASB0) set in BASRB are masked or not.
Bit 20: BASMB Description
0
All BASRB bits are included in break condition, ASID is checked
1
No BASRB bits are included in break condition, ASID is not checked
(Initial value)
Bits 19 to 16—Reserved: These bits are always read as 0. The write value should always be 0.
Bit 15—CPU Condition Match Flag A (SCMFCA): When the CPU bus cycle condition in the
break conditions set for channel A is satisfied, this flag is set to 1 (not cleared to 0). In order to
clear this flag, write 0 into this bit.
Bit 15:
SCMFCA
Description
0
The CPU cycle condition for channel A does not match
1
The CPU cycle condition for channel A matches
(Initial value)
Bit 14—CPU Condition Match Flag B (SCMFCB): When the CPU bus cycle condition in the
break conditions set for channel B is satisfied, this flag is set to 1 (not cleared to 0). In order to
clear this flag, write 0 into this bit.
Bit 14:
SCMFCB
Description
0
The CPU cycle condition for channel B does not match
1
The CPU cycle condition for channel B matches
(Initial value)
Rev. 5.00, 09/03, page 163 of 760
Bit 13—DMAC Condition Match Flag A (SCMFDA): When the on-chip DMAC bus cycle
condition in the break conditions set for channel A is satisfied, this flag is set to 1 (not cleared to
0). In order to clear this flag, write 0 into this bit.
Bit 13:
SCMFDA
Description
0
The DMAC cycle condition for channel A does not match
1
The DMAC cycle condition for channel A matches
(Initial value)
Bit 12—DMAC Condition Match Flag B (SCMFDB): When the on-chip DMAC bus cycle
condition in the break conditions set for channel B is satisfied, this flag is set to 1 (not cleared to
0). In order to clear this flag, write 0 into this bit.
Bit 12:
SCMFDB
Description
0
The DMAC cycle condition for channel B does not match
1
The DMAC cycle condition for channel B matches
(Initial value)
Bit 11—PC Trace Enable (PCTE): Enables PC trace.
Bit 11: PCTE
Description
0
Disables PC trace
1
Enables PC trace
(Initial value)
Bit 10—PC Break Select A (PCBA): Selects the break timing of the instruction fetch cycle for
channel A as before or after instruction execution.
Bit 10: PCBA
Description
0
PC break of channel A is set before instruction execution
1
PC break of channel A is set after instruction execution
(Initial value)
Bits 9 and 8—Reserved: These bits are always read as 0. The write value should always be 0.
Bit 7—Data Break Enable B (DBEB): Selects whether or not the data bus condition is included
in the break condition of channel B.
Bit 7: DBEB
Description
0
No data bus condition is included in the condition of channel B
1
The data bus condition is included in the condition of channel B
Rev. 5.00, 09/03, page 164 of 760
(Initial value)
Bit 6—PC Break Select B (PCBB): Selects the break timing of the instruction fetch cycle for
channel B as before or after instruction execution.
Bit 6: PCBB
Description
0
PC break of channel B is set before instruction execution
1
PC break of channel B is set after instruction execution
(Initial value)
Bits 5 and 4—Reserved: These bits are always read as 0. The write value should always be 0.
Bit 3—Sequence Condition Select (SEQ): Selects two conditions of channels A and B as
independent or sequential.
Bit 3: SEQ
Description
0
Channels A and B are compared under the independent condition (Initial value)
1
Channels A and B are compared under the sequential condition (channel A, then
channel B)
Bits 2 and 1—Reserved: These bits are always read as 0. The write value should always be 0.
Bit 0—The Number of Execution Times Break Enable (ETBE): Enable the execution-times
break condition only on channel B. If this bit is 1 (break enable), a user break is issued when the
number of break conditions matches with the number of execution times that is specified by the
BETR register.
Bit 0: ETBE
Description
0
The execution-times break condition is masked on channel B
1
The execution-times break condition is enabled on channel B
(Initial value)
Rev. 5.00, 09/03, page 165 of 760
7.2.10
Execution Times Break Register (BETR)
When the execution-times break condition of channel B is enabled, this register specifies the
number of execution times to make the break. The maximum number is 2 12 – 1 times. A power-on
reset initializes BETR to H'0000. When a break condition is satisfied, it decreases the BETR. A
break is issued when the break condition is satisfied after the BETR becomes H'0001. Bits 15-12
are always read as 0 and 0 should always be written in these bits.
Bit:
15
14
13
12
—
—
—
—
11
10
9
8
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R
R
R
R/W
R/W
R/W
R/W
Bit:
7
6
5
4
3
2
1
0
Initial value:
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W:
Rev. 5.00, 09/03, page 166 of 760
7.2.11
Branch Source Register (BRSR)
BRSR is a 32-bit read register. BRSR stores the last fetched address before branch and the pointer
(3 bits) which indicates the number of cycles from fetch to execution for the last executed
instruction. BRSR has the flag bit that is set to 1 when branch occurs. This flag bit is cleared to 0,
when BRSR is read and also initialized by power-on resets or manual resets. Other bits are not
initialized by reset. Eight BRSR registers have queue structure and a stored register is shifted
every branch.
Bit:
31
30
29
28
27
26
25
24
SVF
PID2
PID1
PID0
BSA27
BSA26
BSA25
BSA24
Initial value:
0
*
*
*
*
*
*
*
R/W:
R
R
R
R
R
R
R
R
Bit:
23
22
21
20
19
18
17
16
BSA23
BSA22
BSA21
BSA20
BSA19
BSA18
BSA17
BSA16
Initial value:
*
*
*
*
*
*
*
*
R/W:
R
R
R
R
R
R
R
R
Bit:
15
14
13
12
11
10
9
8
BSA15
BSA14
BSA13
BSA12
BSA11
BSA10
BSA9
BSA8
Initial value:
*
*
*
*
*
*
*
*
R/W:
R
R
R
R
R
R
R
R
Bit:
7
6
5
4
3
2
1
0
BSA7
BSA6
BSA5
BSA4
BSA3
BSA2
BSA1
BSA0
Initial value:
*
*
*
*
*
*
*
*
R/W:
R
R
R
R
R
R
R
R
Note: * Undefined value
Bit 31—BRSR Valid Flag (SVF): Indicates whether the address and the pointer by which the
branch source address can be calculated. When a branch source address is fetched, this flag is set
to 1. This flag is cleared to 0 in reading BRSR.
Bit 31: SVF
Description
0
The value of BRSR register is invalid
1
The value of BRSR register is valid
Rev. 5.00, 09/03, page 167 of 760
Bits 30 to 28—Instruction Decode Pointer (PID2 to PID0): PID is a 3-bit binary pointer (0–7).
These bits indicate the instruction buffer number which stores the last executed instruction before
branch.
Bits 30 to 28:
PID
Description
Even
PID indicates the instruction buffer number.
Odd
PiD+2 indicates the instruction buffer number
Bits 27 to 0—Branch Source Address (BSA27 to BSA0): These bits store the last fetched
address before branch.
7.2.12
Branch Destination Register (BRDR)
BRDR is a 32-bit read register. BRDR stores the branch destination fetch address. BRDR has the
flag bit that is set to 1 when branch occurs. This flag bit is cleared to 0, when BRDR is read and
also initialized by power-on resets or manual resets. Other bits are not initialized by resets. Eight
BRDR registers have queue structure and a stored register is shifted every branch.
Bit:
31
30
29
28
27
26
25
24
DVF
—
—
—
BDA27
BDA26
BDA25
BDA24
Initial value:
0
*
*
*
*
*
*
*
R/W:
R
R
R
R
R
R
R
R
Bit:
23
22
21
20
19
18
17
16
BDA23
BDA22
BDA21
BDA20
BDA19
BDA18
BDA17
BDA16
Initial value:
*
*
*
*
*
*
*
*
R/W:
R
R
R
R
R
R
R
R
Bit:
15
14
13
12
11
10
9
8
BDA15
BDA14
BDA13
BDA12
BDA11
BDA10
BDA9
BDA8
Initial value:
*
*
*
*
*
*
*
*
R/W:
R
R
R
R
R
R
R
R
Bit:
7
6
5
4
3
2
1
0
BDA7
BDA6
BDA5
BDA4
BDA3
BDA2
BDA1
BDA0
Initial value:
*
*
*
*
*
*
*
*
R/W:
R
R
R
R
R
R
R
R
Note: * Undefined value
Rev. 5.00, 09/03, page 168 of 760
Bit 31—BRDR Valid Flag (DVF): Indicates whether a branch destination address is stored.
When a branch destination address is fetched, this flag is set to 1. This flag is set to 0 in reading
BRDR.
Bit 31: DVF
Description
0
The value of BRDR register is invalid
1
The value of BRDR register is valid
Bits 30 to 28—Reserved: These bits are always read as 0. The write value should always be 0.
Bits 27 to 0—Branch Destination Address (BDA27 to BDA0): These bits store the first fetched
address after branch.
7.2.13
Break ASID Register A (BASRA)
Break ASID register A (BASRA) is an 8-bit read/write register that specifies the ASID that serves
as the break condition for channel A. It is not initialized by resets.
Bit:
Initial value:
R/W:
7
6
5
4
3
2
1
0
BASA7
BASA6
BASA5
BASA4
BASA3
BASA2
BASA1
BASA0
*
*
*
*
*
*
*
*
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Note: * Undefined value
Bits 7 to 0—Break ASID A7 to 0 (BASA7 to BASA0): These bits store the ASID (bits 7 to 0)
that is the channel A break condition.
7.2.14
Break ASID Register B (BASRB)
Break ASID register B (BASRB) is an 8-bit read/write register that specifies the ASID that serves
as the break condition for channel B. It is not initialized by resets.
Bit:
Initial value:
R/W:
7
6
5
4
3
2
1
0
BASB7
BASB6
BASB5
BASB4
BASB3
BASB2
BASB1
BASB0
*
*
*
*
*
*
*
*
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Note: * Undefined value
Bits 7 to 0—Break ASID A7 to 0 (BASB7 to BASB0): These bits store the ASID (bits 7 to 0)
that is the channel B break condition.
Rev. 5.00, 09/03, page 169 of 760
7.3
Operation Description
7.3.1
Flow of the User Break Operation
The flow from setting of break conditions to user break exception processing is described below:
1. The break addresses and the corresponding ASIDs are loaded in the break address registers
(BARA and BARB) and break ASID registers (BASRA and BASRB). The masked addresses
are set in the break address mask registers (BAMRA and BAMRB). The break data is set in the
break data register (BDRB). The masked data is set in the break data mask register (BDMRB).
The breaking bus conditions are set in the break bus cycle registers (BBRA and BBRB). Three
groups of the BBRA and BBRB (CPU cycle/DMAC cycle select, instruction fetch/data access
select, and read/write select) are each set. No user break will be generated if even one of these
groups is set with 00. The respective conditions are set in the bits of the BRCR.
2. When the break conditions are satisfied, the UBC sends a user break request to the interrupt
controller. The break type will be sent to CPU indicating the instruction fetch, pre/post
instruction break, data access break. When conditions match up, the CPU condition match
flags (SCMFCA and SCMFCB) and DMAC condition match flags (SCMFDA and SCMFDB)
for the respective channels are set.
3. The appropriate condition match flags (SCMFCA, SCMFDA, SCMFCB, and SCMFDB) can
be used to check if the set conditions match or not. The matching of the conditions sets flags,
but they are not reset. 0 must first be written to them before they can be used again.
4. There is a chance that the data access break and its following instruction fetch break occur
around the same time, there will be only one break request to the CPU, but these two break
channel match flags could be both set.
7.3.2
Break on Instruction Fetch Cycle
1. When CPU/instruction fetch/read/word or longword is set in the break bus cycle registers
(BBRA/BBRB), the break condition becomes the CPU instruction fetch cycle. Whether it then
breaks before or after the execution of the instruction can then be selected with the
PCBA/PCBB bits of the break control register (BRCR) for the appropriate channel.
2. An instruction set for a break before execution breaks when it is confirmed that the instruction
has been fetched and will be executed. This means this feature cannot be used on instructions
fetched by overrun (instructions fetched at a branch or during an interrupt transition, but not to
be executed). When this kind of break is set for the delay slot of a delay branch instruction, the
break is generated prior to execution of the instruction that then first accepts the break.
Meanwhile, the break set for pre-instruction-break on delay slot instruction and postinstruction-break on SLEEP instruction are also prohibited.
Rev. 5.00, 09/03, page 170 of 760
3. When the condition is specified to be occurred after execution, the instruction set with the
break condition is executed and then the break is generated prior to the execution of the next
instruction. As with pre-execution breaks, this cannot be used with overrun fetch instructions.
When this kind of break is set for a delay branch instruction, the break is generated at the
instruction that then first accepts the break.
4. When an instruction fetch cycle is set for channel B, break data register B (BDRB) is ignored.
There is thus no need to set break data for the break of the instruction fetch cycle.
7.3.3
Break by Data Access Cycle
1. The memory cycles in which CPU data access breaks occur are from instructions.
2. The relationship between the data access cycle address and the comparison condition for
operand size are listed in table 7.2:
Table 7.2
Data Access Cycle Addresses and Operand Size Comparison Conditions
Access Size
Address Compared
Longword
Compares break address register bits 31–2 to address bus bits 31–2
Word
Compares break address register bits 31–1 to address bus bits 31–1
Byte
Compares break address register bits 31–0 to address bus bits 31–0
This means that when address H'00001003 is set without specifying the size condition, for
example, the bus cycle in which the break condition is satisfied is as follows (where other
conditions are met).
Longword access at H'00001000
Word access at H'00001002
Byte access at H'00001003
3. When the data value is included in the break conditions on B channel:
When the data value is included in the break conditions, either longword, word, or byte is
specified as the operand size of the break bus cycle registers (BBRA and BBRB). When data
values are included in break conditions, a break is generated when the address conditions and
data conditions both match. To specify byte data for this case, set the same data in two bytes at
bits 15–8 and bits 7–0 of the break data register B (BDRB) and break data mask register B
(BDMRB). When word or byte is set, bits 31–16 of BDRB and BDMRB are ignored.
4. When the DMAC data access is included in the break condition:
When the address is included in the break condition on DMAC data access, the operand size of
the break bus cycle registers (BBRA and BBRB) should be byte, word or no specified operand
size. When the data value is included, select either byte or word.
Rev. 5.00, 09/03, page 171 of 760
7.3.4
Sequential Break
1. By specifying SEQ in BRCR is set to 1, the sequential break is issued when channel B break
condition matches after channel A break condition matches. A user break is ignored even if
channel B break condition matches before channel A break condition matches. When channels
A and B condition match at the same time, the sequential break is not issued.
2. In sequential break specification, a logical bus or internal bus can be selected and the execution
times break condition can be also specified. For example, when the execution times break
condition is specified, the break condition is satisfied at channel B condition match with BETR
= H'0001 after channel A condition match.
7.3.5
Value of Saved Program Counter
The PC when a break occurs is saved to the SPC in user breaks. The PC value saved is as follows
depending on the type of break.
1. When instruction fetch (before instruction execution) is specified as a break condition:
The value of the program counter (PC) saved is the address of the instruction that matches the
break condition. The fetched instruction is not executed, and a break occurs before it.
2. When instruction fetch (after instruction execution) is specified as a break condition:
The PC value saved is the address of the instruction to be executed following the instruction in
which the break condition matches. The fetched instruction is executed, and a break occurs
before the execution of the next instruction.
3. When data access (address only) is specified as a break condition:
The PC value is the address of the instruction to be executed following the instruction that
matched the break condition. The instruction that matched the condition is executed and the
break occurs before the next instruction is executed.
4. When data access (address + data) is specified as a break condition:
The PC value is the start address of the instruction that follows the instruction already executed
when break processing started up. When a data value is added to the break conditions, the
place where the break will occur cannot be specified exactly. The break will occur before the
execution of an instruction fetched around the data access where the break occurred.
Rev. 5.00, 09/03, page 172 of 760
7.3.6
PC Trace
1. Setting PCTE in BRCR to 1 enables PC traces. When branch (branch instruction, repeat, and
interrupt) is generated, the address from which the branch source address can be calculated and
the branch destination address are stored in BRSR and BRDR, respectively. The branch
address and the pointer, which corresponds to the branch, are included in BRSR.
2. The branch address before branch occurs can be calculated from the address and the pointer
stored in BRSR. The expression from BSA (the address in BRSR), PID (the pointer in BRSR),
and IA (the instruction address before branch occurs) is as follows: IA = BSA – 2 * PID.
Notes are needed when an interrupt (a branch) is issued before the branch destination
instruction is executed. In case of the next figure, the instruction “Exec” executed immediately
before branch is calculated by IA = BSA – 2 * PID. However, when branch “branch” has delay
slot and the destination address is 4n + 2 address, the address “Dest” which is specified by
branch instruction is stored in BRSR (Dest = BSA). Therefore, as IA = BSA – 2 * PID is not
applied to this case, this PID is invalid. The case where BSA is 4n + 2 boundary is applied
only to this case and then some cases are classified as follows:
Exec:branch Dest
Dest:instr
(not executed)
interrupt
Int: interrupt routine
If the PID value is odd, instruction buffer indicates PID+2 buffer. However, these expressions
in this table are accounted for it. Therefore, the true branch source address is calculated with
BSA and PID values stored in BRSR.
3. The branch address before branch occurrence, IA, has different values due to some kinds of
branch.
a. Branch instruction
The branch instruction address
b. Interrupt
The last instruction executed before interrupt
The top address of interrupt routine is stored in BRDR.
4. BRSR and BRDR have eight pairs of queue structures. The top of queues is read first when the
address stored in the PC trace register is read. BRSR and BRDR share the read pointer. Read
BRSR and BRDR in order, the queue only shifts after BRDR is read. When reading BRDR,
longword access should be used. Also, the PC trace has a trace pointer, which initially points
to the bottom of the queues. The first pair of branch addresses will be stored at the bottom of
the queues, then push up when next pairs come into the queues. The trace pointer will points to
the next branch address to be executed, unless it got push out of the queues. When the branch
address has been executed, the trace pointer will shift down to next pair of addresses, until it
Rev. 5.00, 09/03, page 173 of 760
reaches the bottom of the queues. After switching the PCTE bit (in BRCR) off and on, the
values in the queues are invalid. The read pointer stay at the position before PCTE is switched,
but the trace pointer restart at the bottom of the queues.
7.3.7
Usage Examples
Break Condition Specified to a CPU Instruction Fetch Cycle
1. Register specifications
BARA = H'00000404, BAMRA = H'00000000, BBRA = H'0054, BARB = H'00008010,
BAMRB = H'00000006, BBRB = H'0054, BDRB = H'00000000, BDMRB = H'00000000,
BRCR = H'00300400
Specified conditions: Channel A/channel B independent mode
•
Channel A
Address:
H'00000404, Address mask: H'00000000
Bus cycle: CPU/instruction fetch (after instruction execution)/read (operand size is not
included in the condition)
No ASID check is included
•
Channel B
Address:
H'00008010, Address mask: H'00000006
Data:
H'00000000, Data mask: H'00000000
Bus cycle: CPU/instruction fetch (before instruction execution)/read (operand size is not
included in the condition)
No ASID check is included
A user break occurs after an instruction of address H'00000404 is executed or before
instructions of adresses H'00008010 to H'00008016 are executed.
Rev. 5.00, 09/03, page 174 of 760
2. Register specifications
BARA = H'00037226, BAMRA = H'00000000, BBRA = H'0056, BARB = H'0003722E,
BAMRB = H'00000000, BBRB = H'0056, BDRB = H'00000000, BDMRB = H'00000000,
BRCR = H'00000008, BASRA = H'80, BASRB = H'70
Specified conditions: Channel A/channel B sequence mode
•
Channel A
Address:
H'00037226, Address mask: H'00000000, ASID = H'80
Bus cycle: CPU/instruction fetch (before instruction execution)/read/word
•
Channel B
Address:
H'0003722E, Address mask: H'00000000, ASID = H'70
Data:
H'00000000, Data mask: H'00000000
Bus cycle: CPU/instruction fetch (before instruction execution)/read/word
An instruction with ASID = H'80 and address H'00037226 is executed, and a user break occurs
before an instruction with ASID = H'70 and address H'0003722E is executed.
3. Register specifications
BARA = H'00027128, BAMRA = H'00000000, BBRA = H'005A, BARB = H'00031415,
BAMRB = H'00000000, BBRB = H'0054, BDRB = H'00000000, BDMRB = H'00000000,
BRCR = H'00300000
Specified conditions: Channel A/channel B independent mode
•
Channel A
Address:
H'00027128, Address mask: H'00000000
Bus cycle: CPU/instruction fetch (before instruction execution)/write/word
No ASID check is included
•
Channel B
Address:
H'00031415, Address mask: H'00000000
Data:
H'00000000, Data mask: H'00000000
Bus cycle: CPU/instruction fetch (before instruction execution)/read (operand size is not
included in the condition)
No ASID check is included
On channel A, no user break occurs since instruction fetch is not a write cycle. On channel B,
no user break occurs since instruction fetch is performed for an even address.
Rev. 5.00, 09/03, page 175 of 760
4. Register specifications
BARA = H'00037226, BAMRA = H'00000000, BBRA = H'005A, BARB = H'0003722E,
BAMRB = H'00000000, BBRB = H'0056, BDRB = H'00000000, BDMRB = H'00000000,
BRCR = H'00000008, BASRA = H'80, BASRB = H'70
Specified conditions: Channel A/channel B sequence mode
•
Channel A
Address:
H'00037226, Address mask: H'00000000, ASID: H'80
Bus cycle: CPU/instruction fetch (before instruction execution)/write/word
•
Channel B
Address:
H'0003722E, Address mask: H'00000000, ASID: H'70
Data:
H'00000000, Data mask: H'00000000
Bus cycle: CPU/instruction fetch (before instruction execution)/read/word
Since instruction fetch is not a write cycle on channel A, a sequence condition does not match.
Therefore, no user break occurs.
5. Register specifications
BARA = H'00000500, BAMRA = H'00000000, BBRA = H'0057, BARB = H'00001000,
BAMRB = H'00000000, BBRB = H'0057, BDRB = H'00000000, BDMRB = H'00000000,
BRCR = H'00300001, BETR = H'0005
Specified conditions: Channel A/channel B independent mode
•
Channel A
Address:
H'00000500, Address mask: H'00000000
Bus cycle: CPU/instruction fetch (before instruction execution)/read/longword
•
Channel B
Address:
H'00001000, Address mask: H'00000000
Data:
H'00000000, Data mask: H'00000000
Bus cycle: CPU/instruction fetch (before instruction execution)/read/longword
The number of execution-times break enable (5 times)
On channel A, a user break occurs before an instruction of address H'00000500 is executed.
On channel B, a user break occurs before the fifth instruction execution after instructions of
address H'00001000 are executed four times.
Rev. 5.00, 09/03, page 176 of 760
6. Register specifications
BARA = H'00008404, BAMRA = H'00000FFF, BBRA = H'0054, BARB = H'00008010,
BAMRB = H'00000006, BBRB = H'0054, BDRB = H'00000000, BDMRB = H'00000000,
BRCR = H'00000400, BASRA = H'80, BASRB = H'70
Specified conditions: Channel A/channel B independent mode
•
Channel A
Address:
H'00008404, Address mask: H'00000FFF, ASID: H'80
Bus cycle: CPU/instruction fetch (after instruction execution)/read (operand size is not
included in the condition)
•
Channel B
Address:
H'00008010, Address mask: H'00000006, ASID: H'70
Data:
H'00000000, Data mask: H'00000000
Bus cycle: CPU/instruction fetch (before instruction execution)/read (operand size is not
included in the condition)
A user break occurs after an instruction with ASID = H'80 and address H'00008000 to
H'00008FFE is executed or before instructions with ASID = H'70 and addresses H'00008010
to H'00008016 are executed.
Break Condition Specified to a CPU Data Access Cycle
1. Register specifications
BARA = H'00123456, BAMRA = H'00000000, BBRA = H'0064, BARB = H'000ABCDE,
BAMRB = H'000000FF, BBRB = H'006A, BDRB = H'0000A512, BDMRB = H'00000000,
BRCR = H'00000080, BASRA = H'80, BASRB = H'70
Specified conditions: Channel A/channel B independent mode
•
Channel A
Address:
H'00123456, Address mask: H'00000000
Bus cycle: CPU/data access/read (operand size is not included in the condition)
•
Channel B
Address:
H'000ABCDE, Address mask: H'000000FF, ASID: H'70
Data:
H'0000A512, Data mask: H'00000000
Bus cycle: CPU/data access/write/word
On channel A, a user break occurs with ASID = H'80 during longword read to address
H'00123454, word read to address H'00123456, or byte read to address H'00123456. On
channel B, a user break occurs with ASID = H'70 when word H'A512 is written in addresses
H'000ABC00 to H'000ABCFE.
Rev. 5.00, 09/03, page 177 of 760
Break Condition Specified to a DMAC Data Access Cycle
1. Register specifications:
BARA = H'00314156, BAMRA = H'00000000, BBRA = H'0094, BARB = H'00055555,
BAMRB = H'00000000, BBRB = H'00A9, BDRB = H'00000078, BDMRB = H'0000000F,
BRCR = H'00000080, BASRA = H'80, BASRB = H'70
Specified conditions: Channel A/channel B independent mode
•
Channel A
Address:
H'00314156, Address mask: H'00000000, ASID: H'80
Bus cycle: DMAC/instruction fetch/read (operand size is not included in the condition)
•
Channel B
Address:
H'00055555, Address mask: H'00000000, ASID: H'70
Data:
H'00000078, Data mask: H'0000000F
Bus cycle: DMAC/data access/write/byte
On channel A, no user break occurs since instruction fetch is not performed in DMAC cycles.
On channel B, a user break occurs with ASID = H'70 when the DMAC writes byte H'7* in
address H'00055555.
Rev. 5.00, 09/03, page 178 of 760
7.3.8
Notes
1. Only CPU can read/write UBC registers.
2. UBC cannot monitor CPU and DMAC access in the same channel.
3. Notes in specification of sequential break are described below:
a. A condition match occurs when B-channel match occurs in a bus cycle after an A-channel
match occurs in another bus cycle in sequential break setting. Therefore, no condition
match occurs even if a bus cycle, in which an A-channel match and a channel B match
occur simultaneously, is set.
b. Since the CPU has a pipeline configuration, the pipeline determines the order of an
instruction fetch cycle and a memory cycle. Therefore, when a channel condition matches
in the order of bus cycles, a sequential condition is satisfied.
c. When the bus cycle condition for channel A is specified as a break before execution
(PCBA = 0 in BRCR) and an instruction fetch cycle (in BBRA), the attention is as follows.
A break is issued and condition match flags in BRCR are set to 1, when the bus cycle
conditions both for channels A and B match simultaneously.
4. The change of a UBC register value is executed in MA (memory access) stage. Therefore,
even if the break condition matches in the instruction fetch address following the instruction in
which the pre-execution break is specified as the break condition, no break occurs. In order to
know the timing UBC register is changed, read the last written register. Instructions after then
are valid for the newly written register value.
5. The branch instruction should not be executed as soon as PC trace register BRSR and BRDR
are read.
6. When PC breaks and TLB exceptions or errors occur in the same instruction. The priority is as
follows:
a. Break and instruction fetch exceptions: Instruction fetch exception occurs first.
b. Break before execution and operand exception: Break before execution occurs first.
c. Break after execution and operand exception: Operand exception occurs first.
Rev. 5.00, 09/03, page 179 of 760
Rev. 5.00, 09/03, page 180 of 760
Section 8 Power-Down Modes
8.1
Overview
In the power-down modes, all CPU and some on-chip peripheral module functions are halted. This
lowers power consumption.
8.1.1
Power-Down Modes
The SH7709S has the following power-down modes and function:
1. Sleep mode
2. Standby mode
3. Module standby function (TMU, RTC, SCI, UBC, DMAC, DAC, ADC, SCIF, and IrDA onchip peripheral modules)
4. Hardware standby mode
Table 8.1 shows the transition conditions for entering the modes from the program execution state,
as well as the CPU and peripheral module states in each mode and the procedures for canceling
each mode.
Rev. 5.00, 09/03, page 181 of 760
Table 8.1
Power-Down Modes
State
Mode
Transition
Conditions
CPU
RegCPG CPU ister
On-Chip
Memory
On-Chip
Peripheral
Modules
Pins
External
Memory
Canceling
Procedure
Held
Run
Refresh
1. Interrupt
Sleep
mode
Execute SLEEP
instruction with
STBY bit cleared
to 0 in STBCR
Runs Halts Held
Standby
mode
Execute SLEEP
instruction with
STBY bit set to
1 in STBCR
Halts Halts Held
Module
standby
function
Set MSTP bit to
1 in STBCR
Runs Runs Held
or
halts
Hardware Drive CA pin low
standby
mode
Held
2. Reset
Halts Halts Held
Held
Halt*1
Held
Held
Specified
module
halts
*2
Held
Halt*3
Held
Selfrefresh
1. Interrupt
Refresh
1. Clear MSTP
bit to 0
2. Reset
2. Reset
Selfrefresh
Power-on reset
Notes: 1. The RTC still runs if the START bit in RCR2 is set to 1 (see section 13, Realtime Clock
(RTC)). The TMU still runs when output of the RTC is used as input to its counter (see
section 12, Timer (TMU)).
2. Depends on the on-chip peripheral module.
TMU external pin: Held
SCI external pin: Reset
3. The RTC still runs if the START bit in RCR2 is set to 1. The TMU does not run.
Rev. 5.00, 09/03, page 182 of 760
8.1.2
Pin Configuration
Table 8.2 lists the pins used for the power-down modes.
Table 8.2
Pin Configuration
Pin Name
Abbreviation
I/O
Description
Processing state 1
STATUS1
O
Operating state of the processor.
Processing state 0
STATUS0
Wakeup from
standby mode
WAKEUP
HH: Reset, HL: Sleep mode, LH: Standby mode,
LL: Normal operation
O
Active-low assertion after accepting wakeup
interrupt in standby mode until returning to normal
operation with WDT overflow
Note: H: high level; L: low level
8.1.3
Register Configuration
Table 8.3 shows the control register configuration for the power-down modes.
Table 8.3
Register Configuration
Name
Abbreviation
R/W
Initial Value Access Size
Address
Standby control register
STBCR
R/W
H'FFFFFF82
8
Standby control register 2
STBCR2
R/W
H'00*
H'00*
H'FFFFFF88
8
Note: * Initialized by a power-on reset. This value is not initialized by a manual reset; the current
value is retained.
8.2
Register Descriptions
8.2.1
Standby Control Register (STBCR)
The standby control register (STBCR) is an 8-bit readable/writable register that sets the powerdown mode. STBCR is initialized to H'00 by a power-on reset.
Bit:
Initial value:
R/W:
7
6
5
4
3
2
1
0
STBY
—
—
STBXTL
—
MSTP2
MSTP1
MSTP0
0
0
0
0
0
0
0
0
R/W
R
R
R/W
R
R/W
R/W
R/W
Rev. 5.00, 09/03, page 183 of 760
Bit 7—Standby (STBY): Specifies transition to standby mode.
Bit 7: STBY
Description
0
Executing SLEEP instruction puts chip into sleep mode
1
Executing SLEEP instruction puts chip into standby mode
(Initial value)
Bits 6, 5, and 3—Reserved: These bits are always read as 0. The write value should always be 0.
Bit 4—Standby Crystal (STBXTL): Specifies halting or operating of the clock pulse generator
in standby mode.
Bit 4: STBXTL
Description
0
Clock pulse generator is halted in standby mode
1
Clock pulse generator is operates in standby mode
(Initial value)
Bit 2—Module Standby 2 (MSTP2): Specifies halting of the clock supply to the timer unit TMU
(an on-chip peripheral module). When the MSTP2 bit is set to 1, the supply of the clock to the
TMU is halted.
Bit 2: MSTP2
Description
0
TMU runs
1
Clock supply to TMU is halted
(Initial value)
Bit 1—Module Standby 1 (MSTP1): Specifies halting of the clock supply to the realtime clock
RTC (an on-chip peripheral module). When the MSTP1 bit is set to 1, the supply of the clock to
the RTC is halted. When the clock halts, all RTC registers become inaccessible, but the counter
keeps running.
Bit 1: MSTP1
Description
0
RTC runs
1
Clock supply to RTC is halted
(Initial value)
Before switching the RTC to module standby, access at least one among the registers RTC, SCI,
and TMU.
Rev. 5.00, 09/03, page 184 of 760
Bit 0—Module Standby 0 (MSTP0): Specifies halting of the clock supply to the serial
communication interface SCI (an on-chip peripheral module). When the MSTP0 bit is set to 1, the
supply of the clock to the SCI is halted.
Bit 0: MSTP0
Description
0
SCI operates
1
Clock supply to SCI is halted
8.2.2
(Initial value)
Standby Control Register 2 (STBCR2)
The standby control register 2 (STBCR2) is a readable/writable 8-bit register that sets the powerdown mode. STBCR2 is initialized to H'00 by a power-on reset.
Bit:
7

Initial value:
R/W:
6
5
MDCHG MSTP8
4
3
2
1
0
MSTP7
MSTP6
MSTP5
MSTP4
MSTP3
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Bit 7—Reserved: The write value set in the program should always be 1.
Bit 6—Pin MD5 to MD0 Control (MDCHG): Specifies whether or not pins MD5 to MD0 are
changed in standby mode. When this bit is set to 1, the MD5 to MD0 pin values are latched when
returning from standby mode by means of a reset or interrupt.
Bit 6: MDCHG
Description
0
Pins MD5 to MD0 are not changed in standby mode
1
Pins MD5 to MD0 are changed in standby mode
(Initial value)
Bit 5— Module Stop 8 (MSTP8): Specifies halting of the clock supply to the user break
controller UBC (an on-chip peripheral module). When the MSTP8 bit is set to 1, the supply of the
clock to the UBC is halted.
Bit 5: MSTP8
Description
0
UBC runs
1
Clock supply to UBC is halted
(Initial value)
Rev. 5.00, 09/03, page 185 of 760
Bit 4—Module Stop 7 (MSTP7): Specifies halting of the clock supply to the DMAC (an on-chip
peripheral module). When the MSTP7 bit is set to 1, the supply of the clock to the DMAC is
halted.
Bit 4: MSTP7
Description
0
DMAC runs
1
Clock supply to DMAC halted
(Initial value)
Bit 3—Module Stop 6 (MSTP6): Specifies halting of the clock supply to the DAC (an on-chip
peripheral module). When the MSTP6 bit is set to 1, the supply of the clock to the DAC is halted.
Bit 3: MSTP6
Description
0
DAC runs
1
Clock supply to DAC halted
(Initial value)
Bit 2—Module Stop 5 (MSTP5): Specifies halting of the clock supply to the ADC (an on-chip
peripheral module). When the MSTP5 bit is set to 1, the supply of the clock to the ADC is halted
and all registers are initialized.
Bit 2: MSTP5
Description
0
ADC runs
1
Clock supply to ADC halted and all registers initialized
(Initial value)
Bit 1—Module Stop 4 (MSTP4): Specifies halting of the clock supply to the SCI2 (SCIF) serial
communication interface with FIFO (an on-chip peripheral module). When the MSTP1 bit is set to
1, the supply of the clock to SCI2 (SCIF) is halted.
Bit 1: MSTP4
Description
0
SCI2 (SCIF) runs
1
Clock supply to SCI2 (SCIF) halted
(Initial value)
Bit 0—Module Stop 3 (MSTP3): Specifies halting of the clock supply to the SCI1 (IrDA)
Infrared Data Association interface with FIFO (an on-chip peripheral module). When the MSTP3
bit is set to 1, the supply of the clock to SCI1 (IrDA) is halted.
Bit 0: MSTP3
Description
0
SCI1(IrDA) runs
1
Clock supply to SCI1(IrDA) halted
Rev. 5.00, 09/03, page 186 of 760
(Initial value)
8.3
Sleep Mode
8.3.1
Transition to Sleep Mode
Executing the SLEEP instruction when the STBY bit in STBCR is 0 causes a transition from the
program execution state to sleep mode. Although the CPU halts immediately after executing the
SLEEP instruction, the contents of its internal registers remain unchanged. The on-chip peripheral
modules continue to run in sleep mode and the clock continues to be output to the CKIO and
CKIO2 pins. In sleep mode, the STATUS1 pin is set high and the STATUS0 pin low.
8.3.2
Canceling Sleep Mode
Sleep mode is canceled by an interrupt (NMI, IRQ, IRL, on-chip peripheral module, PINT) or
reset. Interrupts are accepted in sleep mode even when the BL bit in the SR register is 1. If
necessary, save SPC and SSR to the stack before executing the SLEEP instruction.
Canceling with an Interrupt: When an NMI, IRQ, IRL or on-chip peripheral module interrupt
occurs, sleep mode is canceled and interrupt exception handling is executed. A code indicating the
interrupt source is set in the INTEVT and INTEVT2 registers.
Canceling with a Reset: Sleep mode is canceled by a power-on reset or a manual reset.
8.3.3
Precautions when Using the Sleep Mode
DMAC transfers should not be performed in the sleep mode under conditions other than when the
clock ratio of Iφ (on-chip clock) to Bφ (bus clock) is 1:1.
Rev. 5.00, 09/03, page 187 of 760
8.4
Standby Mode
8.4.1
Transition to Standby Mode
To enter standby mode, set the STBY bit to 1 in STBCR, then execute the SLEEP instruction. The
chip switches from the program execution state to standby mode. In standby mode, power
consumption is greatly reduced by halting not only the CPU, but the clock and on-chip peripheral
modules as well. The clock output from the CKIO and CKIO2 pins also halts. CPU and cache
register contents are held, but some on-chip peripheral modules are initialized. Table 8.4 lists the
states of registers in standby mode.
Table 8.4
Register States in Standby Mode
Module
Registers Initialized
Registers Retaining Data
Interrupt controller (INTC)
—
All registers
On-chip clock pulse generator
(OSC)
—
All registers
User break controller (UBC)
—
All registers
Bus state controller (BSC)
—
All registers
Timer unit (TMU)
TSTR register
Registers other than TSTR
Realtime clock (RTC)
—
All registers
A/D converter (ADC)
All registers
—
D/A converter (DAC)
—
All registers
The procedure for moving to standby mode is as follows:
1. Clear the TME bit in the WDT’s timer control register (WTCSR) to 0 to stop the WDT. Clear
the WDT’s timer counter (WTCNT) to 0 and the CKS2–CKS0 bits in the WTCSR register to
appropriate values to secure the specified oscillation settling time.
2. After the STBY bit in the STBCR register is set to 1, a SLEEP instruction is executed.
3. Standby mode is entered and the clocks within the chip are halted. The STATUS1 pin output
goes low and the STATUS0 pin output goes high.
Rev. 5.00, 09/03, page 188 of 760
8.4.2
Canceling Standby Mode
Standby mode is canceled by an interrupt (NMI, IRQ, IRL, PINT, or on-chip peripheral module)
or a reset.
Canceling with an Interrupt: The on-chip WDT can be used for hot starts. When the chip detects
an NMI, IRL, IRQ, PINT*1, or on-chip peripheral module (except interval timer)*2 interrupt, the
clock will be supplied to the entire chip and standby mode canceled after the time set in the
WDT’s timer control/status register has elapsed. The STATUS1 and STATUS0 pins both go low.
Interrupt handling then begins and a code indicating the interrupt source is set in the INTEVT and
INTEVT2 registers. After the branch to the interrupt handling routine, clear the STBY bit in the
STBCR register. WTCNT stops automatically. If the STBY bit is not cleared, WTCNT continues
operation and a transition is made to standby mode*3 when it reaches H'80. This function prevents
the data from being destroyed due to a rise in voltage with an unstable power supply, etc.
Interrupts are accepted in standby mode even when the BL bit in the SR register is 1. If necessary,
save SPC and SSR to the stack before executing the SLEEP instruction. Immediately after an
interrupt is detected, the phase of the CKIO pin clock output may be unstable, until the processor
starts interrupt handling. (The canceling condition is that the IRL3–IRL0 level is higher than the
mask level in the I3–I0 bits in the SR register.)
Notes: 1. When the RTC is being used, standby mode can be canceled using IRL3–IRL0, IRQ4–
IRQ0, or PINT0/1.
2. Standby mode can be canceled with an RTC or TMU (only when running on the RTC
clock) interrupt.
3. This standby mode can be canceled only by a power-on reset.
Interrupt
request
Crystal oscillator settling
time and PLL synchronization
time
WTCNT value
WDT overflow and branch to
interrupt handling routine
Clear bit STBCR.STBY before
WTCNT reaches H'80. When
STBCR.STBY is cleared, WTCNT
halts automatically.
H'FF
H'80
Time
Figure 8.1 Canceling Standby Mode with STBCR.STBY
Rev. 5.00, 09/03, page 189 of 760
Canceling with a Reset: Standby mode is canceled by a reset (power-on or manual). Keep the
RESET pin low until the clock oscillation settles. The internal clock will continue to be output to
the CKIO and CKIO2 pins.
8.4.3
Clock Pause Function
In standby mode, the clock input from the EXTAL pin or CKIO pin can be halted and the
frequency can be changed. This function is used as follows:
1. Enter standby mode using the appropriate procedures.
2. Once standby mode is entered and the clock stopped within the chip, the STATUS1 pin output
is low and the STATUS0 pin output is high.
3. Once the STATUS1 pin goes low and the STATUS0 pin goes high, the input clock is stopped
or the frequency is changed.
4. When the frequency is changed, an NMI, IRL, IRQ, PINT, or on-chip peripheral module
(except interval timer) interrupt is input after the change. When the clock is stopped, the same
interrupts are input after the clock is applied.
5. After the time set in the WDT has elapsed, the clock starts being applied internally within the
chip, the STATUS1 and STATUS0 pins both go low, and operation resumes from interrupt
exception handling.
Rev. 5.00, 09/03, page 190 of 760
8.5
Module Standby Function
8.5.1
Transition to Module Standby Function
Setting the standby control register MSTP8–MSTP0 bits to 1 halts the supply of clocks to the
corresponding on-chip peripheral modules. This function can be used to reduce the power
consumption in normal mode and sleep mode. The module standby function holds the state prior
to halting the external pins of the on-chip peripheral modules. TMU external pins hold their state
prior to the halt. SCI external pins go to the reset state. With a few exceptions, all registers hold
their values.
Bit
Value
Description
MSTP8
0
UBC runs
1
Supply of clock to UBC halted
0
DMAC runs
1
Supply of clock to DMAC halted
0
DAC runs
1
Supply of clock to DAC halted
MSTP5
0
ADC runs
1
Supply of clock to ADC halted, and all registers initialized
MSTP4
0
SCIF runs
1
Supply of clock to SCIF halted
0
IrDA runs
1
Supply of clock to IrDA halted
0
TMU runs
1
1
Supply of clock to TMU halted. Registers initialized*
0
RTC runs
1
2 3
Supply of clock to RTC halted. Register access prohibited* *
0
SCI runs
1
Supply of clock to SCI halted
MSTP7
MSTP6
MSTP3
MSTP2
MSTP1
MSTP0
Notes: 1. The registers initialized are the same as in standby mode (see table 8.4).
2. The counter runs.
3. Before switching the RTC to module standby, access at least one among the registers
RTC, SCI, and TMU.
8.5.2
Clearing Module Standby Function
The module standby function can be cleared by clearing the MSTPSLP0 and MSTP8–MSTP0 bits
to 0, or by a power-on reset or manual reset.
Rev. 5.00, 09/03, page 191 of 760
8.6
Timing of STATUS Pin Changes
The timing of STATUS1 and STATUS0 pin changes is shown in figures 8.1 to 8.8.
8.6.1
Timing for Resets
Power-On Reset
CKIO, CKIO2*4
PLL settling
time
RESETP
STATUS
Normal*2
Reset*1
Normal*2
RESETOUT
0 to 5 Bcyc*3
Notes: 1.
2.
3.
4.
0 to 30 Bcyc*3
Reset:
HH (STATUS1 high, STATUS0 high)
Normal: LL (STATUS1 low, STATUS0 low)
Bcyc:
Bus clock cycle
The CKIO2 output is available only in clock modes 0, 1, and 2.
Figure 8.2 Power-On Reset (Clock Modes 0, 1, 2, and 7) STATUS Output
Rev. 5.00, 09/03, page 192 of 760
Manual Reset
CKIO, CKIO2*5
RESETM
STATUS
Normal*3
Reset*2
Normal*3
RESETOUT
0 Bcyc or more*4
Notes: 1.
2.
3.
4.
5.
0 to 30 Bcyc*4
In a manual reset, STATUS becomes HH (reset) and the internal reset begins
after waiting for the executing bus cycle to end.
Reset:
HH (STATUS1 high, STATUS0 high)
Normal: LL (STATUS1 low, STATUS0 low)
Bcyc:
Bus clock cycle
The CKIO2 output is available only in clock modes 0, 1, and 2.
Figure 8.3 Manual Reset STATUS Output
Rev. 5.00, 09/03, page 193 of 760
8.6.2
Timing for Canceling Standby
Standby to Interrupt
Oscillation stops
Interrupt request
WDT overflow
CKIO, CKIO2*3
WDT count
STATUS
Normal*2
Standby*1
WAKEUP
Notes: 1.
2.
3.
Standby: LH (STATUS1 low, STATUS0 high)
Normal: LL (STATUS1 low, STATUS0 low)
The CKIO2 output is available only in clock modes 0, 1, and 2.
Figure 8.4 Standby to Interrupt STATUS Output
Rev. 5.00, 09/03, page 194 of 760
Normal*2
Standby to Power-On Reset
Oscillation stops
Reset
CKIO, CKIO2*7
RESETP*1
STATUS
Normal*5
Standby*4
*2
0 to 10 Bcyc*6
Notes: 1.
2.
3.
4.
5.
6.
7.
Reset*3
Normal*5
0 to 30 Bcyc*6
When standby mode is cleared with a power-on reset, the WDT does not
count. Keep RESETP low during the PLL’s oscillation settling time.
Undefined
Reset:
HH (STATUS1 high, STATUS0 high)
Standby: LH (STATUS1 low, STATUS0 high)
Normal: LL (STATUS1 low, STATUS0 low)
Bcyc:
Bus clock cycle
The CKIO2 output is available only in clock modes 0, 1, and 2.
Figure 8.5 Standby to Power-On Reset STATUS Output
Rev. 5.00, 09/03, page 195 of 760
Standby to Manual Reset
Oscillation stops
Reset
CKIO, CKIO2*6
RESETM*1
Normal*4
STATUS
Standby*3
Reset*2
Normal*4
0 to 20 Bcyc*5
Notes: 1.
2.
3.
4.
5.
6.
When standby mode is cleared with a manual reset, the WDT does not count.
Keep RESETM low during the PLL’s oscillation settling time.
Reset:
HH (STATUS1 high, STATUS0 high)
Standby: LH (STATUS1 low, STATUS0 high)
Normal: LL (STATUS1 low, STATUS0 low)
Bcyc:
Bus clock cycle
The CKIO2 output is available only in clock modes 0, 1, and 2.
Figure 8.6 Standby to Manual Reset STATUS Output
8.6.3
Timing for Canceling Sleep Mode
Sleep to Interrupt
Interrupt request
CKIO, CKIO2*3
STATUS
Notes: 1.
2.
3.
Normal*2
Sleep*1
Normal*2
Sleep:
HL (STATUS1 high, STATUS0 low)
Normal: LL (STATUS1 low, STATUS0 low)
The CKIO2 output is available only in clock modes 0, 1, and 2.
Figure 8.7 Sleep to Interrupt STATUS Output
Rev. 5.00, 09/03, page 196 of 760
Sleep to Power-On Reset
Reset
CKIO, CKIO2*7
RESETP*1
STATUS
Normal*5
Sleep*4
*2
0 to 10 Bcyc*6
Notes: 1.
2.
3.
4.
5.
6.
7.
Reset*3
Normal*5
0 to 30 Bcyc*6
When the PLL1’s multiplication ratio is changed by a power-on reset,
keep RESETP low during the PLL’s oscillation settling time.
Undefined
Reset:
HH (STATUS1 high, STATUS0 high)
Sleep:
HL (STATUS1 high, STATUS0 low)
Normal: LL (STATUS1 low, STATUS0 low)
Bcyc:
Bus clock cycle
The CKIO2 output is available only in clock modes 0, 1, and 2.
Figure 8.8 Sleep to Power-On Reset STATUS Output
Rev. 5.00, 09/03, page 197 of 760
Sleep to Manual Reset
Reset
CKIO, CKIO2*6
RESETM*1
STATUS
Normal*4
Sleep*3
0 to 80 Bcyc*5
Notes: 1.
2.
3.
4.
5.
6.
Reset*2
0 to 30 Bcyc*5
Keep RESETM low until STATUS becomes reset.
Reset:
HH (STATUS1 high, STATUS0 high)
Sleep:
HL (STATUS1 high, STATUS0 low)
Normal: LL (STATUS1 low, STATUS0 low)
Bcyc:
Bus clock cycle
The CKIO2 output is available only in clock modes 0, 1, and 2.
Figure 8.9 Sleep to Manual Reset STATUS Output
Rev. 5.00, 09/03, page 198 of 760
Normal*4
8.7
Hardware Standby Mode
8.7.1
Transition to Hardware Standby Mode
Driving the CA pin low causes a transition to hardware standby mode. In hardware standby mode,
all modules except those operating on an RTC clock are halted, as in the standby mode entered on
execution of a SLEEP instruction ((software) standby mode).
Hardware standby mode differs from (software) standby mode as follows.
1. Interrupts and manual resets are not accepted.
2. The TMU does not operate.
Operation when a low-level signal is input at the CA pin depends on the CPG state, as follows.
1. In standby mode
The clock remains stopped and the chip enters the hardware standby state. Acceptance of
interrupts and manual resets is disabled, TCLK output is fixed low, and the TMU halts.
2. During WDT operation when standby mode is canceled by an interrupt
The chip enters hardware standby mode after standby mode is canceled and the CPU resumes
operation.
3. In sleep mode
The chip enters hardware standby mode after sleep mode is canceled and the CPU resumes
operation.
Hold the CA pin low in hardware standby mode.
8.7.2
Canceling Hardware Standby Mode
Hardware standby mode can only be canceled by a power-on reset.
When the CA pin is driven high while the RESETP pin is low, clock oscillation is started. Hold
the RESETP pin low until clock oscillation stabilizes. When the RESETP pin is driven high, the
CPU begins power-on reset processing.
Operation is not guaranteed in the event of an interrupt or manual reset.
Rev. 5.00, 09/03, page 199 of 760
8.7.3
Hardware Standby Mode Timing
Figures 8.10 and 8.11 show examples of pin timing in hardware standby mode.
The CA pin is sampled using EXTAL2 (32.768 kHz), and a hardware standby request is only
recognized when the pin is low for two consecutive clock cycles.
The CA pin must be held low while the chip is in hardware standby mode.
Clock oscillation starts when the CA pin is driven high after the RESETP pin is driven low.
Rcyc: EXTAL2 (32.768 kHz) cycle
CKIO, CKIO2*6
CA
RESETP
STATUS
Normal*3
2 Rcyc or more*5
Notes: 1.
2.
3.
4.
5.
6.
Standby*2
Undefined
0−10Bcyc*4
Reset:
HH (STATUS1 high, STATUS0 high)
Standby: LH (STATUS1 low, STATUS0 high)
Normal: LL (STATUS1 low, STATUS0 low)
Bcyc:
Bus clock cycle
Rcyc:
EXTAL2 (32.768 kHz) cycle
The CKIO2 output is available only in clock modes 0, 1, and 2.
Figure 8.10 Hardware Standby Mode
(When CA Goes Low in Normal Operation)
Rev. 5.00, 09/03, page 200 of 760
Reset*1
CKIO, CKIO2*6
CA
RESETP
STATUS
Standby
Normal*3
WDT operation
Standby*2
Undefined
Reset*1
0−10 Bcyc*4
2 Rcyc or more*5
Notes: 1.
2.
3.
4.
5.
6.
Reset:
HH (STATUS1 high, STATUS0 high)
Standby: LH (STATUS1 low, STATUS0 high)
Normal: LL (STATUS1 low, STATUS0 low)
Bcyc:
Bus clock cycle
Rcyc:
EXTAL2 (32.768 kHz) cycle
The CKIO2 output is available only in clock modes 0, 1, and 2.
Figure 8.11 Hardware Standby Mode Timing
(When CA Goes Low during WDT Operation on Standby Mode Cancellation)
Rev. 5.00, 09/03, page 201 of 760
Rev. 5.00, 09/03, page 202 of 760
Section 9 On-Chip Oscillation Circuits
9.1
Overview
The on-chip oscillation circuits consist of a clock pulse generator (CPG) block and a watchdog
timer (WDT) block. The WDT is a single-channel timer that counts the clock settling time and is
used when clearing standby mode and temporary standbys, such as frequency changes. It can also
be used as an ordinary watchdog timer or interval timer.
9.1.1
Features
The CPG has the following features:
• Four clock modes: Selection of four clock modes for different frequency ranges, power
consumption, direct crystal input, and external clock input.
• Three clocks generated independently: An internal clock for the CPU, cache, and TLB (Iφ); a
peripheral clock (Pφ) for the on-chip peripheral modules; and a bus clock (CKIO) for the
external bus interface.
• Frequency change function: Internal and peripheral clock frequencies can be changed
independently using the PLL circuit and divider circuit within the CPG. Frequencies are
changed by software using frequency control register (FRQCR) settings.
• Power-down mode control: The clock can be stopped for sleep mode and standby mode and
specific modules can be stopped using the module standby function.
The WDT has the following features:
• Can be used to ensure the clock settling time: Use the WDT to cancel standby mode and the
temporary standbys which occur when the clock frequency is changed.
• Can switch between watchdog timer mode and interval timer mode.
• Generates internal resets in watchdog timer mode: Internal resets occur after counter overflow.
Selection of power-on reset or manual reset.
• Generates interrupts in interval timer mode: Internal timer interrupts occur after counter
overflow.
• Selection of eight counter input clocks. Eight clocks (×1 to ×1/4096) can be obtained by
dividing the peripheral clock.
Rev. 5.00, 09/03, page 203 of 760
9.2
Overview of CPG
9.2.1
CPG Block Diagram
A block diagram of the on-chip clock pulse generator is shown in figure 9.1.
Clock pulse generator
Divider 1
×1
× 1/2
× 1/3
× 1/4
× 1/6
CAP1
PLL circuit 1
(× 1, 2, 3, 4,
6)
CKIO
Internal
clock (Iφ)
Cycle = Icyc
Cycle = Bcyc
CAP2
XTAL
Crystal
oscillator
Divider 2
×1
× 1/2
× 1/3
× 1/4
× 1/6
PLL circuit 2
(× 1, 4)
EXTAL
Peripheral
clock (Pφ)
Cycle = Pcyc
CPG control unit
MD2
Clock frequency
control circuit
Standby control
circuit
FRQCR
STBCR
MD1
MD0
Bus interface
Internal bus
Legend
FRQCR: Frequency control register
STBCR: Standby control register
Figure 9.1 Block Diagram of Clock Pulse Generator
Rev. 5.00, 09/03, page 204 of 760
Standby
control
The clock pulse generator blocks function as follows:
1. PLL Circuit 1: PLL circuit 1 doubles, triples, quadruples, sextuples, or leaves unchanged the
input clock frequency from the CKIO pin. The multiplication rate is set by the frequency
control register. When this is done, the phase of the leading edge of the internal clock is
controlled so that it will agree with the phase of the leading edge of the CKIO pin.
2. PLL Circuit 2: PLL circuit 2 leaves unchanged or quadruples the frequency of the crystal
oscillator or the input clock frequency from the EXTAL pin. The multiplication ratio is fixed
by the clock operation mode. The clock operation mode is set by pins MD0, MD1, and MD2.
See table 9.3 for more information on clock operation modes.
3. Crystal Oscillator: This oscillator is used when a crystal oscillator element is connected to the
XTAL and EXTAL pins. It operates according to the clock operating mode setting.
4. Divider 1: Divider 1 generates a clock at the operating frequency used by the internal clock.
The operating frequency can be 1, 1/2, 1/3, 1/4 or 1/6 times the output frequency of PLL
circuit 1, as long as it is not lower than the CKIO pin clock frequency. The division ratio is set
in the frequency control register.
5. Divider 2: Divider 2 generates a clock at the operating frequency used by the peripheral clock.
The operating frequency can be 1, 1/2, 1/3, 1/4 or 1/6 times the output frequency of PLL
circuit 1 or the CKIO pin clock frequency, as long as it is not higher than the CKIO pin clock
frequency. The division ratio is set in the frequency control register.
6. Clock Frequency Control Circuit: The clock frequency control circuit controls the clock
frequency using the MD pins and the frequency control register.
7. Standby Control Circuit: The standby control circuit controls the state of the clock pulse
generator and other modules during clock switching and sleep/standby modes.
8. Frequency Control Register: The frequency control register has control bits assigned for the
following functions: the frequency multiplication ratio of PLL 1, and the frequency division
ratio of the internal clock and the peripheral clock.
9. Standby Control Register: The standby control register has bits for controlling the power-down
modes. See section 8, Power-Down Modes, for more information.
Rev. 5.00, 09/03, page 205 of 760
9.2.2
CPG Pin Configuration
Table 9.1 lists the CPG pins and their functions.
Table 9.1
CPG Pins and Functions
Pin Name
Symbol
I/O
Description
Mode control
pins
MD0
I
Set the clock operating mode
MD1
I
MD2
I
Crystal I/O pins
(clock input pins)
XTAL
O
Connects a crystal oscillator
EXTAL
I
Connects a crystal oscillator. Also used to input an
external clock
Clock I/O pin
CKIO
I/O
Inputs or outputs an external clock
Capacitor
connection pins
for PLL
CAP1
I
Connects capacitor for PLL circuit 1 operation
(recommended value 470 pF)
CAP2
I
Connects capacitor for PLL circuit 2 operation
(recommended value 470 pF)
9.2.3
CPG Register Configuration
Table 9.2 shows the CPG register configuration.
Table 9.2
CPG Register
Register Name
Abbreviation
R/W
Initial Value
Address
Access Size
Frequency control register
FRQCR
R/W
H'0102
H'FFFFFF80
16
Rev. 5.00, 09/03, page 206 of 760
9.3
Clock Operating Modes
Table 9.3 shows the relationship between the mode control pin (MD2–MD0) combinations and the
clock operating modes. Table 9.4 shows the usable frequency ranges in the clock operating modes.
Table 9.3
Clock Operating Modes
Pin Values
Clock I/O
Mode
MD2 MD1 MD0
Source Output
0
0
0
0
EXTAL
CKIO
On,
On
multiplication
ratio: 1
PLL1
output
PLL1
(EXTAL)
1
0
0
1
EXTAL
CKIO
On,
On
multiplication
ratio: 4
PLL1
output
PLL1
(EXTAL) × 4
2
0
1
0
Crystal CKIO
oscillator
On,
On
multiplication
ratio: 4
PLL1
output
PLL1
(Crystal) × 4
7
1
1
1
CKIO
Off
PLL1
output
PLL1
(CKIO)
—
Except above
value
—
PLL2
PLL1 Divider 1 Divider 2 CKIO
On/Off On/Off Input
Input
Frequency
On
Reserved
Mode 0: An external clock is input from the EXTAL pin and undergoes waveform shaping by
PLL circuit 2 before being supplied inside the chip. PLL circuit 1 is constantly on. An input clock
frequency of 25 MHz to 66.67 MHz can be used, and the CKIO frequency range is 25 MHz to
66.67 MHz.
Mode 1: An external clock is input from the EXTAL pin and its frequency is multiplied by 4 by
PLL circuit 2 before being supplied inside the chip, allowing a low-frequency external clock to be
used. An input clock frequency of 6.25 MHz to 16.67 MHz can be used, and the CKIO frequency
range is 25 MHz to 66.67 MHz.
Mode 2: The on-chip crystal oscillator operates, with the oscillation frequency being multiplied
by 4 by PLL circuit 2 before being supplied inside the chip, allowing a low crystal frequency to be
used. A crystal oscillation frequency of 6.25 MHz to 16.67 MHz can be used, and the CKIO
frequency range is 25 MHz to 66.67 MHz.
Rev. 5.00, 09/03, page 207 of 760
Mode 7: In this mode, the CKIO pin is an input, an external clock is input to this pin, and
undergoes waveform shaping, and also frequency multiplication according to the setting, by PLL
circuit 1 before being supplied to the chip. In modes 0 to 2, the system clock is generated from the
output of the chip’s CKIO pin. Consequently, if a large number of ICs are operating on the clock
cycle, the CKIO pin load will be large. This mode, however, assumes a comparatively large-scale
system. If a large number of ICs are operating on the clock cycle, a clock generator with a number
of low-skew clock outputs can be provided, so that the ICs can operate synchronously by
distributing the clocks to each one.
As PLL circuit 1 compensates for fluctuations in the CKIO pin load, this mode is suitable for
connection of synchronous DRAM.
Table 9.4
Available Combinations of Clock Mode and FRQCR Values
Clock
Mode FRQCR PLL1
0
PLL2
Clock Rate* Input Frequency
(I:B:P)
Range
CKIO Frequency
Range
H'0100
ON (× 1) ON (× 1) 1:1:1
25 MHz to 33.34 MHz
25 MHz to 33.34 MHz
H'0101
ON (× 1) ON (× 1) 1:1:1/2
25 MHz to 66.67 MHz
25 MHz to 66.67 MHz
H'0102
ON (× 1) ON (× 1) 1:1:1/4
25 MHz to 66.67 MHz
25 MHz to 66.67 MHz
H'0111
ON (× 2) ON (× 1) 2:1:1
25 MHz to 33.34 MHz
25 MHz to 33.34 MHz
H'0112
ON (× 2) ON (× 1) 2:1:1/2
25 MHz to 66.67 MHz
25 MHz to 66.67 MHz
H'0115
ON (× 2) ON (× 1) 1:1:1
25 MHz to 33.34 MHz
25 MHz to 33.34 MHz
H'0116
ON (× 2) ON (× 1) 1:1:1/2
25 MHz to 66.67 MHz
25 MHz to 66.67 MHz
H'0122
ON (× 4) ON (× 1) 4:1:1
25 MHz to 33.34 MHz
25 MHz to 33.34 MHz
H'0126
ON (× 4) ON (× 1) 2:1:1
25 MHz to 33.34 MHz
25 MHz to 33.34 MHz
H'012A
ON (× 4) ON (× 1) 1:1:1
25 MHz to 33.34 MHz
25 MHz to 33.34 MHz
H'A100
ON (× 3) ON (× 1) 3:1:1
25 MHz to 33.34 MHz
25 MHz to 33.34 MHz
H'A101
ON (× 3) ON (× 1) 3:1:1/2
25 MHz to 66.67 MHz
25 MHz to 66.67 MHz
H'E100
ON (× 3) ON (× 1) 1:1:1
25 MHz to 33.34 MHz
25 MHz to 33.34 MHz
H'E101
ON (× 3) ON (× 1) 1:1:1/2
25 MHz to 66.67 MHz
25 MHz to 66.67 MHz
H'A111
ON (× 6) ON (× 1) 6:1:1
25 MHz to 33.34 MHz
25 MHz to 33.34 MHz
Rev. 5.00, 09/03, page 208 of 760
Clock
Mode FRQCR PLL1
1, 2
7
PLL2
Clock Rate* Input Frequency
(I:B:P)
Range
CKIO Frequency
Range
H'0100
ON (× 1) ON (× 4) 4:4:4
6.25 MHz to 8.34 MHz
H'0101
ON (× 1) ON (× 4) 4:4:2
6.25 MHz to 16.67 MHz 25 MHz to 66.67 MHz
25 MHz to 33.34 MHz
H'0102
ON (× 1) ON (× 4) 4:4:1
6.25 MHz to 16.67 MHz 25 MHz to 66.67 MHz
H'0111
ON (× 2) ON (× 4) 8:4:4
6.25 MHz to 8.34 MHz
H'0112
ON (× 2) ON (× 4) 8:4:2
6.25 MHz to 16.67 MHz 25 MHz to 66.67 MHz
H'0115
ON (× 2) ON (× 4) 4:4:4
6.25 MHz to 8.34 MHz
H'0116
ON (× 2) ON (× 4) 4:4:2
6.25 MHz to 16.67 MHz 25 MHz to 66.67 MHz
H'0122
ON (× 4) ON (× 4) 16:4:4
6.25 MHz to 8.34 MHz
25 MHz to 33.34 MHz
H'0126
ON (× 4) ON (× 4) 8:4:4
6.25 MHz to 8.34 MHz
25 MHz to 33.34 MHz
H'012A
ON (× 4) ON (× 4) 4:4:4
6.25 MHz to 8.34 MHz
25 MHz to 33.34 MHz
H'A100
ON (× 3) ON (× 4) 12:4:4
6.25 MHz to 8.34 MHz
25 MHz to 33.34 MHz
H'A101
ON (× 3) ON (× 4) 12:4:2
6.25 MHz to 16.67 MHz 25 MHz to 66.67 MHz
H'E100
ON (× 3) ON (× 4) 4:4:4
6.25 MHz to 8.34 MHz
H'E101
ON (× 3) ON (× 4) 4:4:2
6.25 MHz to 16.67 MHz 25 MHz to 66.67 MHz
H'A111
ON (× 6) ON (× 4) 24:4:4
6.25 MHz to 8.34 MHz
25 MHz to 33.34 MHz
H'0100
ON (× 1) OFF
1:1:1
25 MHz to 33.34 MHz
25 MHz to 33.34 MHz
H'0101
ON (× 1) OFF
1:1:1/2
25 MHz to 66.67 MHz
25 MHz to 66.67 MHz
H'0102
ON (× 1) OFF
1:1:1/4
25 MHz to 66.67 MHz
25 MHz to 66.67 MHz
H'0111
ON (× 2) OFF
2:1:1
25 MHz to 33.34 MHz
25 MHz to 33.34 MHz
H'0112
ON (× 2) OFF
2:1:1/2
25 MHz to 66.67 MHz
25 MHz to 66.67 MHz
H'0115
ON (× 2) OFF
1:1:1
25 MHz to 33.34 MHz
25 MHz to 33.34 MHz
H'0116
ON (× 2) OFF
1:1:1/2
25 MHz to 66.67 MHz
25 MHz to 66.67 MHz
H'0122
ON (× 4) OFF
4:1:1
25 MHz to 33.34 MHz
25 MHz to 33.34 MHz
H'0126
ON (× 4) OFF
2:1:1
25 MHz to 33.34 MHz
25 MHz to 33.34 MHz
H'012A
ON (× 4) OFF
1:1:1
25 MHz to 33.34 MHz
25 MHz to 33.34 MHz
H'A100
ON (× 3) OFF
3:1:1
25 MHz to 33.34 MHz
25 MHz to 33.34 MHz
H'A101
ON (× 3) OFF
3:1:1/2
25 MHz to 66.67 MHz
25 MHz to 66.67 MHz
H'E100
ON (× 3) OFF
1:1:1
25 MHz to 33.34 MHz
25 MHz to 33.34 MHz
H'E101
ON (× 3) OFF
1:1:1/2
25 MHz to 66.67 MHz
25 MHz to 66.67 MHz
H'A111
ON (× 6) OFF
6:1:1
25 MHz to 33.34 MHz
25 MHz to 33.34 MHz
25 MHz to 33.34 MHz
25 MHz to 33.34 MHz
25 MHz to 33.34 MHz
Do not set values other than those in the table above in the FRQCR register.
Note: * Taking input clock as 1.
Rev. 5.00, 09/03, page 209 of 760
Cautions:
1. The frequency of the internal clock (Iφ) becomes:
•
The product of the frequency of the CKIO pin, the frequency multiplication ratio of PLL
circuit 1, and the division ratio of divider 1.
•
Do not set the internal clock frequency lower than the CKIO pin frequency.
2. The frequency of the peripheral clock (Pφ) becomes:
•
The product of the frequency of the CKIO pin, the frequency multiplication ratio of PLL
circuit 1, and the division ratio of divider 2.
•
The peripheral clock frequency should not be set higher than the frequency of the CKIO
pin, higher than 33.34 MHz.
3. The output frequency of PLL circuit 1 is the product of the CKIO frequency and the
multiplication ratio of PLL circuit 1.
4. × 1, × 2, × 3, × 4, or × 6 can be used as the multiplication ratio of PLL circuit 1. × 1, × 1/2,
× 1/3, × 1/4, and × 1/6 can be selected as the division ratios of dividers 1 and 2. Set the rate in
the frequency control register. The on/off state of PLL circuit 2 is determined by the mode.
Rev. 5.00, 09/03, page 210 of 760
9.4
Register Descriptions
9.4.1
Frequency Control Register (FRQCR)
The frequency control register (FRQCR) is a 16-bit readable/writable register used to specify the
frequency multiplication ratio of PLL circuit 1 and the frequency division ratio of the internal
clock and the peripheral clock.
Only word access can be used on the FRQCR register.
FRQCR is initialized to H'0102 by a power-on reset, but retains its value in a manual reset and in
standby mode.
FRQCR:
Bit:
Initial value:
R/W:
Bit:
15
14
13
12
11
10
9
8
STC2
IFC2
PFC2
—
—
—
—
—
0
0
0
0
0
0
0
1
R/W
R/W
R/W
R
R
R
R
R
7
6
5
4
3
2
1
0
—
—
STC1
STC0
IFC1
IFC0
PFC1
PFC0
Initial value:
0
0
0
0
0
0
1
0
R/W:
R
R
R/W
R/W
R/W
R/W
R/W
R/W
Bits 15, 5, and 4—Frequency Multiplication Ratio (STC): These bits specify the frequency
multiplication ratio of PLL circuit 1.
Bit 15: STC2
Bit 5: STC1
Bit 4: STC0
Description
0
0
0
×1
0
0
1
×2
1
0
0
×3
0
1
0
×4
1
0
1
×6
Except above value
(Initial value)
Reserved
Rev. 5.00, 09/03, page 211 of 760
Bits 14, 3, and 2—Internal Clock Frequency Division Ratio (IFC): These bits specify the
frequency division ratio of the internal clock with respect to the output frequency of PLL circuit 1.
Bit 14: IFC2
Bit 3: IFC1
Bit 2: IFC0
Description
0
0
0
×1
0
0
1
× 1/2
1
0
0
× 1/3
0
1
0
× 1/4
Except above value
(Initial value)
Reserved (Setting prohibited)
Note: Do not set the internal clock frequency lower than the CKIO pin frequency.
Bits 13, 1, and 0—Peripheral Clock Frequency Division Ratio (PFC): These bits specify the
division ratio of the peripheral clock frequency with respect to the frequency of the output
frequency of PLL circuit 1 or the frequency of the CKIO pin.
Bit 13: PFC2
Bit 1: PFC1
Bit 0: PFC0
Description
0
0
0
×1
0
0
1
× 1/2
1
0
0
× 1/3
0
1
0
× 1/4
1
0
1
× 1/6
Except above value
(Initial value)
Reserved (Setting prohibited)
Note: Do not set the peripheral clock frequency higher than the CKIO pin frequency.
Bits 12 to 9, 7, and 6—Reserved: These bits are always read as 0. The write value should always
be 0.
Bit 8—Reserved: This bit is always read as 1. The write value should always be 1.
Rev. 5.00, 09/03, page 212 of 760
9.5
Changing the Frequency
The frequency of the internal clock and peripheral clock can be changed either by changing the
multiplication ratio of PLL circuit 1 or by changing the division ratios of dividers 1 and 2. All of
these are controlled by software through the frequency control register. The methods are described
below. To the FRQCR register, do not set values other than those given in table 9.4.
9.5.1
Changing the Multiplication Rate
A PLL settling time is required when the multiplication rate of PLL circuit 1 is changed. The onchip WDT counts the settling time.
1. In the initial state, the multiplication rate of PLL circuit 1 is 1.
2. Set a value that will become the specified oscillation settling time in the WDT and stop the
WDT. The following must be set:
WTCSR register TME bit = 0: WDT stops
WTCSR register CKS2–CKS0 bits: Division ratio of WDT count clock
WTCNT counter: Initial counter value
3. Set the desired value in the STC2 to STC0 bits. The division ratio can also be set in the IFC2–
IFC0 bits and PFC2–PFC0 bits.
4. The processor pauses internally and the WDT starts incrementing. In clock modes 0–2 and 7,
the internal and peripheral clocks both stop. (except for the peripheral clock supplied to the
WDT)
5. Supply of the clock that has been set begins at WDT count overflow, and the processor begins
operating again. The WDT stops after it overflows.
When the following three conditions are all met, FRQCR should not be changed while a DMAC
transfer is in progress.
•
Bits IFC2 to IFC0 are changed.
•
STC2 to STC0 are not changed.
•
The clock ratio of Iφ (on-chip clock) to Bφ (bus clock) after the change is other than 1:1.
9.5.2
Changing the Division Ratio
The WDT will not count unless the multiplication ratio is changed simultaneously.
1. In the initial state, IFC2–IFC0 = 000 and PFC2–PFC0 = 010.
2. Set the IFC2, IFC1, IFC0, PFC2, PFC1, and PFC0 bits to the new division ratio. The values
that can be set are limited by the clock mode and the multiplication ratio of PLL circuit 1. Note
that if the wrong value is set, the processor will malfunction.
3. The clock is immediately supplied at the new division ratio.
Rev. 5.00, 09/03, page 213 of 760
9.6
Overview of WDT
9.6.1
Block Diagram of WDT
Figure 9.2 shows a block diagram of the WDT.
WDT
Standby
cancellation
Standby
mode
Peripheral
clock
Standby
control
Internal
reset
request
Divider
Reset
control
Clock selection
Clock selector
Interrupt
request
Overflow
Interrupt
control
Clock
WTCSR
WTCNT
Bus interface
Legend
WTCSR:
WTCNT:
Watchdog timer control/status register
Watchdog timer counter
Figure 9.2 Block Diagram of WDT
9.6.2
Register Configuration
The WDT has two registers that select the clock, switch the timer mode, and perform other
functions. Table 9.5 shows the WDT registers.
Table 9.5
Register Configuration
Name
Abbreviation
R/W
Address
Access Size
Watchdog timer counter
WTCNT
R/W * H'00
Initial Value
H'FFFFFF84
R: 8;
W: 16*
Watchdog timer
control/status register
WTCSR
R/W * H'00
H'FFFFFF86
R: 8;
W: 16*
Note: * Write with word access. Write with H'5A and H'A5, respectively, in the upper byte. Byte or
longword writes are not possible. Read with byte access.
Rev. 5.00, 09/03, page 214 of 760
9.7
WDT Registers
9.7.1
Watchdog Timer Counter (WTCNT)
The watchdog timer counter (WTCNT) is an 8-bit readable/writable counter that increments on the
selected clock. WTCNT differs from other registers in that it is more difficult to write to. See
section 9.7.3, Notes on Register Access, for details. When an overflow occurs, it generates a reset
in watchdog timer mode and an interrupt in interval time mode. Its address is H'FFFFFF84. The
WTCNT counter is initialized to H'00 only by a power-on reset through the RESETP pin. Use
word access to write to the WTCNT counter, with H'5A in the upper byte. Use byte access to read
WTCNT.
Bit:
7
6
5
4
3
2
1
0
Initial value:
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W:
9.7.2
Watchdog Timer Control/Status Register (WTCSR)
The watchdog timer control/status register (WTCSR) is an 8-bit readable/writable register
composed of bits to select the clock used for the count, bits to select the timer mode, and overflow
flags. WTCSR differs from other registers in that it is more difficult to write to. See section 9.7.3,
Notes on Register Access, for details. Its address is H'FFFFFF86. The WTCSR register is
initialized to H'00 only by a power-on reset through the RESETP pin. When a WDT overflow
causes an internal reset, WTCSR retains its value. When used to count the clock settling time for
canceling a standby, it retains its value after counter overflow. Use word access to write to the
WTCSR counter, with H'A5 in the upper byte. Use byte access to read WTCSR.
Bit:
Initial value:
R/W:
7
6
5
4
3
2
1
0
TME
WT/IT
RSTS
WOVF
IOVF
CKS2
CKS1
CKS0
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Bit 7—Timer Enable (TME): Starts and stops timer operation. Clear this bit to 0 when using the
WDT in standby mode or when changing the clock frequency.
Bit 7: TME
Description
0
Timer disabled: Count-up stops and WTCNT value is retained
(Initial value)
1
Timer enabled
Rev. 5.00, 09/03, page 215 of 760
Bit 6—Timer Mode Select (WT/IIT): Selects whether to use the WDT as a watchdog timer or an
interval timer.
Bit 6: WT/IIT
Description
0
Used as interval timer
1
Used as watchdog timer
(Initial value)
Note: If WT/IT is modified when the WDT is running, the up-count may not be performed correctly.
Bit 5—Reset Select (RSTS): Selects the type of reset when WTCNT overflows in watchdog
timer mode. In interval timer mode, this setting is ignored.
Bit 5: RSTS
Description
0
Power-on reset
1
Manual reset
(Initial value)
Note: RESETOUT is output.
Bit 4—Watchdog Timer Overflow (WOVF): Indicates that the WTCNT has overflowed in
watchdog timer mode. This bit is not set in interval timer mode.
Bit 4: WOVF
Description
0
No overflow
1
WTCNT has overflowed in watchdog timer mode
(Initial value)
Bit 3—Interval Timer Overflow (IOVF): Indicates that WTCNT has overflowed in interval
timer mode. This bit is not set in watchdog timer mode.
Bit 3: IOVF
Description
0
No overflow
1
WTCNT has overflowed in interval timer mode
(Initial value)
Bits 2 to 0—Clock Select 2 to 0 (CKS2 to CKS0): These bits select the clock to be used for the
WTCNT count from the eight types obtainable by dividing the peripheral clock. The overflow
period in the table is the value when the peripheral clock (Pφ) is 15 MHz.
Rev. 5.00, 09/03, page 216 of 760
Bit 2: CKS2
Bit 1: CKS1
Bit 0: CKS0
Clock Division Ratio
Overflow Period
(when Pφ
φ = 15 MHz)
0
0
0
1
17 µs
1
1/4
68 µs
0
1/16
273 µs
1
1/32
546 µs
0
1/64
1.09 ms
1
1/256
4.36 ms
1
1
0
1
(Initial value)
0
1/1024
17.48 ms
1
1/4096
69.91 ms
Note: If bits CKS2–CKS0 are modified when the WDT is running, the up-count may not be
performed correctly. Ensure that these bits are modified only when the WDT is not running.
9.7.3
Notes on Register Access
The watchdog timer counter (WTCNT) and watchdog timer control/status register (WTCSR) are
more difficult to write to than other registers. The procedure for writing to these registers is given
below.
Writing to WTCNT and WTCSR: These registers must be written to using a word transfer
instruction. They cannot be written to with a byte or longword transfer instruction. When writing
to WTCNT, set the upper byte to H'5A and transfer the lower byte as the write data, as shown in
figure 9.3. When writing to WTCSR, set the upper byte to H'A5 and transfer the lower byte as the
write data. This transfer procedure writes the lower byte data to WTCNT or WTCSR.
WTCNT write
15
Address: H'FFFFFF84
8
7
H'5A
0
Write data
WTCSR write
15
Address: H'FFFFFF86
8
7
H'A5
0
Write data
Figure 9.3 Writing to WTCNT and WTCSR
Rev. 5.00, 09/03, page 217 of 760
9.8
Using the WDT
9.8.1
Canceling Standby
The WDT can be used to cancel standby mode with an NMI or other interrupt. The procedure is
described below. (The WDT does not run when a reset is used for canceling, so keep the RESET
pin low until the clock stabilizes.)
1. Before transitioning to standby mode, always clear the TME bit in WTCSR to 0. When the
TME bit is 1, an erroneous reset or interval timer interrupt may be generated when the count
overflows.
2. Set the type of count clock used in the CKS2–CKS0 bits in WTCSR and the initial values for
the counter in the WTCNT counter. These values should ensure that the time till count
overflow is longer than the clock oscillation settling time.
3. Switch to standby mode by executing a SLEEP instruction to stop the clock.
4. The WDT starts counting by detecting the edge change of the NMI signal or detecting
interrupts.
5. When the WDT count overflows, the CPG starts supplying the clock and the processor
resumes operation. The WOVF flag in WTCSR is not set when this happens.
6. Since the WDT continues counting from H'00, set the STBY bit in the STBCR register to 0 in
the interrupt handling routine and this will stop the WDT. When the STBY bit remains at 1,
the SH7709S again enters standby mode when the WDT has counted up to H'80. This standby
mode can be canceled by a power-on reset.
9.8.2
Changing the Frequency
To change the frequency used by the PLL, use the WDT. When changing the frequency only by
switching the divider, do not use the WDT.
1. Before changing the frequency, always clear the TME bit in WTCSR to 0. When the TME bit
is 1, an erroneous reset or interval timer interrupt may be generated when the count overflows.
2. Set the type of count clock used in the CKS2–CKS0 bits of WTCSR and the initial values for
the counter in the WTCNT counter. These values should ensure that the time till count
overflow is longer than the clock oscillation settling time.
3. When the frequency control register (FRQCR) is written to, the clock stops and the processor
enters standby mode temporarily. The WDT starts counting.
4. When the WDT count overflows, the CPG resumes supplying the clock and the processor
resumes operation. The WOVF flag in WTCSR is not set when this happens.
5. The counter stops at a value of H'00 or H'01. The stop value depends on the clock ratio.
Rev. 5.00, 09/03, page 218 of 760
When the following three conditions are all met, FRQCR should not be changed while a DMAC
transfer is in progress.
•
Bits IFC2 to IFC0 are changed.
•
STC2 to STC0 are not changed.
•
The clock ratio of Iφ (on-chip clock) to Bφ (bus clock) after the change is other than 1:1.
9.8.3
Using Watchdog Timer Mode
1. Set the WT/IT bit in the WTCSR register to 1, set the reset type in the RSTS bit, set the type of
count clock in the CKS2–CKS0 bits, and set the initial value of the counter in the WTCNT
counter.
2. Set the TME bit in WTCSR to 1 to start the count in watchdog timer mode.
3. While operating in watchdog timer mode, rewrite the counter periodically to H'00 to prevent
the counter from overflowing.
4. When the counter overflows, the WDT sets the WOVF flag in WTCSR to 1 and generates the
type of reset specified by the RSTS bit. The counter then resumes counting. When a reset is
generated, a low level is output at the RESETOUT pin, and a high level at the STATUS0 and
STATUS1 pins. The output period is approximately 1 count clock cycle in the case of a poweron reset, and approximately 5 peripheral clock cycles in the case of a manual reset.
9.8.4
Using Interval Timer Mode
When operating in interval timer mode, interval timer interrupts are generated at every overflow of
the counter. This enables interrupts to be generated at set periods.
1. Clear the WT/IT bit in the WTCSR register to 0, set the type of count clock in the CKS2–
CKS0 bits, and set the initial value of the counter in the WTCNT counter.
2. Set the TME bit in WTCSR to 1 to start the count in interval timer mode.
3. When the counter overflows, the WDT sets the IOVF flag in WTCSR to 1 and an interval
timer interrupt request is sent to the INTC. The counter then resumes counting.
Rev. 5.00, 09/03, page 219 of 760
9.9
Notes on Board Design
When Using an External Crystal Resonator: Place the crystal resonator, capacitors CL1 and
CL2 close to the EXTAL and XTAL pins. To prevent induction from interfering with correct
oscillation, use a common grounding point for the capacitors connected to the resonator, and do
not locate a wiring pattern near these components.
Avoid crossing
signal lines
CL1
EXTAL
CL2
XTAL
SH7709S
Note: The values for CL1 and CL2 should be determined after
consultation with the crystal manufacturer.
Figure 9.4 Points for Attention when Using Crystal Resonator
Decoupling Capacitors: Insert a laminated ceramic capacitor of 0.1 to 1 µF as a passive capacitor
for each VSS/VCC pair. Mount the passive capacitors close to the SH7709S power supply pins, and
use components with a frequency characteristic suitable for the chip’s operating frequency, as well
as a suitable capacitance value.
Digital system VSS/VCC pairs: 19-21, 27-29, 33-35, 45-47, 57-59, 69-71, 79-81, 83-85, 95-97, 109111, 132-134, 153-154, 161-163, 173-175, 181-183, 205-208
On-chip oscillator VSS/VCC pairs: 3-6, 145-147, 148-150
Note: The pin numbers above apply to LQFP and HQFP packages.
When Using a PLL Oscillator Circuit: Keep the wiring from the PLL V CC and VSS connection
pattern to the power supply pins short, and make the pattern width large, to minimize the
inductance component. Ground the oscillation stabilization capacitors C1 and C2 to V SS (PLL1)
and VSS (PLL2), respectively. Place C1 and C2 close to the CAP1 and CAP2 pins and do not
locate a wiring pattern in the vicinity. In clock mode 7, connect the EXTAL pin to V CC or VSS and
leave the XTAL pin open.
Rev. 5.00, 09/03, page 220 of 760
Avoid crossing
signal lines
VCC (PLL2)
Power supply
CAP2
VSS (PLL2)
C2
VCC
Reference values
C1 = 470 pF
C2 = 470 pF
VCC (PLL1)
VSS
CAP1
C1
VSS (PLL1)
Figure 9.5 Points for Attention when Using PLL Oscillator Circuit
Rev. 5.00, 09/03, page 221 of 760
Rev. 5.00, 09/03, page 222 of 760
Section 10 Bus State Controller (BSC)
10.1
Overview
The bus state controller (BSC) divides physical address space and output control signals for
various types of memory and bus interface specifications. BSC functions enable the chip to link
directly with synchronous DRAM, SRAM, ROM, and other memory storage devices without an
external circuit. The BSC also allows direct connection to PCMCIA interfaces, simplifying system
design and allowing high-speed data transfers in a compact system.
10.1.1
Features
The BSC has the following features:
• Physical address space is divided into six areas
 A maximum 64 Mbytes for each of the six areas, 0, 2–6
 Area bus width can be selected by register (area 0 is set by external pin)
 Wait states can be inserted using the WAIT pin
 Wait state insertion can be controlled through software. Register settings can be used to
specify the insertion of 1–10 cycles independently for each area (1–38 cycles for areas 5
and 6 and the PCMCIA interface only)
 The type of memory connected can be specified for each area, and control signals are
output for direct memory connection
 Wait cycles are automatically inserted to avoid data bus conflict for continuous memory
accesses to different areas or writes directly following reads in the same area
• Direct interface to synchronous DRAM
 Multiplexes row/column addresses according to synchronous DRAM capacity
 Supports burst operation
 Supports bank active mode
 Has both auto-refresh and self-refresh functions
 Controls timing of synchronous DRAM direct-connection control signals according to
register setting
• Burst ROM interface
 Insertion of wait states controllable through software
 Register setting control of burst transfers
• PCMCIA direct-connection interface
 Insertion of wait states controllable through software
 Bus sizing function for I/O bus width (only in little-endian mode)
Rev. 5.00, 09/03, page 223 of 760
• Short refresh cycle control
 The overflow interrupt function of the refresh counter enables the refresh function
immediately after a self-refresh operation using low power-consumption DRAM
• The refresh counter can be used as an interval timer
 Outputs an interrupt request signal using the compare-match function
 Outputs an interrupt request signal when the refresh counter overflows
Rev. 5.00, 09/03, page 224 of 760
10.1.2
Block Diagram
Bus
interface
Wait
controller
WAIT
Internal bus
Figure 10.1 shows a block diagram of the bus state controller.
WCR1
WCR2
CS0, CS6 to CS2,
CE2A, CE2B
MCS0 to MCS7
Area
controller
BS
RD
RD/WR
WE3 to WE0
RASxx
CASx
CKE
ICIORD, ICIOWR
Interrupt
controller
MCR
Memory
controller
PCR
Module bus
BCR2
MCSCRn
Peripheral bus
IOIS16
BCR1
RFCR
RTCNT
Refresh
controller
Comparator
RTCOR
RTCSR
BSC
Legend
WCR: Wait state control register
BCR: Bus control register
MCR: Memory control register
PCR: PCMCIA control register
RFCR:
RTCNT:
RTCOR:
RTCSR:
MCSCRn:
Refresh count register
Refresh timer count register
Refresh time constant register
Refresh timer control/status register
MCSn control register (n = 0−7)
Figure 10.1 Block Diagram of Bus State Controller
Rev. 5.00, 09/03, page 225 of 760
10.1.3 Pin Configuration
Table 10.1 shows the BSC pin configuration.
Table 10.1 BSC Pins
Pin Name
Signal
I/O
Description
Address bus
A25–A0
O
Address output
Data bus
D15–D0
I/O
Data I/O
D31–D16
I/O
Data I/O when using 32-bit bus width
Bus cycle start
BS
O
Shows start of bus cycle. During burst transfers,
asserted every data cycle.
Chip select 0, 2–4
CS0, CS2–CS4
O
Chip select signals to indicate area being accessed.
Chip select 5, 6
CS5/CE1A,
CS6/CE1B
O
Chip select signals to indicate area being accessed.
CS5/CE1A and CS6/CE1B can also be used as
CE1A and CE1B of PCMCIA.
PCMCIA card
select
CE2A, CE2B
O
CE2A and CE2B signals when PCMCIA is used
Read/write
RD/WR
O
Data bus direction indication signal. PCMCIA write
indication signal.
Row address
strobe 3L
RAS3L
O
When synchronous DRAM is used, RAS3L for lower
32-Mbyte address and 64-Mbyte address.
Row address
strobe 3U
RAS3U
O
When synchronous DRAM is used, RAS3U for
upper 32-Mbyte address.
Column address
strobe
CASL
O
When synchronous DRAM is used, CASL signal for
lower 32-Mbyte address and 64-Mbyte address.
Column address
strobe LH
CASU
O
When synchronous DRAM is used, CASU signal for
upper 32-Mbyte address.
Data enable 0
WE0/DQMLL
O
When memory other than synchronous DRAM is
used, D7–D0 write strobe signal. When
synchronous DRAM is used, selects D7–D0.
Data enable 1
WE1/DQMLU/
WE
O
When memory other than synchronous DRAM and
PCMCIA is used, D15–D8 write strobe signal. When
synchronous DRAM is used, selects D15–D8. When
PCMCIA is used, strobe signal indicating write
cycle.
Data enable 2
WE2/DQMUL/
ICIORD
O
When memory other than synchronous DRAM and
PCMCIA is used, D23–D16 write strobe signal.
When synchronous DRAM is used, selects D23–
D16. When PCMCIA is used, strobe signal
indicating I/O read.
Rev. 5.00, 09/03, page 226 of 760
Pin Name
Signal
I/O
Description
Data enable 3
WE3/DQMUU/
ICIOWR
O
When memory other than synchronous DRAM and
PCMCIA is used, D31–D24 write strobe signal.
When synchronous DRAM is used, selects D31–
D24. When PCMCIA is used, strobe signal
indicating I/O write.
Read
RD
O
Strobe signal indicating read cycle
Wait
WAIT
I
Wait state request signal
Clock enable
CKE
O
Clock enable control signal for synchronous DRAM
IOIS16
IOIS16
I
Signal indicating PCMCIA 16-bit I/O. Valid only in
little-endian mode.
Bus release
request
BREQ
I
Bus release request signal
Bus release
acknowledgment
BACK
O
Bus release acknowledge signal
Mask ROM chip
select
MCS[0]– MCS[7] O
Chip select signal for mask ROM connected to area
0 or 2.
Rev. 5.00, 09/03, page 227 of 760
10.1.4
Register Configuration
The BSC has 21 registers (table 10.2). Synchronous DRAM also has a built-in synchronous
DRAM mode register. These registers control direct connection interfaces to memory, wait states,
and refreshes devices.
Table 10.2 BSC Registers
Name
Abbr.
R/W
Initial Value* Address
Bus Width
Bus control register 1
BCR1
R/W
H'0000
H'FFFFFF60
16
Bus control register 2
BCR2
R/W
H'3FF0
H'FFFFFF62
16
Wait state control register 1
WCR1
R/W
H'3FF3
H'FFFFFF64
16
Wait state control register 2
WCR2
R/W
H'FFFF
H'FFFFFF66
16
Individual memory control
register
MCR
R/W
H'0000
H'FFFFFF68
16
PCMCIA control register
PCR
R/W
H'0000
H'FFFFFF6C
16
Refresh timer control/status
register
RTCSR
R/W
H'0000
H'FFFFFF6E
16
Refresh timer counter
RTCNT
R/W
H'0000
H'FFFFFF70
16
Refresh time constant register
RTCOR
R/W
H'0000
H'FFFFFF72
16
Refresh count register
RFCR
R/W
H'0000
H'FFFFFF74
16
Synchronous DRAM mode
register, area 2
SDMR
W
—
H'FFFFD000– 8
H'FFFFDFFF
Synchronous DRAM mode
register, area 3
H'FFFFE000–
H'FFFFEFFF
MCS0 control register
MCSCR0
R/W
H'0000
H'FFFFFF50
16
MCS1 control register
MCSCR1
R/W
H'0000
H'FFFFFF52
16
MCS2 control register
MCSCR2
R/W
H'0000
H'FFFFFF54
16
MCS3 control register
MCSCR3
R/W
H'0000
H'FFFFFF56
16
MCS4 control register
MCSCR4
R/W
H'0000
H'FFFFFF58
16
MCS5 control register
MCSCR5
R/W
H'0000
H'FFFFFF5A
16
MCS6 control register
MCSCR6
R/W
H'0000
H'FFFFFF5C
16
MCS7 control register
MCSCR7
R/W
H'0000
H'FFFFFF5E
16
Notes: For details, see section 10.2.7, Synchronous DRAM Mode Register (SDMR).
* Initialized by a power-on reset.
Rev. 5.00, 09/03, page 228 of 760
10.1.5
Area Overview
Space Allocation: In the architecture of the SH7709S, both logical spaces and physical spaces
have 32-bit address spaces. The logical space is divided into five areas by the value of the upper
bits of the address. The physical space is divided into eight areas.
Logical space can be allocated to physical space using a memory management unit (MMU). For
details, refer to section 3, Memory Management Unit (MMU), which describes area allocation for
physical space.
As shown in table 10.3, the SH7709S can be connected directly to six memory/PCMCIA interface
areas, and it outputs chip select signals (CS0, CS2–CS6, CE2A, CE2B) for each of them. CS0 is
asserted during area 0 access; CS6 is asserted during area 6 access. When PCMCIA interface is
selected in area 5 or 6, in addition to CS5/CS6, CE2A/CE2B are asserted for the corresponding
bytes accessed.
H'00000000
H'20000000
H'40000000
P0, U0
H'60000000
Area 0 (CS0)
H'00000000
Internal I/O
H'04000000
Area 2 (CS2)
H'08000000
Area 3 (CS3)
H'0C000000
Area 4 (CS4)
H'10000000
Area 5 (CS5)
H'14000000
H'18000000
Area 6 (CS6)
Reserved area
H'80000000
P1
Physical address space
H'A0000000
P2
H'C0000000
P3
H'E0000000
P4
Logical address space
Note: For logical address spaces P0 and P3, when the memory management unit (MMU) is
on, it can optionally generate a physical address for the logical address. This diagram
can be applied when the MMU is off, and when the MMU is on and each physical
address corresponding to a logical address is equal except for the upper three bits.
When translating logical addresses to arbitrary physical addresses, refer to table 10.3.
Figure 10.2 Correspondence between Logical Address Space and Physical Address Space
Rev. 5.00, 09/03, page 229 of 760
Table 10.3 Physical Address Space Map
Area
Connectable Memory
Physical Address
Capacity
Access Size
H'00000000 to H'03FFFFFF
64 Mbytes
8, 16, 32*
H'00000000 + H'20000000 × n to
H'03FFFFFF + H'20000000 × n
Shadow
n = 1–6
H'04000000 to H'07FFFFFF
64 Mbytes
3
8, 16, 32*
H'04000000 + H'20000000 × n to
H'07FFFFFF + H'20000000 × n
Shadow
n = 1–6
H'08000000 to H'0BFFFFFF
64 Mbytes
3 4
8, 16, 32* *
H'08000000 + H'20000000 × n to
H'0BFFFFFF + H'20000000 × n
Shadow
n = 1–6
H'0C000000 to H'0FFFFFFF
64 Mbytes
3 4
8, 16, 32* *
H'0C000000 + H'20000000 × n to
H'0FFFFFFF + H'20000000 × n
Shadow
n = 1–6
H'10000000 to H'13FFFFFF
64 Mbytes
3
8, 16, 32*
H'10000000 + H'20000000 × n to
H'13FFFFFF + H'20000000 × n
Shadow
n = 1–6
Ordinary memory* ,
PCMCIA, burst ROM
H'14000000 to H'15FFFFFF
32 Mbytes
3 5
8, 16, 32 * *
H'16000000 to H'17FFFFFF
32 Mbytes
Ordinary memory,
burst ROM
H'14000000 + H'20000000 × n to
H'17FFFFFF + H'20000000 × n
Shadow
n = 1–6
H'18000000 to H'19FFFFFF
32 Mbytes
3 5
8, 16, 32 * *
Shadow
n = 1–6
*1
0
Ordinary memory ,
burst ROM
7
Internal I/O registers*
1
1
Ordinary memory* ,
synchronous DRAM
2
1
Ordinary memory* ,
synchronous DRAM
3
1
Ordinary memory*
4
1
5
1
Ordinary memory* ,
PCMCIA, burst ROM
6
H'1A000000 to H'1BFFFFFF
H'18000000 + H'20000000 × n to
H'1BFFFFFF + H'20000000 × n
6
7*
Reserved area
Notes: 1.
2.
3.
4.
5.
6.
2
H'1C000000 + H'20000000 × n
to H'1FFFFFFF + H'20000000 × n
n = 0–7
Memory with interface such as SRAM or ROM.
Use external pin to specify memory bus width.
Use register to specify memory bus width.
With synchronous DRAM interfaces, bus width must be 16 or 32 bits.
With PCMCIA interface, bus width must be 8 or 16 bits.
Do not access the reserved area. If the reserved area is accessed, correct operation
cannot be guaranteed.
7. When the control register in area 1 is not used for address translation by the MMU, set
the first three bits of the logical address to 101 for allocation to the P2 space.
Rev. 5.00, 09/03, page 230 of 760
Area 0: H'00000000
Area 1: H'04000000
Ordinary memory/
burst ROM
Internal I/O
Area 2: H'08000000
Ordinary memory/
synchronous DRAM
Area 3: H'0C000000
Ordinary memory/
synchronous DRAM
Area 4: H'10000000
Ordinary memory
Area 5: H'14000000
Ordinary memory/
burst ROM/PCMCIA
The PCMCIA interface is shared
by the memory and I/O card
Area 6: H'18000000
Ordinary memory/
burst ROM/PCMCIA
The PCMCIA interface is shared
by the memory and I/O card
Figure 10.3 Physical Space Allocation
Memory Bus Width: The memory bus width in the SH7709S can be set for each area. In area 0,
external pins can be used to select byte (8 bits), word (16 bits), or longword (32 bits) on power-on
reset. The correspondence between the external pins (MD4 and MD3) and the memory size is
shown in table below.
Table 10.4 Correspondence between External Pins (MD4 and MD3) and Memory Size
MD4
MD3
Memory Size
0
0
Reserved (Do not set)
0
1
8 bits
1
0
16 bits
1
1
32 bits
For areas 2–6, byte, word, and longword can be chosen for the bus width using bus control register
2 (BCR2) whenever ordinary memory, ROM, or burst ROM are used. When the synchronous
DRAM interface is used, word or longword can be chosen as the bus width.
When the PCMCIA interface is used, set the bus width to byte or word. When synchronous
DRAM is connected to both area 2 and area 3, set the same bus width for areas 2 and 3. When
using the port function, set each of the bus widths to byte or word for all areas. For more
information, see section 10.2.2, Bus Control Register 2 (BCR2).
Rev. 5.00, 09/03, page 231 of 760
Shadow Space: Areas 0 and 2–6 are decoded by physical addresses A28–A26, which correspond
to areas 000 to 110. Address bits 31–29 are ignored. This means that the range of area 0 addresses,
for example, is H'00000000 to H'03FFFFFF, and its corresponding shadow space is the address
space obtained by adding to it H'20000000 × n (n = 1–6). The address range for area 7, which is
on-chip I/O space, is H'1C000000 to H'1FFFFFFF. The address space H'1C000000 + H'20000000
× n–H'1FFFFFFF + H'20000000 × n (n = 0–7) corresponding to the area 7 shadow space is
reserved, and must not be used.
10.1.6
PCMCIA Support
The SH7709S supports PCMCIA standard interface specifications in physical space areas 5 and 6.
The interfaces supported are basically the “IC memory card interface” and “I/O card interface”
stipulated in JEIDA Specifications Ver. 4.2 (PCMCIA2.1).
Table 10.5 PCMCIA Interface Characteristics
Item
Feature
Access
Random access
Data bus
8/16 bits
Memory type
Mask ROM, OTPROM, EPROM, EEPROM, flash memory, SRAM
Memory capacity
Maximum 32 Mbytes
I/O space capacity
Maximum 32 Mbytes
Other features
Dynamic bus sizing of I/O bus width *
The PCMCIA interface can be accessed from the address translation
area or non-address translation area.
Note: * Dynamic bus sizing of the I/O bus width is supported only in little-endian mode.
Area 5: H'14000000
Common memory/Attribute memory
Area 5: H'16000000
I/O space
Area 6: H'18000000
Common memory/Attribute memory
Area 6: H'1A000000
I/O space
Figure 10.4 PCMCIA Space Allocation
Rev. 5.00, 09/03, page 232 of 760
Table 10.6 PCMCIA Support Interface
IC Memory Card Interface
I/O Card Interface
Pin Signal
I/O Function
Signal
I/O Function
SH7709S Pin
1
GND
—
GND
—
—
2
D3
I/O Data
D3
I/O Data
D3
3
D4
I/O Data
D4
I/O Data
D4
4
D5
I/O Data
D5
I/O Data
D5
5
D6
I/O Data
D6
I/O Data
D6
6
D7
I/O Data
D7
I/O Data
D7
7
CE1
I
Card enable
CE1
I
Card enable
CE1A or CE1B
8
A10
I
Address
A10
I
Address
A10
9
OE
I
Output enable
OE
I
Output enable
RD
Ground
Ground
10
A11
I
Address
A11
I
Address
A11
11
A9
I
Address
A9
I
Address
A9
12
A8
I
Address
A8
I
Address
A8
13
A13
I
Address
A13
I
Address
A13
14
A14
I
Address
A14
I
Address
A14
15
WE/PGM
I
Write enable
WE/PGM
I
Write enable
WE
16
RDY/BSY
O
Ready/Busy
IREQ
O
Ready/Busy
—
17
VCC
Operation power
VCC
Operation power
—
18
VPP1
Program power
VPP1
Program/
peripheral power
—
19
A16
I
Address
A16
I
Address
A16
20
A15
I
Address
A15
I
Address
A15
21
A12
I
Address
A12
I
Address
A12
22
A7
I
Address
A7
I
Address
A7
23
A6
I
Address
A6
I
Address
A6
24
A5
I
Address
A5
I
Address
A5
25
A4
I
Address
A4
I
Address
A4
26
A3
I
Address
A3
I
Address
A3
27
A2
I
Address
A2
I
Address
A2
28
A1
I
Address
A1
I
Address
A1
29
A0
I
Address
A0
I
Address
A0
30
D0
I/O Data
D0
I/O Data
D0
Rev. 5.00, 09/03, page 233 of 760
IC Memory Card Interface
I/O Card Interface
Pin Signal
I/O Function
Signal
I/O Function
SH7709S Pin
31
D1
I/O Data
D1
I/O Data
D1
32
D2
I/O Data
D2
I/O Data
D2
33
WP
O
Write protect
IOIS16
O
16-bit I/O port
IOIS16
34
GND
Ground
GND
Ground
—
35
GND
Ground
GND
Ground
—
36
CD1
O
Card detection
CD1
O
Card detection
—
37
D11
I/O Data
D11
I/O Data
D11
38
D12
I/O Data
D12
I/O Data
D12
39
D13
I/O Data
D13
I/O Data
D13
40
D14
I/O Data
D14
I/O Data
D14
41
D15
I/O Data
D15
I/O Data
D15
42
CE2
I
Card enable
CE2
I
Card enable
CE2A or CE2B
43
VS1
I
Voltage sense 1
VS1
I
Voltage sense 1
—
44
RFU
Reserved
IORD
I
I/O read
ICIORD
45
RFU
Reserved
IOWR
I
I/O write
ICIOWR
46
A17
I
Address
A17
I
Address
A17
47
A18
I
Address
A18
I
Address
A18
48
A19
I
Address
A19
I
Address
A19
49
A20
I
Address
A20
I
Address
A20
50
A21
I
Address
A21
I
Address
A21
51
VCC
Power supply
VCC
Power supply
—
52
VPP2
Program power
VPP2
Program/
peripheral power
—
53
A22
I
Address
A22
I
Address
A22
54
A23
I
Address
A23
I
Address
A23
55
A24
I
Address
A24
I
Address
A24
56
A25
I
Address
A25
I
Address
A25
57
VS2
I
Voltage sense 2
VS2
I
Voltage sense 2
—
58
RESET
I
Reset
RESET
I
Reset
—
59
WAIT
O
Wait request
WAIT
O
Wait request
—
60
RFU
Reserved
INPACK
O
Input acknowledge —
Rev. 5.00, 09/03, page 234 of 760
IC Memory Card Interface
Pin Signal
I/O Card Interface
I/O Function
Signal
I/O Function
SH7709S Pin
—
61
REG
I
Attribute memory
space select
REG
I
Attribute memory
space select
62
BVD2
O
Battery voltage
detection
SPKR
O
Digital voice signal —
63
BVD1
O
Battery voltage
detection
STSCHG
O
Card state
change
64
D8
I/O Data
D8
I/O Data
D8
65
D9
I/O Data
D9
I/O Data
D9
66
D10
I/O Data
D10
I/O Data
D10
67
CD2
O
Card detection
CD2
O
Card detection
—
68
GND
Ground
GND
Ground
—
10.2
BSC Registers
10.2.1
Bus Control Register 1 (BCR1)
—
Bus control register 1 (BCR1) is a 16-bit readable/writable register that sets the functions and bus
cycle state for each area. It is initialized to H'0000 by a power-on reset, but is not initialized by a
manual reset or in standby mode. Do not access external memory outside area 0 until BCR1
register initialization is complete.
Bit:
Initial value:
R/W:
Bit:
15
14
PULA
PULD
13
0
0
0
0
0/1*
0
0
0
R/W
R/W
R/W
R/W
R
R/W
R/W
R/W
7
6
5
1
0
A5BST0 A6BST1 A6BST0
Initial value:
R/W:
12
11
10
9
8
HIZMEM HIZCNT ENDIAN A0BST1 A0BST0 A5BST1
4
3
2
DRAM
TP2
DRAM
TP1
DRAM
TP0
A5 PCM A6 PCM
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Note: * Samples the value of the external pin (MD5) designating the endian in a power-on reset.
Rev. 5.00, 09/03, page 235 of 760
Bit 15—Pin A25 to A0 Pull-Up (PULA): Specifies whether or not pins A25 to A0 are pulled up
for 4 cycles immediately after BACK is asserted.
Bit 15: PULA
Description
0
Not pulled up
1
Pulled up
(Initial value)
Bit 14—Pin D31 to D0 Pull-Up (PULD): Specifies whether or not pins D31 to D0 are pulled up
when not in use.
Bit 14: PULD
Description
0
Not pulled up
1
Pulled up
(Initial value)
Bit 13—Hi-Z Memory Control (HIZMEM): Specifies the state of A25–A0, BS, CS, RD/WR,
WE/DQM, RD, CE2A, CE2B and DRAK0/1 in standby mode.
Bit 13: HIZMEM
Description
0
A25–A0, BS, CS, RD/WR, WE/DQM, RD, CE2A, CE2B and DRAK0/1 are
Hi-Z in standby mode
(Initial value)
1
A25–A0, BS, CS, RD/WR, WE/DQM, RD, CE2A, CE2B and DRAK0/1 are
high in standby mode
Bit 12—High-Z Control (HIZCNT): Specifies the state of the RAS and CAS signals in standby
mode and when the bus is released.
Bit 12: HIZCNT
Description
0
RAS and CAS signals are high-impedance (High-Z) in standby mode and
when bus is released
(Initial value)
1
RAS and CAS signals are driven in standby mode and when bus is released
Bit 11—Endian Flag (ENDIAN): Samples the value of the external pin designating the endian in
a power-on reset. The endian for all physical spaces is decided by this bit, which is read-only.
Bit 11: ENDIAN
Description
0
(On reset) Endian setting external pin (MD5) is low. Indicates the SH7709S
is set as big-endian
1
(On reset) Endian setting external pin (MD5) is high. Indicates the SH7709S
is set as little-endian
Rev. 5.00, 09/03, page 236 of 760
Bits 10 and 9—Area 0 Burst ROM Control (A0BST1, A0BST0): Specify whether to use burst
ROM in physical space area 0. When burst ROM is used, these bits set the number of burst
transfers.
Bit 10: A0BST1
Bit 9: A0BST0
Description
0
0
Access area 0 accessed as ordinary memory
(Initial value)
1
Access area 0 accessed as burst ROM (4 consecutive
accesses). Can be used when bus width is 8, 16, or 32.
0
Access area 0 accessed as burst ROM (8 consecutive
accesses). Can be used when bus width is 8 or 16.
Should not be specified when bus width is 16 or 32.
1
Access area 0 accessed as burst ROM (16 consecutive
accesses). Can be used only when bus width is 8.
Should not be specified when bus width is 16 or 32.
1
Bits 8 and 7—Area 5 Burst Enable (A5BST1, A5BST0): Specify whether to use burst ROM
and PCMCIA burst mode in physical space area 5. When burst ROM and PCMCIA burst mode
are used, these bits set the number of burst transfers.
Bit 8: A5BST1
Bit 7: A5BST0
Description
0
0
Access area 5 accessed as ordinary memory
(Initial value)
1
Burst access of area 5 (4 consecutive accesses). Can
be used when bus width is 8, 16, or 32.
0
Burst access of area 5 (8 consecutive accesses). Can
be used when bus width is 8 or 16. Should not be
specified when bus width is 32.
1
Burst access of area 5 (16 consecutive accesses). Can
be used only when bus width is 8. Should not be
specified when bus width is 16 or 32.
1
Bits 6 and 5—Area 6 Burst Enable (A6BST1, A6BST0): Specify whether to use burst ROM
and PCMCIA burst mode in physical space area 6. When burst ROM and PCMCIA burst mode
are used, these bits set the number of burst transfers.
Rev. 5.00, 09/03, page 237 of 760
Bit 6: A6BST1
Bit 5: A6BST0
Description
0
0
Access area 6 accessed as ordinary memory
(initial value)
1
Burst access of area 6 (4 consecutive accesses). Can
be used when bus width is 8, 16, or 32.
0
Burst access of area 6 (8 consecutive accesses). Can
be used when bus width is 8 or 16. Should not be
specified when bus width is 32.
1
Burst access of area 6 (16 consecutive accesses). Can
be used only when bus width is 8. Should not be
specified when bus width is 16 or 32.
1
Bits 4 to 2—Area 2, Area 3 Memory Type (DRAMTP2, DRAMTP1, DRAMTP0): Designate
the types of memory connected to physical space areas 2 and 3. Ordinary memory, such as ROM,
SRAM, or flash ROM, can be directly connected. Synchronous DRAM can also be directly
connected.
Bit 4: DRAMTP2 Bit 3: DRAMTP1 Bit 2: DRAMTP0 Description
0
0
1
1
0
1
0
Areas 2 and 3 are ordinary memory
(Initial value)
1
Reserved (Setting prohibited)
0
Area 2: ordinary memory; area 3:
2
synchronous DRAM*
1
Areas 2 and 3 are synchronous DRAM*
*2
0
Reserved (Setting prohibited)
1
Reserved (Setting prohibited)
0
Reserved (Setting prohibited)
1
Reserved (Setting prohibited)
1
Notes: 1. When selecting this mode, set the same bus width for area 2 and area 3.
2. Do not access synchronous DRAM when clock ratio Iφ:Bφ = 1:1
Bit 1—Area 5 Bus Type (A5PCM): Designates whether to access physical space area 5 as
PCMCIA space.
Bit 1: A5PCM
Description
0
Physical space area 5 accessed as ordinary memory
1
Physical space area 5 accessed as PCMCIA space
Rev. 5.00, 09/03, page 238 of 760
(Initial value)
Bit 0—Area 6 Bus Type (A6PCM): Designates whether to access physical space area 6 as
PCMCIA space.
Bit 0: A6PCM
Description
0
Physical space area 6 accessed as ordinary memory
1
Physical space area 6 accessed as PCMCIA space
10.2.2
(Initial value)
Bus Control Register 2 (BCR2)
Bus control register 2 (BCR2) is a 16-bit readable/writable register that selects the bus size of each
area and whether an 8-bit port is used or not. It is initialized to H'3FF0 by a power-on reset, but is
not initialized by a manual reset or in standby mode. Do not access external memory outside area
0 until BCR2 register initialization is complete.
Bit:
15
14
13
12
11
10
9
8
—
—
A6SZ1
A6SZ0
A5SZ1
A5SZ0
A4SZ1
A4SZ0
Initial value:
0
0
1
1
1
1
1
1
R/W:
R
R
R/W
R/W
R/W
R/W
R/W
R/W
Bit:
Initial value:
R/W:
7
6
5
4
3
2
1
0
A3SZ1
A3SZ0
A2SZ1
A2SZ0
—
—
—
—
1
1
1
1
0
0
0
0
R/W
R/W
R/W
R/W
R
R
R
R
Bits 15, 14, 3, 2, 1, and 0—Reserved: These bits are always read as 0. The write value should
always be 0.
Bits 2n + 1, 2n—Area n (2–6) Bus Size Specification (AnSZ1, AnSZ0): Specify the bus size of
physical space area n (n = 2 to 6).
Rev. 5.00, 09/03, page 239 of 760
Bit 2n + 1: AnSZ1
Bit 2n: AnSZ0
Port A / B
Description
0
0
Not used
Reserved (Setting prohibited)
1
0
Byte (8-bit) size
0
Word (16-bit) size
1
Longword (32-bit) size
0
1
10.2.3
1
Used
Reserved (Setting prohibited)
1
Byte (8-bit) size
0
Word (16-bit) size
1
Reserved (Setting prohibited)
Wait State Control Register 1 (WCR1)
Wait state control register 1 (WCR1) is a 16-bit readable/writable register that specifies the
number of idle (wait) state cycles inserted for each area. For some memories, data bus drive may
not be turned off quickly even when the read signal from the external device is turned off. This
can result in conflicts between data buses when consecutive memory accesses are to different
memories or when a write immediately follows a memory read. This LSI automatically inserts the
number of idle states set in WCR1 in those cases.
WCR1 is initialized to H'3FF3 by a power-on reset. It is not initialized by a manual reset or in
standby mode, and retains its contents.
Bit:
Initial value:
R/W:
Bit:
Initial value:
R/W:
15
14
13
12
11
10
9
8
WAITSE
L
—
A6IW1
A6IW0
A5IW1
A5IW0
A4IW1
A4IW0
0
0
1
1
1
1
1
1
R/W
R
R/W
R/W
R/W
R/W
R/W
R/W
7
6
5
4
3
2
1
0
A3IW1
A3IW0
A2IW1
A2IW0
—
—
A0IW1
A0IW0
1
1
1
1
0
0
1
1
R/W
R/W
R/W
R/W
R
R
R/W
R/W
Rev. 5.00, 09/03, page 240 of 760
Bit 15—WAIT Sampling Timing Select (WAITSEL): Specifies the WAIT signal sampling
timing.
Bit 15: WAITSEL
Description
0
Setting to 1 when using the WAIT signal*
1
Sampled WAIT signal at fall of CKIO
(Initial value)
Note: * Operation is not guaranteed if WAIT is asserted while WEITSEL = 0.
Bits 14, 3, and 2 —Reserved: These bits are always read as 0. The write value should always be
0.
Bits 2n + 1, 2n—Area n (6–2, 0) Intercycle Idle Specification (AnIW1, AnIW0): Specify the
number of idles inserted between bus cycles when switching between physical space area n (6–2,
0) and another space or between a read access and a write access in the same physical space.
Bit 2n + 1: AnIW1
Bit 2n: AnIW0
Description
0
0
1 idle cycle inserted
1
1 idle cycle inserted
0
2 idle cycles inserted
1
3 idle cycles inserted
1
10.2.4
(Initial value)
Wait State Control Register 2 (WCR2)
Wait state control register 2 (WCR2) is a 16-bit readable/writable register that specifies the
number of wait state cycles inserted for each area. It also specifies the data access pitch for burst
memory accesses. This allows direct connection of even low-speed memories without an external
circuit. WCR2 is initialized to H'FFFF by a power-on reset. It is not initialized by a manual reset
or in standby mode.
Bit:
Initial value:
R/W:
Bit:
Initial value:
R/W:
15
14
13
12
11
10
9
8
A6 W2
A6 W1
A6 W0
A5 W2
A5 W1
A5 W0
A4 W2
A4 W1
1
1
1
1
1
1
1
1
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
7
6
5
4
3
2
1
0
A4 W0
A3 W1
A3 W0
A2 W1
A2 W0
A0 W2
A0 W1
A0 W0
1
1
1
1
1
1
1
1
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Rev. 5.00, 09/03, page 241 of 760
Bits 15 to 13—Area 6 Wait Control (A6W2, A6W1, A6W0): Specify the number of wait states
inserted in physical space area 6. Also specify the number of states for burst transfer.
Description
Burst Cycle
(Excluding First Cycle)
First Cycle
Bit 15:
A6W2
Bit 14:
A6W1
Bit 13:
A6W0
Inserted
Wait States
WAIT Pin
Number of States
Per Data Transfer
WAIT Pin
0
0
0
0
Disabled
2
Enabled
1
1
Enabled
2
Enabled
0
2
Enabled
3
Enabled
1
3
Enabled
4
Enabled
0
4
Enabled
4
Enabled
1
6
Enabled
6
Enabled
0
8
Enabled
8
Enabled
1
10
(Initial value)
Enabled
10
Enabled
1
1
0
1
Bits 12 to 10—Area 5 Wait Control (A5W2, A5W1, A5W0): Specify the number of wait states
inserted in physical space area 5. Also specify the number of states for burst transfer.
Description
Burst Cycle
(Excluding First Cycle)
First Cycle
Bit 12:
A5W2
Bit 11:
A5W1
Bit 10:
A5W0
Inserted
Wait States
WAIT Pin
Number of States
Per Data Transfer
WAIT Pin
0
0
0
0
Disabled
2
Enabled
1
1
Enabled
2
Enabled
0
2
Enabled
3
Enabled
1
3
Enabled
4
Enabled
0
4
Enabled
4
Enabled
1
6
Enabled
6
Enabled
0
8
Enabled
8
Enabled
1
10
(Initial value)
Enabled
10
Enabled
1
1
0
1
Rev. 5.00, 09/03, page 242 of 760
Bits 9 to 7—Area 4 Wait Control (A4W2, A4W1, A4W0): Specify the number of wait states
inserted in physical space area 4.
Description
Bit 9: A4W2
Bit 8: A4W1
Bit 7: A4W0
Inserted Wait State WAIT Pin
0
0
0
0
Ignored
1
1
Enabled
0
2
Enabled
1
3
Enabled
0
4
Enabled
1
6
Enabled
0
8
Enabled
1
10
Enabled (Initial value)
1
1
0
1
Bits 6 and 5—Area 3 Wait Control (A3W1, A3W0): Specify the number of wait states inserted
in physical space area 3.
• For Ordinary Memory
Description
Bit 6: A3W1
Bit 5: A3W0
Inserted Wait States
WAIT Pin
0
0
0
Ignored
1
1
Enabled
0
2
Enabled
1
3
Enabled
1
(Initial value)
• For Synchronous DRAM
Description
Bit 6: A3W1
Bit 5: A3W0
Synchronous DRAM: CAS Latency
0
0
1
1
1
0
2
1
3
1
(Initial value)
Rev. 5.00, 09/03, page 243 of 760
Bits 4 and 3—Area 2 Wait Control (A2W1, A2W0): Specify the number of wait states inserted
in physical space area 2.
• For Ordinary Memory
Description
Bit 4: A2W0
Bit 3: A2W0
Inserted Wait States
WAIT Pin
0
0
0
Ignored
1
1
Enabled
1
0
2
Enabled
1
3
Enabled (Initial value)
• For Synchronous DRAM
Description
Bit 4: A2W1
Bit 3: A2W0
Synchronous DRAM: CAS Latency
0
0
1
1
1
0
2
1
3
1
(Initial value)
Bits 2 to 0—Area 0 Wait Control (A0W2, A0W1, A0W0): Specify the number of wait states
inserted in physical space area 0. Also specify the burst pitch for burst transfer.
Description
Burst Cycle
(Excluding First Cycle)
First Cycle
Bit 2:
A0W2
Bit 1:
A0W1
Bit 0:
A0W0
Inserted
Wait States
WAIT Pin
Number of States
Per Data Transfer
WAIT Pin
0
0
0
0
Ignored
2
Enabled
1
1
Enabled
2
Enabled
0
2
Enabled
3
Enabled
1
3
Enabled
4
Enabled
0
4
Enabled
4
Enabled
1
6
Enabled
6
Enabled
0
8
Enabled
8
Enabled
1
10
(Initial value)
Enabled
10
Enabled
1
1
0
1
Rev. 5.00, 09/03, page 244 of 760
10.2.5
Individual Memory Control Register (MCR)
The individual memory control register (MCR) is a 16-bit readable/writable register that specifies
RAS and CAS timing for synchronous DRAM (areas 2 and 3), specifies address multiplexing, and
controls refresh. This enables direct connection of synchronous DRAM without external circuits.
MCR is initialized to H'0000 by a power-on reset, but is not initialized by a manual reset or in
standby mode. Bits TPC1–TPC0, RCD1–RCD0, TRWL1–TRWL0, TRAS1–TRAS0, RASD, and
AMX3–AMX0 are written to in the initialization after a power-on reset and should not then be
modified again. When RFSH and RMODE are written to, write the same values to the other bits.
When using synchronous DRAM, do not access areas 2 and 3 until this register is initialized.
Bit:
Initial value:
R/W:
Bit:
Initial value:
R/W:
15
14
13
12
11
10
9
8
TPC1
TPC0
RCD1
RCD0
TRWL1
TRWL0
TRAS1
TRAS0
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
7
6
5
4
3
2
1
0
RASD
AMX3
AMX2
AMX1
AMX0
RFSH
RMODE
—
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R
Bits 15 and 14—RAS Precharge Time (TPC1, TPC0): When synchronous DRAM interface is
selected as connected memory, they set the minimum number of cycles until output of the next
bank-active command after precharge. However, the number of cycles input immediately after the
issue of an all-bank-precharge command (PALL) in the case of an auto-refresh or a precharge
command (PRE) in the bank active mode is one fewer than the normal value. TPC1 should not be
set to 0 and TPC0 to 1 in the bank active mode.
Description
Bit 15:
TPC1
Bit 14:
TPC0
Normal Operation
Immediately after
Precharge Command*
Immediately after
Self-Refresh
0
0
1 cycle (Initial value)
0 cycle (Initial value)
2 cycles (Initial value)
1
2 cycles
1 cycle
5 cycles
0
3 cycles
2 cycles
8 cycles
1
4 cycles
3 cycles
11 cycles
1
Note: * Immediately after all-bank-precharge (PALL) in the case of an auto-refresh or precharge
(PRE) in the bank active mode.
Rev. 5.00, 09/03, page 245 of 760
Bits 13 and 12—RAS–CAS Delay (RCD1, RCD0): When synchronous DRAM interface is
selected as connected memory, these bits set the bank active read/write command delay time.
Bit 13: RCD1
Bit 12: RCD0
Description
0
0
1 cycle
1
2 cycles
0
3 cycles
1
4 cycles
1
(Initial value)
Bits 11 and 10—Write-Precharge Delay (TRWL1, TRWL0): Set the synchronous DRAM
write-precharge delay time. This designates the time between the end of a write cycle and the next
bank-active command. This setting is valid only when synchronous DRAM is connected. After the
write cycle, the next bank-active command is not issued for the period TPC + TRWL.
Bit 11: TRWL1
Bit 10: TRWL0
Description
0
0
1 cycle
1
2 cycles
0
3 cycles
1
Reserved (Setting prohibited)
1
(Initial value)
Bits 9 and 8—C
CAS-Before-R
RAS Refresh RAS Assert Time (TRAS1, TRAS0): When
synchronous DRAM interface is selected, no bank-active command is issued during the period
TPC + TRAS after an auto-refresh command.
Bit 9: TRAS1
Bit 8: TRAS0
Description
0
0
2 cycles
1
3 cycles
0
4 cycles
1
5 cycles
1
(Initial value)
Bit 7—Synchronous DRAM Bank Active (RASD): Specifies whether synchronous DRAM is
used in bank active mode or auto-precharge mode. Set auto-precharge mode when areas 2 and 3
are both designated as synchronous DRAM space.
Bit 7: RASD
Description
0
Auto-precharge mode
1
Bank active mode
The bank active mode should not be used unless the bus width for all areas is 32 bits.
Rev. 5.00, 09/03, page 246 of 760
(Initial value)
Bits 6 to 3—Address Multiplex (AMX3, AMX2, AMX1, AMX0): Specify address multiplexing
for synchronous DRAM.
For Synchronous DRAM Interface:
Bit6:
AMX3
Bit5:
AMX2
Bit 4:
AMX1
Bit 3:
AMX0
1
1
0
1
The row address begins with A10 (The A10 value is output at
A1 when the row address is output. 4M × 16-bit × 4-bank
products)
1
0
The row address begins with A11 (The A11 value is output at
A1 when the row address is output. 8M × 16-bit × 4-bank
1
products)*
0
0
The row address begins with A9 (The A9 value is output at A1
when the row address is output. 1M × 16-bit × 4-bank
products)
1
The row address begins with A10 (The A10 value is output at
A1 when the row address is output. 2M × 8-bit × 4-bank
products, 2M × 16-bit × 4-bank products)
1
1
The row address begins with A9 (The A9 value is output at A1
when the row address is output. 512k × 32-bit × 4-bank
2
products)*
0
0
Begin synchronous DRAM access after setting AMX3 to 0 =
*1**
(Initial value)
0
0
1
0
Except above value
Description
Reserved (Setting prohibited)
Notes: 1. Can only be set when using a 16-bit bus width.
2. Can only be set when using a 32-bit bus width.
Bit 2—Refresh Control (RFSH): The RFSH bit determines whether or not synchronous DRAM
refresh operations are is performed. If the refresh function is not used, the timer for generation of
periodic refresh requests can also be used as an interval timer.
Bit 2: RFSH
Description
0
No refresh
1
Refresh
(Initial value)
Rev. 5.00, 09/03, page 247 of 760
Bit 1—Refresh Mode (RMODE): Selects whether to perform an ordinary refresh or a selfrefresh when the RFSH bit is 1. When the RFSH bit is 1 and this bit is 0, an auto-refresh is
performed on synchronous DRAM at the period set by refresh-related registers RTCNT, RTCOR,
and RTCSR. When a refresh request occurs during an external bus cycle, the refresh cycle is
performed after the bus cycle ends. When the RFSH bit is 1 and this bit is also 1, the synchronous
DRAM will wait for the end of any executing external bus cycle before going into a self-refresh.
All refresh requests to memory that is in the self-refresh state are ignored.
Bit 1: RMODE
Description
0
Auto refresh (RFSH must be 1)
1
Self-refresh (RFSH must be 1)
(Initial value)
Bit 0—Reserved: This bit is always read as 0. The write value should always be 0.
10.2.6
PCMCIA Control Register (PCR)
The PCMCIA control register (PCR) is a 16-bit readable/writable register that specifies the
assertion and negation timing of the OE and WE signals for the PCMCIA interface connected to
areas 5 and 6. The OE and WE signal assertion width is set by the wait control bits in the WCR2
register.
PCR is initialized to H'0000 by a power-on reset, but is not initialized, and retains its contents, in a
manual reset and in standby mode.
Bit:
Initial value:
R/W:
Bit:
15
14
13
12
11
10
9
8
A6W3
A5W3
—
—
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
7
6
5
4
3
2
1
0
A5TED2 A6TED2 A5TEH2 A6TEH2
A5TED1 A5TED0 A6TED1 A6TED0 A5TEH1 A5TEH0 A6TEH1 A6TEH0
Initial value:
R/W:
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Rev. 5.00, 09/03, page 248 of 760
Bit 15—Area 6 Wait Control (A6W3): Specifies the number of inserted wait states for area 6
combined with bits A6W2–A6W0 in WCR2. Also specifies the number of transfer states in burst
transfer. Clear this bit to 0 when area 6 is not set to PCMCIA.
First Cycle
Burst Cycle
A6W3
A6W2
A6W1
A6W0
Inserted Wait
States
WAIT Pin
Number of
States per
One-data
Transfer
0
0
0
0
0
Ignored
2
Enabled
0
0
0
1
1
Enabled
2
Enabled
0
0
1
0
2
Enabled
3
Enabled
0
0
1
1
3
Enabled
4
Enabled
0
1
0
0
4
Enabled
5
Enabled
0
1
0
1
6
Enabled
7
Enabled
0
1
1
0
8
Enabled
9
Enabled
0
1
1
1
10
(Initial value)
Enabled
11
Enabled
1
0
0
0
12
Enabled
13
Enabled
1
0
0
1
14
Enabled
15
Enabled
1
0
1
0
18
Enabled
19
Enabled
1
0
1
1
22
Enabled
23
Enabled
1
1
0
0
26
Enabled
27
Enabled
1
1
0
1
30
Enabled
31
Enabled
1
1
1
0
34
Enabled
35
Enabled
1
1
1
1
38
Enabled
39
Enabled
WAIT Pin
Bit 14—Area 5 Wait Control (A5W3): Specifies the number of inserted wait states for area 5
combined with bits A5W2–A5W0 in WCR2. Also specifies the number of transfer states in burst
transfer. Clear this bit to 0 when area 5 is not set to PCMCIA.
The relationship between the set value and the number of waits is the same as for A6W3.
Bits 13 and 12—Reserved: These bits are always read as 0. The write value should always be 0.
Rev. 5.00, 09/03, page 249 of 760
Bits 11, 7, and 6—Area 5 Address OE/W
WE Assert Delay (A5TED2, A5TED1, A5TED0):
Specify the delay time from address output to OE/WE assertion for the PCMCIA interface
connected to area 5.
Bit 11:
A5TED2
Bit 7:
A5TED1
Bit 6:
A5TED0
Description
0
0
0
0.5-cycle delay
1
1.5-cycle delay
0
2.5-cycle delay
1
3.5-cycle delay
0
4.5-cycle delay
1
5.5-cycle delay
0
6.5-cycle delay
1
7.5-cycle delay
1
1
0
1
(Initial value)
Bits 10, 5, and 4—Area 6 Address OE/W
WE Assert Delay (A6TED2, A6TED1, A6TED0): The
A6TED bits specify the delay time from address output to OE/WE assertion for the PCMCIA
interface connected to area 6.
Bit 10:
A6TED2
Bit 5:
A6TED1
Bit 4:
A6TED0
Description
0
0
0
0.5-cycle delay
1
1.5-cycle delay
0
2.5-cycle delay
1
3.5-cycle delay
0
4.5-cycle delay
1
5.5-cycle delay
0
6.5-cycle delay
1
7.5-cycle delay
1
1
0
1
Rev. 5.00, 09/03, page 250 of 760
(Initial value)
Bits 9, 3, and 2—Area 5 OE/W
WE Negate Address Delay (A5TEH2, A5TEH1, A5TEH0):
Specify the address hold delay time from OE/WE negation for the PCMCIA interface connected to
area 5.
Bit 9:
A5TEH2
Bit 3:
A5TEH1
Bit 2:
A5TEH0
Description
0
0
0
0.5-cycle delay
1
1.5-cycle delay
0
2.5-cycle delay
1
3.5-cycle delay
0
4.5-cycle delay
1
5.5-cycle delay
0
6.5-cycle delay
1
7.5-cycle delay
1
1
0
1
(Initial value)
Bits 8, 1, and 0—Area 6 OE/W
WE Negate Address Delay (A6TEH2, A6TEH1, A6TEH0):
Specify the address hold delay time from OE/WE negation for the PCMCIA interface connected to
area 6.
Bit 8:
A6TEH2
Bit 1:
A6TEH1
Bit 0:
A6TEH0
Description
0
0
0
0.5-cycle delay
1
1.5-cycle delay
0
2.5-cycle delay
1
3.5-cycle delay
0
4.5-cycle delay
1
5.5-cycle delay
0
6.5-cycle delay
1
7.5-cycle delay
1
1
0
1
(Initial value)
Rev. 5.00, 09/03, page 251 of 760
10.2.7
Synchronous DRAM Mode Register (SDMR)
The synchronous DRAM mode register (SDMR) is an 8-bit write-only register that is written to
via the synchronous DRAM address bus. It sets synchronous DRAM mode for areas 2 and 3.
SDMR must be set before accessing the synchronous DRAM.
Writes to the synchronous DRAM mode register use the address bus rather than the data bus. If
the value to be set is X and the SDMR address is Y, the value X is written in the synchronous
DRAM mode register by writing in address X + Y. Since, with a 32-bit bus width, A0 of the
synchronous DRAM is connected to A2 of the chip and A1 of the synchronous DRAM is
connected to A3 of the chip, the value actually written to the synchronous DRAM is the X value
shifted two bits right. With a 16-bit bus width, the value written is the X value shifted one bit
right. For example, with a 32-bit bus width, when H'0230 is written to the SDMR register of area
2, random data is written to the address H'FFFFD000 (address Y) + H'08C0 (value X), or
H'FFFFD8C0. As a result, H'0230 is written to the SDMR register. The range for value X is
H'0000 to H'0FFC. When H'0230 is written to the SDMR register of area 3, random data is written
to the address H'FFFFE000 (address Y) + H'08C0 (value X), or H'FFFFE8C0. As a result, H'0230
is written to the SDMR register. The range for value X is H'0000 to H'0FFC.
Bit:
31
12
SDMR address
11
10
9
8
—
—
—
—
Initial value:
—
......................
—
—
—
—
—
R/W:
—
......................
—
W*
W*
W
W
Bit:
7
6
5
4
3
2
1
0
—
—
—
—
—
—
—
—
Initial value:
—
—
—
—
—
—
—
—
R/W:
W
W
W
W
W
W
—
—
Note: * Depending on the type of synchronous DRAM.
Rev. 5.00, 09/03, page 252 of 760
10.2.8
Refresh Timer Control/Status Register (RTCSR)
The refresh timer control/status register (RTCSR) is a 16-bit readable/writable register that
specifies the refresh cycle, whether to generate an interrupt, and the cycle of that interrupt. It is
initialized to H'0000 by a power-on reset, but is not initialized by a manual reset or in standby
mode. Make the RTCOR setting before setting bits CKS2 to CKS0 in RTCSR.
Note: The method of writing to RTCSR differs from that for general registers to ensure that
RTCSR is not rewritten incorrectly. Use a word transfer instruction to set the upper byte as
B'10100101 and the lower byte as the write data. For details, see section 10.2.12, Cautions
on Accessing Refresh Control Related Registers.
Bit:
15
14
13
12
11
10
9
8
—
—
—
—
—
—
—
—
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R
R
R
R
R
R
R
Bit:
7
6
5
4
3
2
1
0
CMF
CMIE
CKS2
CKS1
CKS0
OVF
OVIE
LMTS
Initial value:
R/W:
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Bits 15 to 8—Reserved: These bits are always read as 0. The write value should always be 0.
Bit 7—Compare Match Flag (CMF): Indicates that the values of RTCNT and RTCOR match.
Bit 7: CMF
Description
0
The values of RTCNT and RTCOR do not match
(Initial value)
Clearing condition: When a refresh is performed after 0 has been written to
CMF and RFSH = 1 and RMODE = 0 (to perform a CBR refresh)
1
The values of RTCNT and RTCOR match
Setting condition: RTCNT = RTCOR*
Note: * Contents do not change when 1 is written to CMF.
Bit 6—Compare Match Interrupt Enable (CMIE): Enables or disables an interrupt request
caused when CMF in RTCSR is set to 1. Do not set this bit to 1 when using auto-refresh.
Bit 6: CMIE
Description
0
Interrupt request by CMF is disabled
1
Interrupt request by CMF is enabled
(Initial value)
Rev. 5.00, 09/03, page 253 of 760
Bits 5 to 3—Clock Select Bits (CKS2 to CKS0): Select the clock input to RTCNT. The source
clock is the external bus clock (CKIO). The RTCNT count clock is CKIO divided by the specified
ratio. RTCOR must be set before setting CKS2-CKS0.
Description
Bit 5: CKS2
Bit 4: CKS1
Bit 3: CKS0
Normal external bus clock
0
0
0
Clock input disabled
1
Bus clock (CKIO)/4
0
CKIO/16
1
CKIO/64
0
CKIO/256
1
CKIO/1024
0
CKIO/2048
1
CKIO/4096
1
1
0
1
Bit 2—Refresh Count Overflow Flag (OVF): Indicates when the number of refresh requests
indicated in the refresh count register (RFCR) exceeds the limit set in the LMTS bit in RTCSR.
Bit 2: OVF
Description
0
RFCR has not exceeded the count limit value set in LMTS
(Initial value)
Clearing condition: When 0 is written to OVF
1
RFCR has exceeded the count limit value set in LMTS
Setting condition: When the RFCR value has exceeded the count limit value
set in LMTS*
Note: * Contents do not change when 1 is written to OVF.
Bit 1—Refresh Count Overflow Interrupt Enable (OVIE): Selects whether to suppress
generation of interrupt requests by the OVF bit in RTCSR when OVF is set to 1.
Bit 1: OVIE
Description
0
Interrupt request by OVF is disabled
1
Interrupt request by OVF is enabled
Rev. 5.00, 09/03, page 254 of 760
(Initial value)
Bit 0—Refresh Count Overflow Limit Select (LMTS): Indicates the count limit value to be
compared to the number of refreshes indicated in the refresh count register (RFCR). When the
value in RFCR overflows the value specified by LMTS, the OVF flag is set.
Bit 0: LMTS
Description
0
Count limit value is 1024
1
Count limit value is 512
10.2.9
(Initial value)
Refresh Timer Counter (RTCNT)
RTCNT is a 16-bit register containing a readable/writable 8-bit counter that counts up on an input
clock. The clock select bits (CKS2–CKS0) in RTCSR select the input clock. When RTCNT
matches RTCOR, the CMF bit in RTCSR is set and RTCNT is cleared. RTCNT is initialized to
H'00 by a power-on reset, but continues incrementing after a manual reset. It is not initialized in
standby mode, but holds its contents.
Note: The method of writing to RTCNT differs from that for general registers to ensure that
RTCNT is not rewritten incorrectly. Use a word transfer instruction to set the upper byte
as B'10100101 and the lower byte as the write data. For details, see section 10.2.12,
Cautions on Accessing Refresh Control Related Registers.
Bit:
15
14
13
12
11
10
9
8
Initial value:
0
0
0
0
0
0
0
0
R/W:
—
—
—
—
—
—
—
—
Bit:
7
6
5
4
3
2
1
0
Initial value:
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W:
Rev. 5.00, 09/03, page 255 of 760
10.2.10 Refresh Time Constant Register (RTCOR)
The refresh time constant register (RTCOR) specifies the upper-limit value of RTCNT. The values
of RTCOR and RTCNT (lower 8 bits) are constantly compared. When the values match, the
compare match flag (CMF) in RTCSR is set and RTCNT is cleared to 0. When the refresh bit
(RFSH) in the individual memory control register (MCR) is set to 1 and the refresh mode is set to
auto refresh, a memory refresh cycle occurs when the CMF bit is set. RTCOR is a
readable/writable register. RTCOR is initialized to H'00 by a power-on reset. It is not initialized by
a manual reset or in standby mode, but holds its contents. Make the RTCOR setting before setting
bits CKS2 to CKS0 in RTCSR.
Note: The method of writing to RTCOR differs from that for general registers to ensure that
RTCOR is not rewritten incorrectly. Use a word transfer instruction to set the upper byte
as B'10100101 and the lower byte as the write data. For details, see section 10.2.12,
Cautions on Accessing Refresh Control Related Registers.
Bit:
15
14
13
12
11
10
9
8
Initial value:
0
0
0
0
0
0
0
0
R/W:
—
—
—
—
—
—
—
—
Bit:
7
6
5
4
3
2
1
0
Initial value:
R/W:
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
10.2.11 Refresh Count Register (RFCR)
The refresh count register (RFCR) counts the number of refreshing. When RFCR exceeds the
count limit value set in the LMTS bit in RTCSR, the OVF bit in RTCSR is set and RFCR is
cleared. RFCR is a 10-bit readable/writable counter. RFCR is initialized to H'0000 by a power-on
reset. RFCR continues incrementing in a manual reset. It is not initialized by in standby mode, but
holds its contents.
Note: The method of writing to RFCR differs from that for general registers to ensure that RFCR
is not rewritten incorrectly. Use a word transfer instruction to set the six bits starting from
the MSB in the upper byte as B'101001, and the remaining bits as the write data. For
details, see section 10.2.12, Cautions on Accessing Refresh Control Related Registers.
Rev. 5.00, 09/03, page 256 of 760
Bit:
15
14
13
12
11
10
9
8
Initial value:
0
0
0
0
0
0
0
0
R/W:
—
—
—
—
—
—
R/W
R/W
Bit:
7
6
5
4
3
2
1
0
Initial value:
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W:
10.2.12 Cautions on Accessing Refresh Control Related Registers
RFCR, RTCSR, RTCNT, and RTCOR require that a specific code be appended to the data when it
is written to prevent data from being mistakenly overwritten by program overruns or other write
operations (figure 10.5). Perform reads and writes using the following methods:
1. When writing to RFCR, RTCSR, RTCNT, and RTCOR, use only word transfer instructions.
Byte transfer instructions cannot be used.
When writing to RTCNT, RTCSR, or RTCOR, place B'10100101 in the upper byte and the
write data in the lower byte. When writing to RFCR, place B'101001 in the upper 6 bits and
the write data in the remaining bits, as shown in figure 10.5.
2. When reading from RFCR, RTCSR, RTCNT, and RTCOR, carry out reads with a 16-bit
width. 0 is read from undefined bits.
15
RTCSR, RTCNT,
RTCOR
1
1
0
0
15
RFCR
1
0
8 7
0
1
0
1
Write data
10 9
0
1
0
0
1
0
Write data
Figure 10.5 Writing to RFCR, RTCSR, RTCNT, and RTCOR
Rev. 5.00, 09/03, page 257 of 760
10.2.13 MCS0 Control Register (MCSCR0)
The MCS0 control register (MCSCR0) is a 16-bit readable/writable register that specifies the
MCS[0] pin output conditions.
MCSCR0 is initialized to H'0000 by a power-on reset, but is not initialized by a manual reset or in
standby mode.
As the MCS[0] pin is multiplexed as the PTC0 pin, when using the pin as MCS[0], bits
PC0MD[1:0] in the PCCR register should be set to 00 (other function).
Bit:
15
14
13
12
11
10
9
8
—
—
—
—
—
—
—
—
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R
R
R
R
R
R
R
Bit:
7
6
5
4
3
2
1
0
—
CS2/0
CAP1
CAP0
A25
A24
A23
A22
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Bits 15 to 7—Reserved: These bits are always read as 0. The write value should always be 0.
Bit 6—CS2/CS0 Select (CS2/0): Selects whether an area 2 or area 0 address is to be decoded.
Bit 6: CS2/0
Description
0
Area 0 is selected
1
Area 2 is selected
Only 0 should be used for the CS2/0 bit in MCSCR0. Either 0 or 1 may be used for MCSCR1 to
MCSCR7.
Bits 5 and 4—Connected Memory Size Specification (CAP1, CAP0)
Bit 5: CAP1
Bit 4: CAP0
Description
0
0
32-Mbit memory is connected
0
1
64-Mbit memory is connected
1
0
128-Mbit memory is connected
1
1
256-Mbit memory is connected
Bits 3 to 0—Start Address Specification (A25, A24, A23, A22): These bits specify the start
address of the memory area for which MCS[0] is asserted.
Rev. 5.00, 09/03, page 258 of 760
10.2.14 MCS1 Control Register (MCSCR1)
The MCS1 control register (MCSCR1) specifies the MCS[1] pin output conditions.
The bit configuration and functions are the same as those of MCSCR0.
10.2.15 MCS2 Control Register (MCSCR2)
The MCS2 control register (MCSCR2) specifies the MCS[2] pin output conditions.
The bit configuration and functions are the same as those of MCSCR0.
10.2.16 MCS3 Control Register (MCSCR3)
The MCS3 control register (MCSCR3) specifies the MCS[3] pin output conditions.
The bit configuration and functions are the same as those of MCSCR0.
10.2.17 MCS4 Control Register (MCSCR4)
The MCS4 control register (MCSCR4) specifies the MCS[4] pin output conditions.
The bit configuration and functions are the same as those of MCSCR0.
10.2.18 MCS5 Control Register (MCSCR5)
The MCS5 control register (MCSCR5) specifies the MCS[5] pin output conditions.
The bit configuration and functions are the same as those of MCSCR0.
10.2.19 MCS6 Control Register (MCSCR6)
The MCS6 control register (MCSCR6) specifies the MCS[6] pin output conditions.
The bit configuration and functions are the same as those of MCSCR0.
10.2.20 MCS7 Control Register (MCSCR7)
The MCS7 control register (MCSCR7) specifies the MCS[7] pin output conditions.
The bit configuration and functions are the same as those of MCSCR0.
Rev. 5.00, 09/03, page 259 of 760
10.3
BSC Operation
10.3.1
Endian/Access Size and Data Alignment
The SH7709S supports both big endian, in which the 0 address is the most significant byte in the
byte data, and little endian, in which the 0 address is the least significant byte. Switching between
the two is designated by an external pin (MD5 pin) at the time of a power-on reset. After a poweron reset, big endian is engaged when MD5 is low; little endian is engaged when MD5 is high.
Three data bus widths are available for ordinary memory (byte, word, longword) and two data bus
widths (word and longword) for synchronous DRAM. For the PCMCIA interface, choose from
byte and word. This means data alignment is done by matching the device’s data width and
endian. The access unit must also be matched to the device’s bus width. This also means that when
longword data is read from a byte-width device, four read operations must be performed. In the
SH7709S, data alignment and conversion of data length is performed automatically between the
respective interfaces.
Tables 10.7 to 10.12 show the relationship between endian, device data width, and access unit.
Table 10.7 32-Bit External Device/Big-Endian Access and Data Alignment
Data Bus
Strobe Signals
Operation
D31–D24
D23–D16
D15–D8
D7–D0
WE3,
DQMUU
Byte access
at 0
Data
7–0
—
—
—
Asserted
Byte access
at 1
—
Data
7–0
—
—
Byte access
at 2
—
—
Data
7–0
—
Byte access
at 3
—
—
—
Data
7–0
Word access
at 0
Data
15–8
Data
7–0
—
—
Word access
at 2
—
—
Data
15–8
Data
7–0
Longword
access at 0
Data
31–24
Data
23–16
Data
15–8
Data
7–0
Rev. 5.00, 09/03, page 260 of 760
WE2,
DQMUL
WE1,
DQMLU
WE0,
DQMLL
Asserted
Asserted
Asserted
Asserted
Asserted
Asserted
Asserted
Asserted
Asserted
Asserted
Asserted
Table 10.8 16-Bit External Device/Big-Endian Access and Data Alignment
Data Bus
Operation
D31–
D24
D23–
D16
Byte access at 0
—
Byte access at 1
Strobe Signals
WE3,
DQMUU
WE2,
DQMUL
WE1,
DQMLU
WE0,
DQMLL
Asserted
—
D15–D8
D7–D0
—
Data
7–0
—
—
—
—
Data
7–0
Byte access at 2
—
—
Data
7–0
—
Byte access at 3
—
—
—
Data
7–0
Word access at 0
—
—
Data
15–8
Data
7–0
Asserted
Asserted
Word access at 2
—
—
Data
15–8
Data
7–0
Asserted
Asserted
Longword
access
at 0
—
—
Data
31–24
Data
23–16
Asserted
Asserted
2nd time —
at 2
—
Data
15–8
Data
7–0
Asserted
Asserted
1st time
at 0
Asserted
Asserted
—
Asserted
Rev. 5.00, 09/03, page 261 of 760
Table 10.9 8-Bit External Device/Big-Endian Access and Data Alignment
Data Bus
Strobe Signals
WE3,
DQMUU
WE2,
DQMUL
WE1,
DQMLU
WE0,
DQMLL
Operation
D31–
D24
D23–
D16
D15–
D8
D7–D0
Byte access at 0
—
—
—
Data 7–0
Asserted
Byte access at 1
—
—
—
Data 7–0
Asserted
Byte access at 2
—
—
—
Data 7–0
Asserted
Byte access at 3
—
—
—
Data 7–0
Asserted
Word access 1st time —
at 0
at 0
—
—
Data
15–8
Asserted
2nd time —
at 1
—
—
Data
7–0
Asserted
Word access 1st time —
at 2
at 2
—
—
Data
15–8
Asserted
2nd time —
at 3
—
—
Data
7–0
Asserted
1st time —
at 0
—
—
Data
31–24
Asserted
2nd time —
at 1
—
—
Data
23–16
Asserted
3rd time —
at 2
—
—
Data
15–8
Asserted
4th time —
at 3
—
—
Data
7–0
Asserted
Longword
access at 0
Rev. 5.00, 09/03, page 262 of 760
Table 10.10 32-Bit External Device/Little-Endian Access and Data Alignment
Data Bus
Strobe Signals
WE3,
DQMUU
WE2,
DQMUL
Operation
D31–D24
D23–D16
D15–D8
D7–D0
Byte access
at 0
—
—
—
Data
7–0
Byte access
at 1
—
—
Data
7–0
—
Byte access
at 2
—
Data
7–0
—
—
Byte access
at 3
Data
7–0
—
—
—
Word access
at 0
—
—
Data
15–8
Data
7–0
Word access
at 2
Data
15–8
Data
7–0
—
—
Asserted
Asserted
Longword
access at 0
Data
31–24
Data
23–16
Data
15–8
Data
7–0
Asserted
Asserted
WE1,
DQMLU
WE0,
DQMLL
Asserted
Asserted
Asserted
Asserted
Asserted
Asserted
Asserted
Asserted
Table 10.11 16-Bit External Device/Little-Endian Access and Data Alignment
Data Bus
Strobe Signals
WE3,
DQMUU
WE2,
DQMUL
WE1,
DQMLU
WE0,
DQMLL
Operation
D31–
D24
D23–
D16
D15–D8
D7–D0
Byte access at 0
—
—
—
Data
7–0
Byte access at 1
—
—
Data
7–0
—
Byte access at 2
—
—
—
Data
7–0
Byte access at 3
—
—
Data
7–0
—
Asserted
Word access at 0
—
—
Data
15–8
Data
7–0
Asserted
Asserted
Word access at 2
—
—
Data
15–8
Data
7–0
Asserted
Asserted
Longword
access
at 0
—
—
Data
15–8
Data
7–0
Asserted
Asserted
2nd time —
at 2
—
Data
31–24
Data
23–16
Asserted
Asserted
1st time
at 0
Asserted
Asserted
Asserted
Rev. 5.00, 09/03, page 263 of 760
Table 10.12 8-Bit External Device/Little-Endian Access and Data Alignment
Data Bus
Strobe Signals
WE3,
DQMUU
WE2,
DQMUL
WE1,
DQMLU
WE0,
DQMLL
D31–
D24
D23–
D16
D15–D8
Operation
Byte access at 0
—
—
—
Data
7–0
Asserted
Byte access at 1
—
—
—
Data
7–0
Asserted
Byte access at 2
—
—
—
Data
7–0
Asserted
Byte access at 3
—
—
—
Data
7–0
Asserted
Word access
at 0
1st time
at 0
—
—
—
Data
7–0
Asserted
2nd time
at 1
—
—
—
Data
15–8
Asserted
1st time
at 2
—
—
—
Data
7–0
Asserted
2nd time
at 3
—
—
—
Data
15–8
Asserted
1st time
at 0
—
—
—
Data
7–0
Asserted
2nd time
at 1
—
—
—
Data
15–8
Asserted
3rd time
at 2
—
—
—
Data
23–16
Asserted
4th time
at 3
—
—
—
Data
31–24
Asserted
Word access
at 2
Longword
access at 0
Rev. 5.00, 09/03, page 264 of 760
D7–D0
10.3.2
Description of Areas
Area 0: Area 0 physical address bits A28–A26 are 000. Address bits A31–A29 are ignored and
the address range is H'00000000 + H'20000000 × n – H'03FFFFFF + H'20000000 × n (n = 0–6
and n = 1–6 are the shadow spaces).
Ordinary memories such as SRAM, ROM, and burst ROM can be connected to this space. Byte,
word, or longword can be selected as the bus width using external pins MD3 and MD4. When the
area 0 space is accessed, the CS0 signal is asserted. The RD signal that can be used as OE and the
WE0–WE3 signals for write control are also asserted. The number of bus cycles is selected
between 0 and 10 wait cycles using the A0W2–A0W0 bits in WCR2. When the burst function is
used, the bus cycle pitch of the burst cycle is determined within a range of 2–10 according to the
number of waits.
Area 1: Area 1 physical address bits A28–A26 are 001. Address bits A31–A29 are ignored and
the address range is H'04000000 + H'20000000 × n – H'07FFFFFF + H'20000000 × n (n = 0–6
and n = 1–6 are the shadow spaces).
Area 1 is the area specifically for internal peripheral modules. External memories cannot be
connected.
Control registers of the peripheral modules shown below are mapped to this area 1. Their
addresses are physical addresses, to which logical addresses can be mapped when the MMU is
enabled:
DMAC, PORT, IrDA, SCIF, ADC, DAC, INTC (except INTEVT, IPRA, IPRB)
These registers must be set not to be cached by using software.
Area 2: Area 2 physical address bits A28–A26 are 010. Address bits A31–A29 are ignored and
the address range is H'08000000 + H'20000000 × n – H'0BFFFFFF + H'20000000 × n (n = 0–6
and n = 1–6 are the shadow spaces).
Ordinary memories such as SRAM and ROM, as well as synchronous DRAM, can be connected
to this space. Byte, word, or longword can be selected as the bus width using bits A2SZ1 and
A2SZ0 in BCR2 for ordinary memory.
When the area 2 space is accessed, the CS2 signal is asserted. When ordinary memories are
connected, the RD signal that can be used as OE and the WE0–WE3 signals for write control are
also asserted and the number of bus cycles is selected between 0 and 3 wait cycles using bits
A2W1 and A2W0 bits in WCR2. Only when ordinary memories are connected, any way can be
inserted in each bus cycle by means of the external wait pin (WAIT).
When synchronous DRAM is connected, the RAS3U and RAS3L signals, CASU and CASL
signals, RD/WR signal, and byte control signals DQMHH, DQMHL, DQMLH, and DQMLL are
all asserted and addresses multiplexed. Control of RAS3U, RAS3L, CASU, CASL, data timing,
and address multiplexing is set with MCR.
Rev. 5.00, 09/03, page 265 of 760
Area 3: Area 3 physical address bits A28–A26 are 011. Address bits A31–A29 are ignored and
the address range is H'0C000000 + H'20000000 × n – H'0FFFFFFF + H'20000000 × n (n = 0–6
and n = 1–6 are the shadow spaces).
Ordinary memories such as SRAM and ROM, as well as synchronous DRAM, can be connected
to this space. Byte, word or longword can be selected as the bus width using bits A3SZ1 and
A3SZ0 bits in BCR2 for ordinary memory.
When area 3 space is accessed, CS3 is asserted.
When ordinary memories are connected, the RD signal that can be used as OE and the WE0–WE3
signals for write control are asserted and the number of bus cycles is selected between 0 and 3 wait
cycles using the A3W1 and A3W0 bits in WCR2.
When synchronous DRAM is connected, the RAS3U and RAS3L signals, CASU and CASL
signals, RD/WR signal, and byte control signals DQMHH, DQMHL, DQMLH, and DQMLL are
all asserted and addresses multiplexed.
Area 4: Area 4 physical address bits A28–A26 are 100. Address bits A31–A29 are ignored and
the address range is H'10000000 + H'20000000 × n – H'13FFFFFF + H'20000000 × n (n = 0–6
and n = 1–6 are the shadow spaces).
Only ordinary memories such as SRAM and ROM can be connected to this space. Byte, word, or
longword can be selected as the bus width using bits A4SZ1 and A4SZ0 in BCR2. When the area
4 space is accessed, the CS4 signal is asserted. The RD signal that can be used as OE and the
WE0–WE3 signals for write control are also asserted. The number of bus cycles is selected
between 0 and 10 wait cycles using the A4W2–A4W0 bits in WCR2. Any wait can be inserted in
each bus cycle by means of the external wait pin (WAIT).
Area 5: Area 5 physical address bits A28–A26 are 101. Address bits A31–A29 are ignored and
the address range is the 64 Mbytes at H'14000000 + H'20000000 × n – H'17FFFFFF +
H'20000000 × n (n = 0–6 and n = 1–6 are the shadow spaces).
Ordinary memories such as SRAM and ROM as well as burst ROM and PCMCIA interfaces can
be connected to this space. When the PCMCIA interface is used, the IC memory card interface
address range comprises the 32 Mbytes at H'14000000 + H'20000000 × n to H'15FFFFFF +
H'20000000 × n (n = 0–6 and n = 1–6 are the shadow spaces), and the I/O card interface address
range comprises the 32 Mbytes at H'16000000 + H'20000000 × n to H'17FFFFFF + H'20000000 ×
n (n = 0–6 and n = 1–6 are the shadow spaces).
For ordinary memory and burst ROM, byte, word, or longword can be selected as the bus width
using bits A5SZ1 and A5SZ0 in BCR2. For the PCMCIA interface, byte or word can be selected
as the bus width using bits A5SZ1 and A5SZ0 bits in BCR2.
Rev. 5.00, 09/03, page 266 of 760
When the area 5 space is accessed and ordinary memory is connected, the CS5 signal is asserted.
The RD signal that can be used as OE and the WE0–WE3 signals for write control are also
asserted. When the PCMCIA interface is used, the CE1A signal, CE2A signal, RD signal as OE
signal, and WE1 signal are asserted.
The number of bus cycles is selected between 0 and 10 wait cycles using the A5W2–A5W0 bits in
WCR2. With the PCMCIA interface, from 0 to 38 wait cycles can be selected using the A5W2–
A5W0 bits in WCR2 and the A5W3 bit in PCR. In addition, any number of waits can be inserted
in each bus cycle by means of the external wait pin (WAIT). When a burst function is used, the
bus cycle pitch of the burst cycle is determined within a range of 2–11 (2–39 for the PCMCIA
interface) according to the number of waits. The setup and hold times of address/CS5 for the
read/write strobe signals can be set in the range 0.5–7.5 using bits A5TED2–A5TED0 and
A5TEH2–A5TEH0 in the PCR register.
Area 6: Area 6 physical address bits A28–A26 are 110. Address bits A31–A29 are ignored and
the address range is the 64 Mbytes at H'18000000 + H'20000000 × n – H'1BFFFFFF +
H'20000000 × n (n = 0–6 and n = 1–6 are the shadow spaces).
Ordinary memories such as SRAM and ROM as well as burst ROM and PCMCIA interfaces can
be connected to this space. When the PCMCIA interface is used, the IC memory card interface
address range is 32 Mbytes at H'18000000 + H'20000000 × n – H'19FFFFFF + H'20000000 × n
and the I/O card interface address range is 32 Mbytes at H'1A000000 + H'20000000 × n –
H'1BFFFFFF + H'20000000 × n (n = 0–6 and n = 1–6 are the shadow spaces).
For ordinary memory and burst ROM, byte, word, or longword can be selected as the bus width
using bits A6SZ1 and A6SZ0 in BCR2. For the PCMCIA interface, byte or word can be selected
as the bus width using bits A6SZ1 and A6SZ0 in BCR2.
When the area 6 space is accessed and ordinary memory is connected, the CS6 signal is asserted.
The RD signal that can be used as OE and the WE0–WE3 signals for write control are also
asserted. When the PCMCIA interface is used, the CE1B signal, CE2B signal, RD signal as OE
signal, and WE, ICIORD, and ICIOWR signals are asserted.
The number of bus cycles is selected between 0 and 10 wait cycles using the A6W2–A6W0 bits in
WCR2. With the PCMCIA interface, from 0 to 38 wait cycles can be selected using the A6W2–
A6W0 bits in WCR2 and the A6W3 bit in PCR. In addition, any number of waits can be inserted
in each bus cycle by means of the external wait pin (WAIT). The bus cycle pitch of the burst cycle
is determined within a range of 2–11 (2–39 for the PCMCIA interface) according to the number of
waits. The address/CS6 setup and hold times for the read/write strobe signals can be set in the
range 0.5–7.5 using bits A6TED2–A6TED0 and A6TEH2–A6TEH0 in the PCR register.
Rev. 5.00, 09/03, page 267 of 760
10.3.3
Basic Interface
Basic Timing: The basic interface of the SH7709S uses strobe signal output in consideration of
the fact that mainly static RAM will be directly connected. Figure 10.6 shows the basic timing of
normal space accesses. A no-wait normal access is completed in two cycles. The BS signal is
asserted for one cycle to indicate the start of a bus cycle. The CSn signal is negated on the T2
clock falling edge to secure the negation period. Therefore, in case of access at minimum pitch,
there is a half-cycle negation period.
There is no access size specification when reading. The correct access start address is output in the
least significant bit of the address, but since there is no access size specification, 32 bits are always
read in case of a 32-bit device, and 16 bits in case of a 16-bit device. When writing, only the WE
signal for the byte to be written is asserted. For details, see section 10.3.1, Endian/Access Size and
Data Alignment.
Read/write for cache fill or write-back follows the set bus width and transfers a total of 16 bytes
continuously. The bus is not released during this transfer. For cache misses that occur during byte
or word operand accesses or branching to odd word boundaries, the fill is always performed by
longword accesses on the chip-external interface. Write-through-area write access and noncacheable read/write access are based on the actual address size.
Rev. 5.00, 09/03, page 268 of 760
T1
T2
CKIO
A25 to A0
CSn
RD/WR
RD
Read
D31 to D0
WEn
Write
D31 to D0
BS
Figure 10.6 Basic Timing of Basic Interface
Rev. 5.00, 09/03, page 269 of 760
Figures 10.7, 10.8, and 10.9 show examples of connection to 32, 16, and 8-bit data-width static
RAM, respectively.
128k × 8-bit
SRAM
••••
A0
CS
OE
I/O7
••••
I/O0
WE
••••
••••
••••
••••
A16
A0
CS
OE
I/O7
••••
••••
D8
WE1
D7
••••
••••
D16
WE2
D15
••••
••••
D24
WE3
D23
I/O0
WE
••••
D0
WE0
A16
••••
••••
A2
CSn
RD
D31
A16
••••
••••
••••
A18
••••
SH7709S
••••
A0
CS
OE
I/O7
••••
A16
A0
CS
OE
I/O7
••••
••••
••••
I/O0
WE
I/O0
WE
Figure 10.7 Example of 32-Bit Data-Width Static RAM Connection
Rev. 5.00, 09/03, page 270 of 760
128k × 8-bit
SRAM
••••
A0
CS
OE
I/O7
••••
I/O0
WE
••••
••••
••••
D0
WE0
A16
••••
••••
D8
WE1
D7
A0
CS
OE
I/O7
••••
••••
A1
CSn
RD
D15
A16
••••
••••
••••
A17
••••
SH7709S
I/O0
WE
Figure 10.8 Example of 16-Bit Data-Width Static RAM Connection
Rev. 5.00, 09/03, page 271 of 760
128k × 8-bit
SRAM
D0
WE0
••••
••••
A16
A0
CS
OE
I/O7
••••
••••
••••
A0
CSn
RD
D7
••••
••••
A16
••••
SH7709S
I/O0
WE
Figure 10.9 Example of 8-Bit Data-Width Static RAM Connection
Rev. 5.00, 09/03, page 272 of 760
Wait State Control: Wait state insertion on the basic interface can be controlled by the WCR2
settings. If the WCR2 wait specification bits corresponding to a particular area are not zero, a
software wait is inserted in accordance with that specification. For details, see section 10.2.4, Wait
State Control Register 2 (WCR2).
The specified number of Tw cycles are inserted as wait cycles using the basic interface wait timing
shown in figure 10.10.
T1
Tw
T2
CKIO
A25 to A0
CSn
RD/WR
RD
Read
D31 to D0
WEn
Write
D31 to D0
BS
Figure 10.10 Basic Interface Wait Timing (Software Wait Only)
Rev. 5.00, 09/03, page 273 of 760
When software wait insertion is specified by WCR2, the external wait input WAIT signal is also
sampled. WAIT pin sampling is shown in figure 10.11. A 2-cycle wait is specified as a software
wait. Sampling is performed at the transition from the Tw state to the T2 state; therefore, if the
WAIT signal has no effect if asserted in the T 1 cycle or the first Tw cycle.
When the WAITSEL bit in the WCR1 register is set to 1, the WAIT signal is sampled at the
falling edge of the clock. If the setup time and hold times with respect to the falling edge of the
clock are not satisfied, the value sampled at the next falling edge is used.
However, the WAIT signal is ignored in the following three cases:
• A write to external address space in dual address mode with 16-byte DMA transfer
• Transfer from an external device with DACK to external address space in single address mode
with 16-byte DMA transfer
• Cache write-back access
Rev. 5.00, 09/03, page 274 of 760
Wait states inserted
by WAIT signal
T1
Tw
Tw
Tw
T2
CKIO
A25 to A0
CSn
RD/WR
RD
Read
D31 to D0
WEn
Write
D31 to D0
WAIT
BS
Figure 10.11 Basic Interface Wait State Timing (Wait State Insertion by WAIT Signal
WAITSEL = 1)
Rev. 5.00, 09/03, page 275 of 760
10.3.4
Synchronous DRAM Interface
Synchronous DRAM Direct Connection: Since synchronous DRAM can be selected by the CS
signal, physical space areas 2 and 3 can be connected using RAS and other control signals in
common. If the memory type bits (DRAMTP2–0) in BCR1 are set to 010, area 2 is ordinary
memory space and area 3 is synchronous DRAM space; if set to 011, areas 2 and 3 are both
synchronous DRAM space. Note, however, that synchronous DRAM must not be accessed when
clock ratio Iφ:Bφ = 1:1.
With the SH7709S, burst length 1 burst read/single write mode is supported as the synchronous
DRAM operating mode. A data bus width of 16 or 32 bits can be selected. A 16-bit burst transfer
is performed in a cache fill/write-back cycle, and only one access is performed in a write-through
area write or a non-cacheable area read/write.
The control signals for direct connection of synchronous DRAM are RAS3L, RAS3U, CASL,
CASU, RD/WR, CS2 or CS3, DQMUU, DQMUL, DQMLU, DQMLL, and CKE. All the signals
other than CS2 and CS3 are common to all areas, and signals other than CKE are valid and fetched
to the synchronous DRAM only when CS2 or CS3 is asserted. Synchronous DRAM can therefore
be connected in parallel to a number of areas. CKE is negated (low) only when self-refreshing is
performed, and is always asserted (high) at other times.
In the refresh cycle and mode-register write cycle, RAS3U and RAS3L or CASU and CASL are
output.
Commands for synchronous DRAM are specified by RAS3L, RAS3U, CASL, CASU, RD/WR,
and special address signals. The commands are NOP, auto-refresh (REF), self-refresh (SELF),
precharge all banks (PALL), row address strobe bank active (ACTV), read (READ), read with
precharge (READA), write (WRIT), write with precharge (WRITA), and mode register write
(MRS).
Byte specification is performed by DQMUU, DQMUL, DQMLU, and DQMLL. A read/write is
performed for the byte for which the corresponding DQM is low. In big-endian mode, DQMUU
specifies an access to address 4n, and DQMLL specifies an access to address 4n + 3. In littleendian mode, DQMUU specifies an access to address 4n + 3, and DQMLL specifies an access to
address 4n.
Figures 10.12 and 10.13 show examples of the connection of two 1M × 16-bit × 4-bank
synchronous DRAMs and one 1M × 16-bit × 4-bank synchronous DRAM, respectively.
Rev. 5.00, 09/03, page 276 of 760
64M synchronous
DRAM
(1M × 16-bit × 4-bank)
SH7709S
DQ0
DQMU
DQML
Note : "x" is U or L
••••
••••
A13
••••
A0
CLK
CKE
CS
RAS
CAS
WE
DQ15
••••
••••
••••
D16
DQMUU
DQMUL
D15
D0
DQMLU
DQMLL
••••
••••
A0
CLK
CKE
CS
RAS
CAS
WE
DQ15
••••
••••
A2
CKI0
CKE
CSn
RAS3x
CASx
RD/WR
D31
••••
••••
A13
••••
••••
A15
DQ0
DQMU
DQML
Figure 10.12 Example of 64-Mbit Synchronous DRAM Connection (32-Bit Bus Width)
Rev. 5.00, 09/03, page 277 of 760
64M synchronous DRAM
(1M × 16 bit × 4 bank)
SH7709S
•••
•••
D0
DQMLU
DQMLL
•••
•••
•••
•••
A0
CLK
CKE
CS
RAS
CAS
WE
DQ15
A1
CKIO
CKE
CSn
RAS3x
CASx
RD/WR
D15
•••
•••
A13
A12
A11
A14
A13
A12
DQ0
DQMU
DQML
Figure 10.13 Example of 64-Mbit Synchronous DRAM Connection (16-Bit Bus Width)
Address Multiplexing: Synchronous DRAM can be connected without external multiplexing
circuitry in accordance with the address multiplex specification bits AMX2-AMX0 in MCR. Table
10.13 shows the relationship between the address multiplex specification bits and the bits output at
the address pins.
A25–A17 and A0 are not multiplexed; the original values are always output at these pins.
When A0, the LSB of the synchronous DRAM address, is connected to the SH7709S, it performs
longword address specification. Connection should therefore be made in the following order: with
a 32-bit bus width, connect pin A0 of the synchronous DRAM to pin A2 of the SH7709S, then
connect pin A1 to pin A3; with a 16-bit bus width, connect pin A0 of the synchronous DRAM to
pin A1 of the SH7709S, then connect pin A1 to pin A2.
Rev. 5.00, 09/03, page 278 of 760
Table 10.13 Relationship between Bus Width, AMX Bits, and Address Multiplex Output
Setting
External Address Pins
Bus
Memory AMX AMX AMX AMX Output
Width Type
3
2
1
0
Timing
A1 to
A8
A9
32 bits 4M ×
1
16bits ×
4banks*1
Column
address
A1 to A9
A8
Row
address
A10 to A18 A19 A20 A21 A22 A23 A24*4 A25*4
A17
Column
address
A1 to A9
A8
Row
address
A10 to A18 A19 A20 A21 A22 A23*4 A24*4
A17
Column
address
A1 to A9
A8
Row
address
A9 to A17 A18 A19 A20 A21 A22*4 A23*4
A16
Column
address
A1 to A9
A8
Row
address
A10 to A18 A19 A20 A21 A22 A23*4 A24*4
A17
Column
address
A1 to A9
A8
Row
address
A9 to A17 A18 A19 A20 A21*4 A22*4 A23
A16
Column
address
A1 to A9
A8
Row
address
A11 to A19 A20 A21 A22 A23 A24*4 A25*4
A18
Column
address
A1 to A9
A8
Row
address
A10 to A18 A19 A20 A21 A22 A23*4 A24*4
A17
2M ×
0
16bits ×
4banks*2
1M ×
0
16bits ×
4banks*2
2M ×
0
8bits ×
4banks*2
512k ×
0
32bits ×
4banks*2
16 bits 8M ×
1
16bits ×
4banks*1
4M ×
1
16bits ×
4banks*2
1
1
1
1
1
1
1
0
0
0
0
1
1
0
1
1
0
1
1
0
1
A10 A11 A12 A13 A14 A15 A16
3
A10 A11 L/H* A13 A23 A24*4 A25*4
3
A10 A11 L/H* A13 A23*4 A24*4
3
A10 A11 L/H* A13 A22*4 A23*4
3
A10 A11 L/H* A13 A23*4 A24*4
3
A10 A11 L/H* A21*4 A22*4 A15
3
A10 L/H* A12 A23 A24*4 A25*4
3
A10 L/H* A12 A22 A23*4 A24*4
Rev. 5.00, 09/03, page 279 of 760
Setting
External Address Pins
Bus
Memory AMX AMX AMX AMX Output
Width Type
3
2
1
0
Timing
2M ×
0
16bits ×
4banks*2
1M ×
0
16bits ×
4banks*2
2M ×
0
8bits ×
4banks*2
1
1
1
0
0
0
1
0
1
A1 to
A8
A9
A10 A11 A12 A13 A14 A15 A16
3
A10 L/H* A12 A22*4 A23*4 A24
Column
address
A1 to A9
A8
Row
address
A10 to A18 A19 A20 A21 A22*4 A23*4 A24
A17
Column
address
A1 to A9
A8
Row
address
A 9 to A17 A18 A19 A20 A21*4 A22*4 A23
A16
Column
address
A1 to A9
A8
Row
address
A10 to A18 A19 A20 A21 A22*4 A23*4 A24
A17
3
A10 L/H* A12 A21*4 A22*4 A15
3
A10 L/H* A12 A22*4 A23*4 A24
Notes: 1. Only RAL3L or CASL is output.
2. When addresses are upper 32 Mbytes, RAS3U or CASU is output.
When addresses are lower 32 Mbytes, RAS3L or CASL is output.
3. L/H is a bit used in the command specification; it is fixed at L or H according to the
access mode.
4. Bank address specification
Rev. 5.00, 09/03, page 280 of 760
Table 10.14 Example of Correspondence between SH7709S and Synchronous DRAM
Address Pins (AMX [3:0] = 0100 (32-Bit Bus Width))
SH7709S Address Pin
Synchronous DRAM Address Pin
RAS Cycle
CAS Cycle
Function
A15
A23
A23
A13(BA1)
A14
A22
A22
A12(BA0)
A13
A21
A13
A11
Address
A12
A20
L/H
A10
Address precharge setting
A11
A19
A11
A9
Address
A10
A18
A10
A8
A9
A17
A9
A7
A8
A16
A8
A6
A7
A15
A7
A5
A6
A14
A6
A4
A5
A13
A5
A3
A4
A12
A4
A2
A3
A11
A3
A1
A2
A10
A2
A0
A1
A9
A1
Not used
A0
A0
A0
Not used
BANK select bank address
Burst Read: In the example in figure 10.15 it is assumed that four 2M × 8-bit synchronous
DRAMs are connected and a 32-bit data width is used, and the burst length is 1. Following the Tr
cycle in which ACTV command output is performed, a READ command is issued in the Tc1, Tc2,
and Tc3 cycles, and a READA command in the Tc4 cycle, and the read data is accepted at the
rising edge of the external command clock (CKIO) from cycle Td1 to cycle Td4. The Tpc cycle is
used to wait for completion of auto-precharge based on the READA command inside the
synchronous DRAM; no new access command can be issued to the same bank during this cycle,
but access to synchronous DRAM for another area is possible. In the SH7709S, the number of Tpc
cycles is determined by the TPC bit specification in MCR, and commands cannot be issued for the
same synchronous DRAM during this interval.
The example in figure 10.14 shows the basic cycle. To connect low-speed synchronous DRAM,
the cycle can be extended by setting WCR2 and MCR bits. The number of cycles from the ACTV
command output cycle, Tr, to the READ command output cycle, Tc1, can be specified by the
RCD bits in MCR, with values of 0 to 3 specifying 1 to 4 cycles, respectively. In case of 2 or more
cycles, a Trw cycle, in which an NOP command is issued for the synchronous DRAM, is inserted
between the Tr cycle and the Tc cycle. The number of cycles from READ and READA command
output cycles Tc1-Tc4 to the first read data latch cycle, Td1, can be specified as 1 to 3 cycles
Rev. 5.00, 09/03, page 281 of 760
independently for areas 2 and 3 by means of bits A2W1 and A2W0 or A3W1 and A3W0 in
WCR2. This number of cycles corresponds to the number of synchronous DRAM CAS latency
cycles.
Tr
Tc1
Tc2/Td1
Tc3/Td2
Tc4/Td3
Td4
CKIO
A25 to A16,
A13
A12
A15, A14,
A11 to A0
CS2 or CS3
RAS3x
CASx
RD/WR
DQMxx
D31 to D0
BS
Figure 10.14 Basic Timing for Synchronous DRAM Burst Read
Rev. 5.00, 09/03, page 282 of 760
Tpc
Figure 10.15 shows the burst read timing when RCD is set to 1, A3W1 and A3W0 are set to 10,
and TPC is set to 1.
The BS cycle, which is asserted for one cycle at the start of a bus cycle for normal access space, is
asserted in each of cycles Td1–Td4 in a synchronous DRAM cycle. When a burst read is
performed, the address is updated each time CAS is asserted. As the unit of burst transfer is 16
bytes, address updating is performed for A3 and A2 only (when the bus width is 16 bits, address
updating is performed for A3, A2, and A1). The order of access is as follows: in a fill operation in
the event of a cache miss, the missed data is read first, then 16-byte boundary data including the
missed data is read in wraparound mode.
Tr
Trw
Tc1
Tc2
Tc3/Td1 Tc4/Td2
Td3
Td4
Tpc
CKIO
A25 to A16,
A13
A12
A15, A14,
A11 to A0
CS2 or CS3
RAS3x
CASx
RD/WR
DQMxx
D31 to D0
BS
Figure 10.15 Synchronous DRAM Burst Read Wait Specification Timing
Rev. 5.00, 09/03, page 283 of 760
Single Read: Figure 10.16 shows the timing when a single address read is performed. As the burst
length is set to 1 in synchronous DRAM burst read/single write mode, only the required data is
output. Consequently, no unnecessary bus cycles are generated even when a cache-through area is
accessed.
Tr
Tc1
Td1
Tpc
CKIO
A25 to A16,
A13
A12
A15, A14,
A11 to A0
CS2 or CS3
RAS3x
CASx
RD/WR
DQMxx
D31 to D0
BS
Figure 10.16 Basic Timing for Synchronous DRAM Single Read
Rev. 5.00, 09/03, page 284 of 760
Burst Write: The timing chart for a burst write is shown in figure 10.17. In the SH7709S, a burst
write occurs only in the event of cache write-back or 16-byte DMAC transfer. In a burst write
operation, following the Tr cycle in which ACTV command output is performed, a WRIT
command is issued in the Tc1, Tc2, and Tc3 cycles, and a WRITA command that performs autoprecharge is issued in the Tc4 cycle. In the write cycle, the write data is output at the same time as
the write command. In case of the write with auto-precharge command, precharging of the
relevant bank is performed in the synchronous DRAM after completion of the write command,
and therefore no command can be issued for the same bank until precharging is completed.
Consequently, in addition to the precharge wait cycle, Tpc, used in a read access, cycle Trwl is
also added as a wait interval until precharging is started following the write command. Issuance of
a new command for the same bank is deferred during this interval. The number of Trwl cycles can
be specified by the TRWL bits in MCR.
Rev. 5.00, 09/03, page 285 of 760
Tr
Tc1
Tc2
Tc3
Tc4
(Trwl)
(Tpc)
CKIO
Address
upper bits
A12, A11,
A10 or A9
Address
lower bits
CSn
RD/WR
RAS3x
CASx
DQMxx
D31 to D0
(read)
BS
Figure 10.17 Basic Timing for Synchronous DRAM Burst Write
Rev. 5.00, 09/03, page 286 of 760
Single Write: The basic timing chart for write access is shown in figure 10.18. In a single write
operation, following the Tr cycle in which ACTV command output is performed, a WRITA
command that performs auto-precharge is issued in the Tc1 cycle. In the write cycle, the write
data is output at the same time as the write command. In case of the write with auto-precharge
command, precharging of the relevant bank is performed in the synchronous DRAM after
completion of the write command, and therefore no command can be issued for the same bank
until precharging is completed. Consequently, in addition to the precharge wait cycle, Tpc, used in
a read access, cycle Trwl is also added as a wait interval until precharging is started following the
write command. Issuance of a new command for the same bank is deferred during this interval.
The number of Trwl cycles can be specified by the TRWL bits in MCR.
Rev. 5.00, 09/03, page 287 of 760
Tr
Tc1
(Trwl)
(Tpc)
CKIO
Address
upper bits
A12 or A10
Address
lower bits
CSn
RD/WR
RAS3x
CASx
DQMxx
D31 to D0
BS
CKE
Figure 10.18 Basic Timing for Synchronous DRAM Single Write
Rev. 5.00, 09/03, page 288 of 760
Bank Active: The synchronous DRAM bank function is used to support high-speed accesses to
the same row address. When the RASD bit in MCR is 1, read/write command accesses are
performed using commands without auto-precharge (READ, WRIT). In this case, precharging is
not performed when the access ends. When accessing the same row address in the same bank, it is
possible to issue the READ or WRIT command immediately, without issuing an ACTV command,
in the same way as in the RAS down state in DRAM fast page mode. As synchronous DRAM is
internally divided into two or four banks, it is possible to activate one row address in each bank. If
the next access is to a different row address, a PRE command is first issued to precharge the
relevant bank, then when precharging is completed, the access is performed by issuing an ACTV
command followed by a READ or WRIT command. If this is followed by an access to a different
row address, the access time will be longer because of the precharging performed after the access
request is issued.
In a write, when auto-precharge is performed, a command cannot be issued for a period of Trwl +
Tpc cycles after issuance of the WRITA command. When bank active mode is used, READ or
WRIT commands can be issued successively if the row address is the same. The number of cycles
can thus be reduced by Trwl + Tpc cycles for each write. The number of cycles between issuance
of the precharge command and the row address strobe command is determined by the TPC bits in
MCR.
Whether faster execution speed is achieved by use of bank active mode or by use of basic access is
determined by the probability of accessing the same row address (P1), and the average number of
cycles from completion of one access to the next access (Ta). If Ta is greater than Tpc, the delay
due to the precharge wait when writing is imperceptible. In this case, the access speed for bank
active mode and basic access is determined by the number of cycles from the start of access to
issuance of the read/write command: (Tpc + Trcd) × (1 – P1) and Trcd, respectively.
There is a limit on Tras, the time for placing each bank in the active state. If there is no guarantee
that there will not be a cache hit and another row address will be accessed within the period in
which this value is maintained by program execution, it is necessary to set auto-refresh and set the
refresh cycle to no more than the maximum value of Tras. In this way, it is possible to observe the
restrictions on the maximum active state time for each bank. If auto-refresh is not used, measures
must be taken in the program to ensure that the banks do not remain active for longer than the
prescribed time.
A burst read cycle without auto-precharge is shown in figure 10.19, a burst read cycle for the same
row address in figure 10.20, and a burst read cycle for different row addresses in figure 10.21.
Similarly, a burst write cycle without auto-precharge is shown in figure 10.22, a burst write cycle
for the same row address in figure 10.23, and a burst write cycle for different row addresses in
figure 10.24.
Rev. 5.00, 09/03, page 289 of 760
A Tnop cycle, in which no operation is performed, is inserted before the Tc cycle in which the
READ command is issued in figure 10.20, but when synchronous DRAM is read, there is a twocycle latency for the DQMxx signal that performs the byte specification. If the Tc cycle were
performed immediately, without inserting a Tnop cycle, it would not be possible to perform the
DQMxx signal specification for Td1 cycle data output. This is the reason for inserting the Tnop
cycle. If the CAS latency is two cycles or longer, Tnop cycle insertion is not performed, since the
timing requirements will be met even if the DQMxx signal is set after the Tc cycle.
When bank active mode is set, if only accesses to the respective banks in the area 3 space are
considered, as long as accesses to the same row address continue, the operation starts with the
cycle in figure 10.19 or 10.22, followed by repetition of the cycle in figure 10.20 or 10.23. An
access to a different area 3 space during this time has no effect. If there is an access to a different
row address in the bank active state, after this is detected the bus cycle in figure 10.21 or 10.24 is
executed instead of that in figure 10.20 or 10.23. In bank active mode, too, all banks become
inactive after a refresh cycle or after the bus is released as the result of bus arbitration.
The bank active mode should not be used unless the bus width for all areas is 32 bits.
Rev. 5.00, 09/03, page 290 of 760
Tr
Tc1
Tc2/Td1 Tc3/Td2 Tc4/Td3
Td4
CKIO
A25 to A16,
A13 (A25 to
A16, A11)
A12 (A10)
A15, A14,
A11 to A0
(A15 to A12,
A9 to A0)
CS2 or CS3
RAS3x
CASx
RD/WR
DQMxx
D31 to D0
BS
Figure 10.19 Burst Read Timing (No Precharge)
Rev. 5.00, 09/03, page 291 of 760
Tnop
Tc1
Tc2/Td1 Tc3/Td2 Tc4/Td3
Td4
CKIO
A25 to A16,
A13 (A25 to
A16, A11)
A12 (A10)
A15, A14,
A11 to A0
(A15 to A12,
A9 to A0)
CS2 or CS3
RAS3x
CASx
RD/WR
DQMxx
D31 to D0
BS
Figure 10.20 Burst Read Timing (Same Row Address)
Rev. 5.00, 09/03, page 292 of 760
Tp
Tr
Tc1
Tc2/Td1 Tc3/Td2 Tc4/Td3
Td4
CKIO
A25 to A16,
A13 (A25 to
A16, A11)
A12 (A10)
A15, A14,
A11 to A0
(A15 to A12,
A9 to A0)
CS2 or CS3
RAS3x
CASx
RD/WR
DQMxx
D31 to D0
BS
Figure 10.21 Burst Read Timing (Different Row Addresses)
Rev. 5.00, 09/03, page 293 of 760
Tr
Tc1
Tc2
Tc3
Tc4
CKIO
A25 to A16,
A13 (A25 to
A16, A11)
A12 (A10)
A15, A14,
A11 to A0
(A15 to A12,
A9 to A0)
CS2 or CS3
RAS3x
CASx
RD/WR
DQMxx
D31 to D0
BS
Figure 10.22 Burst Write Timing (No Precharge)
Rev. 5.00, 09/03, page 294 of 760
Tc1
Tc2
Tc3
Tc4
CKIO
A25 to A16,
A13 (A25 to
A16, A11)
A12 (A10)
A15, A14,
A11 to A0
(A15 to A12,
A9 to A0)
CS2 or CS3
RAS3x
CASx
RD/WR
DQMxx
D31 to D0
BS
Figure 10.23 Burst Write Timing (Same Row Address)
Rev. 5.00, 09/03, page 295 of 760
Tp
Tr
Tc1
Tc2
Tc3
Td4
CKIO
A25 to A16,
A13 (A25 to
A16, A11)
A12 (A10)
A15, A14,
A11 to A0
(A15 to A12,
A9 to A0)
CS2 or CS3
RAS3x
CASx
RD/WR
DQMxx
D31 to D0
BS
Figure 10.24 Burst Write Timing (Different Row Addresses)
Rev. 5.00, 09/03, page 296 of 760
Refreshing: The bus state controller is provided with a function for controlling synchronous
DRAM refreshing. Auto-refreshing can be performed by clearing the RMODE bit to 0 and setting
the RFSH bit to 1 in MCR. If synchronous DRAM is not accessed for a long period, self-refresh
mode, in which the power consumption for data retention is low, can be activated by setting both
the RMODE bit and the RFSH bit to 1.
• Auto-Refreshing
Refreshing is performed at intervals determined by the input clock selected by bits CKS2-0 in
RTCSR, and the value set in RTCOR. The value of bits CKS2-0 in RTCOR should be set so as
to satisfy the refresh interval stipulation for the synchronous DRAM used. First make the
settings for RTCOR, RTCNT, and the RMODE and RFSH bits in MCR, then make the CKS2CKS0 setting. When the clock is selected by CKS2-CKS0, RTCNT starts counting up from the
value at that time. The RTCNT value is constantly compared with the RTCOR value, and if the
two values are the same, a refresh request is generated and an auto-refresh is performed. At the
same time, RTCNT is cleared to zero and the count-up is restarted. Figure 10.25 shows the
auto-refresh cycle timing.
All-bank precharging is performed in the Tp cycle, then an REF command is issued in the TRr
cycle following the interval specified by the TPC bits in MCR. After the TRr cycle, new
command output cannot be performed for the duration of the number of cycles specified by the
TRAS bits in MCR plus the number of cycles specified by the TPC bits in MCR. The TRAS
and TPC bits must be set so as to satisfy the synchronous DRAM refresh cycle time stipulation
(active/active command delay time).
Auto-refreshing is performed in normal operation, in sleep mode, and in case of a manual
reset.
Rev. 5.00, 09/03, page 297 of 760
RTCNT cleared to 0 when
RTCNT = RTCOR
RTCOR value
RTCNT
Time
H'00000000
RTCSR.CKS(2 to 0)
= 000
≠ 000
CMF
CMF flag cleared by start of
refresh cycle
External bus
Auto-refresh cycle
Figure 10.25 Auto-Refresh Operation
Rev. 5.00, 09/03, page 298 of 760
Tp
TRr
TRrw
TRrw
CKIO
CKE
CSn
RAS3U,
RAS3L
CASU,
CASL
RD/WR
Figure 10.26 Synchronous DRAM Auto-Refresh Timing
Rev. 5.00, 09/03, page 299 of 760
• Self-Refreshing
Self-refresh mode is a kind of standby mode in which the refresh timing and refresh addresses
are generated within the synchronous DRAM. Self-refreshing is activated by setting both the
RMODE bit and the RFSH bit to 1. The self-refresh state is maintained while the CKE signal
is low. Synchronous DRAM cannot be accessed while in the self-refresh state. Self-refresh
mode is cleared by clearing the RMODE bit to 0. After self-refresh mode has been cleared,
command issuance is disabled for the number of cycles specified by the TPC bits in MCR.
Self-refresh timing is shown in figure 10.27. Settings must be made so that self-refresh
clearing and data retention are performed correctly, and auto-refreshing is performed at the
correct intervals. When self-refreshing is activated from the state in which auto-refreshing is
set, or when exiting standby mode other than through a power-on reset, auto-refreshing is
restarted if RFSH is set to 1 and RMODE is cleared to 0 when self-refresh mode is cleared. If
the transition from clearing of self-refresh mode to the start of auto-refreshing takes time, this
time should be taken into consideration when setting the initial value of RTCNT. Making the
RTCNT value 1 less than the RTCOR value will enable refreshing to be started immediately.
After self-refreshing has been set, the self-refresh state continues even if the chip standby state
is entered using the SH7709S’s standby function, and is maintained even after recovery from
standby mode other than through a power-on reset. In case of a power-on reset, the bus state
controller’s registers are initialized, and therefore the self-refresh state is cleared.
Self-refreshing is performed in normal operation, in sleep mode, in standby mode, and in case
of a manual reset.
When using synchronous DRAM, use the following procedure to initiate self-refreshing.
1. Clear the refresh control bit to 0.
2. Write H'00 to the RTCNT register.
3. Set the refresh control bit and refresh mode bit to 1.
Rev. 5.00, 09/03, page 300 of 760
Tp
TRs1
(TRs2)
(TRs2)
TRs3
(Tpc)
(Tpc)
CKIO
CKE
CSn
RAS3U, RAS3L
CASU, CASL
RD/WR
Figure 10.27 Synchronous DRAM Self-Refresh Timing
• Relationship between Refresh Requests and Bus Cycle Requests
If a refresh request is generated during execution of a bus cycle, execution of the refresh is
deferred until the bus cycle is completed. If a refresh request occurs when the bus has been
released by the bus arbiter, refresh execution is deferred until the bus is acquired. If a match
between RTCNT and RTCOR occurs while a refresh is waiting to be executed, so that a new
refresh request is generated, the previous refresh request is eliminated. In order for refreshing
to be performed normally, care must be taken to ensure that no bus cycle or bus right occurs
that is longer than the refresh interval. When a refresh request is generated, the IRQOUT pin is
asserted (driven low). Therefore, normal refreshing can be performed by having the IRQOUT
pin monitored by a bus master other than the SH7709S requesting the bus, or the bus arbiter,
and returning the bus to the SH7709S. When refreshing is started, and if no other interrupt
request has been generated, the IRQOUT pin is negated (driven high).
Rev. 5.00, 09/03, page 301 of 760
Power-On Sequence: In order to use synchronous DRAM, mode setting must first be performed
after powering on. To perform synchronous DRAM initialization correctly, the bus state controller
registers must first be set, followed by a write to the synchronous DRAM mode register. In
synchronous DRAM mode register setting, the address signal value at that time is latched by a
combination of the RAS, CAS, and RD/WR signals. If the value to be set is X, the bus state
controller provides for value X to be written to the synchronous DRAM mode register by
performing a write to address H'FFFFD000 + X for area 2 synchronous DRAM, and to address
H'FFFFE000 + X for area 3 synchronous DRAM. In this operation the data is ignored, but the
mode write is performed as a byte-size access. To set burst read/single write, CAS latency 1 to 3,
wrap type = sequential, and burst length 1 supported by the SH7709S, arbitrary data is written in a
byte-size access to the following addresses.
With 32-bit bus width:
CAS latency 1
CAS latency 2
CAS latency 3
Area 2
FFFFD840
FFFFD880
FFFFD8C0
Area 3
FFFFE840
FFFFE880
FFFFE8C0
Area 2
FFFFD420
FFFFD440
FFFFD460
Area 3
FFFFE420
FFFFE440
FFFFE460
With 16-bit bus width:
CAS latency 1
CAS latency 2
CAS latency 3
Mode register setting timing is shown in figure 10.28.
As a result of the write to address H'FFFFD000 + X or H'FFFFE000 + X, a precharge all banks
(PALL) command is first issued in the TRp1 cycle, then a mode register write command is issued
in the TMw1 cycle.
Address signals, when the mode-register write command is issued, are as follows:
32-bit bus width:
A15–A9 = 0000100 (burst read and single write)
A8–A6 = CAS latency
A5 = 0 (burst type = sequential)
A4–A2 = 000 (burst length 1)
16-bit bus width:
A14–A8 = 0000100 (burst read and single write)
A7–A5 = CAS latency
A4 = 0 (burst type = sequential)
A3–A1 = 000 (burst length 1)
Rev. 5.00, 09/03, page 302 of 760
Before mode register setting, a 100 µs idle time (depending on the memory manufacturer) must be
guaranteed after powering on requested by the synchronous DRAM. If the reset signal pulse width
is greater than this idle time, there is no problem in performing mode register setting immediately.
The number of dummy auto-refresh cycles specified by the manufacturer (usually 8) or more must
be executed. This is usually achieved automatically while various kinds of initialization are being
performed after auto-refresh setting, but a way of carrying this out more dependably is to set a
short refresh request generation interval just while these dummy cycles are being executed. With
simple read or write access, the address counter in the synchronous DRAM used for autorefreshing is not initialized, and so the cycle must always be an auto-refresh cycle.
TRp1
TRp2
TRp3
TRp4
TMw1
TMw2
TMw3
TMw4
CKIO
A15 to A13
or A15 to A12
A11
A12 or A10
A9 to A2
CSn
RD/WR
RAS3U or RAS3L
CASU or CASL
D31 to D0
CKE
(High)
Figure 10.28 Synchronous DRAM Mode Write Timing
Rev. 5.00, 09/03, page 303 of 760
10.3.5
Burst ROM Interface
Setting bits A0BST1–0, A5BST1–0, and A6BST1–0 in BCR1 to a non-zero value allows burst
ROM to be connected to areas 0, 5, and 6. The burst ROM interface provides high-speed access to
ROM that has a nibble access function. The timing for nibble access to burst ROM is shown in
figure 10.29. Two wait cycles are set. Basically, access is performed in the same way as for
normal space, but when the first cycle ends the CS0 signal is not negated, and only the address is
changed before the next access is executed. When 8-bit ROM is connected, the number of
consecutive accesses can be set as 4, 8, or 16 by bits A0BST1–0, A5BST1–0, or A6BST1–0.
When 16-bit ROM is connected, 4 or 8 can be set in the same way. When 32-bit ROM is
connected, only 4 can be set.
WAIT pin sampling is performed in the first access if one or more wait states are set, and is
always performed in the second and subsequent accesses.
The second and subsequent access cycles also comprise two cycles when a burst ROM setting is
made and the wait specification is 0. The timing in this case is shown in figure 10.30.
However, the WAIT signal is ignored in the following three cases:
• A write to external address space in dual address mode with 16-byte DMA transfer
• Transfer from an external device with DACK to external address space in single address mode
with 16-byte DMA transfer
• Cache write-back access
Rev. 5.00, 09/03, page 304 of 760
T1
TW
TW
TB2
TB1
TW
TB2
TB1
T2
CKIO
A25 to A4
A3 to A0
CSn
RD/WR
RD
D31 to
D0
BS
WAIT
Note: For a write cycle, a basic bus cycle (write cycle) is performed.
Figure 10.29 Burst ROM Wait Access Timing
Rev. 5.00, 09/03, page 305 of 760
T1
TB2
TB1
TB2
TB1
TB2
TB1
CKIO
A25 to A4
A3 to A0
CSn
RD/WR
RD
D31 to D0
BS
WAIT
Note: For a write cycle, a basic bus cycle (write cycle) is performed.
Figure 10.30 Burst ROM Basic Access Timing
Rev. 5.00, 09/03, page 306 of 760
T2
10.3.6
PCMCIA Interface
In the SH7709S, setting the A5PCM bit in BCR1 to 1 makes the bus interface for physical space
area 5 an IC memory card and I/O card interface as stipulated in JEIDA version 4.2
(PCMCIA2.1). Setting the A6PCM bit to 1 makes the bus interface for physical space area 6 an IC
memory card and I/O card interface as stipulated in JEIDA version 4.2.
When the PCMCIA interface is used, a bus size of 8 or 16 bits can be set by bits A5SZ1 and
A5SZ0, or A6SZ1 and A6SZ0, in BCR2.
Figure 10.31 shows an example of PCMCIA card connection to the SH7709S. To enable active
insertion of the PCMCIA cards (i.e. insertion or removal while system power is being supplied), a
3-state buffer must be connected between the SH7709S’s bus interface and the PCMCIA cards.
As operation in big-endian mode is not explicitly stipulated in the JEIDA/PCMCIA specifications,
the PCMCIA interface for the SH7709S in big-endian mode is stipulated independently.
However, the WAIT signal is ignored in the following three cases:
• A write to external address space in dual address mode with 16-byte DMA transfer
• Transfer from an external device with DACK to external address space in single address mode
with 16-byte DMA transfer
• Cache write-back access
Rev. 5.00, 09/03, page 307 of 760
A24 to A0
A25 to A0
D15 to D0
G
D7 to D0
RD/WR
CE1B/(CS6)
CE1A/(CS5)
CE2B
CE2A
D15 to D0
G
DIR
D15 to D8
PC card
(memory/IO)
G
DIR
SH7709S
RD
WE1
ICIORD
ICIOWR
CE1
CE2
OE
WE/PGM
(IORD)
(IOWR)
G
WAIT
WAIT
IOIS16
(IOIS16)
Card
detection
circuit
Output
port
CD1, CD2
A25 to A0
G
D7 to D0
D15 to D0
G
DIR
D15 to D8
PC card
(memory/IO)
G
DIR
CE1
CE2
OE
WE/PGM
G
WAIT
Card
detection
circuit
Figure 10.31 Example of PCMCIA Interface
Rev. 5.00, 09/03, page 308 of 760
CD1, CD2
Memory Card Interface Basic Timing: Figure 10.32 shows the basic timing for the PCMCIA IC
memory card interface. When physical space areas 5 and 6 are designated as PCMCIA interface
areas, bus accesses are automatically performed as IC memory card interface accesses.
With a high external bus frequency (CKIO), the setup and hold times for the address (A24–A0),
card enable (CS5, CE2A, CS6, CE2B), and write data (D15–D0) in a write cycle, become
insufficient with respect to RD and WR (the WE pin in the SH7709S). The SH7709S provides for
this by enabling setup and hold times to be set for physical space areas 5 and 6 in the PCR register.
Also, software waits by means of a WCR2 register setting and hardware waits by means of the
WAIT pin can be inserted in the same way as for the basic interface. Figure 10.33 shows the
PCMCIA memory bus wait timing.
Rev. 5.00, 09/03, page 309 of 760
Tpcm1
Tpcm2
CKIO
A25 to A0
CExx
RD/WR
RD
(read)
D15 to D0
(read)
WE
(write)
D15 to D0
(write)
BS
Figure 10.32 Basic Timing for PCMCIA Memory Card Interface
Rev. 5.00, 09/03, page 310 of 760
Tpcm0
Tpcm0w
Tpcm1
Tpcm1w Tpcm1w
Tpcm2
Tpcm2w
CKIO
A25 to A0
CExx
RD/WR
RD
(read)
D15 to D0
(read)
WE
(write)
D15 to D0
(write)
BS
WAIT
Figure 10.33 Wait Timing for PCMCIA Memory Card Interface
Rev. 5.00, 09/03, page 311 of 760
Memory Card Interface Burst Timing: In the SH7709S, when the IC memory card interface is
selected, page mode burst access mode can be used, for read access only, by setting bits A5BST1
and A5BST0 in BCR1 for physical space area 5, or bits A6BST1 and A6BST0 in BCR1 for area
6. This burst access mode is not stipulated in JEIDA version 4.2 (PCMCIA2.1), but allows highspeed data access using ROM provided with a burst mode, etc.
Burst access mode timing is shown in figures 10.34 and 10.35.
Tpcm1
Tpcm2
Tpcm1
Tpcm2
Tpcm1
Tpcm2
Tpcm1
Tpcm2
CKIO
A25 to A4
A3 to A0
CExx
RD/WR
RD
(read)
D15 to D0
(read)
BS
Figure 10.34 Basic Timing for PCMCIA Memory Card Interface Burst Access
Rev. 5.00, 09/03, page 312 of 760
Tpcm0
Tpcm1 Tpcm1w Tpcm1w Tpcm1w Tpcm2
Tpcm1 Tpcm1w
Tpcm2 Tpcm2w
CKIO
A25 to A4
A3 to A0
CExx
RD/WR
RD
(read)
D15 to D0
(read)
BS
WAIT
Figure 10.35 Wait Timing for PCMCIA Memory Card Interface Burst Access
Rev. 5.00, 09/03, page 313 of 760
When the entire 32-Mbyte memory space is used as IC memory card interface space, the common
memory/attribute memory switching signal REG is generated using a port, etc. If 16 Mbytes or
less of memory space is sufficient, using 16 Mbytes of memory space as common memory space
and 16 Mbytes as attribute memory space enables the A24 pin to be used for the REG signal.
32-Mbyte capacity (REG = I/O port)
Area 5: H'14000000
Area 5: H'16000000
Area 6: H'18000000
Area 6: H'1A000000
Common memory/
attribute memory
I/O space
Common memory/
attribute memory
I/O space
Up to 16-Mbyte capacity (REG = A24)
Area 5: H'14000000
Attribute memory
Area 5: H'15000000
Common memory
Area 5: H'16000000
I/O space
H'17000000
Area 6: H'18000000
Attribute memory
Area 6: H'19000000
Common memory
Area 6: H'1A000000
I/O space
H'1B000000
Figure 10.36 PCMCIA Space Allocation
Rev. 5.00, 09/03, page 314 of 760
I/O Card Interface Timing: Figures 10.37 and 10.38 show the timing for the PCMCIA I/O card
interface.
Switching between the I/O card interface and the IC memory card interface is performed
according to the accessed address. When PCMCIA is designed for physical space area 5, the bus
access is automatically performed as an I/O card interface access when a physical address from
H'16000000 to H'17FFFFFF is accessed. When PCMCIA is designated for physical space area 6,
the bus access is automatically performed as an I/O card interface access when a physical address
from H'1A000000 to H'1BFFFFFF is accessed.
When accessing a PCMCIA I/O card, the access should be performed using a non-cacheable area
in virtual space (P2 or P3 space) or an area specified as non-cacheable by the MMU.
When an I/O card interface access is made to a PCMCIA card in little-endian mode, dynamic
sizing of the I/O bus width is possible using the IOIS16 pin. When a 16-bit bus width is set for are
5 or area 6, if the IOIS16 signal is high during a word-size I/O bus cycle, the I/O port is
recognized as being 8 bits in width. In this case, a data access for only 8 bits is performed in the
I/O bus cycle being executed, followed automatically by a data access for the remaining 8 bits.
Figure 10.39 shows the basic timing for dynamic bus sizing.
In big-endian mode, the IOIS16 signal is not supported, and should be fixed low.
Rev. 5.00, 09/03, page 315 of 760
Tpci1
Tpci2
CKIO
A25 to A0
CExx
RD/WR
ICIORD
(read)
D15 to D0
(read)
ICIOWR
(write)
D15 to D0
(write)
BS
Figure 10.37 Basic Timing for PCMCIA I/O Card Interface
Rev. 5.00, 09/03, page 316 of 760
Tpci0
Tpci0w
Tpci1
Tpci1w
Tpci1w
Tpci2
Tpci2w
CKIO
A25 to A0
CExx
RD/WR
ICIORD
(read)
D15 to D0
(read)
ICIOWR
(write)
D15 to D0
(write)
BS
WAIT
IOIS16
Figure 10.38 Wait Timing for PCMCIA I/O Card Interface
Rev. 5.00, 09/03, page 317 of 760
Tpci0
Tpci1 Tpci1w Tpci2
Tpci1
Tpci1w Tpci2 Tpci2w
CKIO
A25 to A1
A0
CExx
RD/WR
ICIORD
(read)
D15 to D0
(read)
ICIOWR
(write)
D15 to D0
(write)
BS
WAIT
IOIS16
Figure 10.39 Dynamic Bus Sizing Timing for PCMCIA I/O Card Interface
Rev. 5.00, 09/03, page 318 of 760
10.3.7
Waits between Access Cycles
A problem associated with higher external memory bus operating frequencies is that data buffer
turn-off on completion of a read from a low-speed device may be too slow, causing a collision
with data in the next access. This results in lower reliability or incorrect operation. To avoid this
problem, a data collision prevention feature has been provided. This memorizes the preceding
access area and the kind of read/write. If there is a possibility of a bus collision when the next
access is started, a wait cycle is inserted before the access cycle thus preventing a data collision.
There are two cases in which a wait cycle is inserted: when an access is followed by an access to a
different area, and when a read access is followed by a write access from the SH7709S. When the
SH7709S performs consecutive write cycles, the data transfer direction is fixed (from the
SH7709S to other memory) and there is no problem. With read accesses to the same area, in
principle, data is output from the same data buffer, and wait cycle insertion is not performed. Bits
AnIW1 and AnIW0 (n = 0, 2–6) in WCR1 specify the number of idle cycles to be inserted
between access cycles when a physical space area access is followed by an access to another area,
or when the SH7709S performs a write access after a read access to physical space area n. If there
is originally space between accesses, the number of idle cycles inserted is the specified number of
idle cycles minus the number of empty cycles.
Waits are not inserted between accesses when bus arbitration is performed, since empty cycles are
inserted for arbitration purposes.
Rev. 5.00, 09/03, page 319 of 760
T1
T2
Twait
T1
T2
Twait
T1
T2
CKIO
A25 to A0
CSm
CSn
BS
RD/WR
RD
D31 to D0
Area m read
Area n space read
Area n space write
Area m inter-access wait specification
Area n inter-access wait specification
Figure 10.40 Waits between Access Cycles
10.3.8
Bus Arbitration
When a bus release request (BREQ) is asserted from an external device, buses are released after
the bus cycle being executed is completed and a bus grant signal (BACK) is output. The bus is not
released during burst transfers for cache fills or write-back, or TAS instruction execution between
the read cycle and write cycle. Bus arbitration is not executed in multiple bus cycles that are
generated when the data bus width is shorter than the access size; i.e. in the bus cycles when
longword access is executed for the 8-bit memory. At the negation of BREQ, BACK is negated
and bus use is restarted. See Appendix A.1, Pin States, for the pin states when the bus is released.
The SH7709S sometimes needs to retrieve a bus it has released. For example, when memory
generates a refresh request or an interrupt request internally, the SH7709S must perform the
appropriate processing. The SH7709S has a bus request signal (IRQOUT) for this purpose. When
it must retrieve the bus, it asserts the IRQOUT signal. Devices asserting an external bus release
request receive the assertion of the IRQOUT signal and negate the BREQ signal to release the bus.
The SH7709S retrieves the bus and carries out the processing.
Rev. 5.00, 09/03, page 320 of 760
IRQOUT Pin Assertion Conditions:
• When a memory refresh request has been generated but the refresh cycle has not yet begun
• When an interrupt is generated with an interrupt request level higher than the setting of the
interrupt mask bits (I3–I0) in the status register (SR). (This does not depend on the SR.BL bit.)
10.3.9
Bus Pull-Up
With the SH7709S, address pin pull-up can be performed when the bus is released by setting the
PULA bit in BCR1 to 1. The address pins are pulled up for a 4-clock period after BACK is
asserted. Figure 10.41 shows the address pin pull-up timing. Similarly, data pin pull-up can be
performed by setting the PULD bit in BCR1 to 1. The data pins should be pulled up when the data
bus is not in use. The data pin pull-up timing for a read cycle is shown in figure 10.42, and the
timing for a write cycle in figure 10.43.
CKIO
A25 to A0
Pull-up
Hi-Z
BACK
Figure 10.41 Pull-Up Timing for Pins A25 to A0
Rev. 5.00, 09/03, page 321 of 760
CKIO
D31 to D0
Pull-up
Pull-up
RD
CSn
Figure 10.42 Pull-Up Timing for Pins D31 to D0 (Read Cycle)
CKIO
D31 to D0
Pull-up
Pull-up
WEn
CSn
Figure 10.43 Pull-Up Timing for Pins D31 to D0 (Write Cycle)
Rev. 5.00, 09/03, page 322 of 760
10.3.10 MCS[0] to MCS[7] Pin Control
The SH7709S is provided with pins MCS[0]–MCS[7] as dedicated CS pins for the ROM
connected to area 0 or 2. Assertion of MCS[0]–MCS[7] is controlled by settings in MCSCR0–
MCSCR7. This enables 32-, 64-, 128-, or 256-Mbit memory to be connected to area 0 or area 2.
However, only CS2/0 = 0 (area 0) should be used for MCSCR0. Table 10.15 shows MCSCR0–
MCSCR7 settings and MCS[0]–MCS[7] assertion conditions.
As the MCS[0]–MCS[7] pins are multiplexed as the PTC0–PTC7 pins, when using these pins as
MCS[0]–MCS[7], the corresponding bits in the PCCR register should be set to “other function.”
When CS2/0 = 0 in the MCSCR0 and when the PTC0 pin is switched to MCS[0] (when
PCOMD1–PCOMD0 are set to “other function”), the CS0 pin is also switched to MCS[0].
As port register writes operate on the peripheral clock, they take time compared with instruction
execution by the CPU operating on the high-speed internal clock. Therefore, if an instruction that
accesses MCS[1] to MCS[7] is located several instructions after an instruction that switches port C
to MCS, the switch from PTC[n] to MCSn and from CS0 to MCS[0] may not be performed
correctly.
To prevent this problem, the following switching procedure should be used.
• When the program runs with cache on
(1) To switch port C to MCS, set the corresponding bits in the PCCR register to 00 ("other
function").
(2) Read the PCCR register and check whether the set value is read. Repeat until the set value is
read.
(3) Perform a dummy read from non-cacheable CS0 space (e.g. address H'A0000000). This will
result in an access to the CS0 space, and immediately afterward, CS0 will be switched to
MCS[0], and port C[n] will be switched to MCS[n].
(4) Access can now be made to the MCS[1] to MCS[7] spaces.
• When the program runs in MCS[0] space with cache off
(1) Set the PCCR register as in (1) above.
(2) Place at least three NOP instructions after the instruction in (1). As a result, when the PCCR
register is rewritten, an access to the CS0 space will be generated, and immediately afterward,
CS0 will be switched to MCS[0], and port C[n] will be switched to MCS[n].
(3) Access can now be made to the MCS[1] to MCS[7] spaces.
Rev. 5.00, 09/03, page 323 of 760
Table 10.15 MCSCRx Settings and MCS[x] Assertion Conditions (x: 0–7)
MCS[x] Assertion Conditions
MCSCRx Settings
CS2/0 CAP1 CAP0 A25
0
1
1
0
0
1
0
1
0
A24
A23
A22
CS0
CS2
Address Bus A [25:0]
Notes
0
—
—
—
L
H
H'0000000 to H'1FFFFFF 256-Mbit ROM
1
—
—
—
L
H
H'2000000 to H'3FFFFFF
0
0
—
—
L
H
H'0000000 to H'0FFFFFF 128-Mbit ROM
0
1
—
—
L
H
H'1000000 to H'1FFFFFF
1
0
—
—
L
H
H'2000000 to H'2FFFFFF
1
1
—
—
L
H
H'3000000 to H'3FFFFFF
0
0
0
—
L
H
H'0000000 to H'07FFFFF 64-Mbit ROM
0
0
1
—
L
H
H'0800000 to H'0FFFFFF
0
1
0
—
L
H
H'1000000 to H'17FFFFF
0
1
1
—
L
H
H'1800000 to H'1FFFFFF
1
0
0
—
L
H
H'2000000 to H'27FFFFF
1
0
1
—
L
H
H'2800000 to H'2FFFFFF
1
1
0
—
L
H
H'3000000 to H'37FFFFF
1
1
1
—
L
H
H'3800000 to H'3FFFFFF
0
0
0
0
L
H
H'0000000 to H'03FFFFF 32-Mbit ROM
0
0
0
1
L
H
H'0400000 to H'07FFFFF
0
0
1
0
L
H
H'0800000 to H'0BFFFFF
0
0
1
1
L
H
H'0C00000 to H'0FFFFFF
0
1
0
0
L
H
H'1000000 to H'13FFFFF
0
1
0
1
L
H
H'1400000 to H'17FFFFF
0
1
1
0
L
H
H'1800000 to H'1BFFFFF
0
1
1
1
L
H
H'1C00000 to H'1FFFFFF
1
0
0
0
L
H
H'2000000 to H'23FFFFF
1
0
0
1
L
H
H'2400000 to H'27FFFFF
1
0
1
0
L
H
H'2800000 to H'2BFFFFF
1
0
1
1
L
H
H'2C00000 to H'2FFFFFF
1
1
0
0
L
H
H'3000000 to H'33FFFFF
1
1
0
1
L
H
H'3400000 to H'37FFFFF
1
1
1
0
L
H
H'3800000 to H'3BFFFFF
1
1
1
1
L
H
H'3C00000 to H'3FFFFFF
Rev. 5.00, 09/03, page 324 of 760
MCS[x] Assertion Conditions
MCSCRx Settings
CS2/0 CAP1 CAP0 A25
A24
A23
A22
CS0
CS2
Address Bus A[25:0]
1
—
—
—
H
L
H'0000000 to H'1FFFFFF 256-Mbit ROM
Notes
1
1
0
1
—
—
—
H
L
H'2000000 to H'3FFFFFF
1
0
0
0
—
—
H
L
H'0000000 to H'0FFFFFF 128-Mbit ROM
0
1
—
—
H
L
H'1000000 to H'1FFFFFF
1
0
—
—
H
L
H'2000000 to H'2FFFFFF
1
1
—
—
H
L
H'3000000 to H'3FFFFFF
0
0
0
—
H
L
H'0000000 to H'07FFFFF 64-Mbit ROM
0
0
1
—
H
L
H'0800000 to H'0FFFFFF
0
1
0
—
H
L
H'1000000 to H'17FFFFF
0
1
1
—
H
L
H'1800000 to H'1FFFFFF
1
0
0
—
H
L
H'2000000 to H'27FFFFF
1
0
1
—
H
L
H'2800000 to H'2FFFFFF
1
1
0
—
H
L
H'3000000 to H'37FFFFF
0
0
1
0
1
1
1
—
H
L
H'3800000 to H'3FFFFFF
0
0
0
0
H
L
H'0000000 to H'03FFFFF 32-Mbit ROM
0
0
0
1
H
L
H'0400000 to H'07FFFFF
0
0
1
0
H
L
H'0800000 to H'0BFFFFF
0
0
1
1
H
L
H'0C00000 to H'0FFFFFF
0
1
0
0
H
L
H'1000000 to H'13FFFFF
0
1
0
1
H
L
H'1400000 to H'17FFFFF
0
1
1
0
H
L
H'1800000 to H'1BFFFFF
0
1
1
1
H
L
H'1C00000 to H'1FFFFFF
1
0
0
0
H
L
H'2000000 to H'23FFFFF
1
0
0
1
H
L
H'2400000 to H'27FFFFF
1
0
1
0
H
L
H'2800000 to H'2BFFFFF
1
0
1
1
H
L
H'2C00000 to H'2FFFFFF
1
1
0
0
H
L
H'3000000 to H'33FFFFF
1
1
0
1
H
L
H'3400000 to H'37FFFFF
1
1
1
0
H
L
H'3800000 to H'3BFFFFF
1
1
1
1
H
L
H'3C00000 to H'3FFFFFF
Rev. 5.00, 09/03, page 325 of 760
Rev. 5.00, 09/03, page 326 of 760
Section 11 Direct Memory Access Controller (DMAC)
11.1
Overview
The SH7709S includes a four-channel direct memory access controller (DMAC). The DMAC can
be used in place of the CPU to perform high-speed transfers between external devices that have
DACK (transfer request acknowledge signal), external memory, memory-mapped external
devices, and on-chip peripheral modules (IrDA, SCIF, A/D converter, and D/A converter). Using
the DMAC reduces the burden on the CPU and increases overall operating efficiency.
11.1.1
Features
The DMAC has the following features.
• Four channels
• 4-GB address space in the architecture
• 16-byte transfer (In 16-byte transfer, four 32-bit reads are executed, followed by four 32-bit
writes.)
• Choice of 8-bit, 16-bit, 32-bit, or 16-byte transfer data length
• 16 Mbytes (16,777,216 transfers)
• Address mode: Dual address mode and single address mode are supported. In addition, direct
address transfer mode or indirect address transfer mode can be selected.
 Dual address mode transfer: Both the transfer source and transfer destination are accessed
by address. Dual address mode has direct address transfer mode and indirect address
transfer mode.
Direct address transfer mode: The values specified in the DMAC registers indicates the
transfer source and transfer destination. Two bus cycles are required for one data transfer.
Indirect address transfer mode: Data is transferred with the address stored prior to the
address specified in the transfer source address in the DMAC. Other operations are the
same as those of direct address transfer mode. This function is only available in channel 3.
Four bus cycles are required for one data transfer.
 Single address mode transfer: Either the transfer source or transfer destination peripheral
device is accessed (selected) by means of the DACK signal, and the other device is
accessed by address. One transfer unit of data is transferred in one bus cycle.
• Channel functions: The transfer mode that can be specified depends on the channel:
 Channel 0: External request can be accepted.
 Channel 1: External request can be accepted.
 Channel 2: This channel has a source address reload function, which reloads a source
address every four transfers.
Rev. 5.00, 09/03, page 327 of 760
 Channel 3: In this channel, direct address mode or indirect address transfer mode can be
specified.
• Reload function: The value that was specified in the source address register can be
automatically reloaded every four DMA transfers. This function is only available in channel 2.
• Transfer requests
 External request (From two DREQ pins (channels 0 and 1 only). DREQ can be detected
either by the falling edge or by low level.)
 On-chip module request (Requests from on-chip peripheral modules such as serial
communications interface (IrDA and SCIF), A/D converter (A/D) and a timer (CMT). This
request can be accepted in all the channels.)
 Auto request (The transfer request is generated automatically within the DMAC.)
• Selectable bus modes: Cycle-steal mode or burst mode
• Selectable channel priority levels:
Fixed mode: The channel priority is fixed.
Round-robin mode: The priority of the channel in which the execution request was accepted is
made the lowest.
• Interrupt request: An interrupt request to the CPU can be generated after the specified number
of transfers.
Rev. 5.00, 09/03, page 328 of 760
11.1.2
Block Diagram
Figure 11.1 shows a block diagram of the DMAC.
Internal bus
On-chip
peripheral
module
Peripheral bus
DMAC module
Iteration
control
SARn
Register
control
DARn
DMATCRn
Start-up
control
CHCRn
DMAOR
DREQ0, DREQ1
IrDA, SCIF
A/D converter
CMT
DEIn
Request
priority
control
DACK0, DACK1
DRAK0, DRAK1
External
ROM
Bus interface
External
RAM
External I/O
(memory
mapped)
External I/O
(with
acknowledge)
Bus state
controller
Legend
DMAOR: DMAC operation register
DMAC source address register
SARn:
DMAC destination address register
DARn:
DMATCRn: DMAC transfer count register
CHCRn: DMAC channel control register
DMA transfer-end interrupt request to
DEIn:
CPU
n = 0 to 3
Figure 11.1 Block Diagram of DMAC
Rev. 5.00, 09/03, page 329 of 760
11.1.3
Pin Configuration
Table 11.1 shows the DMAC pins.
Table 11.1 DMAC Pins
Channel
Name
Symbol
I/O
Function
0
DMA transfer request
DREQ0
I
DMA transfer request input from
external device to channel 0
DMA transfer request
acceptance
DACK0
O
Strobe output to an external I/O upon
DMA transfer request from external
device to channel 0
DMA request
acknowledge
DRAK0
O
Output showing that DREQ0 has been
accepted
DMA transfer request
DREQ1
I
DMA transfer request input from
external device to channel 1
DMA transfer request
acceptance
DACK1
O
Strobe output to an external I/O upon
DMA transfer request from external
device to channel 1
DMA request
acknowledge
DRAK1
O
Output showing that DREQ1 has been
accepted
1
Rev. 5.00, 09/03, page 330 of 760
11.1.4
Register Configuration
Table 11.2 summarizes the DMAC registers. The DMAC has a total of 17 registers: each channel
has four registers, and one overall DMAC control register.
Table 11.2 DMAC Registers
Channel Name
Abbreviation
R/W
Initial Value Address
Register Access
Size
Size
0
DMA source address
register 0
SAR0
R/W
Undefined
H'04000020
(H'A4000020)*4
32
16, 32*2
DMA destination
address register 0
DAR0
R/W
Undefined
H'04000024
(H'A4000024)*4
32
16, 32*2
DMA transfer count
register 0
DMATCR0
R/W
Undefined
H'04000028
(H'A4000028)*4
24
16, 32*3
DMA channel control
register 0
CHCR0
R/W*1 H'00000000
H'0400002C
32
(H'A400002C)*4
8, 16, 32*2
DMA source address
register 1
SAR1
R/W
Undefined
H'04000030
(H'A4000030)*4
32
16, 32*2
DMA destination
address register 1
DAR1
R/W
Undefined
H'04000034
(H'A4000034)*4
32
16, 32*2
DMA transfer count
register 1
DMATCR1
R/W
Undefined
H'04000038
(H'A4000038)*4
24
16, 32*3
DMA channel control
register 1
CHCR1
R/W*1 H'00000000
H'0400003C
32
(H'A400003C)*4
8, 16, 32*2
DMA source address
register 2
SAR2
R/W
Undefined
H'04000040
(H'A4000040)*4
32
16, 32*2
DMA destination
address register 2
DAR2
R/W
Undefined
H'04000044
(H'A4000044)*4
32
16, 32*2
DMA transfer count
register 2
DMATCR2
R/W
Undefined
H'04000048
(H'A4000048)*4
24
16, 32*3
DMA channel control
register 2
CHCR2
R/W*1 H'00000000
1
2
H'0400004C
32
(H'A400004C)*4
8, 16, 32*2
Rev. 5.00, 09/03, page 331 of 760
Channel Name
Abbreviation
R/W
Initial Value Address
Register Access
Size
Size
3
DMA source address
register 3
SAR3
R/W
Undefined
H'04000050
(H'A4000050)*4
32
16, 32*2
DMA destination
address register 3
DAR3
R/W
Undefined
H'04000054
(H'A4000054)*4
32
16, 32*2
DMA transfer count
register 3
DMATCR3
R/W
Undefined
H'04000058
(H'A4000058)*4
24
16, 32*3
DMA channel control
register 3
CHCR3
R/W*1 H'00000000
H'0400005C
32
(H'A400005C)*4
8, 16, 32*2
R/W*1 H'0000
H'04000060
(H'A4000060)*4
8, 16*2
Shared
DMA operation register DMAOR
16
Notes: These registers are located in area 1 of physical space. Therefore, when the cache is on,
either access these registers from the P2 area of logical space or else make an appropriate
setting using the MMU so that these registers are not cached.
1. Only 0 can be written to bit 1 of CHCR0 to CHCR3, and bits 1 and 2 of DMAOR to clear
the flag after 1 is read.
2. If 16-bit access is used on SAR0 to SAR3, DAR0 to DAR3, and CHCR0 to CHCR3, the
value in the 16 bits that were not accessed is retained.
3. DMATCR comprises the 24 bits from bit 0 to bit 23. The upper 8 bits, bits 24 to 31,
cannot be written with 1 and are always read as 0.
4. When address translation by the MMU does not apply, the address in parentheses
should be used.
Rev. 5.00, 09/03, page 332 of 760
11.2
Register Descriptions
11.2.1
DMA Source Address Registers 0–3 (SAR0–SAR3)
DMA source address registers 0–3 (SAR0–SAR3) are 32-bit readable/writable registers that
specify the source address of a DMA transfer. During a DMA transfer, these registers indicate the
next source address.
To transfer data in 16 bits or in 32 bits, specify a 16-bit or 32-bit address boundary address. When
transferring data in 16-byte units, a 16-byte boundary (address 16n) must be set for the source
address value. Operation is not guaranteed if other addresses are specified.
An undefined value will be returned in a reset. The previous value is retained in standby mode.
Bit:
31
30
29
28
27
26
25
24
Initial value:
—
—
—
—
—
—
—
—
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
23
22
21
20
R/W:
Bit:
…
0
…
Initial value:
R/W:
—
—
—
—
…
—
R/W
R/W
R/W
R/W
…
R/W
Rev. 5.00, 09/03, page 333 of 760
11.2.2
DMA Destination Address Registers 0–3 (DAR0–DAR3)
DMA destination address registers 0–3 (DAR0–DAR3) are 32-bit readable/writable registers that
specify the destination address of a DMA transfer. These registers include a count function, and
during a DMA transfer, these registers indicate the next destination address.
To transfer data in 16-bit or 32-bit units, make sure to specify a destination address with a 16-byte
boundary (16n address).
An undefined value will be returned in a reset. The previous value is retained in standby mode.
Bit:
31
30
29
28
27
26
25
24
Initial value:
—
—
—
—
—
—
—
—
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
23
22
21
20
R/W:
Bit:
…
0
…
Initial value:
R/W:
—
—
—
—
…
—
R/W
R/W
R/W
R/W
…
R/W
Rev. 5.00, 09/03, page 334 of 760
11.2.3
DMA Transfer Count Registers 0–3 (DMATCR0–DMATCR3)
DMA transfer count registers 0–3 (DMATCR0–DMATCR3) are 24-bit readable/writable registers
that specify the DMA transfer count (bytes, words, or longwords). The number of transfers is 1
when the setting is H'000001, and 16,777,216 (the maximum) when H'000000 is set. During a
DMA transfer, these registers indicate the remaining number of transfers.
In 16-byte transfer, one 16-byte transfer (128 bits) is counted as one.
Writing to upper eight bits in DMATCR is invalid; 0s are read if these bits are read. The write
value should always be 0.
An undefined value will be returned in a reset. The previous value is retained in standby mode.
Bit:
31
30
29
28
27
26
25
24
Initial value:
—
—
—
—
—
—
—
—
R/W:
R
R
R
R
R
R
R
R
Bit:
23
22
21
20
...
0
...
Initial value:
R/W:
—
—
—
—
...
—
R/W
R/W
R/W
R/W
...
R/W
Rev. 5.00, 09/03, page 335 of 760
11.2.4
DMA Channel Control Registers 0–3 (CHCR0–CHCR3)
DMA channel control registers 0–3 (CHCR0–CHCR3) are 32-bit readable/writable registers that
specify the operation mode, transfer method, etc., for each channel.
Bit 20 is only used in CHCR3; it is not used in CHCR0 to CHCR2. Consequently, writing to this
bit is invalid in CHCR0 to CHCR2; 0 is read if this bit is read. Bit 19 is only used in CHCR2; it is
not used in CHCR0, CHCR1, and CHCR3. Consequently, writing to this bit is invalid in CHCR0,
CHCR1, and CHCR3; 0 is read if this bit is read. Bits 6 and 16 to 18 are only used in CHCR0 and
CHCR1; they are not used in CHCR2 and CHCR3. Consequently, writing to these bits is invalid
in CHCR2 and CHCR3; 0s are read if these bits are read.
These register values are initialized to 0 in a reset. The previous value is retained in standby mode.
Bit:
31
...
21
20
19
18
17
16
—
...
—
DI
RO
RL
AM
AL
Initial value:
0
...
0
0
R/W:
R
...
R
Bit:
15
14
13
12
11
10
9
8
DM1
DM0
SM1
SM0
RS3
RS2
RS1
RS0
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
7
6
5
4
3
2
1
0
—
DS
TM
TS1
TS0
IE
TE
DE
0
0
0
0
0
0
0
0
R
2
(R/W)*
R/W
1
R/(W)*
R/W
Initial value:
R/W:
Bit:
Initial value:
R/W:
R/W
0
0
0
0
2
2
2
2
2
*
*
*
*
(R/W)
(R/W)
(R/W)
(R/W)
(R/W)*
R/W
R/W
Notes: 1. Only 0 can be written to the TE bit after 1 is read.
2. The DI, RO, RL, AM, AL, and DS bits are not included in some channels.
Rev. 5.00, 09/03, page 336 of 760
Bits 31 to 21—Reserved: These bits are always read as 0. The write value should always be 0.
Bit 20—Direct/Indirect Selection (DI): Selects direct address mode or indirect address mode in
channel 3.
This bit is only valid in CHCR3. Writing to this bit is invalid in CHCR0 to CHCR2; 0 is read if
this bit is read. The write value should always be 0. When using 16-byte transfer, direct address
mode must be specified. Operation is not guaranteed if indirect address mode is specified.
Bit 20: DI
Description
0
Direct address mode operation for channel 3
1
Indirect address mode operation for channel 3
(Initial value)
Bit 19—Source Address Reload Bit (RO): Selects whether the source address initial value is
reloaded in channel 2.
This bit is only valid in CHCR2. Writing to this bit is invalid in CHCR0, CHCR1, and CHCR3; 0
is read if this bit is read. The write value should always be 0. When using 16-byte transfer, this bit
must be cleared to 0, specifying non-reloading. Operation is not guaranteed if reloading is
specified.
Bit 19: RO
Description
0
Source address is not reloaded
1
Source address is reloaded
(Initial value)
Bit 18—Request Check Level Bit (RL): Specifies whether DRAK (DREQ acknowledge) signal
output is active-high or active-low.
This bit is only valid in CHCR0 and CHCR1. Writing to this bit is invalid in CHCR2 and
CHCR3; 0 is read if this bit is read. The write value should always be 0.
Bit 18: RL
Description
0
Active-low DRAK output
1
Active-high DRAK output
(Initial value)
Rev. 5.00, 09/03, page 337 of 760
Bit 17—Acknowledge Mode Bit (AM): Specifies whether DACK is output in the data read cycle
or in the data write cycle in dual address mode.
DACK is always output in single address mode, regardless of this bit specification.
This bit is only valid in CHCR0 and CHCR1. Writing to this bit is invalid in CHCR2 and
CHCR3; 0 is read if this bit is read. The write value should always be 0.
Bit 17: AM
Description
0
DACK output in read cycle
1
DACK output in write cycle
(Initial value)
Bit 16—Acknowledge Level (AL): Specifies whether DACK (acknowledge) signal output is
active-high or active-low.
This bit is only valid in CHCR0 and CHCR1. Writing to this bit is invalid in CHCR2 and
CHCR3; 0 is read if this bit is read. The write value should always be 0.
Bit 16: AL
Description
0
Active-low DACK output
1
Active-high DACK output
(Initial value)
Bits 15 and 14—Destination Address Mode Bits 1 and 0 (DM1, DM0): Select whether the
DMA destination address is incremented, decremented, or left fixed.
Bit 15: DM1
Bit 14: DM0
Description
0
0
Fixed destination address
0
1
Destination address is incremented (+1 in 8-bit transfer, +2 in
16-bit transfer, +4 in 32-bit transfer, +16 in 16-byte transfer)
1
0
Destination address is decremented (–1 in 8-bit transfer, –2 in
16-bit transfer, –4 in 32-bit transfer; illegal setting in 16-byte
transfer)
1
1
Setting prohibited
Rev. 5.00, 09/03, page 338 of 760
(Initial value)
Bits 13 and 12—Source Address Mode Bits 1 and 0 (SM1, SM0): Select whether the DMA
source address is incremented, decremented, or left fixed.
Bit 13: SM1
Bit 12: SM0
Description
0
0
Fixed source address
0
1
Source address is incremented (+1 in 8-bit transfer, +2 in 16bit transfer, +4 in 32-bit transfer, +16 in 16-byte transfer)
1
0
Source address is decremented (–1 in 8-bit transfer, –2 in 16bit transfer, –4 in 32-bit transfer; illegal setting in 16-byte
transfer)
1
1
Setting prohibited
(Initial value)
If the transfer source is specified by indirect address, specify the address holding the value of the
address in which the data to be transferred is stored (i.e. the indirect address) in source address
register 3 (SAR3).
Specification of SAR3 incrementing or decrementing in indirect address mode depends on the
SM1 and SM0 settings. In this case, however, the SAR3 increment or decrement value is +4, –4,
or fixed at 0, regardless of the transfer data size specified in TS1 and TS0.
Rev. 5.00, 09/03, page 339 of 760
Bits 11 to 8—Resource Select Bits 3 to 0 (RS3 to RS0): Specify which transfer requests will be
sent to the DMAC.
Bit 11:
RS3
Bit 10:
RS2
Bit 9:
RS1
Bit 8:
RS0
Description
0
0
0
0
External request*, dual address mode
0
0
0
1
Setting prohibited
0
0
1
0
External request / Single address mode
(Initial value)
External address space → external device with DACK
0
0
1
1
External request / Single address mode
0
1
0
0
Auto request
0
1
0
1
Setting prohibited
0
1
1
0
Setting prohibited
0
1
1
1
Setting prohibited
1
0
0
0
Setting prohibited
1
0
0
1
Setting prohibited
1
0
1
0
IrDA transmission
1
0
1
1
IrDA reception
1
1
0
0
SCIF transmission
1
1
0
1
SCIF reception
1
1
1
0
A/D converter
1
1
1
1
CMT
External device with DACK → external address space
Notes: When using 16-byte transfer, the following settings must not be made:
1010 IrDA transmission
1011 IrDA reception
1100 SCIF transmission
1101 SCIF reception
1110 A/D converter
1111 CMT
Operation is not guaranteed if these settings are made.
* External request specification is valid only in channels 0 and 1. None of the request
sources can be selected in channels 2 and 3.
Rev. 5.00, 09/03, page 340 of 760
Bit 6—D
DREQ Select Bit (DS): Selects low-level or falling-edge detection as the sampling method
for the DREQ pin used in external request mode.
This bit is only valid in CHCR0 and CHCR1. Writing to this bit is invalid in CHCR2 and
CHCR3; 0 is read if this bit is read. The write value should always be 0.
In channels 0 and 1, if an on-chip peripheral module is specified as a transfer request source or an
auto-request is specified, the specification of this bit is ignored and falling-edge detection is fixed
except in an auto-request.
Bit 6: DS
Description
0
DREQ detected by low level
1
DREQ detected at falling edge
(Initial value)
Bit 5—Transmit Mode (TM): Specifies the bus mode when transferring data.
Bit 5: TM
Description
0
Cycle-steal mode
1
Burst mode
(Initial value)
Bits 4 and 3—Transmit Size Bits 1 and 0 (TS1, TS0): Specify the size of data to be transferred.
Bit 4: TS1
Bit 3: TS0
Description
0
0
Byte size (8 bits)
0
1
Word size (16 bits)
1
0
Longword size (32 bits)
1
1
16-byte unit (4 longword transfers)
(Initial value)
Bit 2—Interrupt Enable Bit (IE): If this bit is set to 1, an interrupt is requested on completion of
the number of data transfers specified in DMATCR (i.e. when TE = 1).
Bit 2: IE
Description
0
Interrupt request is not generated on completion of data transfers
specified in DMATCR
(Initial value)
1
Interrupt request is generated on completion of data transfers specified
in DMATCR
Rev. 5.00, 09/03, page 341 of 760
Bit 1—Transfer End Bit (TE): Set to 1 on completion of the number of data transfers specified
in DMATCR. At this time, if the IE bit is set to 1, an interrupt request is generated.
If data transfer ends due to an NMI interrupt, a DMAC address error, or clearing of the DE bit or
the DME bit in DMAOR before this bit is set to 1, this bit will not be set to 1. Even if the DE bit
is set to 1 while this bit is set to 1, transfer is not enabled.
Bit 1: TE
Description
0
Data transfers specified in DMATCR not completed
(Initial value)
Clearing conditions: Writing 0 to TE after reading TE = 1
Power-on reset, manual reset
1
Data transfers specified in DMATCR completed
Bit 0—DMAC Enable Bit (DE): Enables operation of the corresponding channel.
Bit 0: DE
Description
0
Channel operation disabled
1
Channel operation enabled
(Initial value)
If an auto-request is specified (RS3 to RS0), transfer starts when this bit is set to 1. In an external
request or an internal module request, transfer starts when a transfer request is generated after this
bit is set to 1. Clearing this bit during transfer terminates the transfer.
Even if the DE bit is set, transfer is not enabled if the TE bit is 1, the DME bit in DMAOR is 0, or
the NMIF or AE bit in DMAOR is 1.
Rev. 5.00, 09/03, page 342 of 760
11.2.5
DMA Operation Register (DMAOR)
The DMA operation register (DMAOR) is a 16-bit readable/writable register that controls the
DMAC transfer mode.
These register values are initialized to 0 in a reset. The previous value is retained in standby mode.
Bit:
15
14
13
12
11
10
9
8
—
—
—
—
—
—
PR1
PR0
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R
R
R
R
R
R/W
R/W
Bit:
7
6
5
4
3
2
1
0
—
—
—
—
—
AE
NMIF
DME
0
0
0
0
0
0
0
0
R
R/(W)*
R/(W)*
R/W
Initial value:
R/W:
R
R
R
R
Note: * Only 0 can be written to the AE and NMIF bits after 1 is read.
Bits 15 to 10—Reserved: These bits are always read as 0. The write value should always be 0.
Bits 9 and 8—Priority Mode Bits 1 and 0 (PR1, PR0): Select the priority level between
channels when there are simultaneous transfer requests for multiple channels.
Bit 9: PR1
Bit 8: PR0
Description
0
0
CH0 > CH1 > CH2 > CH3
0
1
CH0 > CH2 > CH3 > CH1
1
0
CH2 > CH0 > CH1 > CH3
1
1
Round-robin
(Initial value)
Bits 7 to 3—Reserved: These bits are always read as 0. The write value should always be 0.
Rev. 5.00, 09/03, page 343 of 760
Bit 2—Address Error Flag Bit (AE): Indicates that an address error occurred by the DMAC. If
this bit is set during data transfer, transfers on all channels are suspended. The CPU cannot write
1 to this bit. This bit can only be cleared by writing 0 after reading 1.
Bit 2: AE
Description
0
No DMAC address error; DMA transfer is enabled
(Initial value)
Clearing conditions: Writing 0 to AE after reading AE = 1
Power-on reset, manual reset
1
DMAC address error; DMA transfer is disabled
This bit is set by occurrence of a DMAC address error
Bit 1—NMI Flag Bit (NMIF): Indicates that an NMI is input. This bit is set regardless of
whether the DMAC is in the operating or halted state. The CPU cannot write 1 to this bit. Only 0
can be written to clear this bit after 1 is read.
Bit 1: NMIF
Description
0
No NMI input; DMA transfer is enabled
(Initial value)
Clearing conditions: Writing 0 to NMIF after reading NMIF = 1
Power-on reset, manual reset
1
NMI input; DMA transfer is disabled
This bit is set by occurrence of an NMI interrupt
Bit 0—DMA Master Enable Bit (DME): Enables or disables the DMAC on all channels. If the
DME bit and the DE bit corresponding to each channel in CHCR are set to 1, transfer is enabled
on the corresponding channel. If this bit is cleared during transfer, transfer on all the channels will
be terminated.
Even if the DME bit is set, transfer is not enabled if the TE bit is 1 or the DE bit is 0 in CHCR, or
the NMIF or AE bit is 1 in DMAOR.
Bit 0: DME
Description
0
DMA transfer disabled on all channels
1
DMA transfer enabled on all channels
Rev. 5.00, 09/03, page 344 of 760
(Initial value)
11.3
Operation
When there is a DMA transfer request, the DMAC starts the transfer according to the
predetermined channel priority order; when the transfer end conditions are satisfied, it ends the
transfer. Transfers can be requested in three modes: auto-request, external request, and on-chip
module request. The dual address mode has direct address transfer mode and indirect address
transfer mode. Burst mode or cycle-steal mode can be selected as the bus mode.
11.3.1
DMA Transfer Flow
After the DMA source address register (SAR), DMA destination address register (DAR), DMA
transfer count register (DMATCR), DMA channel control register (CHCR), and DMA operation
register (DMAOR) are set, the DMAC transfers data according to the following procedure:
1. Checks to see if transfer is enabled (DE = 1, DME = 1, TE = 0, AE = 0, NMIF = 0)
2. When a transfer request comes and transfer is enabled, the DMAC transfers 1 transfer unit of
data (according to the TS0 and TS1 settings). For an auto-request, the transfer begins
automatically when the DE bit and DME bit are set to 1. The DMATCR value will be
decremented for each transfer. The actual transfer flows vary by address mode and bus mode.
3. When the specified number of transfers have been completed (when DMATCR reaches 0), the
transfer ends normally. If the IE bit in CHCR is set to 1 at this time, a DEI interrupt is sent to
the CPU.
4. When an address error occurs by the DMAC or an NMI interrupt is generated, the transfer is
aborted.
Figure 11.2 is a flowchart of this procedure.
Rev. 5.00, 09/03, page 345 of 760
Start
Initial settings
(SAR, DAR, DMATCR, CHCR, DMAOR)
DE, DME = 1 and
AE, NMIF, TE = 0?
No
Yes
Transfer request?*1
No
*2
*3
Yes
Transfer (1 transfer unit);
DMATCR − 1 → DMATCR,
SAR and DAR updated
DMATCR = 0?
No
Yes
Bus mode,
transfer request mode,
DREQ detection selection
system
AE = 1 or
NMIF = 1 or
DE = 0 or
DME = 0?
No
Yes
DEI interrupt request (when IE = 1)
Does
AE = 1 or
NMIF = 1 or
DE = 0 or DME
= 0?
Yes
Transfer end
Transfer aborted
No
Normal end
Notes: 1. In auto-request mode, transfer begins when AE, NMIF, and TE are both 0 and the DE and
DME bits are set to 1.
2. DREQ = level detection in burst mode (external request) or cycle-steal mode.
3. DREQ = edge detection in burst mode (external request), or auto-request mode in burst mode.
Figure 11.2 DMAC Transfer Flowchart
Rev. 5.00, 09/03, page 346 of 760
11.3.2
DMA Transfer Requests
DMA transfer requests are basically generated in either the data transfer source or destination, but
they can also be generated by devices and on-chip peripheral modules that are neither the source
nor the destination. Transfers can be requested in three modes: auto-request, external request, and
on-chip module request. The request mode is selected in the RS3–RS0 bits of DMA channel
control registers 0–3 (CHCR0–CHCR3).
Auto-Request Mode: When there is no transfer request signal from an external source, as in a
memory-to-memory transfer or a transfer between memory and an on-chip peripheral module
unable to request a transfer, the auto-request mode allows the DMAC to automatically generate a
transfer request signal internally. When the DE bit of CHCR0–CHCR3 and the DME bit of
DMAOR are set to 1, the transfer begins so long as the TE bit of CHCR0–CHCR3 and the NMIF
and AE bits of DMAOR are 0.
External Request Mode: In this mode a transfer is performed in response to the request signal
(DREQ) of an external device. Choose one of the modes shown in table 11.3 according to the
application system. When this mode is selected, if DMA transfer is enabled (DE = 1, DME = 1,
TE = 0, AE = 0, NMIF = 0), a transfer is performed upon a request at the DREQ input. Choose
DREQ detection by either a falling edge or low level of the signal input with the DS bit in CHCR0
and CHCR1 (DS = 0 for level detection, DS = 1 for edge detection). The source of the transfer
request does not have to be the data transfer source or destination.
Table 11.3 Selecting External Request Modes with RS Bits
RS3
0
RS2
0
RS1
RS0
Address Mode
Source
Destination
Any*
0
0
Dual address
mode
Any*
1
0
Single address
mode
External memory,
memory-mapped
external device
External device
with DACK
External device with
DACK
External memory,
memory-mapped
external device
1
Note: * External memory, memory-mapped external device, on-chip memory, on-chip peripheral
module (This applies only to IrDA, SCIF, A/D converter, D/A converter, and I/O ports.)
On-Chip Module Request Mode: In this mode a transfer is performed in response to a transfer
request signal (interrupt request signal) of an on-chip module. This mode cannot be set in case of
16-byte transfer. These are six transfer request signals: the receive-data-full interrupts (RXI) and
the transmit-data-empty interrupts (TXI) from two serial communication interfaces (IrDA, SCIF),
the A/D conversion end interrupt (ADI) of the A/D converter, and the compare match timer
interrupt (CMI) of the CMT (table 11.4). When this mode is selected, if DMA transfer is enabled
(DE = 1, DME = 1, TE = 0, AE = 0, NMIF = 0), a transfer is performed upon input of a transfer
Rev. 5.00, 09/03, page 347 of 760
request signal. The source of the transfer request does not have to be the data transfer source or
destination. When RXI is set as the transfer request, however, the transfer source must be the SCI's
receive data register (RDR). Likewise, when TXI is set as the transfer request, the transfer source
must be the SCI's transmit data register (TDR). If the transfer requester is the A/D converter, the
data transfer source must be the A/D data register (ADDR).
Table 11.4 Selecting On-Chip Peripheral Module Request Modes with RS3-0 Bits
DMA
Transfer
Request
RS3 RS2 RS1 RS0 Source
DestiDMA Transfer Request Signal Source nation Bus Mode
1
0
1
0
IrDA
TXI1 (IrDA transmit-data-empty
transmitter interrupt transfer request)
Any*
TDR1
Cycle-steal
1
0
1
1
IrDA
receiver
RDR1
Any*
Cycle-steal
1
1
0
0
SCIF
TXI2 (SCIF transmit-data-empty Any*
transmitter interrupt transfer request)
TDR2
Cycle-steal
1
1
0
1
SCIF
receiver
RXI2 (SCIF receive-data-full
interrupt transfer request)
RDR1
Any*
Cycle-steal
1
1
1
0
A/D
converter
ADI (A/D conversion end
interrupt)
ADDR
Any*
Cycle-steal
1
1
1
1
CMT
CMI (Compare match timer
interrupt)
Any*
Any*
Burst/
cycle-steal
RXI1 (IrDA receive-data-full
interrupt transfer request)
ADDR: A/D data register of A/D converter
Note: * External memory, memory-mapped external device, on-chip peripheral module (This
applies only to IrDA, SCIF, A/D converter, D/A converter, and I/O ports.)
When outputting transfer requests from on-chip peripheral modules, the appropriate interrupt
enable bits must be set to output the interrupt signals.
If the interrupt request signal of the on-chip peripheral module is used as a DMA transfer request
signal, an interrupt is not sent to the CPU.
The DMA transfer request signals in table 11.4 are automatically discontinued when the
corresponding DMA transfer is performed. If cycle-steal mode is being employed, they are
withdrawn at the first transfer; if burst mode is being used, they are discontinued at the last
transfer.
Rev. 5.00, 09/03, page 348 of 760
11.3.3
Channel Priority
When the DMAC receives simultaneous transfer requests on two or more channels, it selects a
channel according to a predetermined priority order. Two modes (fixed mode and round-robin
mode) are selected by priority bits PR1 and PR0 in the DMA operation register (DMAOR).
Fixed Mode: In these modes, the priority order of the channels remain fixed. There are three kinds
of fixed modes as follows:
CH0 > CH1 > CH2 > CH3
CH0 > CH2 > CH3 > CH1
CH2 > CH0 > CH1 > CH3
These are selected by the PR1 and PR0 bits in DMAOR.
Round-Robin Mode: Each time one word, byte, or longword is transferred on one channel, the
priority order is rotated. The channel on which the transfer was just finished rotates to the bottom
of the priority order. The round-robin mode operation is shown in figure 11.3. The priority of the
round-robin mode is CH0 > CH1 > CH2 > CH3 immediately after reset.
Rev. 5.00, 09/03, page 349 of 760
(1) When channel 0 transfers
Initial priority order
CH0 > CH1 > CH2 > CH3
Priority order
after transfer
Channel 0 becomes lowestpriority.
CH1 > CH2 > CH3 > CH0
(2) When channel 1 transfers
Initial priority order
Priority order
after transfer
CH0 > CH1 > CH2 > CH3
Channel 1 becomes lowestpriority.
The priority of channel 0, which
was higher than channel 1, is also
shifted.
CH2 > CH3 > CH0 > CH1
(3) When channel 2 transfers
Channel 2 becomes lowestpriority.
The priority of channels 0 and 1,
which were higher than channel 2,
are also shifted. If immediately
Priority order
CH3 > CH0 > CH1 > CH2 after there is a request to transfer
after transfer
channel 1 only, channel 1 becomes
lowest-priority and the priority of
channels 3 and 0, which were
Post-transfer priority order
higher than channel 1, is also
when there is an
CH2 > CH3 > CH0 > CH1 shifted.
immediate transfer
request to channel 1 only
Initial priority order
CH0 > CH1 > CH2 > CH3
(4) When channel 3 transfers
Priority order
after transfer
CH0 > CH1 > CH2 > CH3
Priority order
after transfer
CH0 > CH1 > CH2 > CH3
Priority order does not change.
Figure 11.3 Round-Robin Mode
Rev. 5.00, 09/03, page 350 of 760
Figure 11.4 shows how the priority order changes when channel 0 and channel 3 transfers are
requested simultaneously and a channel 1 transfer is requested during the channel 0 transfer. The
DMAC operates as follows:
1. Transfer requests are generated simultaneously for channels 0 and 3.
2. Channel 0 has a higher priority than channel 3, so the channel 0 transfer begins first (channel 3
waits for transfer).
3. A channel 1 transfer request occurs during the channel 0 transfer (channels 1 and 3 are both
waiting)
4. When the channel 0 transfer ends, channel 0 becomes lowest-priority.
5. At this point, channel 1 has a higher priority than channel 3, so the channel 1 transfer begins
(channel 3 waits for transfer).
6. When the channel 1 transfer ends, channel 1 becomes lowest-priority.
7. The channel 3 transfer begins.
8. When the channel 3 transfer ends, channels 3 and 2 shift downward in priority so that channel
3 becomes the lowest-priority.
Transfer request
Waiting channel(s) DMAC operation
Channel priority
(1) Channels 0 and 3
(3) Channel 1
3
1,3
0>1>2>3
(2) Channel 0 transfer
start
(4) Channel 0 transfer
ends
Priority order
changes
1>2>3>0
(5) Channel 1 transfer
starts
3
(6) Channel 1 transfer
ends
(7) Channel 3 transfer
starts
None
(8) Channel 3 transfer
ends
Priority order
changes
Priority order
changes
2>3>0>1
0>1>2>3
Figure 11.4 Changes in Channel Priority in Round-Robin Mode
Rev. 5.00, 09/03, page 351 of 760
11.3.4
DMA Transfer Types
The DMAC supports the transfers shown in table 11.5. Dual address mode has a direct address
mode and indirect address mode. In direct address mode, an output address value is the data
transfer target address; in indirect address mode, the value stored in the output address, not the
output address value itself, is the data transfer target address. Data transfer timing depends on the
bus mode, which may be cycle-steal mode or burst mode.
Table 11.5 Supported DMA Transfers
Destination
External Device
with DACK
External
Memory
MemoryMapped External
Device
On-Chip
Peripheral
Module
External device with
DACK
Not available
Dual, single
Dual, single
Not available
External memory
Dual, single
Dual
Dual
Dual
Memory-mapped
external device
Dual, single
Dual
Dual
Dual
On-chip peripheral
module
Not available
Dual
Dual
Dual
Source
Notes: 1.
2.
3.
4.
Dual: Dual address mode
Single: Single address mode
Dual address mode includes direct address mode and indirect address mode.
16-byte transfer is not available for on-chip peripheral modules.
Address Modes:
• Dual Address Mode
In dual address mode, both the transfer source and destination are accessed (selectable) by an
address. The source and destination can be located externally or internally. Dual address mode
has (1) a direct address transfer mode and (2) an indirect address transfer mode.
Rev. 5.00, 09/03, page 352 of 760
(1) In direct address transfer mode, DMA transfer requires two bus cycles because data is read
from the transfer source in a data read cycle and written to the transfer destination in a
data write cycle. At this time, transfer data is temporarily stored in the DMAC. In the
transfer between external memories as shown in figure 11.5, data is read to the DMAC
from one external memory in a data read cycle, and then that data is written to the other
external memory in a write cycle. Figure 11.6 shows an example of the timing at this
time.
DMAC
SAR
Data bus
Address bus
DAR
Memory
Transfer source
module
Transfer destination
module
Data buffer
The SAR value is an address, data is read from the transfer source module,
and the data is temporarily stored in the DMAC.
First bus cycle
DMAC
SAR
Data bus
Address bus
DAR
Memory
Transfer source
module
Transfer destination
module
Data buffer
The DAR value is an address, and the value stored in the data buffer in the
DMAC is written to the transfer destination module.
Second bus cycle
Figure 11.5 Operation of Direct Address Mode in Dual Address Mode
Rev. 5.00, 09/03, page 353 of 760
CKIO
A25 to A0
Transfer source
address
Transfer destination
address
CSn
D31 to D0
RD
WEn
DACKn
Data read cycle
Data write cycle
(1st cycle)
(2nd cycle)
Note: In transfer between external memories, with DACK output in the read cycle, DACK
output timing is the same as that of CSn.
Figure 11.6 Example of DMA Transfer Timing in the Direct Address Mode in Dual Mode
(Transfer Source: Ordinary Memory, Transfer Destination: Ordinary Memory)
(2) In indirect address transfer mode, the address of memory in which data to be transferred is
stored is specified in the transfer source address register (SAR3) in the DMAC.
Consequently, in this mode, the address value specified in the transfer source address
register in the DMAC is read first. This value is temporarily stored in the DMAC. Next,
the read value is output as an address, and the value stored in that address is stored in the
DMAC again. Then, the value read afterwards is written to the address specified in the
transfer destination address; this completes one DMA transfer. 16-byte transfer is not
possible.
Figure 11.7 shows an example. In this example, the transfer destination, the transfer
source, and the storage destination of the indirect address are 16-bit external memories,
and transfer data is 16 or 8 bits. Figure 11.8 shows an example of the transfer timing.
Rev. 5.00, 09/03, page 354 of 760
D
M
A
C
DAR3
Temporary
buffer
Memory
Data bus
Address bus
SAR3
Transfer source
module
Transfer destination
module
Data
buffer
When the value in SAR3 is an address, the memory data is read and
the value is stored in the temporary buffer. The value to be read must
be 32 bits since it is used for the address. If data bus connected to an
external memory space is 16 bits wide, two bus cycles are necessary.
First and second bus cycles
SAR3
Temporary
buffer
Data bus
DAR3
Address bus
D
M
A
C
Memory
Transfer source
module
Transfer destination
module
Data
buffer
When the value in the temporary buffer is an address, the data is read
from the transfer source module to the data buffer.
Third bus cycle
SAR3
Data bus
Address bus
D
DAR3
M
A Temporary
buffer
C
Memory
Transfer source
module
Transfer destination
module
Data
buffer
When the value in SAR3 is an address, the value in the data buffer is
written to the transfer source module.
Fourth bus cycle
Note: This example shows memory, the transfer source module, and
the transfer destination module; in practice, any module can be
connected in the addressing space.
Figure 11.7 Indirect Address Operation in Dual Address Mode
(When External Memory Space has a 16-Bit Width)
Rev. 5.00, 09/03, page 355 of 760
CKIO
A25 to A0
Transfer
source
address (H)
Transfer
source
address (L)
NOP
Transfer
destination
address
Indirect
address
CSn
D31 to D0
Internal
address
bus
Internal
data bus
Indirect
address (H)
Indirect
address (L)
Transfer source
address *1
Transfer
data
Transfer
data
Indirect
address
NOP
Transfer
data
Transfer source address *2
DMAC
indirect
address
buffer
Transfer
data
Indirect
address
DMAC
data
buffer
Transfer
data
RD
WEn
Address read cycle
(1st)
(2nd)
NOP
cycle
Data
read cycle
Data
write cycle
(3rd)
(4th)
External memory space → external memory space (external memory is 16-bit width)
Notes: 1. The internal address bus value does not change, and is controlled by the port.
2. The DMAC does not fetch the value until 32-bit data is output to the internal data bus.
Figure 11.8 Example of Transfer Timing in the Indirect Address Mode
in Dual Address Mode
Rev. 5.00, 09/03, page 356 of 760
• Single Address Mode
In single address mode, either the transfer source or transfer destination peripheral device is
accessed (selected) by means of the DACK signal, and the other device is accessed by address.
In this mode, the DMAC performs one DMA transfer in one bus cycle, accessing one of the
external devices by outputting the DACK transfer request acknowledge signal to it, and at the
same time outputting an address to the other device involved in the transfer. For example, in
the case of transfer between external memory and an external device with DACK shown in
figure 11.9, when the external device outputs data to the data bus, that data is written to the
external memory in the same bus cycle.
External address bus
External data bus
SH7709S
External
memory
DMAC
External device
with DACK
DACK
DREQ
Data flow
Figure 11.9 Data Flow in Single Address Mode
Two kinds of transfer are possible in single address mode: (1) transfer between an external
device with DACK and a memory-mapped external device, and (2) transfer between an
external device with DACK and external memory. In both cases, only the external request
signal (DREQ) is used for transfer requests.
Figures 11.10 and 11.11 show examples of DMA transfer timing in single address mode.
Rev. 5.00, 09/03, page 357 of 760
CKIO
Address output to external memory space
A25 to A0
CSn
WE
Write strobe signal to external memory space
D31 to D0
Data output from external device with DACK
DACKn
DACK signal (active-low) to external device with DACK
BS
(a) External device with DACK
external memory space (ordinary memory)
CKIO
Address output to external memory space
A25 to A0
CSn
RD
Read strobe signal to external memory space
Data output from external memory space
D31 to D0
DACKn
DACK signal (active-low) to external device with DACK
BS
(b) External memory space (ordinary memory)
external device with DACK
Figure 11.10 Example of DMA Transfer Timing in Single Address Mode
Rev. 5.00, 09/03, page 358 of 760
CKIO
A25 to A0
Transfer
source address
+4
+8
+12
CSn
D31 to D0
RD
WEn
DACKn
Figure 11.11 Example of DMA Transfer Timing in Single Address Mode
(16-byte Transfer, External Memory Space (Ordinary Memory) → External Device with
DACK)
Bus Modes: There are two bus modes: cycle-steal and burst. Select the mode in the TM bits of
CHCR0–CHCR3.
• Cycle-Steal Mode
In cycle-steal mode, the bus is given to another bus master after a one-transfer-unit (byte,
word, longword, or 16-byte unit) DMAC. When another transfer request occurs, the bus is
obtained from the other bus master and transfer is performed for one transfer unit. When that
transfer ends, the bus is passed to the other bus master. This is repeated until the transfer end
conditions are satisfied.
In the cycle-steal mode, transfer areas are not affected regardless of the transfer request source,
transfer source, and transfer destination settings. Figure 11.12 shows an example of DMA
transfer timing in cycle-steal mode. Transfer conditions shown in the figure are:
Dual address mode
DREQ level detection
Rev. 5.00, 09/03, page 359 of 760
DREQ
Bus returned to CPU
Bus cycle
CPU
CPU
CPU
DMAC DMAC
Read
CPU
Write
DMAC DMAC CPU
Read
CPU
Write
Figure 11.12 Example of DMA Transfer in Cycle-Steal Mode
• Burst Mode
Once the bus is obtained, the transfer is performed continuously until the transfer end
condition is satisfied. In external request mode with low level detection of the DREQ pin,
however, when the DREQ pin is driven high, the bus passes to the other bus master after the
DMAC transfer request that has already been accepted ends, even if the transfer end conditions
have not been satisfied.
Burst mode cannot be used when a serial communication interface (IrDA, SCI), or A/D
converter is the transfer request source. Figure 11.13 shows an example of burst mode timing.
DREQ
Bus cycle
CPU
CPU
CPU
DMAC DMAC DMAC DMAC DMAC DMAC
Read
Write
Read
Write
Read
Figure 11.13 Example of Transfer in Burst Mode
Rev. 5.00, 09/03, page 360 of 760
Write
CPU
Relationship between Request Modes and Bus Modes by DMA Transfer Category: Table
11.6 shows the relationship between request modes and bus modes by DMA transfer category.
Table 11.6 Relationship between Request Modes and Bus Modes by DMA Transfer
Category
Address
Mode
Dual
Single
Request
Mode
Bus
Mode
Transfer
Size (Bits)
Usable
Channels
External device with DACK and
external memory
External
B/C
8/16/32/128
0,1
External device with DACK and
memory-mapped external device
External
B/C
8/16/32/128
0, 1
External memory and external
memory
All*
1
B/C
8/16/32/128
0–3*
External memory and memorymapped external device
All *
1
B/C
8/16/32/128
0–3*
Memory-mapped external device
and memory-mapped external
device
All *
1
B/C
8/16/32/128
0–3*
External memory and on-chip
peripheral module
All *
2
B/C*
Memory-mapped external device
and on-chip peripheral module
All *
2
B/C*
On-chip peripheral module and on- All *
chip peripheral module
2
External device with DACK and
external memory
External device with DACK and
memory-mapped external device
Transfer Category
3
8/16/32*
3
8/16/32*
B/C*
3
External
External
5
5
5
4
0–3*
5
4
0–3*
8/16/32*
4
0–3*
B/C
8/16/32/128
0, 1
B/C
8/16/32/128
0, 1
5
5
B: Burst, C: Cycle-steal
Notes: 1. External requests, auto requests and on-chip peripheral module (CMT) requests are all
available.
2. External requests, auto requests and on-chip peripheral module requests are all
available. When the IrDA, SCIF, or A/D converter is also the transfer request source,
however, the transfer destination or transfer source must be the IrDA, SCIF, or A/D
converter, respectively.
3. If the transfer request source is the IrDA, SCIF, or A/D converter only cycle-steal mode
is available.
4. The access size permitted when the transfer destination or source is an on-chip
peripheral module register.
5. If the transfer request is an external request, only channels 0 and 1 are available.
Rev. 5.00, 09/03, page 361 of 760
Bus Mode and Channel Priority Order: When, for example, channel 1 is transferring in burst
mode and there is a transfer request to channel 0, which has higher priority, the channel 0 transfer
will begin immediately.
At this time, if the priority is set in the fixed mode (CH0 > CH1), the channel 1 transfer will
continue when the channel 0 transfer has completely finished, even if channel 0 is operating in
cycle-steal mode or burst mode.
If the priority is set in round-robin mode, channel 1 will begin operating again after channel 0
completes the transfer of one transfer unit, even if channel 0 is in cycle-steal mode or burst mode.
The bus will then switch between the two in the order channel 1, channel 0, channel 1, channel 0.
Even if the priority is set in fixed mode or in round-robin mode, the bus will not be given to the
CPU since channel 1 is in burst mode. This example is illustrated in figure 11.14.
CPU
CPU
DMAC
CH1
DMAC
CH1
DMAC CH1
Burst mode
DMAC
CH0
DMAC
CH1
DMAC
CH0
CH0
CH1
CH0
Round-robin mode in
DMAC CH0 and CH1
DMAC
CH1
DMAC
CH1
DMAC CH1
Burst mode
Priority: Round-robin mode
CH0: Cycle-steal mode
CH1: Burst mode
Figure 11.14 Bus State when Multiple Channels Are Operating
Rev. 5.00, 09/03, page 362 of 760
CPU
CPU
11.3.5
Number of Bus Cycle States and DREQ Pin Sampling Timing
Number of Bus Cycle States: When the DMAC is the bus master, the number of bus cycle states
is controlled by the bus state controller (BSC) in the same way as when the CPU is the bus master.
For details, see section 10, Bus State Controller (BSC).
DREQ Pin Sampling Timing: In external request mode, the DREQ pin is sampled by clock pulse
(CKIO) falling edge or low level detection. When DREQ input is detected, a DMAC bus cycle is
generated and DMA transfer performed, at the earliest, three states later.
The second and subsequent DREQ sampling operations are started two cycles after the first
sample.
Operation
• Cycle-Steal Mode
In cycle-steal mode, the DREQ sampling timing is the same regardless of whether level or
edge detection is used.
For example, in figure 11.15 (cycle-steal mode, level input), DMAC transfer begins, at the
earliest, three cycles after the first sampling is performed. The second sampling is started two
cycles after the first. If DREQ is not detected at this time, sampling is performed in each
subsequent cycle.
Thus, DREQ sampling is performed one step in advance. The third sampling operation is not
performed until the idle cycle following the end of the first DMA transfer.
The above conditions are the same whatever the number of CPU transfer cycles, as shown in
figure 11.16. The above conditions are also the same whatever the number of DMA transfer
cycles, as shown in figure 11.17.
DACK is output in a read in the example in figure 11.15, and in a write in the example in
figure 11.16. In both cases, DACK is output for the same duration as CSn.
Figure 11.18 shows an example in which sampling is executed in all subsequent cycles when
DREQ cannot be detected.
Rev. 5.00, 09/03, page 363 of 760
• Burst Mode, Level Detection
In the case of burst mode with level detection, the DREQ sampling timing is the same as in
cycle-steal mode.
For example, in figure 11.20, DMAC transfer begins, at the earliest, three cycles after the first
sampling is performed. The second sampling is started two cycles after the first. Subsequent
sampling operations are performed in the idle cycle following the end of the DMA transfer
cycle.
In burst mode, also, the DACK output period is the same as in cycle-steal mode.
• Burst Mode, Edge Detection
In the case of burst mode with edge detection, DREQ sampling is only performed once.
For example, in figure 11.21, DMAC transfer begins, at the earliest, three cycles after the first
sampling is performed. After this, DMAC transfer is executed continuously until the number
of data transfers set in the DMATCR register have been completed. DREQ is not sampled
during this time.
To restart DMAC after it has been suspended by an NMI, first clear NMIF, then input an edge
request again.
In burst mode, also, the DACK output period is the same as in cycle-steal mode.
Rev. 5.00, 09/03, page 364 of 760
DMAC(W)
DMAC(R)
CPU
DMAC(R)
DMAC(W)
3rd sampling
DACK
DRAK
DREQ
CKIO
Bus cycle
CPU
2nd sampling
1st sampling
Figure 11.15 Cycle-Steal Mode, Level Input (CPU Access: 2 Cycles)
Rev. 5.00, 09/03, page 365 of 760
DMAC(R)
CPU
DMAC(R)
DMAC(W)
3rd sampling
DACK
DRAK
DREQ
CKIO
Bus cycle
CPU
2nd sampling
1st sampling
Figure 11.16 Cycle-Steal Mode, Level Input (CPU Access: 3 Cycles)
Rev. 5.00, 09/03, page 366 of 760
DMAC(W)
CPU
DMAC(R)
DMAC(W)
3rd sampling
2nd sampling
DACK
(RD output)
Bus cycle
DRAK
(High output)
DREQ
CKIO
CPU
1st sampling
Figure 11.17 Cycle-Steal Mode, Level input (CPU Access: 2 Cycles, DMA RD Access:
4 Cycles)
Rev. 5.00, 09/03, page 367 of 760
Figure 11.18 Cycle-Steal Mode, Level input (CPU Access: 2 Cycles, DREQ Input Delayed)
Rev. 5.00, 09/03, page 368 of 760
DACK
(RD output)
Bus cycle
DRAK
DREQ
CKIO
CPU
1st sampling
DMAC(R)
2nd sampling
2nd sampling is performed,
but since DREQ is high,
per-cycle sampling starts
DMAC(W)
CPU
3rd sampling is performed,
but since DREQ is high,
per-cycle sampling starts
DMAC(R)
3rd sampling
DMAC(W)
CPU
Figure 11.19 Cycle-Steal Mode, Edge input (CPU Access: 2 Cycles)
Rev. 5.00, 09/03, page 369 of 760
CPU
DMAC(R)
High
High
DMAC(W)
2nd sampling
CPU
DMAC(R)
High
3rd sampling is performed,
but since there is no DREQ falling edge,
per-cycle sampling starts
Note: When a DREQ falling edge is detected, DREQ must be high for at least one cycle before the sampling point.
DACK
(RD output)
Bus cycle
DRAK
DREQ
CKIO
1st sampling
2nd sampling is performed,
but since there is no DREQ falling edge,
per-cycle sampling starts
High
DMAC(W)
3rd sampling
CPU
Figure 11.20 Burst Mode, Level Input
Rev. 5.00, 09/03, page 370 of 760
DACK
Bus cycle
DRAK
DREQ
CKIO
CPU
1st sampling
DMAC(R)
2nd sampling
DMAC(W)
DMAC(R)
3rd sampling
DMAC(W)
DMAC(R)
Figure 11.21 Burst Mode, Edge Input
Rev. 5.00, 09/03, page 371 of 760
DACK
Bus cycle
DRAK
DREQ
CKIO
CPU
1st sampling
DMAC(R)
DMAC(W)
DMAC(R)
DMAC(W)
DMAC(R)
11.3.6
Source Address Reload Function
Channel 2 includes a reload function, in which the value is returned to the value set in the source
address register (SAR2) every four transfers by setting the RO bit in CHCR2 to 1. 16-byte transfer
cannot be used. Figure 11.22 shows this operation. Figure 11.23 shows a timing chart for the
source address reload function under the following conditions: burst mode, auto-request, 16-bit
transfer data size, SAR2 incremented, DAR2 fixed, reload function on, and use of channel 2 only.
DMAC
DMAC control
Count signal
Transfer
request
Reload control
Reload signal
Reload
signal
4 time
count
CHCR2
DMATCR2
SAR2
(initial value)
SAR2
Figure 11.22 Source Address Reload Function Diagram
Rev. 5.00, 09/03, page 372 of 760
Address bus
RO bit = 1
CK
Internal
address bus
Internal
data bus
SAR2
DAR2
SAR2+2
SAR2 data
DAR2
SAR2+4
SAR2+2 data
DAR2
SAR2+6
DAR2
SAR2+4 data
SAR2
SAR2+6 data
First transfer on
channel 2
Second transfer
Third transfer
Fourth transfer
SAR2 output
DAR2 output
SAR2+2 output
DAR2 output
SAR2+4 output
DAR2 output
SAR2+6 output
DAR2 output
Fifth transfer
SAR2 reload
SAR2 output
DAR2 output
Figure 11.23 Timing Chart of Source Address Reload Function
The reload function can be executed with a transfer data size of 8, 16, or 32 bits.
DMATCR2, which specifies the transfer count, decrements 1 each time a transfer ends regardless
of whether the reload function is on or off. Consequently, a multiple of four must be specified in
DMATCR2 when the reload function is on. Operation is not guaranteed if other values are
specified.
The counter that counts the execution of four transfers for the address reload function is reset by
clearing the DME bit in DMAOR or the DE bit in CHCR2, by setting the transfer end flag (TE bit
in CHCR2), by DMAC address error, and by NMI input, as well as by a reset, but the SAR2,
DAR2, and DMATCR2 registers are not reset. Therefore, if these sources are generated, there will
be a mix of an initialized counter and uninitialized registers in the DMAC, and a malfunction will
be caused by restarting the DMAC in that state. Consequently, if one of these sources other than
setting of the TE bit occurs during use of the address reload function, set SAR2, DAR2, and
DMATCR2 again.
Rev. 5.00, 09/03, page 373 of 760
11.3.7
DMA Transfer Ending Conditions
The DMA transfer ending conditions are different for ending on an individual channel and ending
on all channels together. At the end of transfer, the following conditions are applied except in the
case where the value set in the DMA transfer count register (DMATCR) reaches 0.
(a) Cycle-steal mode (external request, internal request, and auto-request)
When the transfer ending conditions are satisfied, DMAC transfer request acceptance is
suspended. The DMAC stops operating after completing the number of transfers that it has
accepted until the ending conditions are satisfied.
In cycle-steal mode, the operation is the same regardless of whether the transfer request is
detected by level or edge.
(b) Burst mode, edge detection (external request, internal request, and auto-request)
The timing from the point where the ending conditions are satisfied to the point where the
DMAC stops operating is the same as in cycle-steal mode. With edge detection in burst mode,
though only one transfer request is generated to start the DMAC, stop request sampling is
performed at the same timing as transfer request sampling in cycle-steal mode. As a result, the
period when a stop request is not sampled is regarded as the period when a transfer request is
generated, and after performing the DMA transfer for this period, the DMAC stops operating.
(c) Burst mode, level detection (external request)
Same as in (a).
(d) Bus timing when transfer is suspended
Transfer is suspended when one transfer ends. Even if transfer ending conditions are satisfied
during a read in direct address transfer in dual address mode, the subsequent write process is
executed, and after the transfer in (a) to (c) above has been executed, DMAC operation is
suspended.
Individual Channel Ending Conditions: There are two ending conditions. A transfer ends when
the value of the channel’s DMA transfer count register (DMATCR) is 0, or when the DE bit in the
channel’s CHCR register is cleared to 0.
• When DMATCR is 0: When the DMATCR value becomes 0 and the corresponding channel's
DMA transfer ends, the transfer end flag bit (TE) is set in CHCR. If the IE (interrupt enable)
bit has been set, a DMAC interrupt (DEI) request is sent to the CPU. This transfer ending does
not apply to (a) to (d) described above.
• When DE in CHCR is 0: Software can halt a DMA transfer by clearing the DE bit in the
channel’s CHCR register. The TE bit is not set when this happens. This transfer ending applies
to (a) to (d) described above.
Rev. 5.00, 09/03, page 374 of 760
Conditions for Ending on All Channels Simultaneously: Transfers on all channels end (1) when
the AE or NMIF (NMI flag) bit is set to 1 in DMAOR, or (2) when the DME bit in DMAOR is
cleared to 0.
• Transfer ending when the NMIF bit is set to 1 in DMAOR: When an NMI interrupt occurs, the
AE or NMIF bit is set to 1 in DMAOR and all channels stop their transfers according to the
conditions in (a) to (d) described above, and pass the bus to an other bus master. Consequently,
even if the AE or NMI bit is set to 1 during transfer, SAR, DAR, DMATCR are updated. The
TE bit is not set. To resume transfer after NMI interrupt exception handling, clear the NMIF
bit to 0. At this time, if there are channels that should not be restarted, clear the corresponding
DE bit in CHCR.
• Transfer ending when DME is cleared to 0 in DMAOR: Clearing the DME bit to 0 in DMAOR
forcibly aborts transfer on all channels. The TE bit is not set. All channels abort their transfer
according to the conditions in (a) to (d) in section 11.3.7, DMA Transfer Ending Conditions, as
in NMI interrupt generation. In this case, the values in SAR, DAR, and DMATCR are also
updated.
Rev. 5.00, 09/03, page 375 of 760
11.4
Compare Match Timer (CMT)
11.4.1
Overview
The DMAC has an on-chip compare match timer (CMT) to generate DMA transfer requests. The
CMT has a 16-bit counter.
Features
The CMT has the following features:
• Four types of counter input clock can be selected
 One of four internal clocks (Pφ/4, Pφ/8, Pφ/16, Pφ/64) can be selected.
• Generates a DMA transfer request when compare match occurs.
Block Diagram
Figure 11.24 shows a block diagram of the CMT.
Pφ/4 Pφ/8 Pφ/16 Pφ/64
CMT
Clock selection
CMCNT0
Comparator
CMCOR0
CMCSR0
CMSTR
Control circuit
Module bus
Bus
interface
Internal bus
CMSTR:
CMCSR0:
CMCOR0:
CMCNT0:
Compare match timer start register
Compare match timer control/status register 0
Compare match timer constant register 0
Compare match timer counter 0
Figure 11.24 Block Diagram of CMT
Rev. 5.00, 09/03, page 376 of 760
Register Configuration
Table 11.7 summarizes the CMT register configuration.
Table 11.7 Register Configuration
Name
Abbreviation
R/W
Initial
Value
Compare match timer start
register
CMSTR
R/(W)
H'0000
H'04000070
8, 16, 32
2
(H'A4000070)*
Compare match timer
control/status register 0
CMCSR0
R/(W)*
H'0000
H'04000072
8, 16, 32
2
(H'A4000072)*
Compare match counter 0
CMCNT0
R/W
H'0000
H'04000074
8, 16, 32
2
(H'A4000074)*
Compare match constant
register 0
CMCOR0
R/W
H'FFFF
H'04000076
8, 16, 32
2
(H'A4000076)*
1
Address
Access Size
(Bits)
Notes: 1. The only value that can be written to the CMF bit in CMCSR0 is 0 to clear the flag.
2. When address translation by the MMU does not apply, the address in parentheses
should be used.
11.4.2
Register Descriptions
Compare Match Timer Start Register (CMSTR)
The compare match timer start register (CMSTR) is a 16-bit register that selects whether compare
match counter 0 (CMCNT0) is operated or halted. It is initialized to H'0000 by a reset, but retains
its previous value in standby mode.
Bit:
15
14
13
12
11
10
9
8
—
—
—
—
—
—
—
—
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R
R
R
R
R
R
R
Bit:
7
6
5
4
3
2
1
0
—
—
—
—
—
—
—
STR0
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R
R
R
R
R
R/W
R/W
Bits 15 to 2—Reserved: These bits are always read as 0. The write value should alway be 0.
Bit 1—Reserved: This bit can be read or written. The write value should always be 0.
Rev. 5.00, 09/03, page 377 of 760
Bit 0—Count Start 0 (STR0): Selects whether to operate or halt CMCNT0.
Bit 0: STR0
Description
0
CMCNT0 count operation halted
1
CMCNT0 count operation
(Initial value)
Compare Match Timer Control/Status Register 0 (CMCSR0)
The compare match timer control/status register 0 (CMCSR0) is a 16-bit register that indicates the
occurrence of compare matches, sets the enable/disable status of interrupts, and establishes the
clock used for incrementation. It is initialized to H'0000 by a reset, but retains its previous value in
standby mode.
Bit:
15
14
13
12
11
10
9
8
—
—
—
—
—
—
—
—
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R
R
R
R
R
R
R
Bit:
7
6
5
4
3
2
1
0
CMF
—
—
—
—
—
CKS1
CKS0
0
0
0
0
0
0
0
0
R/(W)*
R/W
R
R
R
R
R/W
R/W
Initial value:
R/W:
Note: * The only value that can be written is 0 to clear the flag.
Bits 15 to 8 and 5 to 2—Reserved: These bits are always read as 0. The write value should
always be 0.
Bit 7—Compare Match Flag (CMF): Indicates whether or not the compare match timer counter
0 (CMCNT0) and compare match timer constant 0 (CMCOR0) values match.
Bit 7: CMF
Description
0
CMCNT0 and CMCOR0 values do not match
Clearing condition: Write 0 to CMF after reading CMF = 1
1
CMCNT0 and CMCOR0 values match
Rev. 5.00, 09/03, page 378 of 760
(Initial value)
Bit 6—Reserved: This bit can be read or written. The wite value should always be 0.
Bits 1 and 0—Clock Select 1 and 0 (CKS1, CKS0): Select the clock input to CMCNT from
among the four internal clocks obtained by dividing the system clock (Pφ). When the STR bit in
CMSTR is set to 1, CMCNT0 begins incrementing on the clock selected by CKS1 and CKS0.
Bit 1: CKS1
Bit 0: CKS0
Description
0
0
P φ/4
1
P φ/8
0
P φ/16
1
P φ/64
1
(Initial value)
Compare Match Counter 0 (CMCNT0)
Compare match counter 0 (CMCNT0) is a 16-bit register used as an up-counter.
When an internal clock is selected with the CKS1 and CKS0 bits in the CMCSR0 register and the
STR bit in CMSTR is set to 1, CMCNT0 begins incrementing on that clock. When the CMCNT0
value matches that of compare match constant register 0 (CMCOR0), CMCNT0 is cleared to
H'0000 and the CMF flag in CMCSR0 is set to 1.
CMCNT0 is initialized to H'0000 by a reset, but retains its previous value in standby mode.
Bit:
Initial value:
15
14
13
12
11
10
9
8
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Bit:
7
6
5
4
3
2
1
0
Initial value:
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W:
R/W:
Rev. 5.00, 09/03, page 379 of 760
Compare Match Constant Register 0 (CMCOR0)
Compare match constant register 0 (CMCOR0) is a 16-bit register that sets the CMCNT0 compare
match period.
CMCOR0 is initialized to H'FFFF by a reset, but retains its previous value in standby mode.
Bit:
15
14
13
12
11
10
9
8
Initial value:
1
1
1
1
1
1
1
1
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Bit:
7
6
5
4
3
2
1
0
Initial value:
1
1
1
1
1
1
1
1
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W:
R/W:
11.4.3
Operation
Period Count Operation
When an internal clock is selected with the CKS1 and CKS0 bits in the CMCSR0 register and the
STR bit in CMSTR is set to 1, CMCNT0 begins incrementing on the selected clock. When the
CMCNT counter value matches that of CMCOR0, the CMCNT0 counter is cleared to H'0000 and
the CMF flag in the CMCSR0 register is set to 1. The CMCNT0 counter begins counting up again
from H'0000.
Figure 11.25 shows the compare match counter operation.
CMCNT0 value
Counter cleared by
CMCOR0 compare match
CMCOR0
H'0000
Time
Figure 11.25 Counter Operation
Rev. 5.00, 09/03, page 380 of 760
CMCNT0 Count Timing
One of four clocks (Pφ/4, Pφ/8, Pφ/16, Pφ/64) obtained by dividing the Pφ clock can be selected
with the CKS1 and CKS0 bits in CMCSR0. Figure 11.26 shows the timing.
CK
Internal clock
CMCNT0 input
clock
CMCNT0
N-1
N
N+1
Figure 11.26 Count Timing
11.4.4
Compare Match
Compare Match Flag Setting Timing
The CMF bit in the CMCSR0 register is set to 1 by the compare match signal generated when the
CMCOR0 register and the CMCNT0 counter match. The compare match signal is generated in the
final state of the match (timing at which the CMCNT0 counter matching count value is updated).
Consequently, after the CMCOR0 register and the CMCNT0 counter match, a compare match
signal will not be generated until a CMCNT0 counter input clock occurs. Figure 11.27 shows the
CMF bit setting timing.
Rev. 5.00, 09/03, page 381 of 760
CK
CMCNT0
input clock
CMCNT0
N
CMCOR0
N
0
Compare
match signal
CMF
CMI
Figure 11.27 CMF Setting Timing
Compare Match Flag Clearing Timing
The CMF bit in the CMCSR0 register is cleared by writing 0 to it after reading 1. Figure 11.28
shows the timing when the CMF bit is cleared by the CPU.
CMCSR0 write cycle
T1
T2
CK
CMF
Figure 11.28 Timing of CMF Clearing by the CPU
Rev. 5.00, 09/03, page 382 of 760
11.5
Examples of Use
11.5.1
Example of DMA Transfer between On-Chip IrDA and External Memory
In this example, receive data of the on-chip IrDA is transferred to external memory using DMAC
channel 3. Table 11.8 shows the transfer conditions and register settings. In addition, it is
recommended that the trigger for the number of receive FIFO data bytes in IrDA be set to 1
(RTRG1 = RTRG0 = 0 in SCFCR).
Table 11.8 Transfer Conditions and Register Settings for Transfer between On-Chip SCI
and External Memory
Transfer Conditions
Register
Setting
Transfer source: RDR1 of on-chip IrDA
SAR3
H'0400014A
Transfer destination: External memory
DAR3
H'00400000
Number of transfers: 64
DMATCR3
H'00000040
Transfer source address: Fixed
CHCR3
H'00004B05
DMAOR
H'0101
Transfer destination address: Incremented
Transfer request source: IrDA (RXI1)
Bus mode: Cycle-steal
Transfer unit: Byte
Interrupt request generated at end of transfer
Channel priority order: 0 > 2 > 3 > 1
Rev. 5.00, 09/03, page 383 of 760
11.5.2
Example of DMA Transfer between A/D Converter and External Memory
In this example, DMA transfer is performed between the on-chip A/D converter (transfer source)
and the external memory (transfer destination) with the address reload function on. Table 11.9
shows the transfer conditions and register settings.
Table 11.9 Transfer Conditions and Register Settings for Transfer between On-Chip A/D
Converter and External Memory
Transfer Conditions
Register
Setting
Transfer source: On-chip A/D converter
SAR2
H'04000080
Transfer destination: Internal memory
DAR2
H'00400000
Number of transfers: 128 (reloading 32 times)
DMATCR2
H'00000080
Transfer source address: Incremented
CHCR2
H'00089E35
DMAOR
H'0101
Transfer destination address: Decremented
Transfer request source: A/D converter
Bus mode: Burst
Transfer unit: Longword
Interrupt request generated at end of transfer
Channel priority order: 0 > 2 > 3 > 1
When the address reload function is on, the value set in SAR returns to the initially set value every
four transfers. In this example, when a transfer request is generated from the A/D converter, byte
data is read from the register at address H'04000080 in the A/D converter, and is written to
external memory address H'00400000. Since longword data has been transferred, the values in
SAR and DAR are H'04000084 and H'003FFFFC, respectively. The bus is kept and data transfers
are performed successively because this transfer is in burst mode.
After four transfers end, fifth and sixth transfers are performed if the address reload function is off,
and the value in SAR is incremented from H'0400008C to H'04000090, H'04000094… If the
address reload function is on, DMA transfer stops after the fourth transfer ends, and the bus
request signal to the CPU is cleared. At this time, the value stored in SAR is not incremented
from H'0400008C to H'04000090, but returns to the initially set value, H'04000080. The value in
DAR continues to be decremented regardless of whether the address reload function is on or off.
Rev. 5.00, 09/03, page 384 of 760
As a result, the values in the DMAC are as shown in table 11.10 when the fourth transfer ends,
depending on whether the address reload function is on or off.
Table 11.10 Values in DMAC after End of Fourth Transfer
Items
Address reload on
Address reload off
SAR
H'04000080
H'04000090
DAR
H'003FFFFC
H'003FFFFC
DMATCR
H'0000007C
H'0000007C
Bus right
Released
Held
DMAC operation
Stops
Keeps operating
Interrupt
Not generated
Not generated
Transfer request source flag
clearing
Executed
Not executed
Notes: 1. An interrupt is generated regardless of whether the address reload function is on or off,
if transfers are executed until the value in DMATCR reaches 0 and the IE bit in CHCR
has been set to 1.
2. The transfer request source flag is cleared regardless of whether the address reload
function is on or off, if transfers are executed until the value in DMATCR reaches 0.
3. Specify burst mode when using the address reload function. This function may not be
correctly executed in cycle-steal mode.
4. Set a multiple of four in DMATCR when using the address reload function. This function
may not be correctly executed if other values are specified.
11.5.3
Example of DMA Transfer between External Memory and SCIF Transmitter
(Indirect Address On)
In this example, DMA transfer is performed between the external memory specified by indirect
address (transfer source) and the SCIF transmitter (transfer destination) using DMAC channel 3.
Table 11.11 shows the transfer conditions and register settings. In addition, the trigger for the
number of transmit FIFO data bytes is set to 1 (TTRG1 = TTRG0 = 1 in SCFCR).
Rev. 5.00, 09/03, page 385 of 760
Table 11.11 Transfer Conditions and Register Settings for Transfer between External
Memory and SCIF Transmitter
Transfer Conditions
Register
Setting
Transfer source: External memory
SAR3
H'00400000
Value stored in address H'00400000
—
H'00450000
Value stored in address H'04500000
—
H'55
Transfer destination: On-chip SCIF TDR2
DAR3
H'04000156
Number of transfers: 10
DMATCR3
H'0000000A
Transfer source address: Incremented
CHCR3
H'00011C01
DMAOR
H'0001
Transfer destination address: Fixed
Transfer request source: SCIF (TXI2)
Bus mode: Cycle-steal
Transfer unit: Byte
No interrupt request generated at end of transfer
Channel priority order: 0 > 1 > 2 > 3
If the indirect address is on, data stored in the address set in SAR is not used as transfer source
data. In the indirect address, after the value stored in the address set in SAR is read, that read value
is used as an address again, and the value stored in that address is read and stored in the address
set in DAR.
In the example shown in table 11.11, when an SCIF transfer request is generated, the DMAC reads
the value in address H'00400000 set in SAR3. Since the value H'00450000 is stored in that
address, the DMAC reads the value H'00450000. Next, the DMAC uses that read value as an
address again, and reads the value H'55 stored in that address. Then, the DMAC writes the value
H'55 to address H'04000156 set in DAR3; this completes one indirect address transfer.
In the indirect address, when data is read first from the address set in SAR3, the data transfer size
is always longword regardless of the settings of the TS0 and TS1 bits that specify the transfer data
size. However, whether the transfer source address is fixed, incremented, or decremented is
specified by the SM0 and SM1 bits. Therefore, in this example, though the transfer data size is
specified as byte, the value in SAR3 is H'00400004 when one transfer ends. Write operations are
the same as in normal dual address transfer.
Rev. 5.00, 09/03, page 386 of 760
11.6
Usage Notes
1. The DMA channel control registers (CHCR0–CHCR3) can be accessed with any data size. The
DMA operation register (DMAOR) must be accessed by byte (8 bits) or word (16 bits); other
registers must be accessed by word (16 bits) or longword (32 bits).
2. Before rewriting the RS0–RS3 bits in CHCR0–CHCR3, first clear the DE bit to 0 (when
rewriting CHCR with a byte address, be sure to set the DE bit to 0 in advance).
3. Even if an NMI interrupt is input when the DMAC is not operating, the NMIF bit in DMAOR
will be set.
4. Before entering standby mode, the DME bit in DMAOR must be cleared to 0 and the transfers
accepted by the DMAC completed.
5. The on-chip peripherals which the DMAC can access are the IrDA, SCIF, A/D converter, D/A
converter, and I/O ports. Do not access other peripherals with the DMAC.
6. When starting up the DMAC, set CHCR or DMAOR last. Normal operation is not guaranteed
if settings for another register are made last.
7. Even if the maximum number of transfers are performed in the same channel after the
DMATCR count reaches 0 and DMA transfer ends normally, write 0 to DMATCR.
Otherwise, normal DMA transfer may not be performed.
8. When using the address reload function, specify burst mode as the transfer mode. In cycle-steal
mode, normal DMA transfer may not be performed.
9. When using the address reload function, set a multiple of four in DMATCR. Normal operation
is not guaranteed if other values are specified.
10. When detecting an external request at the falling edge, keep the external request pin high when
setting the DMAC.
11. Do not access the space from H'4000062 to H'400006F, which is not used in the DMAC.
Accessing this space may cause malfunctions.
12. The WAIT signal is ignored in the case of a write to external address space in dual address
mode with 16-byte transfer, or transfer from an external device with DACK to external address
space in signal address mode with 16-byte transfer.
13. DMAC transfers should not be performed in the sleep mode under conditions other than when
the clock ratio of Iφ (on-chip clock) to Bφ (bus clock) is 1:1.
14. When the following three conditions are all met, the frequency control register (FRQCR)
should not be changed while a DMAC transfer is in progress.
•
Bits IFC2 to IFC0 are changed.
•
STC2 to STC0 in FRQCR are not changed.
•
The clock ratio of Iφ (on-chip clock) to Bφ (bus clock) after the change is other than 1:1.
Rev. 5.00, 09/03, page 387 of 760
Rev. 5.00, 09/03, page 388 of 760
Section 12 Timer (TMU)
12.1
Overview
The SH7709S has a three-channel (channels 0 to 2) 32-bit timer unit (TMU).
12.1.1
Features
The TMU has the following features:
• Each channel is provided with an auto-reload 32-bit down counter.
• Channel 2 is provided with an input capture function.
• All channels are provided with 32-bit constant registers and 32-bit down counters that can be
read or written to at any time.
• All channels generate interrupt requests when the 32-bit down counter underflows
(H'00000000 → H'FFFFFFFF).
• Allows selection between 6 counter input clocks: External clock (TCLK), on-chip RTC output
clock (16 kHz), Pφ/4, Pφ/16, Pφ/64, Pφ/256. (Pφ is the internal clock for peripheral modules.)
See section 9, On-Chip Oscillation Circuits, for more information on the clock pulse generator.
• All channels can operate when the SH7709S is in standby mode: When the RTC output clock
is being used as the counter input clock, the SH7709S is still able to count in standby mode.
• Synchronized read: TCNT is a sequentially changing 32-bit register. Since the peripheral
module used has an internal bus width of 16 bits, a time lag can occur between the time when
the upper 16 bits and lower 16 bits are read. To correct the discrepancy in the counter read
value caused by this time lag, a synchronization circuit is built into the TCNT so that the entire
32-bit data in the TCNT can be read at once.
• The maximum operating frequency of the 32-bit counter is 2 MHz on all channels: Operate the
SH7709S so that the clock input to the timer counters of each channel (obtained by dividing
the external clock and internal clock with the prescaler) does not exceed the maximum
operating frequency.
Rev. 5.00, 09/03, page 389 of 760
12.1.2
Block Diagram
Pφ
Bus interface
Prescaler
TOCR
TCLK
RTCCLK
Clock
controller
TSTR
Ch. 0
TCR0
Counter
controller
TCNT0
TCOR0
TUNI0
Ch. 1
TCR1
Counter
controller
Interrupt
controller
TUNI1
TCNT1
Module bus
Interrupt
controller
TCOR1
Ch. 2
TCR2
Counter
controller
TCPR2
TCNT2
Interrupt
controller
TUNI2
TICPI2
TCOR2
TMU
Legend
TOCR: Timer output control register
TSTR: Timer start register
TCR: Timer control register
TCNT: 32-bit timer counter
TCOR: 32-bit timer constant register
TCPR2: 32-bit input capture register
Figure 12.1 Block Diagram of TMU
Rev. 5.00, 09/03, page 390 of 760
Internal bus
Figure 12.1 shows a block diagram of the TMU.
12.1.3
Pin Configuration
Table 12.1 shows the pin configuration of the TMU.
Table 12.1 TMU Pin
Channel
Pin
I/O
Description
Clock input/clock output
TCLK
I/O
External clock input pin/input capture control input
pin/realtime clock (RTC) output pin
12.1.4
Register Configuration
Table 12.2 shows the TMU register configuration.
Table 12.2 TMU Registers
Channel
Abbreviation
R/W
Initial Value* Address
Access
Size
TOCR
R/W
H'00
H'FFFFFE90
8
Timer start register
TSTR
R/W
H'00
H'FFFFFE92
8
Timer constant register 0
TCOR0
R/W
H'FFFFFFFF
H'FFFFFE94
32
Timer counter 0
TCNT0
R/W
H'FFFFFFFF
H'FFFFFE98
32
Timer control register 0
TCR0
R/W
H'0000
H'FFFFFE9C 16
Timer constant register 1
TCOR1
R/W
H'FFFFFFFF
H'FFFFFEA0
32
Timer counter 1
TCNT1
R/W
H'FFFFFFFF
H'FFFFFEA4
32
16
Register
Common Timer output control
register
0
1
2
Timer control register 1
TCR1
R/W
H'0000
H'FFFFFEA8
Timer constant register 2
TCOR2
R/W
H'FFFFFFFF
H'FFFFFEAC 32
Timer counter 2
TCNT2
R/W
H'FFFFFFFF
H'FFFFFEB0
32
Timer control register 2
TCR2
R/W
H'0000
H'FFFFFEB4
16
Input capture register 2
TCPR2
R
Undefined
H'FFFFFEB8
32
Note: * Initialized by power-on resets or manual resets.
Rev. 5.00, 09/03, page 391 of 760
12.2
12.2.1
TMU Registers
Timer Output Control Register (TOCR)
TOCR is an 8-bit readable/writable register that selects whether to use the external TCLK pin as
an external clock or an input capture control usage input pin, or an output pin for the on-chip RTC
output clock. TOCR is initialized to H'00 by a power-on reset or manual reset, but is not initialized
in standby mode.
Bit:
7
6
5
4
3
2
1
0
—
—
—
—
—
—
—
TCOE
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R
R
R
R
R
R
R/W
Bits 7 to 1—Reserved: These bits are always read as 0. The write value should always be 0.
Bit 0—Timer Clock Pin Control (TCOE): Selects use of the timer clock pin (TCLK) as an
external clock output pin or input pin for input capture control for the on-chip timer, or as an
output pin for the on-chip RTC output clock. Since the TCLK pin is multiplexed as the PTH7 pin,
when the pin is used as TCLK, bits PH7MD1 and PH7MD0 in the PHCR register should be set to
00 (the "other function" setting).
Bit 0: TCOE
Description
0
Timer clock pin (TCLK) used as external clock input or input capture control
input pin for the on-chip timer
(Initial value)
1
Timer clock pin (TCLK) used as output pin for on-chip RTC output clock
12.2.2
Timer Start Register (TSTR)
TSTR is an 8-bit readable/writable register that selects whether to run or halt the timer counters
(TCNT) for channels 0–2. TSTR is initialized to H'00 by a power-on reset or manual reset, but is
not initialized in standby mode when the input clock selected for the channel is the on-chip RTC
clock (RTCCLK). Only when an external clock (TCLK) or the peripheral clock (Pφ) is used as the
input clock, it is initialized in standby mode when the multiplication ratio of PLL circuit 1 is
changed or when the MSTP2 bit in STBCR is set to 1.
Bit:
7
6
5
4
3
2
1
0
—
—
—
—
—
STR2
STR1
STR0
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R
R
R
R
R/W
R/W
R/W
Rev. 5.00, 09/03, page 392 of 760
Bits 7 to 3—Reserved: These bits are always read as 0. The write value should always be 0.
Bit 2—Counter Start 2 (STR2): Selects whether to run or halt timer counter 2 (TCNT2).
Bit 2: STR2
Description
0
TCNT2 count halted
1
TCNT2 counts
(Initial value)
Bit 1—Counter Start 1 (STR1): Selects whether to run or halt timer counter 1 (TCNT1).
Bit 1: STR1
Description
0
TCNT1 count halted
1
TCNT1 counts
(Initial value)
Bit 0—Counter Start 0 (STR0): Selects whether to run or halt timer counter 0 (TCNT0).
Bit 0: STR0
Description
0
TCNT0 count halted
1
TCNT0 counts
12.2.3
(Initial value)
Timer Control Registers (TCR)
The timer control registers (TCR) control the timer counters (TCNT) and interrupts. The TMU has
three TCR registers, one for each channel.
The TCR registers are 16-bit readable/writable registers that control the issuance of interrupts
when the flag indicating timer counter (TCNT) underflow has been set to 1, and also carry out
counter clock selection. When the external clock has been selected, they also select its edge.
Additionally, TCR2 controls the channel 2 input capture function and the issuance of interrupts
during input capture. The TCR registers are initialized to H'0000 by a power-on reset and manual
reset, but are not initialized in standby mode and retain their contents.
Rev. 5.00, 09/03, page 393 of 760
Channels 0 and 1 TCR Bit Configuration:
Bit:
15
14
13
12
11
10
9
8
—
—
—
—
—
—
—
UNF
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R
R
R
R
R
R
R/W
Bit:
7
6
5
4
3
2
1
0
—
—
UNIE
CKEG1
CKEG0
TPSC2
TPSC1
TPSC0
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R
R/W
R/W
R/W
R/W
R/W
R/W
Channel 2 TCR Bit Configuration:
Bit:
15
14
13
12
11
10
9
8
—
—
—
—
—
—
ICPF
UNF
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R
R
R
R
R
R/W
R/W
Bit:
7
6
5
4
3
2
1
0
ICPE1
ICPE0
UNIE
CKEG1
CKEG0
TPSC2
TPSC1
TPSC0
Initial value:
R/W:
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Bits 15 to 10, 9 (except TCR2), 7, and 6 (except TCR2)—Reserved: These bits are always read
as 0. The write value should always be 0.
Bit 9—Input Capture Interrupt Flag (ICPF): A function of channel 2 only: the flag is set when
input capture is requested via the TCLK pin.
Bit 9: ICPF
Description
0
No input capture request has been issued
Clearing condition: When 0 is written to ICPF
1
(Initial value)
Input capture has been requested via the TCLK pin
Setting condition: When input capture is requested via the TCLK pin*
Note: * Contents do not change when 1 is written to ICPF.
Rev. 5.00, 09/03, page 394 of 760
Bit 8—Underflow Flag (UNF): Status flag that indicates occurrence of a TCNT underflow.
Bit 8: UNF
Description
0
TCNT has not underflowed
Clearing condition: When 0 is written to UNF
1
(Initial value)
TCNT has underflowed
Setting condition: When TCNT underflows*
Note: * Contents do not change when 1 is written to UNF.
Bits 7 and 6—Input Capture Control (ICPE1, ICPE0): A function of channel 2 only:
determines whether the input capture function can be used, and when used, whether or not to
enable interrupts.
When using this input capture function it is necessary to set the TCLK pin to input mode with the
TCOE bit in the TOCR register. Additionally, use the CKEG bit to designate use of either the
rising or falling edge of the TCLK pin to set the value in TCNT2 in the input capture register
(TCPR2).
Bit 7: ICPE1
Bit 6: ICPE0
Description
0
0
Input capture function is not used
1
Reserved (Setting prohibited)
1
0
Input capture function is used. Interrupt due to ICPF (TICPI2)
is not enabled
1
Input capture function is used. Interrupt due to ICPF (TICPI2)
is enabled
(Initial value)
Bit 5—Underflow Interrupt Control (UNIE): Controls enabling of interrupt generation when
the status flag (UNF) indicating TCNT underflow has been set to 1.
Bit 5: UNIE
Description
0
Interrupt due to UNF (TUNI) is not enabled
1
Interrupt due to UNF (TUNI) is enabled
(Initial value)
Rev. 5.00, 09/03, page 395 of 760
Bits 4 and 3—Clock Edge 1 and 0 (CKEG1, CKEG0): Select the external clock edge when the
external clock is selected, or when the input capture function is used.
Bit 4: CKEG1
Bit 3: CKEG0
Description
0
0
Count/capture register set on rising edge
1
Count/capture register set on falling edge
X
Count/capture register set on both rising and falling edge
1
(Initial value)
Note: X means 0, 1, or ‘Don’t care’.
Bits 2 to 0—Timer Prescaler 2 to 0 (TPSC2 to TPSC0): Select the TCNT count clock.
Bit 2: TPSC2
Bit 1: TPSC1
Bit 0: TPSC0
Description
0
0
0
Internal clock: count on Pφ/4
1
Internal clock: count on Pφ/16
0
Internal clock: count on Pφ/64
1
Internal clock: count on Pφ/256
0
Internal clock: count on clock output of on-chip
RTC (RTC CLK)
1
Count on TCLK pin input
0
Reserved (Setting prohibited)
1
Reserved (Setting prohibited)
1
1
0
1
Rev. 5.00, 09/03, page 396 of 760
(Initial value)
12.2.4
Timer Constant Registers (TCOR)
The TMU has three TCOR registers, one for each channel. TCOR specifies the value for setting in
TCNT when a TCNT count-down results in an under flow.
TCOR is a 32-bit readable/writable register. TCOR is initialized to H'FFFFFFFF by a power-on
reset or manual reset, but is not initialized, and retains its contents, in standby mode.
Bit:
31
30
29
28
27
26
25
24
Initial value:
1
1
1
1
1
1
1
1
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
23
22
21
20
19
18
17
16
R/W:
Bit:
Initial value:
R/W:
Bit:
Initial value:
1
1
1
1
1
1
1
R/W
R/W
R/W
R/W
R/W
R/W
R/W
15
14
13
12
11
10
9
8
1
1
1
1
1
1
1
1
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Bit:
7
6
5
4
3
2
1
0
Initial value:
1
1
1
1
1
1
1
1
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W:
R/W:
12.2.5
1
R/W
Timer Counters (TCNT)
The timer counters are 32-bit readable/writable registers. The TMU has three timer counters, one
for each channel.
TCNT counts down upon input of a clock. The clock input is selected using the TPSC2–TPSC0
bits in the timer control register (TCR).
When a TCNT count-down results in an underflow (H'00000000 → H'FFFFFFFF), the underflow
flag (UNF) in the timer control register (TCR) of the relevant channel is set. The TCOR value is
simultaneously set in TCNT itself and the count-down continues from that value.
Rev. 5.00, 09/03, page 397 of 760
Because the internal bus for the SH7709S on-chip peripheral modules is 16 bits wide, a time lag
can occur between the time when the upper 16 bits and lower 16 bits are read. Since TCNT counts
sequentially, this time lag can create discrepancies between the data in the upper and lower halves.
To correct the discrepancy, a buffer register is connected to TCNT so that the upper and lower
halves are not read separately. The entire 32-bit data in TCNT can thus be read at once.
TCNT is initialized to H'FFFFFFFF by a power-on reset or manual reset, but is not initialized, and
retains its contents, in standby mode.
Bit:
31
30
29
28
27
26
25
24
Initial value:
1
1
1
1
1
1
1
1
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Bit:
23
22
21
20
19
18
17
16
Initial value:
1
1
1
1
1
1
1
1
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Bit:
15
14
13
12
11
10
9
8
Initial value:
1
1
1
1
1
1
1
1
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Bit:
7
6
5
4
3
2
1
0
Initial value:
1
1
1
1
1
1
1
1
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W:
R/W:
R/W:
R/W:
Rev. 5.00, 09/03, page 398 of 760
12.2.6
Input Capture Register (TCPR2)
Input capture register 2 (TCPR2) is a read-only 32-bit register provided only in timer 2. Control of
TCPR2 setting conditions due to the TCLK pin is affected by the input capture function bits
(ICPE1/ICPE0 and CKEG1/CKEG0) in TCR2. When a TCPR2 setting indication due to the
TCLK pin occurs, the value of TCNT2 is copied into TCPR2.
TCNT2 is not initialized by a power-on reset or manual reset, but is not initialized, and retains its
contents, or in standby mode.
Bit:
31
30
29
28
27
26
25
24
Initial value:
—
—
—
—
—
—
—
—
R/W:
R
R
R
R
R
R
R
R
Bit:
23
22
21
20
19
18
17
16
Initial value:
—
—
—
—
—
—
—
—
R/W:
R
R
R
R
R
R
R
R
Bit:
15
14
13
12
11
10
9
8
Initial value:
—
—
—
—
—
—
—
—
R/W:
R
R
R
R
R
R
R
R
Bit:
7
6
5
4
3
2
1
0
Initial value:
—
—
—
—
—
—
—
—
R/W:
R
R
R
R
R
R
R
R
Rev. 5.00, 09/03, page 399 of 760
12.3
TMU Operation
Each of three channels has a 32-bit timer counter (TCNT) and a 32-bit timer constant register
(TCOR). TCNT counts down. The auto-reload function enables cycle counting and counting by
external events. Channel 2 has an input capture function.
12.3.1
General Operation
When the STR0–STR2 bits in the timer start register (TSTR) are set to 1, the corresponding timer
counter (TCNT) starts counting. When a TCNT underflows, the UNF flag of the corresponding
timer control register (TCR) is set. At this time, if the UNIE bit in TCR is 1, an interrupt request is
sent to the CPU. Also at this time, the value is copied from TCOR to TCNT and the down-count
operation is continued.
The count operation is set as follows (figure 12.2):
1. Select the counter clock with the TPSC2–TPSC0 bits in the timer control register (TCR). If the
external clock is selected, set the TCLK pin to input mode with the TOCE bit in TOCR, and
select its edge with the CKEG1 and CKEG0 bits in TCR.
2. Use the UNIE bit in TCR to set whether to generate an interrupt when TCNT underflows.
3. When using the input capture function, set the ICPE bits in TCR, including the choice of
whether or not to use the interrupt function (channel 2 only).
4. Set a value in the timer constant register (TCOR) (the cycle is the set value plus 1).
5. Set the initial value in the timer counter (TCNT).
6. Set the STR bit in the timer start register (TSTR) to 1 to start operation.
Rev. 5.00, 09/03, page 400 of 760
Select operation
Select counter
clock
(1)
Set underflow
interrupt generation
(2)
When using input
capture function
Set interrupt
generation
Set timer constant
register
(4)
Initialize timer
counter
(5)
Start counting
(6)
(3)
Note: When an interrupt has been generated, clear the flag in the interrupt handler that
caused it. If interrupts are enabled without clearing the flag, another interrupt will be
generated.
Figure 12.2 Setting the Count Operation
Rev. 5.00, 09/03, page 401 of 760
Auto-Reload Count Operation: Figure 12.3 shows the TCNT auto-reload operation.
TCOR value set to
TCNT during underflow
TCNT value
TCOR
Time
H'00000000
STR0−STR2
UNF
Figure 12.3 Auto-Reload Count Operation
TCNT Count Timing:
• Internal Clock Operation: Set the TPSC2–TPSC0 bits in TCR to select whether peripheral
module clock Pφ or one of the four internal clocks created by dividing it is used (Pφ/4, Pφ/16,
Pφ/64, Pφ/256). Figure 12.4 shows the timing.
Pφ
Internal
clock
TCNT
input clock
TCNT
N+1
N
Figure 12.4 Count Timing when Operating on Internal Clock
Rev. 5.00, 09/03, page 402 of 760
N−1
• External Clock Operation: Set the TPSC2–TPSC0 bits in TCR to select the external clock
(TCLK) as the timer clock. Use the CKEG1 and CKEG0 bits in TCR to select the detection
edge. Rising, falling, or both edges may be selected. The pulse width of the external clock
must be at least 1.5 peripheral module clock cycles for single edges or 2.5 peripheral module
clock cycles for both edges. A shorter pulse width will result in accurate operation. Figure 12.5
shows the timing for both-edge detection.
Pφ
External
clock input
pin (TCLK)
TCNT
input clock
TCNT
N+1
N
N−1
Figure 12.5 Count Timing when Operating on External Clock (Both Edges Detected)
• On-Chip RTC Clock Operation: Set the TPSC2–TPSC0 bits in TCR to select the on-chip RTC
clock as the timer clock. Figure 12.6 shows the timing.
RTC output
clock
TCNT input
clock
TCNT N + 1
N
N−1
Figure 12.6 Count Timing when Operating on On-Chip RTC Clock
12.3.2
Input Capture Function
Channel 2 has an input capture function (figure 12.7). When using the input capture function, set
the TCLK pin to input mode with the TCOE bit in the timer output control register (TOCR) and
set the timer operation clock to internal clock or on-chip RTC clock with the TPCS2–TPCS0 bits
in the timer control register (TCR2). Also, designate use of the input capture function and whether
to generate interrupts on input capture with the IPCE1–IPCE0 bits in TCR2, and designate the use
of either the rising or falling edge of the TCLK pin to set the timer counter (TCNT2) value into the
input capture register (TCPR2) with the CKEG1–CKEG0 bits in TCR2.
The input capture function cannot be used in standby mode.
Rev. 5.00, 09/03, page 403 of 760
TCOR value set to
TCNT during underflow
TCNT value
TCOR
Time
H'00000000
TCLK
TCPR2
Set TCNT value
ICPI
Figure 12.7 Operation Timing when Using Input Capture Function
(Using TCLK Rising Edge)
12.4
Interrupts
There are two sources of TMU interrupts: underflow interrupts (TUNI) and interrupts when using
the input capture function (TICPI2).
12.4.1
Status Flag Setting Timing
UNF is set to 1 when the TCNT underflows. Figure 12.8 shows the timing.
Pφ
TCNT
H'00000000
TCOR value
Underflow
signal
UNF
TUNI
Figure 12.8 UNF Setting Timing
Rev. 5.00, 09/03, page 404 of 760
12.4.2
Status Flag Clearing Timing
The status flag can be cleared by writing 0 from the CPU. Figure 12.9 shows the timing.
TCR write cycle
T1
T2
T3
Pφ
Peripheral address bus
TCR address
UNF, ICPF
Figure 12.9 Status Flag Clearing Timing
12.4.3
Interrupt Sources and Priorities
The TMU produces underflow interrupts for each channel. When the interrupt request flag and
interrupt enable bit are both set to 1, an interrupt is requested. Codes are set in the interrupt event
registers (INTEVT, INTEVT2) for these interrupts and interrupt handling occurs according to the
codes.
The relative priorities of channels can be changed using the interrupt controller (see section 4,
Exception Handling, and section 6, Interrupt Controller (INTC)). Table 12.3 lists TMU interrupt
sources.
Table 12.3 TMU Interrupt Sources
Channel
Interrupt Source
Description
Priority
0
TUNI0
Underflow interrupt 0
High
1
TUNI1
Underflow interrupt 1
2
TUNI2
Underflow interrupt 2
2
TICPI2
Input capture interrupt 2
Low
Rev. 5.00, 09/03, page 405 of 760
12.5
Usage Notes
12.5.1
Writing to Registers
Synchronization processing is not performed for timer counting during register writes. When
writing to registers, always clear the appropriate start bits for the channel (STR2–STR0) in the
timer start register (TSTR) to halt timer counting.
12.5.2
Reading Registers
Synchronization processing is performed for timer counting during register reads. When timer
counting and register read processing are performed simultaneously, the register value before
TCNT counting down (with synchronization processing) is read.
Rev. 5.00, 09/03, page 406 of 760
Section 13 Realtime Clock (RTC)
13.1
Overview
The SH7709S has a realtime clock (RTC) with its own 32.768-kHz crystal oscillator.
13.1.1
Features
• Clock and calendar functions (BCD display): Seconds, minutes, hours, date, day of the week,
month, and year
• 1-Hz to 64-Hz timer (binary display)
• Start/stop function
• 30-second adjust function
• Alarm interrupt: Frame comparison of seconds, minutes, hours, date, day of the week, and
month can be used as conditions for the alarm interrupt
• Cyclic interrupts: The interrupt cycle may be 1/256 second, 1/64 second, 1/16 second, 1/4
second, 1/2 second, 1 second, or 2 seconds
• Carry interrupt: A carry interrupt indicates when a carry occurs during a counter read
• Automatic leap year correction
Rev. 5.00, 09/03, page 407 of 760
13.1.2
Block Diagram
Figure 13.1 shows a block diagram of the RTC.
Oscillator
circuit
XTAL2
32.768 kHz
128 Hz
30second
Reset ADJ
R64CNT
RSECCNT
Prescaler
(÷ 2)
16.384 kHz
RTCCLK
Bus
interface
RMINCNT
Internal bus
Externally
connected
circuit
EXTAL2
RHRCNT
RWKCNT
Prescaler
(÷ 128)
RDAYCNT
RMONCNT
RYRCNT
PRI
Interrupt
control
circuit
Comparator
RSECAR
RMINAR
CUI
Carry
detection
circuit
Module bus
ATI
RHRAR
RWKAR
RDAYAR
RMONAR
RCR1
RCR2
RTC
Legend
R64CNT:
RSECCNT:
RMINCNT:
RHRCNT:
RWKCNT:
RDAYCNT:
RMONCNT:
RYRCNT:
64 Hz counter
Second counter
Minute counter
Hour counter
Day-of-week counter
Day counter
Month counter
Year counter
RSECAR:
RMINAR:
RHRAR:
RWKAR:
RDAYAR:
RMONAR:
RCR1:
RCR2:
Second alarm register
Minute alarm register
Hour alarm register
Day-of-week alarm register
Day alarm register
Month alarm register
RTC control register 1
RTC control register 2
Figure 13.1 Block Diagram of RTC
Rev. 5.00, 09/03, page 408 of 760
13.1.3
Pin Configuration
Table 13.1 shows the RTC pin configuration.
Table 13.1 RTC Pins
Pin
Signal Name
I/O
Description
RTC oscillator crystal pin
EXTAL2
I
RTC oscillator crystal pin
XTAL2
O
Connects crystal to RTC oscillator*
2
Connects crystal to RTC oscillator*
Clock input/clock output
TCLK
I/O
Dedicated power-supply pin
for RTC
Vcc–RTC
—
External clock input pin/input capture
control input pin/realtime clock (RTC)
output pin (shared by TMU)
1
Dedicated power-supply pin for RTC*
Dedicated GND pin for RTC
Vss–RTC
—
Dedicated GND pin for RTC*
2
1
Notes: 1. Except in hardware standby mode, power must be supplied to all power supply pins,
including these, even when only the RTC is used (including standby mode).
2. When the RTC is not used, pull EXTAL2 up (to Vcc) and make no connection for
XTAL2.
Rev. 5.00, 09/03, page 409 of 760
13.1.4
RTC Register Configuration
Table 13.2 shows the RTC register configuration.
Table 13.2 RTC Registers
Name
Abbreviation R/W
Initial Value
Address
Access Size
64-Hz counter
R64CNT
R
Undefined
H'FFFFFEC0
8
Second counter
RSECCNT
R/W
Undefined
H'FFFFFEC2
8
Minute counter
RMINCNT
R/W
Undefined
H'FFFFFEC4
8
Hour counter
RHRCNT
R/W
Undefined
H'FFFFFEC6
8
Day of week counter
RWKCNT
R/W
Undefined
H'FFFFFEC8
8
Date counter
RDAYCNT
R/W
Undefined
H'FFFFFECA
8
Month counter
RMONCNT
R/W
Undefined
H'FFFFFECC
8
Year counter
RYRCNT
R/W
Undefined
H'FFFFFECE
8
R/W
Undefined*
H'FFFFFED0
8
Second alarm register
RSECAR
Minute alarm register
RMINAR
R/W
Undefined*
H'FFFFFED2
8
Hour alarm register
RHRAR
R/W
H'FFFFFED4
8
Day of week alarm register RWKAR
R/W
Undefined*
Undefined*
H'FFFFFED6
8
R/W
Undefined*
H'FFFFFED8
8
H'FFFFFEDA
8
Date alarm register
RDAYAR
Month alarm register
RMONAR
R/W
Undefined*
RTC control register 1
RCR1
R/W
H'00
H'FFFFFEDC
8
RTC control register 2
RCR2
R/W
H'09
H'FFFFFEDE
8
Note: * Only the ENB bits of each register are initialized.
Rev. 5.00, 09/03, page 410 of 760
13.2
RTC Registers
13.2.1
64-Hz Counter (R64CNT)
The 64-Hz counter (R64CNT) is an 8-bit read-only register that indicates the states of the RTC
divider circuit, RTC prescaler, and R64CNT between 64 Hz and 1 Hz.
R64CNT is initialized to H'00 by setting the RESET bit in RTC control register 2 (RCR2) or the
ADJ bit in RCR2 to 1.
R64CNT is not initialized by a power-on reset or manual reset, or in standby mode.
Bit 7 is always read as 0.
Bit:
13.2.2
7
6
5
4
3
2
1
0
—
1Hz
2Hz
4Hz
8Hz
16Hz
32Hz
64Hz
Initial value:
0
—
—
—
—
—
—
—
R/W:
R
R
R
R
R
R
R
R
Second Counter (RSECCNT)
The second counter (RSECCNT) is an 8-bit readable/writable register used for setting/counting in
the BCD-coded second section of the RTC. The count operation is performed by a carry for each
second of the 64-Hz counter.
The range that can be set is 00–59 (decimal). Errant operation will result if any other value is set.
Carry out write processing after halting the count operation with the START bit in RCR2.
RSECCNT is not initialized by a power-on reset or manual reset, or in standby mode.
Bit:
7
6
—
5
4
3
10 seconds
2
1
0
1 second
Initial value:
0
—
—
—
—
—
—
—
R/W:
R
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Rev. 5.00, 09/03, page 411 of 760
13.2.3
Minute Counter (RMINCNT)
The minute counter (RMINCNT) is an 8-bit readable/writable register used for setting/counting in
the BCD-coded minute section of the RTC. The count operation is performed by a carry for each
minute of the second counter.
The range that can be set is 00–59 (decimal). Errant operation will result if any other value is set.
Carry out write processing after halting the count operation with the START bit in RCR2.
RMINCNT is not initialized by a power-on reset or manual reset, or in standby mode.
Bit:
7
6
—
13.2.4
5
4
3
10 minutes
2
1
0
1 minute
Initial value:
0
—
—
—
—
—
—
—
R/W:
R
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Hour Counter (RHRCNT)
The hour counter (RHRCNT) is an 8-bit readable/writable register used for setting/counting in the
BCD-coded hour section of the RTC. The count operation is performed by a carry for each 1 hour
of the minute counter.
The range that can be set is 00–23 (decimal). Errant operation will result if any other value is set.
Carry out write processing after halting the count operation with the START bit in RCR2 or using
a carry flag as shown in figure 13.2.
RHRCNT is not initialized by a power-on reset or manual reset, or in standby mode.
Bit:
7
6
—
—
5
4
3
2
10 hours
1
0
1 hour
Initial value:
0
0
—
—
—
—
—
—
R/W:
R
R
R/W
R/W
R/W
R/W
R/W
R/W
Rev. 5.00, 09/03, page 412 of 760
13.2.5
Day of Week Counter (RWKCNT)
The day of week counter (RWKCNT) is an 8-bit readable/writable register used for
setting/counting in the BCD-coded day of week section of the RTC. The count operation is
performed by a carry for each day of the date counter.
The range that can be set is 0–6 (decimal). Errant operation will result if any other value is set.
Carry out write processing after halting the count operation with the START bit in RCR2.
RWKCNT is not initialized by a power-on reset or manual reset, or in standby mode.
Bit:
7
6
5
4
3
2
1
0
—
—
—
—
—
Initial value:
0
0
0
0
0
—
—
—
R/W:
R
R
R
R
R
R/W
R/W
R/W
Day of week
Days of the week are coded as shown in table 13.3.
Table 13.3 Day-of-Week Codes (RWKCNT)
Day of Week
Code
Sunday
0
Monday
1
Tuesday
2
Wednesday
3
Thursday
4
Friday
5
Saturday
6
Rev. 5.00, 09/03, page 413 of 760
13.2.6
Date Counter (RDAYCNT)
The date counter (RDAYCNT) is an 8-bit readable/writable register used for setting/counting in
the BCD-coded date section of the RTC. The count operation is performed by a carry for each day
of the hour counter.
The range that can be set is 01–31 (decimal). Errant operation will result if any other value is set.
Carry out write processing after halting the count operation with the START bit in RCR2.
RDAYCNT is not initialized by a power-on reset or manual reset, or in standby mode.
The RDAYCNT range that can be set changes with each month and in leap years. Please confirm
the correct setting.
Bit:
13.2.7
7
6
5
4
3
—
—
Initial value:
0
0
—
—
—
R/W:
R
R
R/W
R/W
R/W
2
1
0
—
—
—
R/W
R/W
R/W
10 days
1 day
Month Counter (RMONCNT)
The month counter (RMONCNT) is an 8-bit readable/writable register used for setting/counting in
the BCD-coded month section of the RTC. The count operation is performed by a carry for each
month of the date counter.
The range that can be set is 00–12 (decimal). Errant operation will result if any other value is set.
Carry out write processing after halting the count operation with the START bit in RCR2.
RMONCNT is not initialized by a power-on reset or manual reset, or in standby mode.
Bit:
7
6
5
4
—
—
—
10
months
Initial value:
0
0
0
—
—
R/W:
R
R
R
R/W
R/W
Rev. 5.00, 09/03, page 414 of 760
3
2
1
0
—
—
—
R/W
R/W
R/W
1 month
13.2.8
Year Counter (RYRCNT)
The year counter (RYRCNT) is an 8-bit readable/writable register used for setting/counting in the
BCD-coded year section of the RTC. The least significant 2 digits of the western calendar year are
displayed. The count operation is performed by a carry for each year of the month counter.
The range that can be set is 00–99 (decimal). Errant operation will result if any other value is set.
Carry out write processing after halting the count operation with the START bit in RCR2.
RYRCNT is not initialized by a power-on reset or manual reset, or in standby mode.
Leap years are recognized by dividing the year counter value by 4 and obtaining a fractional result
of 0. The year counter value: 00 is included in leap years.
Bit:
7
6
5
4
3
2
10 years
Initial value:
R/W:
13.2.9
1
0
1 year
—
—
—
—
—
—
—
—
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Second Alarm Register (RSECAR)
The second alarm register (RSECAR) is an 8-bit readable/writable register, and an alarm register
corresponding to the BCD-coded second section counter RSECCNT of the RTC. When the ENB
bit is set to 1, a comparison with the RSECCNT value is performed. From among the
RSECAR/RMINAR/RHRAR/RWKAR/RDAYAR/RMONAR registers, the counter and alarm
register comparison is performed only on those with ENB bits set to 1, and if each of those
coincide, an RTC alarm interrupt is generated.
The range that can be set is 00–59 (decimal) + ENB bit. Errant operation will result if any other
value is set.
The ENB bit in RSECAR is initialized to 0 by a power-on reset. The remaining RSECAR fields
are not initialized and retain their contents by a manual reset, or in standby mode.
Bit:
7
6
ENB
Initial value:
R/W:
5
4
3
2
10 seconds
1
0
1 second
0
—
—
—
—
—
—
—
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Rev. 5.00, 09/03, page 415 of 760
13.2.10 Minute Alarm Register (RMINAR)
The minute alarm register (RMINAR) is an 8-bit readable/writable register, and an alarm register
corresponding to the BCD-coded minute section counter RMINCNT of the RTC. When the ENB
bit is set to 1, a comparison with the RMINCNT value is performed. From among the
RSECAR/RMINAR/RHRAR/RWKAR/RDAYAR/RMONAR registers, the counter and alarm
register comparison is performed only on those with ENB bits set to 1, and if each of those
coincide, an RTC alarm interrupt is generated.
The range that can be set is 00–59 (decimal) + ENB bit. Errant operation will result if any other
value is set.
The ENB bit in RMINAR is initialized by a power-on reset. The remaining RMINAR fields are
not initialized and retain their contents by a manual reset, or in standby mode.
Bit:
7
6
ENB
Initial value:
R/W:
5
4
3
10 minutes
2
1
0
1 minute
0
—
—
—
—
—
—
—
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
13.2.11 Hour Alarm Register (RHRAR)
The hour alarm register (RHRAR) is an 8-bit readable/writable register, and an alarm register
corresponding to the BCD-coded hour section counter RHRCNT of the RTC. When the ENB bit is
set to 1, a comparison with the RHRCNT value is performed. From among the
RSECAR/RMINAR/RHRAR/RWKAR/RDAYAR/RMONAR registers, the counter and alarm
register comparison is performed only on those with ENB bits set to 1, and if each of those
coincide, an RTC alarm interrupt is generated.
The range that can be set is 00–23 (decimal) + ENB bit. Errant operation will result if any other
value is set.
The ENB bit in RHRAR is initialized by a power-on reset. The remaining RHRAR fields are not
initialized and retain their contents by a manual reset, or in standby mode.
Bit:
Initial value:
R/W:
7
6
ENB
—
0
0
—
R/W
R
R/W
Rev. 5.00, 09/03, page 416 of 760
5
4
3
2
1
0
—
—
—
—
—
R/W
R/W
R/W
R/W
R/W
10 hours
1 hour
13.2.12 Day of Week Alarm Register (RWKAR)
The day of week alarm register (RWKAR) is an 8-bit readable/writable register, and an alarm
register corresponding to the BCD-coded day of week section counter RWKCNT of the RTC.
When the ENB bit is set to 1, a comparison with the RWKCNT value is performed. From among
the RSECAR/RMINAR/RHRAR/RWKAR/RDAYAR/RMONAR registers, the counter and alarm
register comparison is performed only on those with ENB bits set to 1, and if each of those
coincide, an RTC alarm interrupt is generated.
The range that can be set is 0–6 (decimal) + ENB bit. Errant operation will result if any other
value is set.
The ENB bit in RWKAR is initialized by a power-on reset. The remaining RWKAR fields are not
initialized and retain their contents by a manual reset, or in standby mode.
Bit:
Initial value:
R/W:
7
6
5
4
3
2
1
0
ENB
—
—
—
—
0
0
0
0
0
—
—
—
R/W
R
R
R
R
R/W
R/W
R/W
Day of week
Days of the week are coded as shown in table 13.4.
Table 13.4 Day-of-Week Codes (RWKAR)
Day of Week
Code
Sunday
0
Monday
1
Tuesday
2
Wednesday
3
Thursday
4
Friday
5
Saturday
6
Rev. 5.00, 09/03, page 417 of 760
13.2.13 Date Alarm Register (RDAYAR)
The date alarm register (RDAYAR) is an 8-bit readable/writable register, and an alarm register
corresponding to the BCD-coded date section counter RDAYCNT of the RTC. When the ENB bit
is set to 1, a comparison with the RDAYCNT value is performed. From among the registers
RSECAR, RMINAR, RHRAR, RWKAR, RDAYAR, RMONAR, the counter and alarm register
comparison is performed only on those with ENB bits set to 1, and if each of those coincide, an
RTC alarm interrupt is generated.
The range that can be set is 01–31 (decimal) + ENB bit. Errant operation will result if any other
value is set. The RDAYCNT range that can be set changes with some months and in leap years.
Please confirm the correct setting.
The ENB bit in RDAYAR is initialized by a power-on reset. The remaining RDAYAR fields are
not initialized and retain their contents by a manual reset, or in standby mode.
Bit:
Initial value:
R/W:
7
6
5
4
3
ENB
—
0
0
—
—
—
R/W
R
R/W
R/W
R/W
2
1
0
—
—
—
R/W
R/W
R/W
10 days
1 day
13.2.14 Month Alarm Register (RMONAR)
The month alarm register (RMONAR) is an 8-bit readable/writable register, and an alarm register
corresponding to the BCD-coded month section counter RMONCNT of the RTC. When the ENB
bit is set to 1, a comparison with the RMONCNT value is performed. From among the registers
RSECAR, RMINAR, RHRAR, RWKAR, RDAYAR, RMONAR, the counter and alarm register
comparison is performed only on those with ENB bits set to 1, and if each of those coincide, an
RTC alarm interrupt is generated.
The range that can be set is 01–12 (decimal) + ENB bit. Errant operation will result if any other
value is set.
The ENB bit in RMONAR is initialized by a power-on reset. The remaining RMONAR fields are
not initialized and retain their contents by a manual reset, or in standby mode.
Bit:
Initial value:
R/W:
7
6
5
4
ENB
—
—
10
months
0
0
0
—
—
R/W
R
R
R/W
R/W
Rev. 5.00, 09/03, page 418 of 760
3
2
1
0
—
—
—
R/W
R/W
R/W
1 month
13.2.15 RTC Control Register 1 (RCR1)
The RTC control register 1 (RCR1) is an 8-bit readable/writable register that affects carry flags
and alarm flags. It also selects whether to generate interrupts for each flag. Because flags are
sometimes set after an operand read, do not use this register in read-modify-write processing.
RCR1 is initialized to H'00 by a power-on reset or a manual reset. In a manual reset, all bits are
initialized to H'00 except for the CF flag, which is undefined. When using the CF flag, it must be
initialized beforehand. This register is not initialized in standby mode.
Bit:
Initial value:
R/W:
7
6
5
4
3
2
1
0
CF
—
—
CIE
AIE
—
—
AF
0
0
0
0
0
0
0
0
R/W
R
R
R/W
R/W
R
R
R/W
Bit 7—Carry Flag (CF): Status flag that indicates that a carry has occurred. Setting CF to 1
indicates reading of a counter register value has occurred when (1) the second counter is carried or
(2) the 64-Hz counter is carried. A count register value read at this time cannot be guaranteed;
another read is required.
Bit 7: CF
Description
0
No count up of R64CNT or RSECCNT
Clearing condition: When 0 is written to CF
1
(Initial value)
Count up of R64CNT or RSECCNT
Setting condition: When 1 is written to CF
Bits 6, 5, 2, and 1—Reserved: These bits are always read as 0. The write value should always be
0.
Bit 4—Carry Interrupt Enable Flag (CIE): When the carry flag (CF) is set to 1, the CIE bit
enables interrupts.
Bit 4: CIE
Description
0
A carry interrupt is not generated when the CF flag is set to 1
1
A carry interrupt is generated when the CF flag is set to 1
(Initial value)
Rev. 5.00, 09/03, page 419 of 760
Bit 3—Alarm Interrupt Enable Flag (AIE): When the alarm flag (AF) is set to 1, the AIE bit
allows interrupts.
Bit 3: AIE
Description
0
An alarm interrupt is not generated when the AF flag is set to 1
(Initial value)
1
An alarm interrupt is generated when the AF flag is set to 1
Bit 0—Alarm Flag (AF): The AF flag is set to 1 when the alarm time set in an alarm register
(only registers with ENB bit set to 1) matches the clock and calendar time. This flag is cleared to
0 when 0 is written, but holds its previous value when 1 is written.
Bit 0: AF
Description
0
Clock/calendar and alarm register have not matched since last reset to 0
Clearing condition: When 0 is written to AF
(Initial value)
1
Setting condition: Clock/calendar and alarm register have matched (only
registers with ENB set)*
Note: * Contents do not change when 1 is written to AF.
13.2.16 RTC Control Register 2 (RCR2)
The RTC control register 2 (RCR2) is an 8-bit readable/writable register for periodic interrupt
control, 30-second adjustment ADJ, divider circuit RESET, and RTC count start/stop control. It is
initialized to H'09 by a power-on reset. It is initialized except for RTCEN and START by a
manual reset. It is not initialized, and retains its contents, in standby mode.
Bit:
Initial value:
R/W:
7
6
5
4
3
2
1
0
PEF
PES2
PES1
PES0
RTCEN
ADJ
RESET
START
0
0
0
0
1
0
0
1
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Bit 7—Periodic Interrupt Flag (PEF): Indicates interrupt generation with the period designated
by the PES bits. When set to 1, PEF generates periodic interrupts.
Bit 7: PEF
Description
0
Interrupts not generated with the period designated by the PES bits
Clearing condition: When 0 is written to PEF
(Initial value)
1
Interrupts generated with the period designated by the PES bits
Setting condition: When 1 is written to PEF
Rev. 5.00, 09/03, page 420 of 760
Bits 6 to 4—Periodic Interrupt Flags (PES2-PES0): Specify the periodic interrupt.
Bit 6: PES2
Bit 5: PES1
Bit 4: PES0
Description
0
0
0
No periodic interrupts generated (Initial value)
1
Periodic interrupt generated every 1/256 second
0
Periodic interrupt generated every 1/64 second
1
Periodic interrupt generated every 1/16 second
0
Periodic interrupt generated every 1/4 second
1
Periodic interrupt generated every 1/2 second
0
Periodic interrupt generated every 1 second
1
Periodic interrupt generated every 2 seconds
1
1
0
1
Bit 3—RTCEN: Controls the operation of the crystal oscillator for the RTC.
Bit 3: RTCEN
Description
0
Crystal oscillator for RTC is halted
1
Crystal oscillator for RTC runs
(Initial value)
Bit 2—30 Second Adjustment (ADJ): When 1 is written to the ADJ bit, times of 29 seconds or
less will be rounded to 00 seconds and 30 seconds or more to 1 minute. The divider circuit, RTC
prescaler, and R64CNT will be simultaneously reset. This bit is always read as 0. The maximum
duration between when the ADJ bit is set to 1 and when the new setting is reflected in the readout
value from the seconds counter (RSECCNT) is approximately 91.6 µs (when a 32.768 kHz quartz
oscillator is connected to the EXTAL2 pin).
Bit 2: ADJ
Description
0
Runs normally
1 (Write)
30-second adjustment
(Initial value)
Bit 1—Reset (RESET): When 1 is written, initializes the divider circuit (RTC prescaler and
R64CNT). This bit is always read as 0.
Bit 1: RESET
Description
0
Runs normally
1 (Write)
Divider circuit is reset
(Initial value)
Rev. 5.00, 09/03, page 421 of 760
Bit 0—Start Bit (START): Halts and restarts the counter (clock).
Bit 0: START
Description
0
Second/minute/hour/day/week/month/year counter halts
1
Second/minute/hour/day/week/month/year counter runs normally
(Initial value)
Note: The 64-Hz counter always runs unless stopped with the RTCEN bit.
13.3
RTC Operation
13.3.1
Initial Settings of Registers after Power-On
All the registers should be set after the power is turned on.
13.3.2
Setting the Time
Figure 13.2 shows how to set the time when the clock is stopped. This works when the entire
calendar or clock is to be set. Programming can be easily performed.
To reset the divider circuit (RTC prescaler
and R64CNT) and set the counter
Stop clock,
reset divider circuit
Set seconds, minutes,
hour, day, day of the
week, month and year
Start clock
Write 1 to RESET and 0 to
START in the RCR2 register
Order is irrelevant
Write 1 to START in the
RCR2 register
Figure 13.2 Setting the Time
Rev. 5.00, 09/03, page 422 of 760
13.3.3
Reading the Time
Figure 13.3 shows how to read the time. If a carry occurs while reading the time, the correct time
will not be obtained, so it must be read again. Part (a) in figure 13.3 shows the method of reading
the time without using interrupts; part (b) in figure 13.3 shows the method using carry interrupts.
To keep programming simple, method (a) should normally be used.
a. To read the time
without using interrupts
Disable the carry
interrupt
Clear the carry flag
Clear CIE in RCR1 to 0
Write 0 to CF in RCR1
Note: Set AF to 1 so that alarm
flag is not cleared.
Read counter
register
Yes
Carry flag = 1?
Read RCR1 and check CF
No
b. To use interrupts
Enable the carry
interrupt
Clear the carry flag
Write 1 to CIE in RCR1,
and write 0 to CF in RCR1
Note: Set AF in RCR1 to 1 so that
alarm flag is not cleared.
Read counter
register
Yes
Interrupt
generated?
No
Disable the carry
interrupt
Write 0 to CIE in RCR1
Figure 13.3 Reading the Time
Rev. 5.00, 09/03, page 423 of 760
13.3.4
Alarm Function
Figure 13.4 shows how to use the alarm function.
Alarms can be generated using seconds, minutes, hours, day of the week, date, month, or any
combination of these. Set the ENB bit (bit 7) to 1 in the register to which the alarm applies, and
then set the alarm time in the lower bits. Clear the ENB bit to 0 in registers to which the alarm
does not apply.
When the clock and alarm times match, 1 is set in the AF bit (bit 0) in RCR1. Alarm detection can
be checked by reading this bit, but normally it is done by interrupt. If 1 is placed in the AIE bit (bit
3) in RCR1, an interrupt is generated when an alarm occurs.
Clock running
Set whether to use
alarm interrupt
Disable interrupts for preventing error
interrupts (clear the AIE bit in RCR1 to 0).
Then write 1 to the AIE bit in RCR1.
Set alarm time
Clear alarm flag
Always reset, since the flag may have
been set while the alarm time was being
set (clear the AF bit in RCR1 to 0).
Monitor alarm time
(wait for interrupt or
check alarm flag)
Figure 13.4 Using the Alarm Function
Rev. 5.00, 09/03, page 424 of 760
13.3.5
Crystal Oscillator Circuit
Crystal oscillator circuit constants (recommended values) are shown in table 13.5, and the RTC
crystal oscillator circuit in figure 13.5.
Table 13.5 Recommended Oscillator Circuit Constants (Recommended Values)
fosc
Cin
Cout
32.768 kHz
10 to 22 pF
10 to 22 pF
Rf
SH7709S
RD
XTAL2
EXTAL2
XTAL
Cin
Cout
Notes: 1. Select either the Cin or Cout side for the frequency adjustment variable capacitor
according to requirements such as frequency range, degree of stability, etc.
2. Built-in resistance value Rf (Typ value) = 10 MΩ, RD (Typ value) = 400 kΩ
3. Cin and Cout values include floating capacitance due to the wiring. Take care
when using a ground plane.
4. The crystal oscillation settling time depends on the mounted circuit constants,
floating capacitance, etc., and should be decided after consultation with the
crystal resonator manufacturer.
5. Place the crystal resonator and load capacitors Cin and Cout as close as possible
to the chip.
(Correct oscillation may not be possible if there is externally induced noise in the
EXTAL2 and XTAL2 pins.)
6. Ensure that the crystal resonator connection pin (EXTAL2, XTAL2) wiring is
routed as far away as possible from other power lines (except GND) and signal
lines.
Figure 13.5 Example of Crystal Oscillator Circuit Connection
Rev. 5.00, 09/03, page 425 of 760
13.4
Usage Notes
13.4.1
Register Writing during RTC Count
The following RTC registers cannot be written to during an RTC count (while bit 0 = 1 in RCR2).
RSECCNT, RMINCNT, RHRCNT, RDAYCNT, RWKCNT, RMONCNT, RYRCNT
The RTC count must be halted before writing to any of the above registers.
13.4.2
Use of Realtime Clock (RTC) Periodic Interrupts
The method of using the periodic interrupt function is shown in figure 13.6.
A periodic interrupt can be generated periodically at the interval set by the periodic interrupt
enable flag (PES) in RTC control register 2 (RCR2). When the time set by the periodic interrupt
enable flag (PES) has elapsed, the periodic interrupt flag (PEF) is set to 1.
The periodic interrupt flag (PEF) is cleared to 0 upon periodic interrupt generation when the
periodic interrupt enable flag (PES) is set. Periodic interrupt generation can be confirmed by
reading this bit, but normally the interrupt function is used.
Set PES, clear PEF
Set PES, and clear PEF to 0,
in RCR2
Elapse of time set by PES
Clear PEF
Clear PEF to 0
Figure 13.6 Using Periodic Interrupt Function
13.4.3
Precautions when Using RTC Module Standby
Before switching the RTC to module standby, access at least one among the registers RTC, SCI,
and TMU.
Rev. 5.00, 09/03, page 426 of 760
Section 14 Serial Communication Interface (SCI)
14.1
Overview
The SH7709S has an on-chip serial communication interface (SCI) that supports both
asynchronous and clock synchronous serial communication. It also has a multiprocessor
communication function for serial communication among two or more processors. The SCI
supports a smart card interface, which is a serial communication feature for IC card interfaces that
conforms to the ISO/IEC standard 7816-3 for identification cards. See section 15, Smart Card
Interface, for more information.
14.1.1
Features
Selection of asynchronous or synchronous as the serial communication mode.
• Asynchronous mode:
 Serial data communication is synchronized by start-stop in character units. The SCI can
communicate with a universal asynchronous receiver/transmitter (UART), an asynchronous
communication interface adapter (ACIA), or any other communications chip that employs
a standard asynchronous serial system. It can also communicate with two or more other
processors using the multiprocessor communication function. There are 12 selectable serial
data communication formats.
 Data length: 7 or 8 bits
 Stop bit length: 1 or 2 bits
 Parity: Even, odd, or none
 Multiprocessor bit: 1 or 0
 Receive error detection: Parity, overrun, and framing errors
 Break detection: By reading the RxD level directly from the SC port data register (SCPDR)
when a framing error occurs
• Synchronous mode:
 Serial data communication is synchronized with a clock signal. The SCI can communicate
with other chips having a synchronous communication function. There is one serial data
communication format.
 Data length: 8 bits
 Receive error detection: Overrun errors
• Full duplex communication: The transmitting and receiving sections are independent, so the
SCI can transmit and receive simultaneously. Both sections use double buffering, so
continuous data transfer is possible in both the transmit and receive directions.
• On-chip baud rate generator with selectable bit rates
Rev. 5.00, 09/03, page 427 of 760
• Internal or external transmit/receive clock source: From either baud rate generator (internal) or
SCK pin (external)
• Four types of interrupts: Transmit-data-empty, transmit-end, receive-data-full, and receiveerror interrupts are requested independently.
• When the SCI is not in use, it can be stopped by halting the clock supplied to it, saving power.
14.1.2
Block Diagram
Bus interface
Figure 14.1 shows a block diagram of the SCI.
Module data bus
SCRDR
RxD
TxD
SCRSR
SCTDR
SCTSR
SCPCR
SCPDR
SCSSR
SCSCR
SCSMR
Transmit/
receive
control
Parity check
SCBRR
Baud rate
generator
Receive shift register
Receive data register
Transmit shift register
Transmit data register
Serial mode register
Pφ/64
External clock
SCSCR:
SCSSR:
SCBRR:
SCPDR:
SCPCR:
Serial control register
Serial status register
Bit rate register
SC port data register
SC port control register
Figure 14.1 Block Diagram of SCI
Rev. 5.00, 09/03, page 428 of 760
Pφ/4
Pφ/16
SCI
Legend
SCRSR:
SCRDR:
SCTSR:
SCTDR:
SCSMR:
Pφ
Clock
Parity generation
SCK
Internal
data bus
TEI
TXI
RXI
ERI
Figures 14.2, 14.3, and 14.4 show block diagrams of the SCI I/O port pins.
SCIF pin I/O and data control is performed by bits 11 to 8 of SCPCR and bits 5 and 4 of SCPDR.
For details, see section 14.2.8, SC Port Control Register (SCPCR)/SC Port Data Register
(SCPDR).
Reset
R
D
SCP1MD0
Q
C
Internal data bus
PCRW
Reset
R
Q
D
SCP1MD1
C
SCI
PCRW
Clock input enable
Reset
SCPT[1]/SCK0
R
Q
D
SCP1DT1
C
PDRW
Output enable
Serial clock output
PDRR*
Serial clock input
Legend
PDRW: SCPDR write
PDRR: SCPDR read
PCRW: SCPCR write
Note: * When reading the SCK0 pin, clear the C/A bit in SCSMR and the CKE1 and CKE0
bits in SCSCR to 0, and set the SCP1MD1 bit in SCPCR to 1 (see section 14.2.8,
SC Port Control Register (SCPCR)/SC Port Data Register (SCPDR)).
Figure 14.2 SCPT[1]/SCK0 Pin
Rev. 5.00, 09/03, page 429 of 760
Reset
R
D
SCP0MD0
Q
C
Internal data bus
PCRW
Reset
R
Q
D
SCP0MD1
C
PCRW
Reset
SCPT[0]/TxD0
R
Q
D
SCP0DT1
C
SCI
PDRW
Output enable
Serial
transmission
output
Legend
PCRW: SCPCR write
PDRW: SCPDR write
Figure 14.3 SCPT[0]/TxD0 Pin
Rev. 5.00, 09/03, page 430 of 760
SCI
SCPT[0]/RxD0
Serial
receive
data
Internal data bus
PDRR*
Legend
PDRR: PDR read
Note: * When reading the RxD0 pin, set the RE bit in SCSCR to 1.
Figure 14.4 SCPT[0]/RxD0 Pin
14.1.3
Pin Configuration
The SCI has the serial pins summarized in table 14.1.
Table 14.1 SCI Pins
Pin Name
Abbreviation
I/O
Function
Serial clock pin
SCK0
I/O
Clock I/O
Receive data pin
RxD0
Input
Receive data input
Transmit data pin
TxD0
Output
Transmit data output
Note: These pins are made to function as serial pins by performing SCI operation settings with the
TE, RE, CKEI, and CKE0 bits in SCSCR and the C/A bit in SCSMR. Break state
transmission and detection can be performed by means of the SCI’s SCSPTR register.
Rev. 5.00, 09/03, page 431 of 760
14.1.4
Register Configuration
Table 14.2 summarizes the SCI internal registers. These registers select the communication mode
(asynchronous or synchronous), specify the data format and bit rate, and control the transmitter
and receiver sections.
Table 14.2 SCI Registers
Name
Abbreviation
R/W
Initial Value
Address
Access size
Serial mode register
SCSMR
R/W
H'00
H'FFFFFE80
8
Bit rate register
SCBRR
R/W
H'FF
H'FFFFFE82
8
Serial control register
SCSCR
R/W
H'00
H'FFFFFE84
8
Transmit data register
SCTDR
R/W
H'FF
H'FFFFFE86
8
Serial status register
SCSSR
R/(W)*
H'84
H'FFFFFE88
8
Receive data register
SCRDR
R
H'00
H'FFFFFE8A
8
SC port data register
SCPDR
R/W
H'00
H'04000136
8
2
(H'A4000136)*
SC port control register
SCPCR
R/W
H'A888
H'04000116
16
2
(H'A4000116)*
Notes: These registers are located in area 1 of physical space. Therefore, when the cache is on,
either access these registers from the P2 area of logical space or else make an appropriate
setting using the MMU so that these registers are not cached.
1. The only value that can be written is 0 to clear the flags.
2. When address translation by the MMU does not apply, the address in parentheses
should be used.
14.2
Register Descriptions
14.2.1
Receive Shift Register (SCRSR)
The receive shift register (SCRSR) receives serial data. Data input at the RxD pin is loaded into
SCRSR in the order received, LSB (bit 0) first, converting the data to parallel form. When one
byte has been received, it is automatically transferred to SCRDR. The CPU cannot read or write to
SCRSR directly.
Bit:
7
6
5
4
3
2
1
0
R/W:
—
—
—
—
—
—
—
—
Rev. 5.00, 09/03, page 432 of 760
14.2.2
Receive Data Register (SCRDR)
The receive data register (SCRDR) stores serial receive data. The SCI completes the reception of
one byte of serial data by moving the received data from the receive shift register (SCRSR) into
SCRDR for storage. SCRSR is then ready to receive the next data. This double buffering allows
the SCI to receive data continuously.
The CPU can read but not write to SCRDR. SCRDR is initialized to H'00 by a reset and in standby
or module standby mode.
Bit:
7
6
5
4
3
2
1
0
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R
R
R
R
R
R
R
14.2.3
Transmit Shift Register (SCTSR)
The transmit shift register (SCTSR) transmits serial data. The SCI loads transmit data from the
transmit data register (SCTDR) into SCTSR, then transmits the data serially from the TxD pin,
LSB (bit 0) first. After transmitting one-byte data, the SCI automatically loads the next transmit
data from SCTDR into SCTSR and starts transmitting again. If the TDRE bit in SCSSR is 1,
however, the SCI does not load the SCTDR contents into SCTSR. The CPU cannot read or write
to SCTSR directly.
Bit:
7
6
5
4
3
2
1
0
R/W:
—
—
—
—
—
—
—
—
Rev. 5.00, 09/03, page 433 of 760
14.2.4
Transmit Data Register (SCTDR)
The transmit data register (SCTDR) is an 8-bit register that stores data for serial transmission.
When the SCI detects that the transmit shift register (SCTSR) is empty, it moves transmit data
written in SCTDR into SCTSR and starts serial transmission. Continuous serial transmission is
possible by writing the next transmit data in SCTDR during serial transmission from SCTSR.
The CPU can always read and write to SCTDR. SCTDR is initialized to H'FF by a reset and in
standby or module standby mode.
Bit:
7
6
5
4
3
2
1
0
Initial value:
1
1
1
1
1
1
1
1
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W:
14.2.5
Serial Mode Register (SCSMR)
The serial mode register (SCSMR) is an 8-bit register that specifies the SCI serial communication
format and selects the clock source for the baud rate generator.
The CPU can always read and write to SCSMR. SCSMR is initialized to H'00 by a reset and in
standby or module standby mode.
Bit:
Initial value:
R/W:
7
6
5
4
3
2
1
0
C/A
CHR
PE
O/E
STOP
MP
CKS1
CKS0
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Bit 7—Communication Mode (C/A
A): Selects whether the SCI operates in asynchronous or
synchronous mode.
Bit 7: C/A
A
Description
0
Asynchronous mode
1
Synchronous mode
Rev. 5.00, 09/03, page 434 of 760
(Initial value)
Bit 6—Character Length (CHR): Selects 7-bit or 8-bit data in asynchronous mode. In the
synchronous mode, the data length is always eight bits, regardless of the CHR setting.
Bit 6: CHR
Description
0
8-bit data
7-bit data*
1
(Initial value)
Note: * When 7-bit data is selected, the MSB (bit 7) of the transmit data register (SCTDR) is not
transmitted.
Bit 5—Parity Enable (PE): Selects whether to add a parity bit to transmit data and to check the
parity of receive data, in asynchronous mode. In synchronous mode, a parity bit is neither added
nor checked, regardless of the PE setting.
Bit 5: PE
Description
0
Parity bit not added or checked
Parity bit added and checked*
1
(Initial value)
Note: * When PE is set to 1, an even or odd parity bit is added to transmit data, depending on the
parity mode (O/E) setting. Receive data parity is checked according to the even/odd (O/E)
mode setting.
Bit 4—Parity Mode (O/E
E): Selects even or odd parity when parity bits are added and checked.
The O/E setting is used only in asynchronous mode and only when the parity enable bit (PE) is set
to 1 to enable parity addition and checking. The O/E setting is ignored in synchronous mode, or in
asynchronous mode when parity addition and checking is disabled.
Bit 4: O/E
E
Description
0
Even parity*
2
Odd parity*
1
1
(Initial value)
Notes: 1. If even parity is selected, the parity bit is added to transmit data to make an even
number of 1s in the transmitted character and parity bit combined. Receive data is
checked to see if it has an even number of 1s in the received character and parity bit
combined.
2. If odd parity is selected, the parity bit is added to transmit data to make an odd number
of 1s in the transmitted character and parity bit combined. Receive data is checked to
see if it has an odd number of 1s in the received character and parity bit combined.
Rev. 5.00, 09/03, page 435 of 760
Bit 3—Stop Bit Length (STOP): Selects one or two bits as the stop bit length in asynchronous
mode. This setting is used only in asynchronous mode. It is ignored in synchronous mode because
no stop bits are added.
When receiving, only the first stop bit is checked, regardless of the STOP bit setting. If the second
stop bit is 1, it is treated as a stop bit, but if the second stop bit is 0, it is treated as the start bit of
the next incoming character.
Bit 3: STOP
Description
0
One stop bit*
2
Two stop bits*
1
1
(Initial value)
Notes: 1. When transmitting, a single 1-bit is added at the end of each transmitted character.
2. When transmitting, two 1-bits are added at the end of each transmitted character.
Bit 2—Multiprocessor Mode (MP): Selects multiprocessor format. When multiprocessor format
is selected, settings of the parity enable (PE) and parity mode (O/E) bits are ignored. The MP bit
setting is used only in asynchronous mode; it is ignored in synchronous mode. For the
multiprocessor communication function, see section 14.3.3, Multiprocessor Communication.
Bit 2: MP
Description
0
Multiprocessor function disabled
1
Multiprocessor format selected
(Initial value)
Bits 1 and 0—Clock Select 1 and 0 (CKS1, CKS0): Select the internal clock source of the onchip baud rate generator. Four clock sources are available. Pφ, Pφ/4, Pφ/16 and Pφ/64 can be set
according to the setting of the CKS1 and CKS0 bits. For further information on the clock source,
bit rate register settings, and baud rate, see section 14.2.9, Bit Rate Register (SCBRR).
Bit 1: CKS1
Bit 0: CKS0
Description
0
0
Pφ
1
Pφ/4
0
Pφ/16
1
Pφ/64
1
Note: Pφ: Peripheral clock
Rev. 5.00, 09/03, page 436 of 760
(Initial value)
14.2.6
Serial Control Register (SCSCR)
The serial control register (SCSCR) operates the SCI transmitter/receiver, selects the serial clock
output in asynchronous mode, enables/disables interrupt requests, and selects the transmit/receive
clock source. The CPU can always read and write to SCSCR. SCSCR is initialized to H'00 by a
reset and in standby or module standby mode.
Bit:
Initial value:
R/W:
7
6
5
4
3
2
1
0
TIE
RIE
TE
RE
MPIE
TEIE
CKE1
CKE0
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Bit 7—Transmit Interrupt Enable (TIE): Enables or disables the transmit-data-empty interrupt
(TXI) requested when the transmit data register empty bit (TDRE) in the serial status register
(SCSSR) is set to 1 due to transfer of serial transmit data from SCTDR to SCTSR.
Bit 7: TIE
Description
0
Transmit-data-empty interrupt request (TXI) is disabled*
1
Transmit-data-empty interrupt request (TXI) is enabled
(Initial value)
Note: * The TXI interrupt request can be cleared by reading TDRE after it has been set to 1, then
clearing TDRE to 0, or by clearing TIE to 0.
Bit 6—Receive Interrupt Enable (RIE): Enables or disables the receive-data-full interrupt (RXI)
requested when the receive data register full bit (RDRF) in the serial status register (SCSSR) is set
to 1 due to transfer of serial receive data from SCRSR to SCRDR. It also enables or disables
receive-error interrupt (ERI) requests.
Bit 6: RIE
Description
0
Receive-data-full interrupt (RXI) and receive-error interrupt (ERI) requests are
disabled*
(Initial value)
1
Receive-data-full interrupt (RXI) and receive-error interrupt (ERI) requests are
enabled
Note: * RXI and ERI interrupt requests can be cleared by reading the RDRF flag or error flag
(FER, PER, or ORER) after it has been set to 1, then clearing the flag to 0, or by clearing
RIE to 0.
Rev. 5.00, 09/03, page 437 of 760
Bit 5—Transmit Enable (TE): Enables or disables the SCI serial transmitter.
Bit 5: TE
Description
0
Transmitter disabled*
2
Transmitter enabled*
1
1
(Initial value)
Notes: 1. The transmit data register empty bit (TDRE) in the serial status register (SCSSR) is
fixed at 1.
2. Serial transmission starts when the transmit data register empty (TDRE) bit in the serial
status register (SCSSR) is cleared to 0 after writing of transmit data into the SCTDR.
Select the transmit format in SCSMR before setting TE to 1.
Bit 4—Receive Enable (RE): Enables or disables the SCI serial receiver.
Bit 4: RE
Description
0
Receiver disabled*
2
Receiver enabled*
1
1
(Initial value)
Notes: 1. Clearing RE to 0 does not affect the receive flags (RDRF, FER, PER, ORER). These
flags retain their previous values.
2. Serial reception starts when a start bit is detected in asynchronous mode, or
synchronous clock input is detected in synchronous mode. Select the receive format in
SCSMR before setting RE to 1.
Bit 3—Multiprocessor Interrupt Enable (MPIE): Enables or disables multiprocessor interrupts.
The MPIE setting is used only in asynchronous mode, and only if the multiprocessor mode bit
(MP) in the serial mode register (SCSMR) is set to 1 during reception. The MPIE setting is
ignored in synchronous mode or when the MP bit is cleared to 0.
Bit 3: MPIE
Description
0
Multiprocessor interrupts are disabled (normal receive operation)
(Initial value)
[Clearing conditions]
(1) MPE is cleared to 0 when MPIE is cleared to 0.
(2) The multiprocessor bit (MPB) is set to 1 in receive data.
1
Multiprocessor interrupts are enabled*
Receive-data-full interrupt requests (RXI), receive-error interrupt requests (ERI),
and setting of the RDRF, FER, and ORER status flags in the serial status register
(SCSSR) are disabled until data with a multiprocessor bit of 1 is received.
Note: * The SCI does not transfer receive data from SCRSR to SCRDR, does not detect receive
errors, and does not set the RDRF, FER, and ORER flags in the serial status register
(SCSSR). When it receives data that includes MPB = 1, the SCSSR’s MPB flag is set to 1,
and the SCI automatically clears MPIE to 0, generates RXI and ERI interrupts (if the TIE
and RIE bits in the SCSCR are set to 1), and allows the FER and ORER bits to be set.
Rev. 5.00, 09/03, page 438 of 760
Bit 2—Transmit-End Interrupt Enable (TEIE): Enables or disables the transmit-end interrupt
(TEI) requested if SCTDR does not contain new transmit data when the MSB is transmitted.
Bit 2: TEIE
Description
0
Transmit-end interrupt (TEI) requests are disabled*
Transmit-end interrupt (TEI) requests are enabled *
1
(Initial value)
Note: * The TEI request can be cleared by reading the TDRE bit in the serial status register
(SCSSR) after it has been set to 1, then clearing TDRE to 0 and clearing the transmit end
(TEND) bit to 0, or by clearing the TEIE bit to 0.
Bits 1 and 0—Clock Enable 1 and 0 (CKE1, CKE0): Select the SCI clock source and enable or
disable clock output from the SCK pin. Depending on the combination of CKE1 and CKE0, the
SCK pin can be used for serial clock output or serial clock input.
The CKE0 setting is valid only in asynchronous mode, and only when the SCI is internally
clocked (CKE1 = 0). The CKE0 setting is ignored in synchronous mode, or when an external
clock source is selected (CKE1 = 1). Before selecting the SCI operating mode in the serial mode
register (SCSMR), set CKE1 and CKE0. For further details on selection of the SCI clock source,
see table 14.10 in section 14.3, Operation.
Bit 1:
CKE1
Bit 0:
CKE0
Description
0
0
Asynchronous mode
Internal clock, SCK pin used for input pin (input signal
is ignored)
(Initial value)
Synchronous mode
Internal clock, SCK pin used for synchronous clock
output
(Initial value)
1
Internal clock, SCK pin used for clock output*
1
Asynchronous mode
Synchronous mode
1
0
Asynchronous mode
Synchronous mode
1
Asynchronous mode
Synchronous mode
Internal clock, SCK pin used for synchronous clock
output
2
External clock, SCK pin used for clock input*
External clock, SCK pin used for synchronous clock
input
2
External clock, SCK pin used for clock input*
External clock, SCK pin used for synchronous clock
input
Notes: 1. The output clock frequency is the same as the bit rate.
2. The input clock frequency is 16 times the bit rate.
Rev. 5.00, 09/03, page 439 of 760
14.2.7
Serial Status Register (SCSSR)
The serial status register (SCSSR) is an 8-bit register containing multiprocessor bit values, and
status flags that indicate the SCI operating state.
The CPU can always read and write to SCSSR, but cannot write 1 to the status flags (TDRE,
RDRF, ORER, PER, and FER). These flags can be cleared to 0 only if they have first been read
(after being set to 1). Bits 2 (TEND) and 1 (MPB) are read-only bits that cannot be written.
SCSSR is initialized to H'84 by a reset and in standby or module standby mode.
Bit:
Initial value:
R/W:
7
6
5
4
3
2
1
0
TDRE
RDRF
ORER
FER
PER
TEND
MPB
MPBT
1
0
0
0
0
1
0
0
R/(W)*
R/(W)*
R/(W)*
R/(W)*
R/(W)*
R
R
R/W
Note: * The only value that can be written is 0 to clear the flag.
Bit 7—Transmit Data Register Empty (TDRE): Indicates that the SCI has loaded transmit data
from SCTDR into SCTSR and new serial transmit data can be written in SCTDR.
Bit 7: TDRE
Description
0
SCTDR contains valid transmit data
[Clearing condition]
TDRE is cleared to 0 when software reads TDRE after it has been set to 1.
1
SCTDR does not contain valid transmit data
(Initial value)
[Setting conditions]
(1) TDRE is set to 1 when the chip is reset or enters standby mode.
(2) The TE bit in the serial control register (SCSCR) is cleared to 0.
(3) SCTDR contents are loaded into SCTSR, so new data can be written in
SCTDR.
Rev. 5.00, 09/03, page 440 of 760
Bit 6—Receive Data Register Full (RDRF): Indicates that SCRDR contains received data.
Bit 6: RDRF
Description
0
SCRDR does not contain valid receive data
(Initial value)
[Clearing conditions]
(1) RDRF is cleared to 0 when the chip is reset or enters standby mode.
(2) Software reads RDRF after it has been set to 1, then writes 0 in RDRF.
1
SCRDR contains valid receive data
[Setting condition]
RDRF is set to 1 when serial data is received normally and transferred from
SCRSR to SCRDR.
Note: SCRDR and RDRF are not affected by detection of receive errors or by clearing of the RE
bit to 0 in the serial control register. They retain their previous contents. If RDRF is still set
to 1 when reception of the next data ends, an overrun error (ORER) occurs and the receive
data is lost.
Bit 5—Overrun Error (ORER): Indicates that data reception aborted due to an overrun error.
Bit 5: ORER
Description
0
Receiving is in progress or has ended normally*
1
(Initial value)
[Clearing conditions]
(1) ORER is cleared to 0 when the chip is reset or enters standby mode.
1
(2) When software reads ORER after it has been set to 1, then writes 0 to
ORER.
2
A receive overrun error occurred*
[Setting condition]
ORER is set to 1 if reception of the next serial data ends when RDRF is set to 1.
Notes: 1. Clearing the RE bit to 0 in the serial control register does not affect the ORER bit, which
retains its previous value.
2. SCRDR continues to hold the data received before the overrun error, so subsequent
receive data is lost. Serial receiving cannot continue while ORER is set to 1. In
synchronous mode, serial transmitting is also disabled.
Rev. 5.00, 09/03, page 441 of 760
Bit 4—Framing Error (FER): Indicates that data reception aborted due to a framing error in
asynchronous mode.
Bit 4: FER
Description
0
1
Receiving is in progress or has ended normally*
(Initial value)
[Clearing conditions]
(1) FER is cleared to 0 when the chip is reset or enters standby mode.
(2) When software reads FER after it has been set to 1, then writes 0 to FER.
1
A receive framing error occurred
[Setting condition]
FER is set to 1 if the stop bit at the end of receive data is checked and found to
2
be 0.*
Notes: 1. Clearing the RE bit to 0 in the serial control register does not affect the FER bit, which
retains its previous value.
2. When the stop bit length is two bits, only the first bit is checked. The second stop bit is
not checked. When a framing error occurs, the SCI transfers the receive data into
SCRDR but does not set RDRF. Serial receiving cannot continue while FER is set to 1.
In synchronous mode, serial transmitting is also disabled.
Bit 3—Parity Error (PER): Indicates that data reception (with parity) aborted due to a parity
error in asynchronous mode.
Bit 3: PER
Description
0
1
Receiving is in progress or has ended normally*
(Initial value)
[Clearing conditions]
(1) PER is cleared to 0 when the chip is reset or enters standby mode.
1
(2) When software reads PER after it has been set to 1, then writes 0 to PER.
2
A receive parity error occurred*
[Setting condition]
PER is set to 1 if the number of 1s in receive data, including the parity bit, does
not match the even or odd parity setting of the parity mode bit (O/E) in the serial
mode register (SCSMR).
Notes: 1. Clearing the RE bit to 0 in the serial control register does not affect the PER bit, which
retains its previous value.
2. When a parity error occurs, the SCI transfers the receive data into SCRDR but does not
set RDRF. Serial receiving cannot continue while PER is set to 1. In synchronous
mode, serial transmitting is also disabled.
Rev. 5.00, 09/03, page 442 of 760
Bit 2—Transmit End (TEND): Indicates that when the last bit of a serial character was
transmitted, SCTDR did not contain valid data, so transmission has ended. TEND is a read-only
bit and cannot be written to.
Bit 2: TEND
Description
0
Transmission is in progress
[Clearing condition]
TEND is cleared to 0 when software reads TDRE after it has been set to 1, then
writes 0 to TDRE.
1
End of transmission
(Initial value)
[Setting conditions]
(1) TEND is set to 1 when the chip is reset or enters standby mode.
(2) When TE is cleared to 0 in the serial control register (SCSCR).
(3) If TDRE is 1 when the last bit of a one-byte serial character is transmitted.
Bit 1—Multiprocessor Bit (MPB): Stores the value of the multiprocessor bit in receive data
when a multiprocessor format is selected for receiving in asynchronous mode. MPB is a read-only
bit and cannot be written to.
Bit 1: MPB
Description
0
Multiprocessor bit value in receive data is 0*
1
Multiprocessor bit value in receive data is 1
(Initial value)
Note: * If RE is cleared to 0 when a multiprocessor format is selected, MPB retains its
previous value.
Bit 0—Multiprocessor Bit Transfer (MPBT): Stores the value of the multiprocessor bit added to
transmit data when a multiprocessor format is selected for transmitting in asynchronous mode.
The MPBT setting is ignored in synchronous mode, when a multiprocessor format is not selected,
or when the SCI is not transmitting.
Bit 0: MPBT
Description
0
Multiprocessor bit value in transmit data is 0
1
Multiprocessor bit value in transmit data is 1
(Initial value)
Rev. 5.00, 09/03, page 443 of 760
14.2.8
SC Port Control Register (SCPCR)/SC Port Data Register (SCPDR)
The SC port control register (SCPCR) and SC port data register (SCPDR) control I/O and data for
the port pins multiplexed with the serial communication interface (SCI) pins.
SCPCR settings are used to perform I/O control, to enable data written in SCPDR to be output to
the TxD pin, and input data to be read from the RxD pin, and to control serial
transmission/reception breaks.
It is also possible to read data on the SCK pin, and write output data.
SCPCR
Bit:
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
SCP7 SCP7 SCP6 SCP6 SCP5 SCP5 SCP4 SCP4 SCP3 SCP3 SCP2 SCP2 SCP1 SCP1 SCP0 SCP0
MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0
Initial value:
1
0
1
0
1
0
0
0
1
0
0
0
1
0
0
0
R/W: R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W
SCPDR
Bit:
7
6
5
4
3
2
1
0
SCP7DT SCP6DT SCP5DT SCP4DT SCP3DT SCP2DT SCP1DT SCP0DT
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R/W
R/W
R/W
R/W
R/W
R/W
R/W
SCI pin I/O and data control are performed by bits 3–0 of SCPCR and bits 1 and 0 of SCPDR.
SCPCR Bits 3 and 2—Serial Clock Port I/O (SCP1MD1, SCP1MD0): Specify serial port SCK
pin I/O. When the SCK pin is actually used as a port I/O pin, clear the C/A bit in SCSMR and bits
CKE1 and CKE0 in SCSCR to 0.
Bit 3:
SCP1MD1
Bit 2:
SCP1MD0
Description
0
0
SCP1DT bit value is not output to SCK pin
0
1
SCP1DT bit value is output to SCK pin
1
0
SCK pin value is read from SCP1DT bit
1
1
Rev. 5.00, 09/03, page 444 of 760
(Initial values: 1 and 0)
SCPDR Bit 1—Serial Clock Port Data (SCP1DT): Specifies the serial port SCK pin I/O data.
Input or output is specified by the SCP1MD1 and SCP1MD0 bits. In output mode, the value of
the SCP1DT bit is output to the SCK pin.
Bit 1:
SCP1DT
Description
0
I/O data is low
1
I/O data is high
(Initial value)
SCPCR Bits 1 and 0—Serial Port Break I/O (SCP0MD1, SCP0MD0): Specify the serial port
TxD pin output condition. When the TxD pin is actually used as a port output pin and outputs the
value set with the SCP0DT bit, clear the TE bit in SCSCR to 0.
Bit 1:
SCP0MD1
Bit 0:
SCP0MD0
Description
0
0
SCP0DT bit value is not output to TxD pin
0
1
SCP0DT bit value is output to TxD pin
(Initial value)
SCPDR Bit 0—Serial Port Break Data (SCP0DT): Specifies the serial port RxD pin input data
and TxD pin output data. The TxD pin output condition is specified by the SCP0MD1 and
SCP0MD0 bits. When the TxD pin is set to output mode, the value of the SCP0DT bit is output to
the TxD pin. The RxD pin value is read from the SCP0DT bit regardless of the values of the
SCP0MD1 and SCP0MD0 bits, if RE in SCSCR is set to 1. The initial value of this bit after a
power-on reset is undefined.
Bit 0:
SCP0DT
Description
0
I/O data is low
1
I/O data is high
(Initial value)
Block diagrams of the SCI I/O port pins are shown in figures 14.2, 14.3, and 14.4.
Rev. 5.00, 09/03, page 445 of 760
14.2.9
Bit Rate Register (SCBRR)
The bit rate register (SCBRR) is an 8-bit register that, together with the baud rate generator clock
source selected by the CKS1 and CKS0 bits in the serial mode register (SCSMR), determines the
serial transmit/receive bit rate.
The CPU can always read and write to SCBRR. SCBRR is initialized to H'FF by a reset, and in
module standby or standby mode. Each channel has independent baud rate generator control, so
different values can be set in two channels.
Bit:
7
6
5
4
3
2
1
0
Initial value:
1
1
1
1
1
1
1
1
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W:
The SCBRR setting is calculated as follows:
Asynchronous mode: N =
Synchronous mode: N =
B:
N:
Pφ:
n:
Pφ
64 × 22n – 1 × B
Pφ
8×
22n – 1
×B
× 106 – 1
× 106 – 1
Bit rate (bits/s)
SCBRR setting for baud rate generator (0 ≤ N ≤ 255)
Operating frequency for peripheral modules (MHz)
Baud rate generator clock source (n = 0, 1, 2, 3) (for the clock sources and values of
n, see table 14.3.)
Table 14.3 SCSMR Settings
SCSMR Settings
n
Clock Source
CKS1
CKS0
0
Pφ
0
0
1
Pφ/4
0
1
2
Pφ/16
1
0
3
Pφ/64
1
1
Note: The bit rate error in asynchronous is given by the following formula:
Pφ × 106
Error (%) = (
) × 100
(N + 1) × B × 64 × 22n – 1
Rev. 5.00, 09/03, page 446 of 760
Table 14.4 lists examples of SCBRR settings in asynchronous mode, and table 14.5 lists examples
of SCBRR settings in synchronous mode.
Table 14.4 Bit Rates and SCBRR Settings in Asynchronous Mode
Pφ
φ (MHz)
2
2.097152
2.4576
Bit Rate (bits/s) n
N
Error (%
%) n
N
Error (%
%) n
N
Error (%
%)
110
1
141
0.03
1
148
–0.04
1
174
–0.26
150
1
103
0.16
1
108
0.21
1
127
0.00
300
0
207
0.16
0
217
0.21
0
255
0.00
600
0
103
0.16
0
108
0.21
0
127
0.00
1200
0
51
0.16
0
54
–0.70
0
63
0.00
2400
0
25
0.16
0
26
1.14
0
31
0.00
4800
0
12
0.16
0
13
–2.48
0
15
0.00
9600
0
6
–6.99
0
6
–2.48
0
7
0.00
19200
0
2
8.51
0
2
13.78
0
3
0.00
31250
0
1
0.00
0
1
4.86
0
1
22.88
38400
0
1
–18.62
0
1
–14.67
0
1
0.00
Pφ
φ (MHz)
3.6864
3
4
Bit Rate (bits/s) n
N
Error (%
%) n
N
Error (%
%) n
N
Error (%
%)
110
1
212
0.03
2
64
0.70
2
70
0.03
150
1
155
0.16
1
191
0.00
1
207
0.16
300
1
77
0.16
1
95
0.00
1
103
0.16
600
0
155
0.16
0
191
0.00
0
207
0.16
1200
0
77
0.16
0
95
0.00
0
103
0.16
2400
0
38
0.16
0
47
0.00
0
51
0.16
4800
0
19
–2.34
0
23
0.00
0
25
0.16
9600
0
9
–2.34
0
11
0.00
0
12
0.16
19200
0
4
–2.34
0
5
0.00
0
6
–6.99
31250
0
2
0.00
—
—
—
0
3
0.00
38400
—
—
—
0
2
0.00
0
2
8.51
Rev. 5.00, 09/03, page 447 of 760
Pφ
φ (MHz)
4.9152
5
6
Bit Rate (bits/s) n
N
Error (%
%) n
N
Error (%
%) n
N
Error (%
%)
110
2
86
0.31
2
88
–0.25
2
106
–0.44
150
1
255
0.00
2
64
0.16
2
77
0.16
300
1
127
0.00
1
129
0.16
1
155
0.16
600
0
255
0.00
1
64
0.16
1
77
0.16
1200
0
127
0.00
0
129
0.16
0
155
0.16
2400
0
63
0.00
0
64
0.16
0
77
0.16
4800
0
31
0.00
0
32
–1.36
0
38
0.16
9600
0
15
0.00
0
15
1.73
0
19
–2.34
19200
0
7
0.00
0
7
1.73
0
9
–2.34
31250
0
4
–1.70
0
4
0.00
0
5
0.00
38400
0
3
0.00
0
3
1.73
0
4
–2.34
Pφ
φ (MHz)
7.3728
6.144
8
Bit Rate (bits/s) n
N
Error (%
%) n
N
Error (%
%) n
N
Error (%
%)
110
2
108
0.08
130
–0.07
2
141
0.03
150
2
79
0.00
2
95
0.00
2
103
0.16
300
1
159
0.00
1
191
0.00
1
207
0.16
600
1
79
0.00
1
95
0.00
1
103
0.16
1200
0
159
0.00
0
191
0.00
0
207
0.16
2400
0
79
0.00
0
95
0.00
0
103
0.16
4800
0
39
0.00
0
47
0.00
0
51
0.16
2
9600
0
19
0.00
0
23
0.00
0
25
0.16
19200
0
9
0.00
0
11
0.00
0
12
0.16
31250
0
5
2.40
0
6
5.33
0
7
0.00
38400
0
4
0.00
0
5
0.00
0
6
–6.99
Rev. 5.00, 09/03, page 448 of 760
Pφ
φ (MHz)
14.7456
16
19.6608
20
Bit Rate
(bits/s)
n
N
Error
(%
%)
n
N
Error
(%
%)
n
N
Error
(%
%)
n
N
Error
(%
%)
110
3
64
0.70
3
70
0.03
3
86
0.31
3
88
–0.25
150
2
191
0.00
2
207
0.16
2
255
0.00
3
64
0.16
300
2
95
0.00
2
103
0.16
2
127
0.00
2
129
0.16
600
1
191
0.00
1
207
0.16
1
255
0.00
2
64
0.16
1200
1
95
0.00
1
103
0.16
1
127
0.00
1
129
0.16
2400
0
191
0.00
0
207
0.16
0
255
0.00
1
64
0.16
4800
0
95
0.00
0
103
0.16
0
127
0.00
0
129
0.16
9600
0
47
0.00
0
51
0.16
0
63
0.00
0
64
0.16
19200
0
23
0.00
0
25
0.16
0
31
0.00
0
32
–1.36
31250
0
14
–1.70 0
15
0.00
0
19
–1.70 0
19
0.00
38400
0
11
0.00
12
0.16
0
15
0.00
15
1.73
0
0
Pφ
φ (MHz)
24
24.576
Bit Rate
(bits/s)
n
N
Error
(%
%)
110
3
106
150
3
300
600
28.7
30
N
Error
(%
%)
n
N
Error
(%
%)
n
N
Error
(%
%)
–0.44 3
108
0.08
3
126
0.31
3
132
0.13
77
0.16
3
79
0.00
3
92
0.46
3
97
–0.35
2
155
0.16
2
159
0.00
2
186
–0.08 2
194
0.16
2
77
0.16
2
79
0.00
2
92
0.46
97
–0.35
n
2
1200
1
155
0.16
1
159
0.00
1
186
–0.08 1
194
0.16
2400
1
77
0.16
1
79
0.00
1
92
0.46
97
–0.35
4800
0
155
0.16
0
159
0.00
0
186
–0.08 0
194
–1.36
9600
0
77
0.16
0
79
0.00
0
92
0.46
0
97
–0.35
19200
0
38
0.16
0
39
0.00
0
46
–0.61 0
48
–0.35
31250
0
23
0.00
0
24
–1.70 0
28
–1.03 0
29
0.00
38400
0
19
–2.34 0
19
0.00
22
1.55
23
1.73
0
1
0
Rev. 5.00, 09/03, page 449 of 760
Table 14.5 Bit Rates and SCBRR Settings in Synchronous Mode
Pφ
φ (MHz)
4
8
16
28.7
30
Bit Rate
(bits/s)
n
N
n
N
n
N
n
N
n
N
110
—
—
—
—
—
—
—
—
—
—
250
2
249
3
124
3
249
—
—
—
—
500
2
124
2
249
3
124
3
223
3
233
1k
1
249
2
124
2
249
3
111
3
116
2.5k
1
99
1
199
2
99
2
178
2
187
5k
0
199
1
99
1
199
2
89
2
93
10k
0
99
0
199
1
99
1
178
1
187
25k
0
39
0
79
0
159
1
71
1
74
50k
0
19
0
39
0
79
0
143
0
149
100k
0
9
0
19
0
39
0
71
0
74
250k
0
3
0
7
0
15
—
—
0
29
500k
0
1
0
3
0
7
—
—
0
14
1M
0
0*
0
1
0
3
—
—
—
—
0
0*
0
1
—
—
—
—
2M
Notes: Settings with an error of 1% or less are recommended.
Blank: No setting possible
—:
Setting possible, but error occurs
*:
Continuous transmit/receive operation not possible
Rev. 5.00, 09/03, page 450 of 760
Table 14.6 indicates the maximum bit rates in asynchronous mode when the baud rate generator is
used. Tables 14.7 and 14.8 list the maximum rates for external clock input.
Table 14.6 Maximum Bit Rates for Various Frequencies with Baud Rate Generator
(Asynchronous Mode)
Settings
Pφ
φ (MHz)
Maximum Bit Rate (bits/s)
n
N
2
62500
0
0
2.097152
65536
0
0
2.4576
76800
0
0
3
93750
0
0
3.6864
115200
0
0
4
125000
0
0
4.9152
153600
0
0
8
250000
0
0
9.8304
307200
0
0
12
375000
0
0
14.7456
460800
0
0
16
500000
0
0
19.6608
614400
0
0
20
625000
0
0
24
750000
0
0
24.576
768000
0
0
28.7
896875
0
0
30
937500
0
0
Rev. 5.00, 09/03, page 451 of 760
Table 14.7 Maximum Bit Rates with External Clock Input (Asynchronous Mode)
Pφ
φ (MHz)
External Input Clock (MHz)
Maximum Bit Rate (bits/s)
2
0.5000
31250
2.097152
0.5243
32768
2.4576
0.6144
38400
3
0.7500
46875
3.6864
0.9216
57600
4
1.0000
62500
4.9152
1.2288
76800
8
2.0000
125000
9.8304
2.4576
153600
12
3.0000
187500
14.7456
3.6864
230400
16
4.0000
250000
19.6608
4.9152
307200
20
5.0000
312500
24
6.0000
375000
24.576
6.1440
384000
28.7
7.1750
448436
30
7.5000
468750
Table 14.8 Maximum Bit Rates with External Clock Input (Synchronous Mode)
Pφ
φ (MHz)
External Input Clock (MHz)
Maximum Bit Rate (bits/s)
8
1.3333
1333333.3
16
2.6667
2666666.7
24
4.0000
4000000.0
28.7
4.7833
4783333.3
30
5.0000
5000000.0
Rev. 5.00, 09/03, page 452 of 760
14.3
Operation
14.3.1
Overview
For serial communication, the SCI has an asynchronous mode in which characters are
synchronized individually, and a synchronous mode in which communication is synchronized with
clock pulses. Asynchronous/synchronous mode and the transmission format are selected in the
serial mode register (SCSMR), as shown in table 14.9. The SCI clock source is selected by the
combination of the C/A bit in the serial mode register (SCSMR) and the CKE1 and CKE0 bits in
the serial control register (SCSCR), as shown in table 14.10.
Asynchronous Mode:
• Data length is selectable: 7 or 8 bits.
• Parity and multiprocessor bits are selectable. So is the stop bit length (1 or 2 bits). The
combination of the preceding selections constitutes the communication format and character
length.
• In receiving, it is possible to detect framing errors (FER), parity errors (PER), overrun errors
(ORER) and breaks.
• An internal or external clock can be selected as the SCI clock source.
 When an internal clock is selected, the SCI operates using the on-chip baud rate generator,
and can output a serial clock signal with a frequency matching the bit rate.
 When an external clock is selected, the external clock input must have a frequency 16 times
the bit rate. (The on-chip baud rate generator is not used.)
Synchronous Mode:
• The transmission/reception format has a fixed 8-bit data length.
• In receiving, it is possible to detect overrun errors (ORER).
• An internal or external clock can be selected as the SCI clock source.
 When an internal clock is selected, the SCI operates using the on-chip baud rate generator,
and outputs a serial clock signal to external devices.
 When an external clock is selected, the SCI operates on the input serial clock. The on-chip
baud rate generator is not used.
Rev. 5.00, 09/03, page 453 of 760
Table 14.9 Serial Mode Register Settings and SCI Communication Formats
SCSMR Settings
SCI Communication Format
Bit 7 Bit 6
C/A
A CHR
Bit 5
PE
Bit 2
MP
Bit 3
STOP
Mode
Data
Length
Parity
Bit
Multipro- Stop Bit
cessor Bit Length
0
0
0
0
Asynchronous
8-bit
Not set
Not set
0
1
1
2 bits
0
Set
1 bit
1
1
0
2 bits
0
7-bit
Not set
1 bit
1
1
2 bits
0
Set
1 bit
1
0
1
1
1
*
*
0
*
1
*
0
*
1
*
*
*
1 bit
2 bits
Asynchronous
(multiprocessor
format)
8-bit
Not set
Set
1 bit
2 bits
7-bit
1 bit
2 bits
Synchronous
8-bit
Not set
None
Note: Asterisks (*) indicate don’t care bits.
Table 14.10 SCSMR and SCSCR Settings and SCI Clock Source Selection
SCSMR
SCSCR Settings
Bit 7
C/A
A
Bit 1
CKE1
Bit 0
CKE0
0
0
0
1
1
SCI Transmit/Receive Clock
Mode
Asynchronous
mode
0
Clock
Source
SCK
Pin Function
Internal
SCI does not use the SCK pin
Outputs a clock with frequency
matching the bit rate
External
Inputs a clock with frequency 16
times the bit rate
Internal
Outputs the synchronous clock
External
Inputs the synchronous clock
1
1
0
0
1
1
Synchronous
mode
0
1
Rev. 5.00, 09/03, page 454 of 760
14.3.2
Operation in Asynchronous Mode
In asynchronous mode, each transmitted or received character begins with a start bit and ends with
a stop bit. Serial communication is synchronized one character at a time.
The transmitting and receiving sections of the SCI are independent, so full duplex communication
is possible. The transmitter and receiver are both double buffered, so data can be written and read
while transmitting and receiving are in progress, enabling continuous transmitting and receiving.
Figure 14.5 shows the general format of asynchronous serial communication. In asynchronous
serial communication, the communication line is normally held in the mark (high) state. The SCI
monitors the line and starts serial communication when the line goes to the space (low) state,
indicating a start bit. One serial character consists of a start bit (low), data (LSB first; starting from
the lowerest bit), parity bit (high or low), and stop bit (high), in that order.
When receiving in asynchronous mode, the SCI synchronizes at the falling edge of the start bit.
The SCI samples each data bit on the eighth pulse of a clock with a frequency 16 times the bit rate.
Receive data is latched at the center of each bit.
1
Serial
data
(LSB)
0
D0
(MSB)
D1
D2
D3
D4
D5
Start
bit
D6
D7
Idle (mark) state
1
0/1
1
1
Parity
bit
Stop
bit
1 or
no bit
1 or
2 bits
Transmit/receive data
1 bit
7 or 8 bits
One unit of communication data (character or frame)
Figure 14.5 Example of Data Format in Asynchronous Communication
(8-Bit Data with Parity and Two Stop Bits)
Rev. 5.00, 09/03, page 455 of 760
Transmit/Receive Formats: Table 14.11 lists the 12 communication formats that can be selected
in asynchronous mode. The format is selected by settings in the serial mode register (SCSMR).
Table 14.11 Serial Communication Formats (Asynchronous Mode)
SCSMR Bits
Serial Transmit/Receive Format and Frame Length
CHR PE
MP
STOP
0
0
0
0
START
8-bit data
STOP
0
0
0
1
START
8-bit data
STOP STOP
0
1
0
0
START
8-bit data
P
STOP
0
1
0
1
START
8-bit data
P
STOP STOP
1
0
0
0
START
7-bit data
STOP
1
0
0
1
START
7-bit data
STOP STOP
1
1
0
0
START
7-bit data
P
STOP
1
1
0
1
START
7-bit data
P
STOP STOP
0
—
1
0
START
8-bit data
MPB
STOP
0
—
1
1
START
8-bit data
MPB
STOP STOP
1
—
1
0
START
7-bit data
MPB
STOP
1
—
1
1
START
7-bit data
MPB
STOP STOP
Notes: — :
START:
STOP:
P:
MPB:
1
2
3
4
5
6
7
8
9
10
11
12
Don’t care bits
Start bit
Stop bit
Parity bit
Multiprocessor bit
Clock: An internal clock generated by the on-chip baud rate generator or an external clock input
from the SCK pin can be selected as the SCI transmit/receive clock. The clock source is selected
by the C/A bit in the serial mode register (SCSMR) and bits CKE1 and CKE0 in the serial control
register (SCSCR) (table 14.10).
When an external clock is input at the SCK pin, it must have a frequency equal to 16 times the
desired bit rate.
Rev. 5.00, 09/03, page 456 of 760
When the SCI operates on an internal clock, it can output a clock signal at the SCK pin. The
frequency of this output clock is equal to the bit rate. The phase is aligned as in figure 14.6 so that
the rising edge of the clock occurs at the center of each transmit data bit.
0
D0
D1
D2
D3
D4
D5
D6
D7
0/1
1
1
1 frame
Figure 14.6 Output Clock and Serial Data Timing (Asynchronous Mode)
Transmitting and Receiving Data (SCI Initialization (Asynchronous Mode)): Before
transmitting or receiving, clear the TE and RE bits to 0 in the serial control register (SCSCR), then
initialize the SCI as follows.
When changing the operation mode or communication format, always clear the TE and RE bits to
0 before following the procedure given below. Clearing TE to 0 sets TDRE to 1 and initializes the
transmit shift register (SCTSR). Clearing RE to 0, however, does not initialize the RDRF, PER,
FER, and ORER flags or receive data register (SCRDR), which retain their previous contents.
When an external clock is used, the clock should not be stopped during initialization or subsequent
operation. SCI operation becomes unreliable if the clock is stopped.
Figure 14.7 shows a sample flowchart for initializing the SCI. The procedure for initializing the
SCI is:
1. Select the clock source in the serial control register (SCSCR). Leave RIE, TIE, TEIE, MPIE,
TE, and RE cleared to 0. If clock output is selected in asynchronous mode, clock output starts
immediately after the setting is made in SCSCR.
2. Select the communication format in the serial mode register (SCSMR).
3. Write the value corresponding to the bit rate in the bit rate register (SCBRR) (not necessary if
an external clock is used).
4. Wait for at least the interval required to transmit or receive one bit, then set TE or RE in the
serial control register (SCSCR) to 1. Also set RIE, TIE, TEIE, and MPIE as necessary. Setting
TE or RE enables the SCI to use the TxD or RxD pin. The initial state is the mark state when
transmitting, or the idle state (waiting for a start bit) when receiving.
Rev. 5.00, 09/03, page 457 of 760
Initialization
Clear TE and RE bits in SCSCR to 0
Set CKE1 and CKE0 bits in SCSCR
(TE and RE bits are 0)
(1)
Select communication
format in SCSMR
(2)
Set value in SCBRR
(3)
Wait
Has a 1-bit
interval elapsed?
No
Yes
Set TE and RE bits in SCSCR to 1
and set RIE, TIE, TEIE, and MPIE bits
(4)
End
Note: Numbers in parentheses refer to steps in the preceding procedure description.
Figure 14.7 Sample Flowchart for SCI Initialization
Transmitting Serial Data (Asynchronous Mode): Figure 14.8 shows a sample flowchart for
transmitting serial data. The procedure for transmitting serial data is:
1. SCI status check and transmit data write: Read the serial status register (SCSSR), check that
the TDRE bit is 1, then write transmit data in the transmit data register (SCTDR) and clear
TDRE to 0.
2. To continue transmitting serial data: Read the TDRE bit to check whether it is safe to write (if
it reads 1); if so, write data in SCTDR, then clear TDRE to 0.
3. To output a break at the end of serial transmission: Set the port SC data register (SCPDR) and
port SC control register (SCPCR), then clear the TE bit to 0 in the serial control register
(SCSCR). For SCPCR and SCPDR settings, see section 14.2.8, SC Port Control Register
(SCPCR)/SC Port Data Register (SCPDR).
Rev. 5.00, 09/03, page 458 of 760
Start of transmission
Read TDRE bit in SCSSR
(1)
No
TDRE = 1?
Yes
Write transmit data to
SCTDR and clear TDRE bit in
SCSSR to 0
(2)
No
All data transmitted?
Yes
Read TEND bit in SCSSR
No
TEND = 1?
Yes
No
Break output?
Yes
(3)
Set SCPDR and SCPCR
Clear TE bit in SCSCR to 0
End of transmission
Note: Numbers in parentheses refer to steps in the preceding procedure description.
Figure 14.8 Sample Flowchart for Transmitting Serial Data
Rev. 5.00, 09/03, page 459 of 760
In transmitting serial data, the SCI operates as follows:
1. The SCI monitors the TDRE bit in SCSSR. When TDRE is cleared to 0, the SCI recognizes
that the transmit data register (SCTDR) contains new data, and loads this data from SCTDR
into the transmit shift register (SCTSR).
2. After loading the data from SCTDR into SCTSR, the SCI sets the TDRE bit to 1 and starts
transmitting. If the transmit-data-empty interrupt enable bit (TIE) is set to 1 in SCSCR, the SCI
requests a transmit-data-empty interrupt (TXI) at this time. Serial transmit data is transmitted
in the following order from the TxD pin:
a. Start bit: One 0 bit is output.
b. Transmit data: Seven or eight bits of data are output, LSB first.
c. Parity bit or multiprocessor bit: One parity bit (even or odd parity) or one multiprocessor
bit is output. Formats in which neither a parity bit nor a multiprocessor bit is output can
also be selected.
d. Stop bit: One or two 1-bits (stop bits) are output.
e. Marking: Output of 1-bits continues until the start bit of the next transmit data.
3. The SCI checks the TDRE bit when it outputs the stop bit. If TDRE is 0, the SCI loads new
data from SCTDR into SCTSR, outputs the stop bit, then begins serial transmission of the next
frame. If TDRE is 1, the SCI sets the TEND bit to 1 in SCSSR, outputs the stop bit, then
continues output of 1-bits (marking). If the transmit-end interrupt enable bit (TEIE) in SCSCR
is set to 1, a transmit-end interrupt (TEI) is requested.
Rev. 5.00, 09/03, page 460 of 760
Figure 14.9 shows an example of SCI transmit operation in asynchronous mode.
1
Serial
data
Start
bit
0
Parity Stop Start
bit
bit
bit
Data
D0
D1
D7
0/1
1
0
Parity Stop
bit
bit
Data
D0
D1
D7
0/1
1
1
Idle (mark)
state
TDRE
TEND
TXI interrupt
request
generated
TXI interrupt
handler writes
data to SCTDR
and clears
TDRE bit to 0
TXI interrupt
request
generated
TEI interrupt
request
generated
1 frame
Figure 14.9 Example of SCI Transmit Operation in Asynchronous Mode
(8-Bit Data with Parity and One Stop Bit)
Receiving Serial Data (Asynchronous Mode): Figure 14.10 shows a sample flowchart for
receiving serial data. The procedure for receiving serial data after enabling the SCI for reception
is:
1. Receive error handling and break detection: If a receive error occurs, read the ORER, PER and
FER bits in SCSSR to identify the error. After executing the necessary error handling, clear
ORER, PER and FER to 0. Receiving cannot resume if ORER, PER or FER remains set to 1.
When a framing error occurs, the RxD pin can be read to detect the break state.
2. SCI status check and receive-data read: Read the serial status register (SCSSR), check that
RDRF is set to 1, then read receive data from the receive data register (SCRDR) and clear
RDRF to 0. The RXI interrupt can also be used to determine if the RDRF bit has changed from
0 to 1.
3. To continue receiving serial data: Read the RDRF and SCRDR bits and clear RDRF to 0
before the stop bit of the current frame is received.
Rev. 5.00, 09/03, page 461 of 760
Start of reception
Read ORER, PER, and FER
bits in SCSSR
PER ∨ FER ∨ ORER = 1?
Yes
No
Read RDRF bit in SCSSR
No
(1)
(2)
Error handling
RDRF = 1?
Yes
Read receive data from SCRDR
(3)
and clear RDRF bit in SCSSR to 0
No
All data received?
Yes
Clear RE bit in SCSCR to 0
End of reception
Note: Numbers in parentheses refer to steps in the preceding procedure description.
Figure 14.10 Sample Flowchart for Receiving Serial Data
Rev. 5.00, 09/03, page 462 of 760
Error handling
No
ORER = 1?
Yes
Overrun error handling
No
FER = 1?
Yes
Break?
Yes
No
Framing error handling
No
Clear RE bit in SCSCR to 0
PER = 1?
Yes
Parity error handling
Clear ORER, PER, and
FER bits in SCSSR to 0
End
Figure 14.10 Sample Flowchart for Receiving Serial Data (cont)
Rev. 5.00, 09/03, page 463 of 760
In receiving, the SCI operates as follows:
1. The SCI monitors the communication line. When it detects a start bit (0), the SCI synchronizes
internally and starts receiving.
2. Receive data is shifted into SCRSR in order from the LSB to the MSB.
3. The parity bit and stop bit are received. After receiving these bits, the SCI makes the following
checks:
a. Parity check: The number of 1s in the receive data must match the even or odd parity
setting of the O/E bit in SCSMR.
b. Stop bit check: The stop bit value must be 1. If there are two stop bits, only the first stop bit
is checked.
c. Status check: RDRF must be 0 so that receive data can be loaded from SCRSR into
SCRDR.
If these checks all pass, the SCI sets RDRF to 1 and stores the received data in SCRDR. If
one of the checks fails (receive error), the SCI operates as indicated in table 14.12.
Note: When a receive error flag is set, further receiving is disabled. The RDRF bit is not set to 1.
Be sure to clear the error flags.
4. After setting RDRF to 1, if the receive-data-full interrupt enable bit (RIE) is set to 1 in
SCSCR, the SCI requests a receive-data-full interrupt (RXI). If one of the error flags (ORER,
PER, or FER) is set to 1 and the receive-data-full interrupt enable bit (RIE) in SCSCR is also
set to 1, the SCI requests a receive-error interrupt (ERI).
Table 14.12 Receive Error Conditions and SCI Operation
Receive Error
Abbreviation
Condition
Data Transfer
Overrun error
ORER
Receiving of next data ends while
RDRF is still set to 1 in SCSSR
Receive data not
transferred from SCRSR
into SCRDR
Framing error
FER
Stop bit is 0
Receive data transferred
from SCRSR into SCRDR
Parity error
PER
Parity of receive data differs from
even/odd parity setting in SCSMR
Receive data transferred
from SCRSR into SCRDR
Rev. 5.00, 09/03, page 464 of 760
Figure 14.11 shows an example of SCI receive operation in asynchronous mode.
1
Serial
data
Start
bit
0
Parity Stop Start
bit bit
bit
Data
D0
D1
D7
0/1
1
0
Parity Stop
bit
bit
Data
D0
D1
D7
0/1
1
1
Idle (mark)
state
RDRF
RXI interrupt
request generated
FER
1 frame
RXI interrupt handler
reads data and clears
RDRF bit to 0
ERI interrupt
request generated
by framing error
Figure 14.11 Example of SCI Receive Operation
(8-Bit Data with Parity and One Stop Bit)
14.3.3
Multiprocessor Communication
The multiprocessor communication function enables several processors to share a single serial
communication line. The processors communicate in asynchronous mode using a format with an
additional multiprocessor bit (multiprocessor format).
In multiprocessor communication, each receiving processor is addressed by a unique ID. A serial
communication cycle consists of an ID-sending cycle that identifies the receiving processor, and a
data-sending cycle. The multiprocessor bit distinguishes ID-sending cycles from data-sending
cycles. The transmitting processor starts by sending the ID of the receiving processor with which
it wants to communicate as data with the multiprocessor bit set to 1. Next the transmitting
processor sends transmit data with the multiprocessor bit cleared to 0.
Receiving processors skip incoming data until they receive data with the multiprocessor bit set to
1. When they receive data with the multiprocessor bit set to 1, receiving processors compare the
data with their IDs. The receiving processor with a matching ID continues to receive further
incoming data. Processors with IDs not matching the received data skip further incoming data
until they again receive data with the multiprocessor bit set to 1. Multiple processors can send and
receive data in this way.
Figure 14.12 shows an example of communication among processors using the multiprocessor
format.
Rev. 5.00, 09/03, page 465 of 760
Transmitting
station
Serial communication line
Receiving
station A
Receiving
station B
Receiving
station C
Receiving
station D
(ID = 01)
(ID = 02)
(ID = 03)
(ID = 04)
Serial
data
H'01
H'AA
(MPB = 1)
ID transmit cycle:
specifies receiving station
(MPB = 0)
Data transmit cycle:
data transmission to
receiving station specified
by ID
MPB: Multiprocessor bit
Figure 14.12 Communication Among Processors Using Multiprocessor Format
(Sending Data H'AA to Receiving Processor A)
Communication Formats: Four formats are available. Parity-bit settings are ignored when the
multiprocessor format is selected. For details see table 14.11.
Clock: See the description in the asynchronous mode section.
Transmitting Multiprocessor Serial Data: Figure 14.13 shows a sample flowchart for
transmitting multiprocessor serial data. The procedure for transmitting multiprocessor serial data
is:
1. SCI status check and transmit data write: Read the serial status register (SCSSR), check that
the TDRE bit is 1, then write transmit data in the transmit data register (SCTDR). Also set
MPBT (multiprocessor bit transfer) to 0 or 1 in SCSSR. Finally, clear TDRE to 0.
2. To continue transmitting serial data: Read the TDRE bit to check whether it is safe to write (if
it reads 1); if so, write data in SCTDR, then clear TDRE to 0.
3. To output a break at the end of serial transmission: Set the port SC data register (SCPDR) and
port SC control register (SCPCR), then clear the TE bit to 0 in the serial control register
(SCSCR). For SCPCR and SCPDR settings, see section 14.2.8, SC Port Control Register
(SCPCR)/SC Port Data Register (SCPDR).
Rev. 5.00, 09/03, page 466 of 760
Start of transmission
Read TDRE bit in SCSSR
TDRE = 1?
(1)
No
Yes
Write transmit data to SCTDR
and set MPBT bit in SCSSR
Clear TDRE bit to 0
Transmission ended?
No
(2)
Yes
Read TEND bit in SCSSR
TEND = 1?
No
Yes
Break output?
No
Yes (3)
Set SCPDR and SCPCR
Clear TE bit SCSCR to 0
End of transmission
Note: Numbers in parentheses refer to steps in the preceding procedure description.
Figure 14.13 Sample Flowchart for Transmitting Multiprocessor Serial Data
Rev. 5.00, 09/03, page 467 of 760
In transmitting serial data, the SCI operates as follows:
1. The SCI monitors the TDRE bit in SCSSR. When TDRE is cleared to 0 the SCI recognizes
that the transmit data register (SCTDR) contains new data, and transfers this data from SCTDR
into the transmit shift register (SCTSR).
2. After loading the data from SCTDR into SCTSR, the SCI sets the TDRE bit to 1 and starts
transmitting. If the transmit-data-empty interrupt enable bit (TIE) in SCSCR is set to 1, the SCI
requests a transmit-data-empty interrupt (TXI) at this time. Serial transmit data is transmitted
in the following order from the TxD pin:
a. Start bit: One 0-bit is output.
b. Transmit data: Seven or eight bits are output, LSB first.
c. Multiprocessor bit: One multiprocessor bit (MPBT value) is output.
d. Stop bit: One or two 1-bits (stop bits) are output.
e. Marking: Output of 1-bits continues until the start bit of the next transmit data.
3. The SCI checks the TDRE bit when it outputs the stop bit. If TDRE is 0, the SCI transfers data
from SCTDR into SCTSR, outputs the stop bit, then begins serial transmission of the next
frame. If TDRE is 1, the SCI sets the TEND bit in SCSSR to 1, outputs the stop bit, then
continues output of 1 bits in the mark state. If the transmit-end interrupt enable bit (TEIE) in
SCSCR is set to 1, a transmit-end interrupt (TEI) is requested at this time.
Figure 14.14 shows SCI transmission with a multiprocessor format.
Multiprocessor
bit Stop Start
Data
bit
bit
Start
bit
1
Serial
data
0
D0
D1
D7
0/1
1
0
Multiprocessor
bit Stop
Data
bit
D0
D1
D7
0/1
1
1
Idle (mark)
state
TDRE
TEND
TXI interrupt
request
generated
Writes data to TDR
with the TXI interrupt
processing routine
and clears TDRE
bit to 0
TXI interrupt
request
generated
TEI interrupt
request
generated
1 frame
Figure 14.14 Example of SCI Multiprocessor Transmit Operation
(8-Bit Data with Multiprocessor Bit and One Stop Bit)
Rev. 5.00, 09/03, page 468 of 760
Receiving Multiprocessor Serial Data: Figure 14.15 shows a sample flowchart for receiving
multiprocessor serial data. The procedure for receiving multiprocessor serial data is:
1. ID receive cycle: Set the MPIE bit in the serial control register (SCSCR) to 1.
2. SCI status check and compare to ID reception: Read the serial status register (SCSSR), check
that RDRF is set to 1, then read data from the receive data register (SCRDR) and compare with
the processor’s own ID. If the ID does not match the receive data, set MPIE to 1 again and
clear RDRF to 0. If the ID matches the receive data, clear RDRF to 0.
3. SCI status check and data receiving: Read SCSSR, check that RDRF is set to 1, then read data
from the receive data register (SCRDR).
4. Receive error handling and break detection: If a receive error occurs, read the ORER and FER
bits in SCSSR to identify the error. After executing the necessary error handling, clear both
ORER and FER to 0. Receiving cannot resume if ORER or FER remain set to 1. When a
framing error occurs, the RxD pin can be read to detect the break state.
Rev. 5.00, 09/03, page 469 of 760
Start of reception
Set MPIE bit in SCSCR to 1
(1)
Read ORER and FER
bits in SCSSR
FER = 1 or ORER = 1?
No
Read RDRF bit in SCSSR
No
Yes
(2)
RDRF = 1?
Yes
Read receive data from SCRDR
No
Is ID the
station's ID?
Yes
Read ORER and FER
bits in SSCSR
FER = 1 or ORER = 1?
Yes
No
Read RDRF bit in SCSSR
RDRF = 1?
(4)
No
Yes
Read receive data from SCRDR
No
All data received?
Yes
Clear RE bit in SCSCR to 0
(3)
Error handling
End of reception
Note: Numbers in parentheses refer to steps in the preceding procedure description.
Figure 14.15 Sample Flowchart for Receiving Multiprocessor Serial Data
Rev. 5.00, 09/03, page 470 of 760
Error handling
No
ORER = 1?
Yes
Overrun error handling
No
FER = 1?
Yes
Break?
Yes
No
Framing error handling
Clear RE bit in SCSCR to 0
Clear ORER and
FER bits in SCSSR to 0
End
Figure 14.15 Sample Flowchart for Receiving Multiprocessor Serial Data (cont)
Rev. 5.00, 09/03, page 471 of 760
Figure 14.16 shows an example of SCI receive operation using a multiprocessor format.
1
Serial
data
Start
bit
0
Data
(ID1)
D0
D1
Stop Start Data
bit (data 1)
MPB bit
D7
1
1
0
D0
D1
Stop
MPB bit
D7
0
1
1
Idle (mark)
state
MPIE
RDRF
RDR
value
ID1
RXI interrupt request
(multiprocessor interrupt)
generated, MPIE = 0
RXI interrupt handler
reads RDR data and
clears RDRF bit to 0
ID is not station's
ID, so MPIE bit is
set to 1 again
Example: Own ID does not match data
Figure 14.16 Example of SCI Receive Operation
(8-Bit Data with Multiprocessor Bit and One Stop Bit)
Rev. 5.00, 09/03, page 472 of 760
No RXI interrupt
generated;
RDR state
is maintained
1
Serial
data
Start
bit
0
Data
(ID2)
D0
D1
MPB
D7
1
Data
Stop Start
bit bit (Data 2)
1
0
D0
D1
Stop
MPB bit
D7
0
1
1 Idle (mark)
state
MPIE
RDRF
RDR
value
ID1
RXI interrupt request
(multiprocessor
interrupt) generated,
MPIE = 0
ID2
RXI interrupt handler
reads RDR data and
clears RDRF bit to 0
Data2
ID is that of station,
MPIE bit
so reception continues set to 1
unchanged and data
again
is received by RXI
interrupt handler
Example: Own ID matches data
Figure 14.16 Example of SCI Receive Operation (cont)
(8-Bit Data with Multiprocessor Bit and One Stop Bit)
Rev. 5.00, 09/03, page 473 of 760
14.3.4
Synchronous Operation
In synchronous mode, the SCI transmits and receives data in synchronization with clock pulses.
This mode is suitable for high-speed serial communication.
The SCI transmitter and receiver are independent, so full-duplex communication is possible while
sharing the same clock. The transmitter and receiver are also double buffered, so continuous
transmitting or receiving is possible by reading or writing data while transmitting or receiving is in
progress.
Figure 14.17 shows the general format in synchronous serial communication.
One unit of communication data (character or frame)
*
*
Serial clock
LSB
Serial data
Don't care
Bit 0
MSB
Bit 1
Bit 2
Bit 3
Bit 4
Bit 5
Bit 6
Bit 7
Don't care
Note: * High except in continuous transmitting or receiving
Figure 14.17 Data Format in Synchronous Communication
In synchronous serial communication, each data bit is output on the communication line from one
falling edge of the serial clock to the next. Data is guaranteed valid at the rising edge of the serial
clock. In each character, the serial data bits are transmitted in order from the LSB (first) to the
MSB (last). After output of the MSB, the communication line remains in the state of the MSB. In
synchronous mode, the SCI transmits or receives data by synchronizing with the falling edge of
the serial clock.
Communication Format: The data length is fixed at eight bits. No parity bit or multiprocessor bit
can be added.
Rev. 5.00, 09/03, page 474 of 760
Clock: An internal clock generated by the on-chip baud rate generator or an external clock input
from the SCK pin can be selected as the SCI transmit/receive clock. The clock source is selected
by the C/A bit in the serial mode register (SCSMR) and bits CKE1 and CKE0 in the serial control
register (SCSCR). See table 14.10.
When the SCI operates on an internal clock, it outputs the clock signal at the SCK pin. Eight clock
pulses are output per transmitted or received character. When the SCI is not transmitting or
receiving, the clock signal remains in the high state. When only receiving, the SCI receives in 2character units, so a 16-pulse serial clock is output. To receive in 1-character units, select an
external clock source.
Transmitting and Receiving Data SCI Initialization (Synchronous Mode): Before
transmitting, receiving, or changing the mode or communication format, the software must clear
the TE and RE bits to 0 in the serial control register (SCSCR), then initialize the SCI. Clearing TE
to 0 sets TDRE to 1 and initializes the transmit shift register (SCTSR). Clearing RE to 0, however,
does not initialize the RDRF, PER, FER, and ORER flags and receive data register (SCRDR),
which retain their previous contents.
Figure 14.18 shows a sample flowchart for initializing the SCI. The procedure for initializing the
SCI is:
1. Select the clock source in the serial control register (SCSCR). Leave RIE, TIE, TEIE, MPIE,
TE and RE cleared to 0.
2. Select transmit/receive format in the serial mode register (SCSMR).
3. Write the value corresponding to the bit rate in the bit rate register (SCBRR) (not necessary if
an external clock is used).
4. Wait for at least the interval required to transmit or receive one bit, then set TE or RE in the
serial control register (SCSCR) to 1. Also set RIE, TIE, TEIE and MPIE. Setting TE and RE
allows use of the TxD and RxD pins.
Rev. 5.00, 09/03, page 475 of 760
Initialization
Clear TE and RE bits in SCSCR to 0
Set RIE, TIE, TEIE, MPIE, CKE1,
and CKE0 bits in SCSCR
(TE and RE are 0)
(1)
Set transmit/receive format in SCSMR (2)
Set value in SCBRR
(3)
Wait
Has a 1-bit
period elapsed?
No
Yes
Set TE and RE bits in SCSCR to 1
and set RIE, TIE, TEIE, and MPIE bits (4)
End
Note: Numbers in parentheses refer to steps in the preceding procedure description.
Figure 14.18 Sample Flowchart for SCI Initialization
Transmitting Serial Data (Synchronous Mode): Figure 14.19 shows a sample flowchart for
transmitting serial data. The procedure for transmitting serial data is:
1. SCI status check and transmit data write: Read the serial status register (SCSSR), check that
the TDRE bit is 1, then write transmit data in the transmit data register (SCTDR) and clear
TDRE to 0.
2. To continue transmitting serial data: Read the TDRE bit to check whether it is safe to write (if
it reads 1); if so, write data in SCTDR, then clear TDRE to 0.
Rev. 5.00, 09/03, page 476 of 760
Start of transmission
Read TDRE bit in SCSSR
TDRE = 1?
(1)
No
Yes
Write transmit data to SCTDR
and clear TDRE bit in SCSSR to 0
All data transmitted?
No
(2)
Yes
Read TEND bit in SCSSR
TEND = 1?
No
Yes
Clear TE bit in SCSCR to 0
End of transmission
Note: Numbers in parentheses refer to steps in the preceding procedure description.
Figure 14.19 Sample Flowchart for Transmitting Serial Data
Rev. 5.00, 09/03, page 477 of 760
In transmitting serial data, the SCI operates as follows:
1. The SCI monitors the TDRE bit in SCSSR. When TDRE is cleared to 0 the SCI recognizes
that the transmit data register (SCTDR) contains new data and loads this data from SCTDR
into the transmit shift register (SCTSR).
2. After loading the data from SCTDR into SCTSR, the SCI sets the TDRE bit to 1 and starts
transmitting. If the transmit-data-empty interrupt enable bit (TIE) in SCSCR is set to 1, the SCI
requests a transmit-data-empty interrupt (TXI) at this time.
If clock output mode is selected, the SCI outputs eight synchronous clock pulses. If an external
clock source is selected, the SCI outputs data in synchronization with the input clock. Data is
output from the TxD pin in order from the LSB (bit 0) to the MSB (bit 7).
3. The SCI checks the TDRE bit when it outputs the MSB (bit 7). If TDRE is 0, the SCI loads
data from SCTDR into SCTSR, then begins serial transmission of the next frame. If TDRE is
1, the SCI sets the TEND bit in SCSSR to 1, transmits the MSB, then holds the transmit data
pin (TxD) in the MSB state. If the transmit-end interrupt enable bit (TEIE) in SCSCR is set to
1, a transmit-end interrupt (TEI) is requested at this time.
4. After the end of serial transmission, the SCK pin is held in the high state.
Figure 14.20 shows an example of SCI transmit operation.
Transfer direction
Serial clock
LSB
Bit 0
Serial data
Bit 1
MSB
Bit 7
Bit 0
Bit 1
Bit 6
Bit 7
TDRE
TEND
TXI interrupt
request
generated
TXI interrupt
handler writes
data to TDR and
clears TDRE
bit to 0
TXI interrupt
request
generated
1 frame
Figure 14.20 Example of SCI Transmit Operation
Rev. 5.00, 09/03, page 478 of 760
TEI interrupt
request
generated
Receiving Serial Data (Synchronous Mode): Figure 14.21 shows a sample flowchart for
receiving serial data. When switching from asynchronous mode to synchronous mode, make sure
that ORER, PER, and FER are cleared to 0. If PER or FER is set to 1, the RDRF bit will not be set
and both transmitting and receiving will be disabled.
The procedure for receiving serial data is:
1. Receive error handling: If a receive error occurs, read the ORER bit in SCSSR to identify the
error. After executing the necessary error handling, clear ORER to 0. Transmitting/receiving
cannot resume if ORER remains set to 1.
2. SCI status check and receive data read: Read the serial status register (SCSSR), check that
RDRF is set to 1, then read receive data from the receive data register (SCRDR) and clear
RDRF to 0. The RXI interrupt can also be used to determine if the RDRF bit has changed from
0 to 1.
3. To continue receiving serial data: Read SCRDR, and clear RDRF to 0 before the MSB (bit 7)
of the current frame is received.
Rev. 5.00, 09/03, page 479 of 760
Start of reception
Read ORER bit in SCSSR
ORER = 1?
Yes
No
(1)
Read RDRF bit in SCSSR
No
(2)
Error handling
RDRF = 1?
Yes
Read receive data from SCRDR
(3)
and clear RDRF bit in SCSSR to 0
No
All data received?
Yes
Clear RE bit in SCSCR to 0
End of reception
Note: Numbers in parentheses refer to steps in the preceding procedure description.
Figure 14.21 Sample Flowchart for Receiving Serial Data
Rev. 5.00, 09/03, page 480 of 760
Error handling
No
ORER = 1?
Yes
Overrun error handling
Clear ORER bit in SCSSR to 0
End
Figure 14.21 Sample Flowchart for Receiving Serial Data (cont)
In receiving, the SCI operates as follows:
1. The SCI synchronizes with serial clock input or output and initializes internally.
2. Receive data is shifted into SCRSR in order from the LSB to the MSB. After receiving the
data, the SCI checks that RDRF is 0 so that receive data can be loaded from SCRSR into
SCRDR. If this check is passed, the SCI sets RDRF to 1 and stores the received data in
SCRDR. If the check is not passed (receive error), the SCI operates as indicated in table 14.12.
This state prevents further transmission or reception. While receiving, the RDRF bit is not set
to 1. Be sure to clear the error flag.
3. After setting RDRF to 1, if the receive-data-full interrupt enable bit (RIE) is set to 1 in
SCSCR, the SCI requests a receive-data-full interrupt (RXI). If the ORER bit is set to 1 and the
receive-data-full interrupt enable bit (RIE) in SCSCR is also set to 1, the SCI requests a
receive-error interrupt (ERI).
Figure 14.22 shows an example of SCI receive operation.
Rev. 5.00, 09/03, page 481 of 760
Transfer direction
Serial
clock
Serial
data
Bit 7
Bit 0
Bit 7
Bit 0
Bit 1
Bit 6
Bit 7
RDRF
ORER
RXI interrupt
request
generated
RXI interrupt
handler reads data
and clears RDRF
bit to 0
RXI interrupt
request
generated
ERI interrupt
request generated
by overrun error
1 frame
Figure 14.22 Example of SCI Receive Operation
Transmitting and Receiving Serial Data Simultaneously (Synchronous Mode): Figure 14.23
shows a sample flowchart for transmitting and receiving serial data simultaneously. The procedure
for setting the SCI to transmit and receive serial data simultaneously is:
1. SCI status check and transmit data write: Read the serial status register (SCSSR), check that
the TDRE bit is 1, then write transmit data in the transmit data register (SCTDR) and clear
TDRE to 0. The TXI interrupt can also be used to determine if the TDRE bit has changed from
0 to 1.
2. Receive error handling: If a receive error occurs, read the ORER bit in SCSSR to identify the
error. After executing the necessary error handling, clear ORER to 0. Transmitting/receiving
cannot resume if ORER remains set to 1.
3. SCI status check and receive data read: Read the serial status register (SCSSR), check that
RDRF is set to 1, then read receive data from the receive data register (SCRDR) and clear
RDRF to 0. The RXI interrupt can also be used to determine if the RDRF bit has changed from
0 to 1.
4. To continue transmitting and receiving serial data: Read the RDRF bit and SCRDR, and clear
RDRF to 0 before the MSB (bit 7) of the current frame is received. Also read the TDRE bit to
check whether it is safe to write (if it reads 1); if so, write data in SCTDR, then clear TDRE to
0 before the MSB (bit 7) of the current frame is transmitted.
Rev. 5.00, 09/03, page 482 of 760
Start of transmission/reception
Read TDRE bit in SCSSR
No
(1)
TDRE = 1?
Yes
Write transmit data to SCTDR
and clear TDRE bit in SCSSR to 0
Read ORER bit in SCSSR
ORER = 1?
Yes
(2)
No
Read RDRF bit in SCSSR
No
Error processing
(3)
RDRF = 1?
Yes
Read receive data from SCRDR
and clear RDRF bit in SCSSR to 0
No
(4)
All data
transmitted/received?
Yes
Clear TE and RE bits
in SCSCR to 0
End of transmission/reception
Notes: 1. Numbers in parentheses refer to steps in the preceding procedure description.
2. In switching from transmitting or receiving to simultaneous transmitting
and receiving, clear both TE and RE to 0, then set both TE and RE to 1 simultaneously.
Figure 14.23 Sample Flowchart for Transmitting/Receiving Serial Data
Rev. 5.00, 09/03, page 483 of 760
14.4
SCI Interrupts
The SCI has four interrupt sources transmit-end (TEI), receive-error (ERI), receive-data-full
(RXI), and transmit-data-empty (TXI). Table 14.13 lists the interrupt sources and indicates their
priority. These interrupts can be enabled and disabled by the TIE, RIE, and TEIE bits in the serial
control register (SCSCR). Each interrupt request is sent separately to the interrupt controller.
TXI is requested when the TDRE bit in SCSSR is set to 1.
RXI is requested when the RDRF bit in SCSSR is set to 1.
ERI is requested when the ORER, PER, or FER bit in SCSSR is set to 1.
TEI is requested when the TEND bit in SCSSR is set to 1. Where the TXI interrupt indicates that
transmit data writing is enabled, the TEI interrupt indicates that the transmit operation is complete.
Table 14.13 SCI Interrupt Sources
Interrupt Source
Description
Priority When Reset Is Cleared
ERI
Receive error (ORER, PER, or FER)
High
RXI
Receive data full (RDRF)
TXI
Transmit data empty (TDRE)
TEI
Transmit end (TEND)
Low
See section 4, Exception Handling, for priorities and the relationship to non-SCI interrupts.
Rev. 5.00, 09/03, page 484 of 760
14.5
Usage Notes
Note the following points when using the SCI.
SCTDR Writing and TDRE Flag: The TDRE bit in the serial status register (SCSSR) is a status
flag indicating loading of transmit data from SCTDR into SCTSR. The SCI sets TDRE to 1 when
it transfers data from SCTDR to SCTSR. Data can be written to SCTDR regardless of the TDRE
bit state. If new data is written in SCTDR when TDRE is 0, however, the old data stored in
SCTDR will be lost because the data has not yet been transferred to SCTSR. Before writing
transmit data to SCTDR, be sure to check that TDRE is set to 1.
Simultaneous Multiple Receive Errors: Table 14.14 indicates the state of SCSSR status flags
when multiple receive errors occur simultaneously. When an overrun error occurs, the SCRSR
contents cannot be transferred to SCRDR, so receive data is lost.
Table 14.14 SCSSR Status Flags and Transfer of Receive Data
SCSSR Status Flags
Receive Error Status
RDRF
ORER
FER PER
Receive Data Transfer
SCRSR → SCRDR
Overrun error
1
1
0
0
X
Framing error
0
0
1
0
O
Parity error
0
0
0
1
O
Overrun error + framing error
1
1
1
0
X
Overrun error + parity error
1
1
0
1
X
Framing error + parity error
0
0
1
1
O
Overrun error + framing error + parity error 1
1
1
1
X
X: Receive data is not transferred from SCRSR to SCRDR.
O: Receive data is transferred from SCRSR to SCRDR.
Break Detection and Processing: Break signals can be detected by reading the RxD pin directly
when a framing error (FER) is detected. In the break state, the input from the RxD pin consists of
all 0s, so FER is set and the parity error flag (PER) may also be set. In the break state, the SCI
receiver continues to operate, so if the FER bit is cleared to 0, it will be set to 1 again.
Sending a Break Signal: The TxD pin I/O condition and level can be determined by means of the
SCP0DT bit in the port SC data register (SCPDR) and bits SCP0MD0 and SCP0MD1 in the port
SC control register (SCPCR). This feature can be used to send breaks. To send a break during
serial transmission, clear the SCP0DT bit to 0 (designating low level), then clear the TE bit to 0
(halting transmission). When the TE bit is cleared to 0, the transmitter is initialized regardless of
the current transmission state, and 0 is output from the TxD pin.
Rev. 5.00, 09/03, page 485 of 760
TEND Flag and TE Bit Processing: The TEND flag is set to 1 during transmission of the stop bit
of the last data. Consequently, if the TE bit is cleared to 0 immediately after setting of the TEND
flag has been confirmed, the stop bit will be in the process of transmission and will not be
transmitted normally. Therefore, the TE bit should not be cleared to 0 for at least 0.5 serial clock
cycles (or 1.5 cycles if two stop bits are used) after setting of the TEND flag is confirmed.
Receive Error Flags and Transmitter Operation (Synchronous Mode Only): When a receive
error flag (ORER, PER, or FER) is set to 1, the SCI will not start transmitting even if TDRE is set
to 1. Be sure to clear the receive error flags to 0 before starting to transmit. Note that clearing RE
to 0 does not clear the receive error flags.
Receive Data Sampling Timing and Receive Margin in Asynchronous Mode: In asynchronous
mode, the SCI operates on a base clock of 16 times the transfer rate frequency. In receiving, the
SCI synchronizes internally with the falling edge of the start bit, which it samples on the base
clock. Receive data is latched at the rising edge of the eighth base clock pulse (figure 14.24).
16 clocks
8 clocks
0 1 2 3 4 5 6 7 8 9 10111213 1415 0 1 2 3 4 5 6 7 8 9 10111213 1415 0 1 2 3 4 5
Base clock
−7.5 clocks
Receive
data (RxD)
Start bit
+7.5 clocks
D0
Synchronization
sampling
timing
Data
sampling
timing
Figure 14.24 Receive Data Sampling Timing in Asynchronous Mode
Rev. 5.00, 09/03, page 486 of 760
D1
The receive margin in asynchronous mode can therefore be expressed as in equation 1.
Equation 1:
M = 0.5 −
Where:
1
D − 0.5
(1 + F) × 100%
− (L − 0.5)F −
2N
N
M = Receive margin (%)
N = Ratio of clock frequency to bit rate (N = 16)
D = Clock duty cycle (D = 0 to 1.0)
L = Frame length (L = 9 to 12)
F = Absolute deviation of clock frequency
From equation 1, if F = 0 and D = 0.5, the receive margin is 46.875%, as in equation 2.
Equation 2:
M = (0.5 – 1/(2 × 16)) × 100%
= 46.875%
This is a theoretical value. A reasonable margin to allow in system designs is 20% to 30%.
Notes on Synchronous External Clock Mode:
• Do not set TE = RE = 1 until at least four clocks after external clock SCK has changed from 0
to 1.
• Set TE = RE = 1 only when external clock SCK is 1.
• When receiving, RDRF is set to 1 when RE is set to zero 2.5–3.5 clocks after the rising edge of
the SCK input of the D7 bit in RxD, but data cannot be copied to SCRDR.
Note on Synchronous Internal Clock Mode: When receiving, RDRF is set to 1 when RE is cleared
to zero 1.5 clocks after the rising edge of the SCK output of the D7 bit in RxD, but data cannot be
copied to SCRDR.
Rev. 5.00, 09/03, page 487 of 760
Rev. 5.00, 09/03, page 488 of 760
Section 15 Smart Card Interface
15.1
Overview
As an added serial communications interface function, the SCI supports an IC card (smart card)
interface that conforms to the data transfer protocol (asynchronous half-duplex character
transmission protocol) of the ISO/IEC7816-3 (Identification Card) standard. Register settings are
used to switch between the normal serial communication interface and the smart card interface.
15.1.1
Features
The smart card interface has the following features:
• Asynchronous mode
 Data length: 8 bits
 Parity bit generation and check
 Receive mode error signal detection (parity error)
 Transmit mode error signal detection and automatic re-transmission of data
 Supports both direct convention and inverse convention
• Bit rate can be selected using on-chip baud rate generator.
• Three types of interrupts: Transmit-data-empty, receive-data-full, and communication-error
interrupts are requested independently.
Rev. 5.00, 09/03, page 489 of 760
15.1.2
Block Diagram
Bus interface
Figure 15.1 shows a block diagram of the smart card interface.
Module data bus
SCRDR
RxD
TxD
SCRSR
SCTDR
SCTSR
Parity generation
Parity check
SCK
SCSCMR
SCSSR
SCSCR
SCSMR
Transmit/
receive
control
SCBRR
Baud rate
generator
Pφ/4
Pφ/64
Clock
External clock
Smart card mode register
Receive shift register
Receive data register
Transmit shift register
Transmit data register
Serial mode register
Serial control register
Serial status register
Bit rate register
Figure 15.1 Block Diagram of Smart Card Interface
Rev. 5.00, 09/03, page 490 of 760
Pφ
Pφ/16
SCI
Legend
SCSCMR:
SCRSR:
SCRDR:
SCTSR:
SCTDR:
SCSMR:
SCSCR:
SCSSR:
SCBRR:
Internal
data bus
TXI
RXI
ERI
15.1.3
Pin Configuration
Table 15.1 summarizes the smart card interface pins.
Table 15.1 Smart Card Interface Pins
Pin Name
Abbreviation
I/O
Function
Serial clock pin
SCK0
Output
Clock output
Receive data pin
RxD0
Input
Receive data input
Transmit data pin
TxD0
Output
Transmit data output
15.1.4
Smart Card Interface Registers
Table 15.2 summarizes the registers used by the smart card interface. The SCSMR, SCBRR,
SCSCR, SCTDR, and SCRDR registers are the same as for the normal SCI function. They are
described in section 14, Serial Communication Interface (SCI).
Table 15.2 Registers
Name
Abbreviation R/W
3
Initial Value* Address
Access Size
Serial mode register
SCSMR
H'00
8
R/W
H'FFFFFE80
Bit rate register
SCBRR
R/W
H'FF
H'FFFFFE82
8
Serial control register
SCSCR
R/W
H'00
H'FFFFFE84
8
Transmit data register
SCTDR
R/W
H'FF
H'FFFFFE86
8
H'84
H'FFFFFE88
8
*1
Serial status register
SCSSR
R/(W)
Receive data register
SCRDR
R
H'00
H'FFFFFE8A
8
R/W
2
H'00*
H'FFFFFE8C
8
Smart card mode register
SCSCMR
Notes: 1. Only 0 can be written, to clear the flags.
2. Bits 0, 2, and 3 are cleared. The value of the other bits is undefined.
3. Initialized by a power-on or manual reset.
Rev. 5.00, 09/03, page 491 of 760
15.2
Register Descriptions
This section describes the registers added for the smart card interface and the bits whose functions
are changed.
15.2.1
Smart Card Mode Register (SCSCMR)
The smart card mode register (SCSCMR) is an 8-bit readable/writable register that selects smart
card interface functions. SCSCMR bits 0, 2, and 3 are initialized to H'00 by a reset and in standby
mode.
Bit:
7
6
5
4
3
2
1
0
—
—
—
—
SDIR
SINV
—
SMIF
Initial value:
—
—
—
—
0
0
—
0
R/W:
R
R
R
R
R/W
R/W
R
R/W
Bits 7 to 4 and 1—Reserved: These bits are always read as 0. The write value should always be
0.
Bit 3—Smart Card Data Transfer Direction (SDIR): Selects the serial/parallel conversion
format.
Bit 3: SDIR
Description
0
Contents of SCTDR are transferred LSB-first, and receive data is stored in
SCRDR LSB-first
(Initial value)
1
Contents of SCTDR are transferred MSB-first, and receive data is stored in
SCRDR MSB-first
Bit 2—Smart Card Data Inversion (SINV): Specifies whether to invert the logic level of the
data. This function is used in combination with bit 3 for transmitting and receiving with an inverse
convention card. SINV does not affect the logic level of the parity bit. See section 15.3.4, Register
Settings, for information on how parity is set.
Bit 2: SINV
Description
0
Contents of SCTDR are transferred unchanged, and receive data is stored
in SCRDR unchanged
(Initial value)
1
Contents of SCTDR are inverted before transfer, and receive data is
inverted before storage in SCRDR
Rev. 5.00, 09/03, page 492 of 760
Bit 0—Smart Card Interface Mode Select (SMIF): Enables the smart card interface function.
Bit 0 : SMIF
Description
0
Smart card interface function disabled
1
Smart card interface function enabled
15.2.2
(Initial value)
Serial Status Register (SCSSR)
In smart card interface mode, the function of SCSSR bit 4 is changed. The setting conditions for
bit 2, the TEND bit, are also changed.
Bit:
Initial value:
R/W:
7
6
TDRE
RDRF
5
4
ORER FER/ERS
3
2
1
0
PER
TEND
MPB
MPBT
1
0
0
0
0
1
0
0
R/(W)*
R/(W)*
R/(W)*
R/(W)*
R/(W)*
R
R
R/W
Note: Only 0 can be written, to clear the flag.
Bit 7—Transmit Data Register Empty (TDRE)
Bit 6—Receive Data Register Full (RDRE)
Bit 5—Overrun Error (ORER)
These bits have the same function as in the ordinary SCI. See section 14, Serial Communication
Interface (SCI), for more information.
Bit 4—Error Signal Status (ERS): In the smart card interface mode, bit 4 indicates the state of
the error signal returned from the receiving side during transmission. The smart card interface
cannot detect framing errors.
Bit 4: ERS
Description
0
Receiving ended normally with no error signal
(Initial value)
[Clearing conditions]
(1) By a reset or in standby mode
(2) Cleared by reading ERS when ERS = 1, then writing 0 to ERS
1
An error signal indicating a parity error was transmitted from the receiving side
[Setting condition]
If the error signal sampled is low
Note: The ERS flag maintains its state even when the TE bit in SCSCR is cleared to 0.
Rev. 5.00, 09/03, page 493 of 760
Bits 3 to 0: These bits have the same function as in the ordinary SCI. See section 14, Serial
Communication Interface (SCI), for more information. The setting conditions for bit 2, the
transmit end bit (TEND), are changed as follows.
Bit 2: TEND
Description
0
Transmission is in progress
[Clearing condition]
Cleared by reading TDRE when TDRE = 1, then writing 0 to TDRE
1
End of transmission
(Initial value)
[Setting conditions]
(1) the chip is reset or enters standby mode,
(2) the TE bit in SCSCR is 0 and the FER/ERS bit is also 0,
(3) the C/A bit in SCSMR is 0, and TDRE = 1 and FER/ERS = 0 (normal
transmission) 2.5 etu after a one-byte serial character is transmitted, or
(4) the C/A bit in SCSMR is 1, and TDRE = 1 and FER/ERS = 0 (normal
transmission) 1.0 etu after a one-byte serial character is transmitted.
Note: etu: Elementary Time Unit (time for transfer of 1 bit).
15.3
Operation
15.3.1
Overview
The primary functions of the smart card interface are described below.
1. Each frame consists of 8-bit data and 1 parity bit.
2. During transmission, the card leaves a guard time of at least 2 etu (elementary time units: time
for transfer of 1 bit) from the end of the parity bit to the start of the next frame.
3. During reception, the card outputs an error signal low level for 1 etu after 10.5 etu has elapsed
from the start bit if a parity error was detected.
4. During transmission, it automatically transmits the same data after allowing at least 2 etu from
the time the error signal is sampled.
5. Only start-stop type asynchronous communication functions are supported; no synchronous
communication functions are available.
Rev. 5.00, 09/03, page 494 of 760
15.3.2
Pin Connections
Figure 15.2 shows the pin connection diagram for the smart card interface. During communication
with an IC card, transmission and reception are both carried out over the same data transfer line,
so connect the TxD and RxD pins on the chip. Pull up the data transfer line to the power supply
VCC side with a register.
When using the clock generated by the smart card interface on an IC card, input the SCK pin
output to the IC card’s CLK pin. This connection is not necessary when the internal clock is used
on the IC card.
Use the chip’s port output as the reset signal. Apart from these pins, power and ground pin
connections are usually also required.
Note: When the IC card is not connected and both RE and TE are set to 1, closed communication
is possible and auto-diagnosis can be performed.
VCC
TxD
IO
Data line
RxD
SCK
Clock line
CLK
LSI
Px (port)
Connected device
Reset line
RST
IC card
Figure 15.2 Pin Connection Diagram for Smart Card Interface
Rev. 5.00, 09/03, page 495 of 760
15.3.3
Data Format
Figure 15.3 shows the data format for the smart card interface. In this mode, parity is checked
every frame while receiving and error signals sent to the transmitting side whenever an error is
detected so that data can be re-transmitted. During transmission, error signals are sampled and data
re-transmitted whenever an error signal is detected.
With no parity error
Ds
D0
D1
D2
D3
D4
D5
D6
D7
Dp
D6
D7
Dp
Transmitting station output
With parity error
Ds
D0
D1
D2
D3
D4
D5
DE
Transmitting station output
Ds:
D0−D7:
Dp:
DE:
Start bit
Data bits
Parity bit
Error signal
Receiving
station output
Figure 15.3 Data Format for Smart Card Interface
The operating sequence is:
1. The data line is high-impedance when not in use and is fixed high with a pull-up register.
2. The transmitting side starts one frame of data transmission. The data frame starts with a start
bit (Ds, low level). The start bit is followed by eight data bits (D0–D7) and a parity bit (Dp).
3. On the smart card interface, the data line returns to high-impedance after this. The data line is
pulled high with a pull-up register.
4. The receiving side checks parity. When the data is received normally with no parity errors, the
receiving side then waits to receive the next data. When a parity error occurs, the receiving
side outputs an error signal (DE, low level) and requests re-transfer of data. The receiving
station returns the signal line to high-impedance after outputting the error signal for a specified
period. The signal line is pulled high with a pull-up register.
Rev. 5.00, 09/03, page 496 of 760
5. The transmitting side transmits the next frame of data unless it receives an error signal. If it
does receive an error signal, it returns to step 2 to re-transmit the erroneous data.
15.3.4
Register Settings
Table 15.3 shows the bit map of the registers that the smart card interface uses. Bits shown as 1 or
0 must be set to the indicated value. The settings for the other bits are described below.
Table 15.3 Register Settings for Smart Card Interface
Register
Address
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
SCSMR
H'FFFFFE80
C/A
0
1
O/E
1
0
CKS1
CKS0
SCBRR
H'FFFFFE82
BRR7
BRR6
BRR5
BRR4
BRR3
BRR2
BRR1
BRR0
SCSCR
H'FFFFFE84
TIE
RIE
TE
RE
0
0
CKE1
CKE0
SCTDR
H'FFFFFE86
TDR7
TDR6
TDR5
TDR4
TDR3
TDR2
TDR1
TDR0
SCSSR
H'FFFFFE88
TDRE
RDRF
ORER
FER/
ERS
PER
TEND
0
0
SCRDR
H'FFFFFE8A
RDR7
RDR6
RDR5
RDR4
RDR3
RDR2
RDR1
RDR0
SCSCMR
H'FFFFFE8C
—
—
—
—
SDIR
SINV
—
SMIF
Note: Dashes indicate unused bits.
1. Setting the serial mode register (SCSMR): The C/A bit selects the setting timing of the TEND
flag, and selects the clock output state in combination with bits CKE1 and CKE0 in the serial
control register (SCSCR). Clear the O/E bit to 0 if the IC card uses the direct convention, and
set it to 1 if the card uses the inverse convention. Select the on-chip baud rate generator clock
source with the CKS1 and CKS0 bits (see section 15.3.5, Clock).
2. Setting the bit rate register (SCBRR): Set the bit rate. See section 15.3.5, Clock, to see how to
calculate the set value.
3. Setting the serial control register (SCSCR): The TIE, RIE, TE and RE bits function as they do
for the ordinary SCI. See section 14, Serial Communication Interface (SCI), for more
information. The CKE0 bit specifies the clock output. When no clock is output, clear CKE0 to
0; when a clock is output, set CKE0 to 1.
4. Setting the smart card mode register (SCSCMR): The SDIR and SINV bits are both cleared to
0 for IC cards that use the direct convention, and both set to 1 when the inverse convention is
used. The SMIF bit is set to 1 for the smart card interface.
Figure 15.4 shows sample waveforms for register settings of the two types of IC cards (direct
convention and inverse convention) and their start characters.
In the direct convention type, the logical 1 level is state Z, the logical 0 level is state A, and
communication is LSB-first. The start character data is H'3B. Parity is even (from the smart
card standard), and so the parity bit is 1.
Rev. 5.00, 09/03, page 497 of 760
In the inverse convention type, the logical 1 level is state A, the logical 0 level is state Z, and
communication is MSB first. The start character data is H'3F. Parity is even (from the smart
card standard), and so the parity bit is 0, which corresponds to state Z.
Only data bits D7–D0 are inverted by the SINV bit. To invert the parity bit, set the O/E bit in
SCSMR to odd parity mode. This applies to both transmission and reception.
(Z)
A
Z
Z
A
Z
Z
Z
A
A
Ds
D0
D1
D2
D3
D4
D5
D6
D7
Z
(Z)
State
(Z)
State
Dp
a. Direct convention (SDIR, SINV, and O/E are all 0)
(Z)
A
Z
Z
A
A
A
A
A
A
Ds
D7
D6
D5
D4
D3
D2
D1
D0
Z
Dp
b. Inverse convention (SDIR, SINV, and O/E are all 1)
Figure 15.4 Waveform of Start Character
15.3.5
Clock
Only the internal clock generated by the on-chip baud rate generator can be used as the
communication clock in the smart card interface. The bit rate for the clock is set by the bit rate
register (SCBRR) and the CKS1 and CKS0 bits in the serial mode register (SCSMR), and is
calculated using the equation below. Table 15.5 shows sample bit rates. If clock output is then
selected by setting CKE0 to 1, a clock with a frequency 372 times the bit rate is output from the
SCK0 pin.
B=
Pφ
× 106
1488 × 22n–1 × (N + 1)
Where: N = Value set in SCBRR (0 ≤ N ≤ 255)
B = Bit rate (bits/s)
Pφ = Peripheral module operating frequency (MHz)
n = 0 to 3 (table 15.4)
Rev. 5.00, 09/03, page 498 of 760
Table 15.4 Relationship of n to CKS1 and CKS0
n
CKS1
CKS0
0
0
0
1
0
1
2
1
0
3
1
1
Table 15.5 Examples of Bit Rate B (Bits/s) for SCBRR Settings (n = 0)
Pφ (MHz)
N
7.1424
10.00
10.7136
13.00
14.2848
16.00
18.00
0
9600.0
13440.9
14400.0
17473.1
19200.0
21505.4
24193.5
1
4800.0
6720.4
7200.0
8736.6
9600.0
10752.7
12096.8
2
3200.0
4480.3
4800.0
5824.4
6400.0
7168.5
8064.5
Note: The bit rate is rounded to one decimal place.
Calculate the value to be set in the bit rate register (SCBRR) from the operating frequency and the
bit rate. N is an integer in the range 0 ≤ N ≤ 255, specifying a smallish error.
N=
Pφ
× 106 − 1
1488 × 22n−1 × B
Table 15.6 Examples of SCBRR Settings for Bit Rate B (Bits/s) (n = 0)
φ (MHz) (9600 Bits/s)
7.1424
10.00
10.7136
13.00
14.2848
16.00
18.00
N
Error
N
Error
N
Error
N
Error
N
Error
N
Error
N
Error
0
0.00
1
30.00
1
25.00
1
8.99
1
0.00
1
12.01
2
15.99
Rev. 5.00, 09/03, page 499 of 760
Table 15.7 Maximum Bit Rates for Frequencies (Smart Card Interface Mode)
Pφ (MHz)
Maximum Bit Rate (Bits/s)
N
n
7.1424
9600
0
0
10.00
13441
0
0
10.7136
14400
0
0
13.00
17473
0
0
14.2848
19200
0
0
16.00
21505
0
0
18.00
24194
0
0
The bit rate error is found as follows:
Error (%) = (
1488 ×
Pφ
× 106 − 1) × 100
× B × (N + 1)
22n−1
Table 15.8 shows the relationship between transmit/receive clock register set values and output
states on the smart card interface.
Table 15.8 Register Set Values and SCK Pin
Register Value
SCK Pin
Setting
SMIF
C/A
A
CKE1
CKE0
Output
State
1
1*
1
0
0
0
Port
Determined by setting of port
register SCP1MD1 and
SCP1MD0 bits
1
0
0
1
1
1
0
0
1
1
0
1
1
1
1
0
1
1
1
1
2
2*
2
3*
SCK (serial clock) output state
Low output
Low output state
SCK (serial clock) output state
High output
High output state
SCK (serial clock) output state
Notes: 1. The SCK output state changes as soon as the CKE0 bit is modified. The CKE1 bit
should be cleared to 0.
2. The clock duty remains constant despite stopping and starting of the clock by
modification of the CKE0 bit.
Rev. 5.00, 09/03, page 500 of 760
15.3.6
Data Transmission and Reception
Initialization: Initialize the SCI using the following procedure before sending or receiving data.
Initialization is also required for switching from transmit mode to receive mode or from receive
mode to transmit mode. Figure 15.5 shows a flowchart of the initialization process.
1. Clear TE and RE in the serial control register (SCSCR) to 0.
2. Clear error flags FER/ERS, PER, and ORER to 0 in the serial status register (SCSSR).
3. Set the C/A bit, parity bit (O/E bit), and baud rate generator select bits (CKS1 and CKS0 bits)
in the serial mode register (SCSMR). At this time also clear the CHR and MP bits to 0 and set
the STOP and PE bits to 1.
4. Set the SMIF, SDIR, and SINV bits in the smart card mode register (SCSCMR). When the
SMIF bit is set to 1, the TxD and RxD pins both switch from ports to SCI pins and become
high-impedance.
5. Set the value corresponding to the bit rate in the bit rate register (SCBRR).
6. Set the clock source select bits (CKE1 and CKE0 bits) in the serial control register (SCSCR).
Clear the TIE, RIE, TE, RE, MPIE, and TEIE bits to 0. When the CKE0 bit is set to 1, a clock
is output from the SCK pin.
7. After waiting at least 1 bit, set the TIE, RIE, TE, and RE bits in SCSCR. Do not set the TE and
RE bits simultaneously unless performing auto-diagnosis.
Rev. 5.00, 09/03, page 501 of 760
Initialization
Clear TE and RE bits in SCSCR to 0
(1)
Clear FER/ERS, PER
and ORER flags in SCSSR to 0
(2)
Set parity in O/E bit,
set clock in CKS1 and CKS0 bits,
and set C/A, in SCSMR
(3)
Set SMIF, SDIR,
and SINV bits in SCSMR
(4)
Set value in SCBRR
(5)
Set clock in CKE1 and CKE0 bits,
and clear TIE, RIE, TE, RE, MPIE,
and TEIE bits to 0, in SCSCR
(6)
Wait
Has a 1-bit
interval elapsed?
No
Yes
Set TIE, RIE, TE, and RE bits
in SCSCR
(7)
End
Note: Numbers in parentheses refer to steps in the preceding procedure description.
Figure 15.5 Initialization Flowchart (Example)
Rev. 5.00, 09/03, page 502 of 760
Serial Data Transmission: The processing procedures in the smart card mode differ from
ordinary SCI processing because data is retransmitted when an error signal is sampled during a
data transmission. This results in the transmission processing flowchart shown in figure 15.6.
1. Initialize the smart card interface mode as described in Initialization above.
2. Check that the FER/ERS bit in SCSSR is cleared to 0.
3. Repeat steps 2 and 3 until the TEND flag in SCSSR is set to 1.
4. Write the transmit data into SCTDR, clear the TDRE flag to 0 and start transmitting. The
TEND flag will be cleared to 0.
5. To transmit more data, return to step 2.
6. To end transmission, clear the TE bit to 0.
This processing can be interrupted. When the TIE bit is set to 1 and interrupt requests are enabled,
a transmit-data-empty interrupt (TXI) will be requested when the TEND flag is set to 1 at the end
of transmission. When the RIE bit is set to 1 and interrupt requests are enabled, a communication
error interrupt (ERI) will be requested when the ERS flag is set to 1 when an error occurs in
transmission. See Interrupt Operation below for more information.
Rev. 5.00, 09/03, page 503 of 760
Start
Initialize
(1)
Start of transmission
FER/ERS = 0?
(2)
No
Yes
Error handling
No
TEND = 1?
(3)
Yes
Write transmit data in SCTDR
and clear TDRE
flag in SCSSR to 0
(4)
All data transmitted?
(5)
No
Yes
FER/ERS = 0?
No
Yes
Error handling
No
TEND = 1?
Yes
Clear TE bit in SCSCR to 0
(6)
End of transmission
Note: Numbers in parentheses refer to steps in the preceding procedure description.
Figure 15.6 Transmission Flowchart
Rev. 5.00, 09/03, page 504 of 760
Serial Data Reception: The processing procedures in smart card mode are the same as in ordinary
SCI processing. The reception processing flowchart is shown in figure 15.7.
1. Initialize the smart card interface mode as described above in Initialization and in figure 15.5.
2. Check that the ORER and PER flags in SCSSR are cleared to 0. If either flag is set, clear both
to 0 after performing the appropriate error handling procedures.
3. Repeat steps 2 and 3 until the RDRF flag is set to 1.
4. Read the receive data from SCRDR.
5. To receive more data, clear the RDRF flag to 0 and return to step 2.
6. To end reception, clear the RE bit to 0.
This processing can be interrupted. When the RIE bit is set to 1 and interrupt requests are enabled,
a receive-data-full interrupt (RXI) will be requested when the RDRF flag is set to 1 at the end of
reception. When an error occurs during reception and either the ORER or PER flag is set to 1, a
communication error interrupt (ERI) will be requested. See Interrupt Operation below for more
information.
The received data will be transferred to SCRDR even when a parity error occurs during reception
and PER is set to 1, so this data can still be read.
Rev. 5.00, 09/03, page 505 of 760
Start
Initialize
(1)
Start of reception
ORER = 0 or PER = 0?
(2)
No
Yes
Error handling
No
RDRF = 1?
(3)
Yes
Write receive data from
SCRDR and clear
RDRF flag in SCSSR to 0
(4)
All data received?
(5)
No
Yes
Clear RE bit in SCSCR to 0
(6)
End of reception
Note: Numbers in parentheses refer to steps in the preceding procedure description.
Figure 15.7 Reception Flowchart (Example)
Rev. 5.00, 09/03, page 506 of 760
Switching Modes: When switching from receive mode to transmit mode, check that the receive
operation is completed before starting initialization, clearing RE to 0, and setting TE to 1. The
RDRF, PER, and ORER flags can be used to check if reception is completed. When switching
from transmit mode to receive mode, check that the transmit operation is completed before starting
initialization, clearing TE to 0, and setting RE to 1. The TEND flag can be used to check if
transmission is completed.
Interrupt Operation: In the smart card interface mode, there are three types of interrupts:
transmit-data-empty (TXI), communication error (ERI) and receive-data-full (RXI). In this mode,
the transmit-end interrupt (TEI) cannot be requested.
Set the TEND flag in SCSSR to 1 to request a TXI interrupt. Set the RDRF flag in SCSSR to 1 to
request an RXI interrupt. Set the ORER, PER, or FER/ERS flag in SCSSR to 1 to request an ERI
interrupt (table 15.9).
Table 15.9 Smart Card Mode Operating State and Interrupt Sources
Mode
State
Flag
Mask Bit
Interrupt Source
Transmit mode
Normal
TEND
TIE
TXI
Error
FER/ERS
RIE
ERI
Normal
RDRF
RIE
RXI
Error
PER,
ORER
RIE
ERI
Receive mode
15.4
Usage Notes
When the SCI is used as a smart card interface, be sure that all criteria in sections 15.4.1, Receive
Data Timing and Receive Margin in Asynchronous Mode and 15.4.2, Retransmission are applied.
15.4.1
Receive Data Timing and Receive Margin in Asynchronous Mode
In asynchronous mode, the SCI runs on a base clock with a frequency of 372 times the transfer
rate. During reception, the SCI samples the falling of the start bit using the base clock to achieve
internal synchronization. Receive data is latched internally at the rising edge of the 186th base
clock cycle (figure 15.8).
Rev. 5.00, 09/03, page 507 of 760
372 clock cycles
186 clock cycles
0
185
371 0
185
371 0
Base clock
Start
bit
Receive
data (RxD)
D0
Synchronization
sampling
timing
Data
sampling
timing
Figure 15.8 Receive Data Sampling Timing in Smart Card Mode
The receive margin is found from the following equation:
For smart card mode:
M = (0.5 −
Where:
1
D − 0.5
(1 + F) × 100%
) − (L − 0.5)F −
2N
N
M = Receive margin (%)
N = Ratio of bit rate to clock (N = 372)
D = Clock duty (D = 0 to 1.0)
L = Frame length (L = 10)
F = Absolute value of clock frequency deviation
Using this equation, the receive margin when F = 0 and D = 0.5 is as follows:
M = (0.5 – 1/2 × 372) × 100% = 49.866%
Rev. 5.00, 09/03, page 508 of 760
D1
15.4.2
Retransmission (Receive and Transmit Modes)
Retransmission when SCI is in Receive Mode: Figure 15.9 shows the retransmission operation
in the SCI receive mode.
1. When the received parity bit is checked and an error is found, the PER bit in SCSSR is
automatically set to 1. If the RIE bit in SCSCR is enabled at this time, an ERI interrupt is
requested. Be sure to clear the PER bit before the next parity bit is sampled.
2. The RDRF bit in SCSSR is not set in the frame that caused the error.
3. When the received parity bit is checked and no error is found, the PER bit in SCSSR is not set.
4. When the received parity bit is checked and no error is found, reception is considered to have
been completed normally and the RDRF bit in SCSSR is automatically set to 1. If the RIE bit
in SCSCR is enabled at this time, an RXI interrupt is requested.
5. When a normal frame is received, the pin maintains a three-state state when it transmits the
error signal.
nth transfer frame
Retransmitted frame
Transfer frame n + 1
(DE)
Ds D0 D1 D2 D3 D4 D5 D6 D7 Dp DE
Ds D0 D1 D2 D3 D4 D5 D6 D7 Dp
5
Ds D0 D1 D2 D3 D4
RDRF
2
4
1
3
PER
Figure 15.9 Retransmission in SCI Receive Mode
Rev. 5.00, 09/03, page 509 of 760
Retransmission when SCI is in Transmit Mode: Figure 15.10 shows the retransmission
operation in the SCI transmit mode.
1. After transmission of one frame is completed, the FER/ERS bit in SCSSR is set to 1 when a
error signal is returned from the receiving side. If the RIE bit in SCSCR is enabled at this time,
an ERI interrupt is requested. Be sure to clear the FER/ERS bit before the next parity bit is
sampled.
2. The TEND bit in SCSSR is not set in the frame that received the error signal indicating the
error.
3. The FER/ERS bit in SCSSR is not set when no error signal is returned from the receiving side.
4. When no error signal is returned from the receiving side, the TEND bit in SCSSR is set to 1
when the transmission of the frame that includes the retransmission is considered completed. If
the TIE bit in SCSCR is enabled at this time, a TXI interrupt will be requested.
nth transfer frame
Retransmitted frame
Transfer frame n + 1
(DE)
Ds D0 D1 D2 D3 D4 D5 D6 D7 Dp DE
Ds D0 D1 D2 D3 D4 D5 D6 D7 Dp
TDRE
Transfer from SCTDR
to SCTSR
TEND
Ds D0 D1 D2 D3 D4
Transfer from SCTDR
to SCTSR
Transfer from SCTDR
to SCTSR
2
4
FER/ERS
1
3
Figure 15.10 Retransmission in SCI Transmit Mode
Rev. 5.00, 09/03, page 510 of 760
Section 16 Serial Communication Interface with FIFO
(SCIF)
16.1
Overview
The SH7709S has a two-channel serial communication interface with FIFO (SCIF) that supports
asynchronous serial communication. It also has 16-stage FIFO registers for both transmission and
reception that enable the SH7709S to perform efficient high-speed continuous communication.
16.1.1
Features
• Asynchronous serial communication:
 Serial data communication is performed by start-stop in character units. The SCI can
communicate with a universal asynchronous receiver/transmitter (UART), an asynchronous
communication interface adapter (ACIA), or any other communications chip that employs
a standard asynchronous serial system. There are eight selectable serial data
communication formats.
 Data length: 7 or 8 bits
 Stop bit length: 1 or 2 bits
 Parity: Even, odd, or none
 Receive error detection: Parity and framing errors
 Break detection: Break is detected when a framing error is followed by at least one frame at
the space 0 level (low level). It is also detected by reading the RxD level directly from the
port SC data register (SCPDR) when a framing error occurs.
• Full duplex communication: The transmitting and receiving sections are independent, so the
SCI can transmit and receive simultaneously. Both sections use 16-stage FIFO buffering, so
high-speed continuous data transfer is possible in both the transmit and receive directions.
• On-chip baud rate generator with selectable bit rates
• Internal or external transmit/receive clock source: From either baud rate generator (internal) or
SCK pin (external)
• Four types of interrupts: Transmit-FIFO-data-empty, break, receive-FIFO-data-full, and
receive-error interrupts are requested independently. The direct memory access controller
(DMAC) can be activated to execute a data transfer by a transmit-FIFO-data-empty or receiveFIFO-data-full interrupt.
• When the SCIF is not in use, it can be stopped by halting the clock supplied to it, saving
power.
• On-chip modem control functions (RTS and CTS)
• The quantity of data in the transmit and receive FIFO registers and the number of receive
errors of the receive data in the receive FIFO register can be ascertained.
• A time-out error (DR) can be detected when receiving.
Rev. 5.00, 09/03, page 511 of 760
16.1.2
Block Diagram
Bus interface
Figure 16.1 shows a block diagram of the SCIF.
Module data bus
SCFRDR2
SCFTDR2
(16
(16
stages)
stages)
Receive
buffer
RxD
TxD
SCRSR
Transmit
buffer
SCTSR
SCPCR
SCFDR
SCFDR2
SCFCR2
SCSSR2
SCSCR2
SCSMR2
Transmit/
receive
control
Parity check
SCBRR
Baud rate
generator
Receive shift register
Receive FIFO data register 2
Transmit shift register
Transmit FIFO data register 2
Serial mode register 2
Serial control register 2
Pφ/64
External clock
SCSSR2:
SCBRR2:
SCFCR2:
SCFDR2:
SCPDR:
SCPCR:
TEI
TXI
RXI
BRI
Serial status register 2
Bit rate register 2
FIFO control register 2
FIFO data count register 2
Port SC data register
Port SC control register
Figure 16.1 Block Diagram of SCIF
Rev. 5.00, 09/03, page 512 of 760
Pφ/4
Pφ/16
SCIF
Legend
SCRSR:
SCFRDR2:
SCTSR:
SCFTDR2:
SCSMR2:
SCSCR2:
Pφ
Clock
Parity generation
SCK
Internal
data bus
Figures 16.2 to 16.4 show the SCIF I/O port pins.
SCIF pin I/O and data control is performed by bits 11 to 8 of SCPCR and bits 5 and 4 of SCPDR.
For details, see section 14.2.8, SC Port Control Register (SCPCR)/SC Port Data Register
(SCPDR).
Reset
R
D
SCP5MD0
Q
C
Internal data bus
PCRW
Reset
Q
R
D
SCP5MD1
C
SCIF
PCRW
Clock input enable
Reset
SCPT[5]/SCK2
R
Q
D
SCP5DT1
C
PDRW
Output enable
Serial clock output
PDRR*
Serial clock input
Legend
PDRW: SCPDR write
PDRR: SCPDR read
PCRW: SCPCR write
Note: * When reading the SCK2 pin, clear the CKE1 and CKE0
bits in SCSCR to 0, and set the SCP5MD1 bit in SCSPR to 1 (see section 14.2.8,
SC Port Control Register (SCPCR)/SC Port Data Register (SCPDR)).
Figure 16.2 SCPT[5]/SCK2 Pin
Rev. 5.00, 09/03, page 513 of 760
Reset
R
D
SCP4MD0
Q
C
Internal data bus
PCRW
Reset
Q
R
D
SCP4MD1
C
PCRW
Reset
SCPT[4]/TxD2
R
Q
D
SCP4DT1
C
SCIF
PDRW
Output enable
Serial
transmission
output
Legend
PCRW: SCPCR write
PDRW: SCPDR write
Figure 16.3 SCPT[4]/TxD2 Pin
Rev. 5.00, 09/03, page 514 of 760
SCIF
SCPT[4]/RxD2
Serial
receive
data
PDRR*
Internal data bus
Legend
PDRR: SCPDR read
Note: * When reading the RxD2 pin, set the RE bit in SCSCR to 1.
Figure 16.4 SCPT[4]/RxD2 Pin
16.1.3
Pin Configuration
The SCIF has the serial pins summarized in table 16.1.
Table 16.1 SCIF Pins
Pin Name
Abbreviation
I/O
Function
Serial clock pin
SCK2
I/O
Clock I/O
Receive data pin
RxD2
Input
Receive data input
Transmit data pin
TxD2
Output
Transmit data output
Request to send pin
RTS2
Output
Request to send
Clear to send pin
CTS2
Input
Clear to send
Rev. 5.00, 09/03, page 515 of 760
16.1.4
Register Configuration
Table 16.2 summarizes the SCIF internal registers. These registers specify the data format and bit
rate, and control the transmitter and receiver sections.
Table 16.2 SCIF Registers
Register Name
Abbreviation R/W
Initial Value Address
Serial mode register 2
SCSMR2
R/W
H'00
H'04000150
8 bits
2
(H'A4000150)*
Bit rate register 2
SCBRR2
R/W
H'FF
H'04000152
8 bits
2
(H'A4000152)*
Serial control register 2
SCSCR2
R/W
H'00
H'04000154
8 bits
2
(H'A4000154)*
Transmit FIFO data register 2 SCFTDR2
W
—
H'04000156
8 bits
2
(H'A4000156)*
Serial status register 2
R/(W)* H'0060
H'04000158
16 bits
2
(H'A4000158)*
Receive FIFO data register 2 SCFRDR2
R
Undefined
H'0400015A
8 bits
2
(H'A400015A)*
FIFO control register 2
SCFCR2
R/W
H'00
H'0400015C
8 bits
2
(H'A400015C)*
FIFO data count register 2
SCFDR2
R
H'0000
H'0400015E
16 bits
2
(H'A400015E)*
SCSSR2
1
Access size
Notes: These registers are located in area 1 of physical space. Therefore, when the cache is on,
either access these registers from the P2 area of logical space or else make an appropriate
setting using the MMU so that these registers are not cached.
1. Only 0 can be written to clear the flag.
2. When address translation by the MMU does not apply, the address in parentheses
should be used.
Rev. 5.00, 09/03, page 516 of 760
16.2
Register Descriptions
16.2.1
Receive Shift Register (SCRSR)
The receive shift register (SCRSR) receives serial data. Data input at the RxD pin is loaded into
SCRSR in the order received, LSB (bit 0) first, converting the data to parallel form. When one
byte has been received, it is automatically transferred to SCFRDR, the receive FIFO data register.
The CPU cannot read or write to SCRSR directly.
16.2.2
Bit:
7
6
5
4
3
2
1
0
R/W:
—
—
—
—
—
—
—
—
Receive FIFO Data Register (SCFRDR)
The 16-byte receive FIFO data register (SCFRDR) stores serial receive data. The SCIF completes
the reception of one byte of serial data by moving the received data from the receive shift register
(SCRSR) into SCFRDR for storage. Continuous reception is possible until 16 bytes are stored.
The CPU can read but not write to SCFRDR. If data is read when there is no receive data in the
SCFRDR, the value is undefined. When this register is full of receive data, subsequent serial data
is lost.
16.2.3
Bit:
7
6
5
4
3
2
1
0
R/W:
R
R
R
R
R
R
R
R
Transmit Shift Register (SCTSR)
The transmit shift register (SCTSR) transmits serial data. The SCI loads transmit data from the
transmit FIFO data register (SCFTDR) into SCTSR, then transmits the data serially from the TxD
pin, LSB (bit 0) first. After transmitting one data byte, the SCI automatically loads the next
transmit data from SCFTDR into SCTSR and starts transmitting again. The CPU cannot read or
write to SCTSR directly.
Bit:
7
6
5
4
3
2
1
0
R/W:
—
—
—
—
—
—
—
—
Rev. 5.00, 09/03, page 517 of 760
16.2.4
Transmit FIFO Data Register (SCFTDR)
The transmit FIFO data register (SCFTDR) is a FIFO register comprising sixteen 8-bit stages that
stores data for serial transmission. When the SCIF detects that the transmit shift register (SCTSR)
is empty, it moves transmit data written in the SCFTDR into SCTSR and starts serial transmission.
Continuous serial transmission is performed until there is no transmit data left in SCFTDR. The
CPU can always write to SCFTDR.
When SCFTDR is full of transmit data (16 stages), no more data can be written. If writing of new
data is attempted, the data is ignored.
16.2.5
Bit:
7
6
5
4
3
2
1
0
R/W:
W
W
W
W
W
W
W
W
Serial Mode Register (SCSMR)
The serial mode register (SCSMR) is an 8-bit register that specifies the SCIF serial
communication format and selects the clock source for the baud rate generator.
The CPU can always read and write to SCSMR. SCSMR is initialized to H'00 by a reset and in
standby or module standby mode.
Bit:
7
6
5
4
3
2
1
0
—
CHR
PE
O/E
STOP
—
CKS1
CKS0
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R/W
R/W
R/W
R/W
R
R/W
R/W
Bit 7—Reserved: This bit is always read as 0. The write value should always be 0.
Bit 6—Character Length (CHR): Selects 7-bit or 8-bit data in asynchronous mode.
Bit 6: CHR
Description
0
8-bit data
7-bit data*
1
(Initial value)
Note: * When 7-bit data is selected, the MSB (bit 7) of the transmit FIFO data register is not
transmitted.
Rev. 5.00, 09/03, page 518 of 760
Bit 5—Parity Enable (PE): Selects whether to add a parity bit to transmit data and to check the
parity of receive data.
Bit 5: PE
Description
0
Parity bit not added or checked
Parity bit added and checked*
1
(Initial value)
Note: * When PE is set to 1, an even or odd parity bit is added to transmit data, depending on the
parity mode (O/E) setting. Receive data parity is checked according to the even/odd (O/E)
mode setting.
Bit 4—Parity Mode (O/E
E): Selects even or odd parity when parity bits are added and checked.
The O/E setting is used only when the parity enable bit (PE) is set to 1 to enable parity addition
and checking. The O/E setting is ignored when parity addition and checking is disabled.
Bit 4: O/E
E
Description
0
Even parity*
2
Odd parity*
1
1
(Initial value)
Notes: 1. If even parity is selected, the parity bit is added to transmit data to make an even
number of 1s in the transmitted character and parity bit combined. Receive data is
checked to see if it has an even number of 1s in the received character and parity bit
combined.
2. If odd parity is selected, the parity bit is added to transmit data to make an odd number
of 1s in the transmitted character and parity bit combined. Receive data is checked to
see if it has an odd number of 1s in the received character and parity bit combined.
Bit 3—Stop Bit Length (STOP): Selects one or two bits as the stop bit length.
When receiving, only the first stop bit is checked, regardless of the STOP bit setting. If the second
stop bit is 1, it is treated as a stop bit, but if the second stop bit is 0, it is treated as the start bit of
the next incoming character.
Bit 3: STOP
Description
0
One stop bit*
2
Two stop bits*
1
1
(Initial value)
Notes: 1. When transmitting, a single 1-bit is added at the end of each transmitted character.
2. When transmitting, two 1-bits are added at the end of each transmitted character.
Bit 2—Reserved: This bit is always read as 0. The write value should always be 0.
Rev. 5.00, 09/03, page 519 of 760
Bits 1 and 0—Clock Select 1 and 0 (CKS1, CKS0): Select the internal clock source of the onchip baud rate generator. According to the setting of the CKS1 and CKS0 bits four clock sources
are available. Pφ, Pφ/4, Pφ/16 and Pφ/64. For further information on the clock source, bit rate
register settings, and baud rate, see section 16.2.8, Bit Rate Register (SCBRR).
Bit 1: CKS1
Bit 0: CKS0
Description
0
0
Pφ
1
Pφ/4
0
Pφ/16
1
Pφ/64
1
(Initial value)
Note: Pφ: Peripheral clock
16.2.6
Serial Control Register (SCSCR)
The serial control register (SCSCR) operates the SCIF transmitter/receiver, selects the serial clock
output in asynchronous mode, enables/disables interrupt requests, and selects the transmit/receive
clock source. The CPU can always read and write to SCSCR. SCSCR is initialized to H'00 by a
reset and in standby or module standby mode.
Bit:
Initial value:
R/W:
7
6
5
4
3
2
1
0
TIE
RIE
TE
RE
—
—
CKE1
CKE0
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R
R
R/W
R/W
Bit 7—Transmit Interrupt Enable (TIE): Enables or disables the transmit-FIFO-data-empty
interrupt (TXI) requested when the serial transmit data is transferred from the transmit FIFO data
register (SCFTDR) to the transmit shift register (SCTSR), when the quantity of data in the
transmit FIFO register becomes less than the specified number of transmission triggers, and when
the TDFE flag in the serial FIFO status register (SCFSR) is set to1.
Bit 7: TIE
Description
0
Transmit-FIFO-data-empty interrupt request (TXI) is disabled*
1
Transmit-FIFO-data-empty interrupt request (TXI) is enabled
(Initial value)
Note: * The TXI interrupt request can be cleared by writing a greater quantity of transmit data than
the specified transmission trigger number to SCFTDR and by clearing TDFE to 0 after
reading 1 from TDFE, or can be cleared by clearing TIE to 0.
Rev. 5.00, 09/03, page 520 of 760
Bit 6—Receive Interrupt Enable (RIE): Enables or disables the receive-data-full (RXI) and
receive-error (ERI) interrupts requested when serial receive data is transferred from the receive
shift register (SCRSR) to the receive FIFO data register (SCFRDR), when the quantity of data in
the receive FIFO register becomes more than the specified receive trigger number, and when the
RDRF flag in SCSSR is set to1.
Bit 6: RIE
Description
0
Receive-data-full interrupt (RXI), receive-error interrupt (ERI), and receive break
interrupt (BRI) requests are disabled*
(Initial value)
1
Receive-data-full interrupt (RXI) and receive-error interrupt (ERI) requests are
enabled
Note: * RXI and ERI interrupt requests can be cleared by reading the DR, ER, or RDF flag after it
has been set to 1, then clearing the flag to 0, or by clearing RIE to 0. With the RDF flag,
read 1 from the RDF flag and clear it to 0, after reading receive data from SCRDR until the
quantity of receive data becomes less than the specified receive trigger number.
Bit 5—Transmit Enable (TE): Enables or disables the SCIF serial transmitter.
Bit 5: TE
Description
0
Transmitter disabled
Transmitter enabled*
1
(Initial value)
Note: * Serial transmission starts after writing of transmit data into SCFTDR2. Select the transmit
format in SCSMR2 and SCFCR2 and reset the TFIFO before setting TE to 1.
Bit 4—Receive Enable (RE): Enables or disables the SCIF serial receiver.
Bit 4: RE
Description
0
Receiver disabled*
2
Receiver enabled*
1
1
(Initial value)
Notes: 1. Clearing RE to 0 does not affect the receive flags (DR, ER, BRK, FER, PER, and
ORER). These flags retain their previous values.
2. Serial reception starts when a start bit is detected. Select the receive format in
SCSMR2 before setting RE to 1.
Bits 3 and 2—Reserved: These bits are always read as 0. The write value should always be 0.
Rev. 5.00, 09/03, page 521 of 760
Bits 1 and 0—Clock Enable 1 and 0 (CKE1, CKE0): Select the SCIF clock source and enable
or disable clock output from the SCK pin. Depending on the combination of CKE1 and CKE0, the
SCK pin can be used for serial clock output or serial clock input.
The CKE0 setting is valid only when the SCIF is operating on the internal clock (CKE1 = 0). The
CKE0 setting is ignored when an external clock source is selected (CKE1 = 1). Before selecting
the SCIF operating mode in the serial mode register (SCSMR), set CKE1 and CKE0. For further
details on selection of the SCIF clock source, see table 16.7 in section 16.3, Operation.
Bit 1: CKE1
Bit 0: CKE0
Description
0
0
Internal clock, SCK pin used for input pin (input signal is
ignored)
(Initial value)
1
Internal clock, SCK pin used for clock output*
1
1
2
External clock, SCK pin used for clock input*
2
External clock, SCK pin used for clock input*
0
1
Notes: 1. The output clock frequency is 16 times the bit rate.
2. The input clock frequency is 16 times the bit rate.
16.2.7
Serial Status Register (SCSSR)
The serial status register (SCSSR) is a 16-bit register. The upper 8 bits indicate the number of
receive errors in the SCFRDR data, and the lower 8 bits indicate the SCIF operating state.
The CPU can always read and write to SCSSR, but cannot write 1 to the status flags (ER, TEND,
TDFE, BRK, OPER, and DR). These flags can be cleared to 0 only if they have first been read
(after being set to 1). Bits 3 (FER) and 2 (PER) are read-only bits that cannot be written. SCSSR is
initialized to H'0060 by a reset and in standby or module standby mode.
Lower 8 bits:
Initial value:
R/W:
7
6
5
4
3
2
1
0
ER
TEND
TDFE
BRK
FER
PER
RDF
DR
0
1
1
0
0
0
0
0
R/(W)*
R/(W)*
R/(W)*
R/(W)*
R
R/(W)*
R/(W)*
Note: * The only value that can be written is 0 to clear the flag.
Rev. 5.00, 09/03, page 522 of 760
R
Bit 7—Receive Error (ER): Indicates the occurrence of a framing error, or of a parity error when
receiving data that includes parity.
Bit 7: ER
Description
0
1
Receiving is in progress or has ended normally*
(Initial value)
[Clearing conditions]
(1) By a power-on reset or in standby mode ER is cleared to 0 when the chip is
reset or enters standby mode
(2) When 0 is written after 1 is read from ER
1
2
A framing error or parity error has occurred*
[Setting conditions]
(1) ER is set to 1 when the stop bit is 0 after checking whether or not the last
2
stop bit of the received data is 1 at the end of one data receive operation*
(2) When the total number of 1s in the receive data plus parity bit does not match
the even/odd parity specified by the O/E bit in SCSMR
Notes: 1. Clearing the RE bit to 0 in SCSCR does not affect the ER bit, which retains its previous
value. Even if a receive error occurs, the receive data is transferred to SCFRDR and
the receive operation is continued. Whether or not the data read from SCRDR includes
a receive error can be detected by the FER and PER bits in SCSSR.
2. In stop mode, only the first stop bit is checked; the second stop bit is not checked.
Bit 6—Transmit End (TEND): Indicates that when the last bit of a serial character was
transmitted, SCFTDR did not contain valid data, so transmission has ended.
Bit 6: TEND
Description
0
Transmission is in progress
[Clearing condition]
When data is written in SCFTDR
1
End of transmission
(Initial value)
[Setting conditions]
(1) When the chip is reset or enters standby mode, when TE is cleared to 0 in
the serial control register (SCSCR)
(2) When SCFTDR does not contain receive data when the last bit of a one-byte
serial character is transmitted
Rev. 5.00, 09/03, page 523 of 760
Bit 5—Transmit FIFO Data Empty (TDFE): Indicates that data has been transferred from the
transmit FIFO data register (SCFTDR) to the transmit shift register (SCTSR), the quantity of data
in SCFTDR has become less than the transmission trigger number specified by the TTRG1 and
TTRG0 bits in the FIFO control register (SCFCR), and writing of transmit data to SCFTDR is
enabled.
Bit 5: TDFE
Description
0
The quantity of transmit data written to SCFTDR is greater than the specified
transmission trigger number
(Initial value)
[Clearing condition]
TDFE is cleared to 0 when data exceeding the specified transmission trigger
number is written to SCFTDR, or when software reads TDFE after it has been
set to 1, then writes 0 to TDFE
1
The quantity of transmit data in SCFTDR is less than the specified transmission
trigger number*
[Setting conditions]
(1) TDFE is set to 1 by a reset or in standby mode
(2) When the quantity of transmit data in SCFTDR becomes less than the
specified transmission trigger number as a result of transmission
Note: * Since SCFTDR is a 16-byte FIFO register, the maximum quantity of data that can be
written when TDFE is 1 is “16 minus the specified transmission trigger number”. If an
attempt is made to write additional data, the data is ignored. The quantity of data in
SCFTDR is indicated by the upper 8 bits of SCFTDR.
Bit 4—Break Detection (BRK): Indicates that a break signal has been detected in receive data.
Bit 4: BRK
Description
0
No break signal received
(Initial value)
[Clearing conditions]
(1) BRK is cleared to 0 when the chip is reset or enters standby mode
1
(2) When software reads BRK after it has been set to 1, then writes 0 to BRK
Break signal received*
[Setting conditions]
(1) BRK is set to 1 when data including a framing error is received
(2) A framing error occurs with space 0 in the subsequent receive data
Note: * When a break is detected, transfer of the receive data (H'00) to SCFRDR stops after
detection. When the break ends and the receive signal becomes mark 1, the transfer of
receive data resumes. The receive data of a frame in which a break signal is detected is
transferred to SCFRDR. After this, however, no receive data is transferred until a break
ends with the received signal being mark 1, and the next data is received.
Rev. 5.00, 09/03, page 524 of 760
Bit 3—Framing Error (FER): Indicates a framing error in the data read from the receive FIFO
data register (SCFRDR).
Bit 3: FER
Description
0
No receive framing error occurred in the data read from SCFRDR (Initial value)
[Clearing conditions]
(1) When the chip undergoes a power-on reset or enters standby mode
(2) When no framing error is present in the data read from SCFRDR
1
A receive framing error occurred in the data read from SCFRDR
[Setting condition]
When a framing error is present in the data read from SCFRDR
Bit 2—Parity Error (PER): Indicates a parity error in the data read from the receive FIFO data
register (SCFRDR).
Bit 2: PER
Description
0
No receive parity error occurred in the data read from SCFRDR
(Initial value)
[Clearing conditions]
(1) When the chip undergoes a power-on reset or enters standby mode
(2) When no parity error is present in the data read from SCFRDR
1
A receive framing error occurred in the data read from SCFRDR
[Setting condition]
When a parity error is present in the data read from SCFRDR
Rev. 5.00, 09/03, page 525 of 760
Bit 1—Receive FIFO Data Full (RDF): Indicates that receive data has been transferred to the
receive FIFO data register (SCFRDR), and the quantity of data in SCFRDR has become greater
than the receive trigger number specified by the RTRG1 and RTRG0 bits in the FIFO control
register (SCFCR).
Bit 1: RDF
Description
0
The quantity of transmit data written to SCFRDR is less than the specified
receive trigger number
(Initial value)
[Clearing conditions]
(1) By a power-on reset or in standby mode
(2) When the quantity of receive data in SCFRDR is less than the specified
receive trigger value and 1 is read from RDF, which is then cleared to 0
1
The quantity of receive data in SCFRDR is greater than the specified receive
trigger number
[Setting condition]
When a quantity of receive data greater than the specified receive trigger number
is stored in SCFRDR*
Note: * Since SCFTDR is a 16-byte FIFO register, the maximum quantity of data that can be read
when RDF is 1 is the specified receive trigger number. If an attempt is made to read after
all the data in SCFRDR has been read, the data is undefined. The quantity of receive data
in SCFRDR is indicated by the lower 8 bits of SCFTDR.
Bit 0—Receive Data Ready (DR): Indicates that the quantity of data in the receive FIFO data
register (SCFRDR) is less than the specified receive trigger number, and that the next data has not
yet been received after the elapse of 15 etu from the last stop bit.
Bit 0: DR
Description
0
Receiving is in progress, or no receive data remains in SCFRDR after receiving
ended normally
(Initial value)
[Clearing conditions]
(1) When the chip undergoes a power-on reset or enters standby mode
(2) When software reads DR after it has been set to 1, then writes 0 to DR
1
Next receive data has not been received
[Setting condition]
When SCFRDR contains less data than the specified receive trigger number,
and the next data has not yet been received after the elapse of 15 etu from the
last stop bit*
Note: * This is equivalent to 1.5 frames with the 8-bit, 1-stop-bit format. (etu: elementary time unit)
Rev. 5.00, 09/03, page 526 of 760
Upper 8 bits:
15
14
13
12
11
10
9
8
PER3
PER2
PER1
PER0
FER3
FER2
FER1
FER0
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R
R
R
R
R
R
R
Bits 15 to 12—Number of Parity Errors 3 to 0 (PER3 to PER0): Indicate the quantity of data
including a parity error in the receive data stored in the receive FIFO data register (SCFRDR).
The value indicated by bits 15 to 12 represents the number of parity errors in SCFRDR.
Bits 11 to 8—Number of Framing Errors 3 to 0 (FER3 to FER0): Indicate the quantity of data
including a framing error in the receive data stored in SCFRDR. The value indicated by bits 11 to
8 represents the number of framing errors in SCFRDR.
16.2.8
Bit Rate Register (SCBRR)
The bit rate register (SCBRR) is an 8-bit register that, together with the baud rate generator clock
source selected by the CKS1 and CKS0 bits in the serial mode register (SCSMR), determines the
serial transmit/receive bit rate.
The CPU can always read and write to SCBRR. SCBRR is initialized to H'FF by a reset and in
module standby or standby mode. Each channel has independent baud rate generator control, so
different values can be set in two channels.
Bit:
7
6
5
4
3
2
1
0
Initial value:
1
1
1
1
1
1
1
1
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W:
The SCBRR setting is calculated as follows:
Asynchronous mode:
N=
B:
N:
Pφ:
n:
Pφ
64 × 2
2n – 1
×B
× 106 – 1
Bit rate (bits/s)
SCBRR setting for baud rate generator (0 ≤ N ≤ 255)
Operating frequency for peripheral modules (MHz)
Baud rate generator clock source (n = 0, 1, 2, 3) (for the clock sources and values of
n, see table 16.3.)
Rev. 5.00, 09/03, page 527 of 760
Table 16.3 SCSMR Settings
SCSMR Settings
n
Clock Source
CKS1
CKS0
0
Pφ
0
0
1
Pφ/4
0
1
2
Pφ/16
1
0
3
Pφ/64
1
1
Note: The bit rate error is given by the following formula:
Error (%) =
Pφ
(N+1) × 64 × 22n−1 × B
× 106 − 1
× 100
Table 16.4 lists examples of SCBRR settings.
Table 16.4 Bit Rates and SCBRR Settings
Pφ
φ (MHz)
2
2.097152
2.4576
Bit Rate (bits/s) n
N
Error (%
%) n
N
Error (%
%) n
N
Error (%
%)
110
1
141
0.03
1
148
–0.04
1
174
–0.26
150
1
103
0.16
1
108
0.21
1
127
0.00
300
0
207
0.16
0
217
0.21
0
255
0.00
600
0
103
0.16
0
108
0.21
0
127
0.00
1200
0
51
0.16
0
54
–0.70
0
63
0.00
2400
0
25
0.16
0
26
1.14
0
31
0.00
4800
0
12
0.16
0
13
–2.48
0
15
0.00
9600
0
6
–6.99
0
6
–2.48
0
7
0.00
19200
0
2
8.51
0
2
13.78
0
3
0.00
31250
0
1
0.00
0
1
4.86
0
1
22.88
38400
0
1
–18.62
0
0
–14.67
0
1
0.00
Rev. 5.00, 09/03, page 528 of 760
Pφ
φ (MHz)
3
3.6864
4
Bit Rate (bits/s) n
N
Error (%
%) n
N
Error (%
%) n
N
Error (%
%)
110
1
212
0.03
2
64
0.70
2
70
0.03
150
1
155
0.16
1
191
0.00
1
207
0.16
300
1
77
0.16
1
95
0.00
1
103
0.16
600
0
155
0.16
0
191
0.00
0
207
0.16
1200
0
77
0.16
0
95
0.00
0
103
0.16
2400
0
38
0.16
0
47
0.00
0
51
0.16
4800
0
19
–2.34
0
23
0.00
0
25
0.16
9600
0
9
–2.34
0
11
0.00
0
12
0.16
19200
0
4
–2.34
0
5
0.00
0
6
–6.99
31250
0
2
0.00
0
3
–7.84
0
3
0.00
38400
—
—
—
0
2
0.00
0
2
8.51
Pφ
φ (MHz)
5
4.9152
6
Bit Rate (bits/s) n
N
Error (%
%) n
N
Error (%
%) n
N
Error (%
%)
110
2
86
0.31
2
88
–0.25
2
106
–0.44
150
1
255
0.00
2
64
0.16
2
77
0.16
300
1
127
0.00
1
129
0.16
1
155
0.16
600
0
255
0.00
1
64
0.16
1
77
0.16
1200
0
127
0.00
0
129
0.16
0
155
0.16
2400
0
63
0.00
0
64
0.16
0
77
0.16
4800
0
31
0.00
0
32
–1.36
0
38
0.16
9600
0
15
0.00
0
15
1.73
0
19
–2.34
19200
0
7
0.00
0
7
1.73
0
9
–2.34
31250
0
4
–1.70
0
4
0.00
0
5
0.00
38400
0
3
0.00
0
3
1.73
0
4
–2.34
Rev. 5.00, 09/03, page 529 of 760
Pφ
φ (MHz)
6.144
7.3728
8
Bit Rate (bits/s) n
N
Error (%
%) n
N
Error (%
%) n
N
Error (%
%)
110
2
108
0.08
2
130
–0.07
2
141
0.03
150
2
79
0.00
2
95
0.00
2
103
0.16
300
1
159
0.00
1
191
0.00
1
207
0.16
600
1
79
0.00
1
95
0.00
1
103
0.16
1200
0
159
0.00
0
191
0.00
0
207
0.16
2400
0
79
0.00
0
95
0.00
0
103
0.16
4800
0
39
0.00
0
47
0.00
0
51
0.16
9600
0
19
0.00
0
23
0.00
0
25
0.16
19200
0
9
0.00
0
11
0.00
0
12
0.16
31250
0
5
2.40
0
6
5.33
0
7
0.00
38400
0
4
0.00
0
5
0.00
0
6
–6.99
Pφ
φ (MHz)
10
9.8304
Bit Rate
(bits/s)
n
N
Error
(%
%)
n
N
12
Error
(%
%)
n
N
12.288
Error
(%
%)
n
N
Error
(%
%)
110
1
174
–0.26 2
177
–0.25 1
212
0.03
2
217
0.08
150
1
127
0.00
2
129
0.16
1
155
0.16
2
159
0.00
300
0
255
0.00
2
64
0.16
1
77
0.16
2
79
0.00
600
0
127
0.00
1
129
0.16
0
155
0.16
1
159
0.00
1200
0
255
0.00
1
64
0.16
0
77
0.16
1
79
0.00
2400
0
127
0.00
0
129
0.16
0
38
0.16
0
159
0.00
4800
0
63
0.00
0
64
0.16
0
19
0.16
0
79
0.00
9600
0
31
0.00
0
32
–1.36 0
9
0.16
0
39
0.00
19200
0
15
0.00
0
15
1.73
0
4
0.16
0
19
0.00
31250
0
9
–1.70 0
9
0.00
0
2
0.00
0
11
2.40
38400
0
1
0.00
7
1.73
0
9
–2.34 0
9
0.00
Rev. 5.00, 09/03, page 530 of 760
0
Pφ
φ (MHz)
14.7456
Error
(%
%)
16
19.6608
Bit Rate
(bits/s)
n
N
110
3
64
0.70
3
70
0.03
3
86
0.31
3
88
–0.25
150
2
191
0.00
2
207
0.16
2
255
0.00
2
64
0.16
300
2
95
0.00
2
103
0.16
2
127
0.00
2
129
0.16
n
N
Error
(%
%)
n
N
Error
(%
%)
20
n
Error
(%
%)
N
600
1
191
0.00
1
207
0.16
1
255
0.00
1
64
0.16
1200
1
95
0.00
1
103
0.16
1
127
0.00
1
129
0.16
2400
0
191
0.00
0
207
0.16
0
255
0.00
0
64
0.16
4800
0
95
0.00
0
103
0.16
0
127
0.00
0
129
0.16
9600
0
47
0.00
0
51
0.16
0
63
0.00
0
64
0.16
19200
0
23
0.00
0
25
0.16
0
31
0.00
0
32
–1.36
31250
0
14
–1.70 0
15
0.00
0
19
–1.70 0
19
0.00
38400
0
11
0.00
0
12
0.16
0
15
0.00
0
15
1.73
115200
0
3
0.00
0
3
8.51
0
4
6.67
0
4
8.51
500000
0
0
–7.84 0
0
0.00
0
0
22.9
0
0
25.0
Pφ
φ (MHz)
24
24.576
Bit Rate
(bits/s)
n
N
Error
(%
%)
110
3
106
150
3
300
2
600
2
77
0.16
2
1200
1
155
0.16
1
2400
1
77
0.16
1
79
28.7
30
N
Error
(%
%)
n
N
Error
(%
%)
n
N
Error
(%
%)
–0.44 3
108
0.08
3
126
0.31
3
132
0.13
77
0.16
3
79
0.00
3
92
0.46
3
97
–0.35
155
0.16
2
159
0.00
2
186
–0.08 2
194
0.16
79
0.00
2
92
0.46
97
–0.35
159
0.00
1
186
–0.08 1
194
0.16
0.00
1
92
0.46
97
–0.35
n
2
1
4800
0
155
0.16
0
159
0.00
0
186
–0.08 0
194
–1.36
9600
0
77
0.16
0
79
0.00
0
92
0.46
0
97
–0.35
19200
0
38
0.16
0
39
0.00
0
46
–0.61 0
48
–0.35
31250
0
23
0.00
0
24
–1.70 0
28
–1.03 0
29
0.00
38400
0
19
–2.34 0
19
0.00
22
1.55
23
1.73
115200
0
6
–6.99 0
6
–4.76 0
7
–2.68 0
7
1.73
500000
0
1
–25.0 0
1
–23.2 0
1
–10.3 0
1
–6.25
0
0
Rev. 5.00, 09/03, page 531 of 760
Table 16.5 indicates the maximum bit rates in asynchronous mode when the baud rate generator is
used. Table 16.6 list the maximum rates for external clock input.
Table 16.5 Maximum Bit Rates for Various Frequencies with Baud Rate Generator
(Asynchronous Mode)
Settings
Pφ
φ (MHz)
Maximum Bit Rate (bits/s)
n
N
2
62500
0
0
2.097152
65536
0
0
2.4576
76800
0
0
3
93750
0
0
3.6864
115200
0
0
4
125000
0
0
4.9152
153600
0
0
8
250000
0
0
9.8304
307200
0
0
12
375000
0
0
14.7456
460800
0
0
16
500000
0
0
19.6608
614400
0
0
20
625000
0
0
24
750000
0
0
24.576
768000
0
0
28.7
896875
0
0
30
937500
0
0
Rev. 5.00, 09/03, page 532 of 760
Table 16.6 Maximum Bit Rates with External Clock Input (Asynchronous Mode)
Pφ
φ (MHz)
External Input Clock (MHz)
Maximum Bit Rate (bits/s)
2
0.5000
31250
2.097152
0.5243
32768
2.4576
0.6144
38400
3
0.7500
46875
3.6864
0.9216
57600
4
1.0000
62500
4.9152
1.2288
76800
8
2.0000
125000
9.8304
2.4576
153600
12
3.0000
187500
14.7456
3.6864
230400
16
4.0000
250000
19.6608
4.9152
307200
20
5.0000
312500
24
6.0000
375000
24.576
6.1440
384000
28.7
7.1750
448436
30
7.5000
468750
Rev. 5.00, 09/03, page 533 of 760
16.2.9
FIFO Control Register (SCFCR)
Bit:
Initial value:
R/W:
7
6
5
4
3
2
1
0
RTRG1
RTRG0
TTRG1
TTRG0
MCE
TFRST
RFRST
LOOP
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
The FIFO control register (SCFCR) resets the quantity of data in the transmit and receive FIFO
registers, sets the trigger data quantity, and contains an enable bit for loop-back testing. SCFCR
can always be read and written to by the CPU. It is initialized to H'00 by a reset, by the module
standby function, and in standby mode.
Bits 7 and 6—Receive FIFO Data Trigger (RTRG1, RTRG0): Set the quantity of receive data
which sets the receive data full (RDF) flag in the serial status register (SCSSR). The RDF flag is
set to 1 when the quantity of receive data stored in the receive FIFO register (SCFRDR) exceeds
the set trigger number shown below.
Bit 7: RTRG1
Bit 6: RTRG0
Receive Trigger Number
0
0
1
0
1
4
1
0
8
1
1
14
(Initial value)
Bits 5 and 4—Transmit FIFO Data Trigger (TTRG1, TTRG0): Set the quantity of remaining
transmit data which sets the transmit FIFO data register empty (TDFE) flag in the serial status
register (SCSSR). The TDFE flag is set to 1 when the quantity of transmit data in the transmit
FIFO data register (SCFTDR) becomes less than the set trigger number shown below.
Bit 5: TTRG1
Bit 4: TTRG0
Transmit Trigger Number
0
0
8 (8)*
0
1
4 (12)
1
0
2 (14)
1
1
1 (15)
Note: * Initial value. Values in parentheses mean the number of empty bits in SCFTDR when the
TDFE flag is set to 1.
Rev. 5.00, 09/03, page 534 of 760
Bit 3—Modem Control Enable (MCE): Enables modem control signals CTS and RTS.
Bit 3: MCE
Description
0
Modem signal disabled*
1
Modem signal enabled
(Initial value)
Note: * CTS is fixed at active 0 regardless of the input value, and RTS is also fixed at 0.
Bit 2—Transmit FIFO Data Register Reset (TFRST): Disables the transmit data in the transmit
FIFO data register and resets the data to the empty state.
Bit 2: TFRST
Description
0
Reset operation disabled*
1
Reset operation enabled
(Initial value)
Note: * Reset is executed in a reset or in standby mode.
Bit 1—Receive FIFO Data Register Reset (RFRST): Disables the receive data in the receive
FIFO data register and resets the data to the empty state.
Bit 1: RFRST
Description
0
Reset operation disabled*
1
Reset operation enabled
(Initial value)
Note: * Reset is executed in a reset or in standby mode.
Bit 0—Loop-Back Test (LOOP): Internally connects the transmit output pin (TXD) and receive
input pin (RXD) and enables loop-back testing.
Bit 0: LOOP
Description
0
Loop back test disabled
1
Loop back test enabled
(Initial value)
Rev. 5.00, 09/03, page 535 of 760
16.2.10 FIFO Data Count Register (SCFDR)
SCFDR is a 16-bit register which indicates the quantity of data stored in the transmit FIFO data
register (SCFTDR) and the receive FIFO data register (SCFRDR). It indicates the quantity of
transmit data in SCFTDR with the upper 8 bits, and the quantity of receive data in SCFRDR with
the lower 8 bits. SCFDR can always be read by the CPU.
Upper 8 Bits:
15
14
13
12
11
10
9
8
—
—
—
T4
T3
T2
T1
T0
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R
R
R
R
R
R
R
The upper 8 bits of SCFDR indicate the quantity of non-transmitted data stored in SCFTDR. H'00
means no transmit data, and H'10 means that SCFTDR is full of transmit data.
Lower 8 Bits:
7
6
5
4
3
2
1
0
—
—
—
R4
R3
R2
R1
R0
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R
R
R
R
R
R
R
The lower 8 bits of SCFDR indicate the quantity of receive data stored in SCFRDR. H'00 means
no receive data, and H'10 means that SCFRDR full of receive data.
Rev. 5.00, 09/03, page 536 of 760
16.3
Operation
16.3.1
Overview
For serial communication, the SCIF has an asynchronous mode in which characters are
synchronized individually. Refer to section 14.3.2, Operation in Asynchronous Mode. The SCIF
has a 16-byte FIFO buffer for both transmit and receive operations, reducing the overhead of the
CPU, and enabling continuous high-speed communication. Moreover, it has RTS and CTS signals
as modem control signals. The transmission format is selected in the serial mode register
(SCSMR), as shown in table 16.7. The SCIF clock source is selected by the combination of the
CKE1 and CKE0 bits in the serial control register (SCSCR), as shown in table 16.8.
• Data length is selectable: 7 or 8 bits.
• Parity and multiprocessor bits are selectable, as is the stop bit length (1 or 2 bits). The
combination of the preceding selections constitutes the communication format and character
length.
• In receiving, it is possible to detect framing errors (FER), parity errors (PER), receive FIFO
data full, receive data ready, and breaks.
• In transmitting, it is possible to detect transmit FIFO data empty.
• The number of stored data bytes is indicated for both the transmit and receive FIFO registers.
• An internal or external clock can be selected as the SCIF clock source.
 When an internal clock is selected, the SCIF operates using the on-chip baud rate
generator, and can output a serial clock signal with a frequency 16 times the bit rate.
 When an external clock is selected, the external clock input must have a frequency 16 times
the bit rate. (The on-chip baud rate generator is not used.)
Table 16.7 SCSMR Settings and SCIF Communication Formats
SCSMR Settings
SCIF Communication Format
Mode
Bit 6
CHR
Bit 5
PE
Bit 3
STOP
Data
Length
Parity
Bit
Stop Bit Length
Asynchronous
0
0
0
8-bit
Not set
1 bit
1
1
2 bits
0
Set
1
1
0
0
2 bits
7-bit
Not set
1
1
0
1
1 bit
1 bit
2 bits
Set
1 bit
2 bits
Rev. 5.00, 09/03, page 537 of 760
Table 16.8 SCSCR Settings and SCIF Clock Source Selection
SCSCR Settings
Mode
Asynchronous
mode
SCIF Transmit/Receive Clock
Bit 1
CKE1
Bit 0
CKE0
Clock Source
SCK Pin Function
0
0
Internal
SCIF does not use the SCK pin
1
1
Outputs a clock with a frequency 16 times
the bit rate
0
External
Inputs a clock with frequency 16 times the
bit rate
1
16.3.2
Serial Operation
Transmit/Receive Formats: Table 16.9 lists the eight communication formats that can be
selected. The format is selected by settings in the serial mode register (SCSMR).
Table 16.9 Serial Communication Formats
SCSMR Bits
Serial Transmit/Receive Format and Frame Length
CHR
PE
STOP
1
0
0
0
START
8-bit data
STOP
0
0
1
START
8-bit data
STOP STOP
0
1
0
START
8-bit data
P
STOP
0
1
1
START
8-bit data
P
STOP STOP
1
0
0
START
7-bit data
STOP
1
0
1
START
7-bit data
STOP STOP
1
1
0
START
7-bit data
P
STOP
1
1
1
START
7-bit data
P
STOP STOP
START: Start bit
STOP: Stop bit
P:
Parity bit
Rev. 5.00, 09/03, page 538 of 760
2
3
4
5
6
7
8
9
10
11
12
Clock: An internal clock generated by the on-chip baud rate generator or an external clock input
from the SCK pin can be selected as the SCIF transmit/receive clock. The clock source is selected
by bits CKE1 and CKE0 in the serial control register (SCSCR) (table 16.8).
When an external clock is input at the SCK pin, it must have a frequency equal to 16 times the
desired bit rate.
When the SCIF operates on an internal clock, it can output a clock signal at the SCK pin. The
frequency of this output clock is 16 times the bit rate.
Transmitting and Receiving Data (SCIF Initialization): Before transmitting or receiving, clear
the TE and RE bits to 0 in the serial control register (SCSCR), then initialize the SCIF as follows.
When changing the communication format, always clear the TE and RE bits to 0 before following
the procedure given below. Clearing TE to 0 initializes the transmit shift register (SCTSR).
Clearing TE and RE to 0, however, does not initialize the serial status register (SCSSR), transmit
FIFO data register (SCFTDR), or receive FIFO data register (SCFRDR), which retain their
previous contents. Clear TE to 0 after all transmit data has been transmitted and the TEND flag in
the SCSSR is set. The TE bit can be cleared to 0 during transmission, but the transmit data goes to
the high impedance state after the bit is cleared to 0. Set the TFRST bit in SCFCR to 1 and reset
SCFTDR before TE is set again to start transmission.
When an external clock is used, the clock should not be stopped during initialization or subsequent
operation. SCIF operation becomes unreliable if the clock is stopped.
Figure 16.5 shows a sample flowchart for initializing the SCIF. The procedure for initializing the
SCIF is:
1. Set the clock selection in SCSCR.
Be sure to clear bits RIE TIE, TE, and RE to 0.
When clock output is selected, the clock is output immediately after SCSCR settings are made.
2. Set the communication format in SCSMR.
3. Write a value corresponding to the bit rate into the bit rate register (SCBRR).
(Not necessary if an external clock is used.)
4. Wait at least one bit interval, then set the TE bit or RE bit in SCSCR to 1. Also set the RIE
and TIE bits.
Setting the TE and RE bits enables the TxD and RxD pins to be used. When transmitting, the
SCIF will go to the mark state; when receiving, it will go to the idle state, waiting for a start
bit.
Rev. 5.00, 09/03, page 539 of 760
Initialization
Clear TE and RE bits in SCSCR to 0
(1)
Set TFRST and RFRST bits in
SCFCR to 1
Set CKE1 and CKE0
bits in SCSCR (leaving TE and RE
bits cleared to 0)
Set communication format in SCSMR
(2)
Set value in SCBRR
(3)
Wait
1-bit interval elapsed?
Yes
No
(4)
Set RTRG1-0, TTRG1-0, and MCE
in SCFCR
Clear TFRST and RFRST bits to 0
Set TE and RE bits in
SCSCR to 1,and set RIE, TIE,
TEIE, and MPIE bits
End
Note: Numbers in parentheses refer to steps in the preceding procedure description.
Figure 16.5 Sample Flowchart for SCIF Initialization
Rev. 5.00, 09/03, page 540 of 760
• Serial data transmission
Figure 16.6 shows a sample flowchart for serial transmission.
Use the following procedure for serial data transmission after enabling the SCIF for transmission.
1. SCIF status check and transmit data write:
Read serial status register (SCSSR) and check that the TDFE flag is set to 1, then write
transmit data to the transmit FIFO data register (SCFTDR), read 1 from the TDFE and TEND
flags, then clear these flags to 0.
The number of transmit data bytes that can be written is (16 - transmit trigger set number).
2. Serial transmission continuation procedure:
To continue serial transmission, read 1 from the TDFE flag to confirm that writing is possible,
then write data to SCFTDR, and then clear the TDFE flag to 0.
3. Break output at the end of serial transmission:
To output a break in serial transmission, set the port SC data register (SCPDR) and port SC
control register (SCPCR), then clear the TE bit to 0 in the serial control register (SCSCR). For
information on SCPDR and SCPCR, see section 16.2.8, Bit Rate Register (SCBRR).
In steps 1 and 2, it is possible to ascertain the number of data bytes that can be written from the
number of transmit data bytes in SCFTDR indicated by the upper 8 bits of the FIFO data count
register (SCFDR).
Rev. 5.00, 09/03, page 541 of 760
Start of transmission
Read TDFE bit in SCSSR
TDFE= 1?
(1)
No
Yes
Write transmit data (16 - transmit
trigger set number) to SCFTDR, read 1
from TDFE bit and TEND flag in
SCSSR, then clear to 0
All data transmitted?
(2)
No
Yes
Read TEND bit in SCSSR
TEND= 1?
No
Yes
Break output?
No
Yes (3)
Set SCPDR and SCPCR
Clear TE bit in SCSCR to 0
End of transmission
Note: Numbers in parentheses refer to steps in the preceding procedure description.
Figure 16.6 Sample Flowchart for Transmitting Serial Data
Rev. 5.00, 09/03, page 542 of 760
In serial transmission, the SCIF operates as described below.
1. When data is written into the transmit FIFO data register (SCFTDR), the SCIF transfers the
data from SCFTDR to the transmit shift register (SCTSR) and starts transmitting. Confirm
that the TDFE flag in the serial status register (SCSSR) is set to 1 before writing transmit data
to SCFTDR. The number of data bytes that can be written is (16 – transmit trigger setting).
2. When data is transferred from SCFTDR to SCTSR and transmission is started, consecutive
transmit operations are performed until there is no transmit data left in SCFTDR. When the
number of transmit data bytes in SCFTDR falls below the transmit trigger number set in the
FIFO control register (SCFCR), the TDFE flag is set. If the TIE bit in the serial control
register (SCSR) is set to 1 at this time, a transmit-FIFO-data-empty interrupt (TXI) request is
generated.
The serial transmit data is sent from the TxD pin in the following order.
a. Start bit: One-bit 0 is output.
b. Transmit data: 8-bit or 7-bit data is output in LSB-first order.
c. Parity bit: One parity bit (even or odd parity) is output. (A format in which a parity bit is
not output can also be selected.)
d. Stop bit(s): One or two 1-bits (stop bits) are output.
e. Mark state: 1 is output continuously until the start bit that starts the next transmission is
sent.
3. The SCIF checks the SCFTDR transmit data at the timing for sending the stop bit. If data is
present, the data is transferred from SCFTDR to SCTSR, the stop bit is sent, and then serial
transmission of the next frame is started.
If there is no transmit data, the TEND flag in SCSSR is set to 1, the stop bit is sent, and then
the line goes to the mark state in which 1 is output continuously.
Rev. 5.00, 09/03, page 543 of 760
Figure 16.7 shows an example of the operation for transmission.
1
Serial
data
Start
bit
D0
0
Parity Stop Start
bit
bit
bit
Data
D1
D7
0/1
1
0
Parity Stop
bit
bit
Data
D0
D1
D7
0/1
1
1
Idle (mark)
state
TDFE
TEND
TXI interrupt
request
Data written to
SCFTDR and TDFE
flag read as 1 then
cleared to 0 by TXI
interrupt handler
TXI interrupt
request
One frame
Figure 16.7 Example of Transmit Operation
(8-Bit Data, Parity, One Stop Bit)
4. When modem control is enabled, transmission can be stopped and restarted in accordance with
the CTS input value. When CTS is set to 1, if transmission is in progress, the line goes to the
mark state after transmission of one frame. When CTS is set to 0, the next transmit data is
output starting from the start bit.
Figure 16.8 shows an example of the operation when modem control is used.
Start
bit
Serial
data
TXD
0
Parity Stop
bit
bit
D0
D1
D7
0/1
Start
bit
0
D0
D1
CTS
Rise at this point
before stop bit
Figure 16.8 Example of Operation Using Modem Control (C
CTS)
Rev. 5.00, 09/03, page 544 of 760
D7
0/1
• Serial data reception
Figures 16.9 and 16.10 show a sample flowchart for serial reception.
Use the following procedure for serial data reception after enabling the SCIF for reception.
1. Receive error handling and break detection: Read the DR, ER, and BRK flags in SCSSR to
identify any error, perform the appropriate error handling, then clear the DR, ER, and BRK
flags to 0. In the case of a framing error, a break can also be detected by reading the value of
the RxD pin.
2. SCIF status check and receive data read : Read the serial status register (SCSSR) and check
that RDF = 1, then read the receive data in the receive FIFO data register (SCFRDR), read 1
from the RDF flag, and then clear the RDF flag to 0. The transition of the RDF flag from 0 to
1 can be identified by an RXI interrupt.
3. Serial reception continuation procedure: To continue serial reception, read at least the receive
trigger set number of receive data bytes from SCFRDR, read 1 from the RDF flag, then clear
the RDF flag to 0. The number of receive data bytes in SCFRDR can be ascertained by
reading the lower bits of SCFDR.
Rev. 5.00, 09/03, page 545 of 760
Start of reception
Read ORER, PER, FER
flags in SCSSR
PER v FER v ORER = 1?
No
(1)
Yes
Error handling
Read RDF flag in SCSSR
No
(2)
RDF = 1?
Yes
Read receive data from SCFRDR,
and clear RDF flag in
SCSSR to 0
No
(3)
All data received?
Yes
Clear RE bit in SCSCR to 0
End of reception
Note: Numbers in parentheses refer to steps in the preceding procedure description.
Figure 16.9 Sample Flowchart for Receiving Serial Data
Rev. 5.00, 09/03, page 546 of 760
1. Whether a framing error or parity error has occurred in the receive data read from SCFRDR
can be ascertained from the FER and PER bits in SCSSR.
2. When a break signal is received, receive data is not transferred to SCFRDR while the BRK
flag is set. However, note that the last data in SCFRDR is H'00 and the break data in which a
framing error occurred is stored.
(1)
Error handling
No
ER = 1?
Yes
(2)
Receive error handling
No
BRK = 1?
Yes
Break processing
No
DR = 1?
Yes
Read receive data from SCFRDR
Clear DR, ER, BRK flags in
SCSSR to 0
End
Figure 16.10 Sample Flowchart for Receiving Serial Data (cont)
Rev. 5.00, 09/03, page 547 of 760
In serial reception, the SCIF operates as described below.
1. The SCIF monitors the transmission line, and if a 0 start bit is detected, performs internal
synchronization and starts reception.
2. The received data is stored in SCRSR in LSB-to-MSB order.
3. The parity bit and stop bit are received.
After receiving these bits, the SCIF carries out the following checks.
a. Stop bit check: The SCIF checks whether the stop bit is 1. If there are two stop bits, only
the first is checked.
b. The SCIF checks whether receive data can be transferred from the receive shift register
(SCRSR) to SCFRDR.
c. Break check: The SCIF checks that the BRK flag is 0, indicating that the break state is not
set.
If all the above checks are passed, the receive data is stored in SCFRDR.
Note: Reception is not suspended when a receive error occurs.
4. If the RIE bit in SCSR is set to 1 when the RDF or DR flag changes to 1, a receive-FIFO-datafull interrupt (RXI) request is generated.
If the RIE bit in SCSR is set to 1 when the ER flag changes to 1, a receive-error interrupt (ERI)
request is generated.
If the RIE bit in SCSR is set to 1 when the BRK flag changes to 1, a break reception interrupt
(BRI) request is generated.
Rev. 5.00, 09/03, page 548 of 760
Figure 16.11 shows an example of the operation for reception.
1
Serial
data
Start
bit
0
Parity Stop Start
bit
bit
bit
Data
D0 D1
D7
0/1
1
0
Parity Stop
bit
bit
Data
D0
D1
D7 0/1
1
1
Idle (mark)
state
RDF
RXI interrupt
request
FER
One frame
Data read and RDF
flag read as 1 then
cleared to 0 by
RXI interrupt handler
ERI interrupt
request generated
by receive error
Figure 16.11 Example of SCIF Receive Operation
(8-Bit Data, Parity, One Stop Bit)
5. When modem control is enabled, the RTS signal is output when SCFRDR is empty. When
RTS is 0, reception is possible. When RTS is 1, this indicates that SCFRDR is full and
reception is not possible.
Figure 16.12 shows an example of the operation when modem control is used.
Serial
data
RXD
Start
bit
0 D0 D1 D2
Parity bit
D7 0/1 1
Start
0
RTS
Figure 16.12 Example of Operation Using Modem Control (R
RTS)
Rev. 5.00, 09/03, page 549 of 760
16.4
SCIF Interrupts
The SCIF has four interrupt sources: transmit-FIFO-data-empty (TXI), receive-error (ERI),
receive-data-full (RXI), and break (BRI).
Table 16.10 shows the interrupt sources and their order of priority. The interrupt sources are
enabled or disabled by means of the TIE and RIE bits in SCSCR. A separate interrupt request is
sent to the interrupt controller for each of these interrupt sources.
When the TDFE flag in the serial status register (SCSSR) is set to 1, a TXI interrupt request is
generated. The DMAC can be activated and data transfer performed when this interrupt is
generated. When data exceeding the transmit trigger number is written to the transmit data register
(SCFTDR) by the DMAC, 1 is read from the TDFE flag, after which 0 is written to it to clear it.
When the RDF flag in SCSSR is set to 1, an RXI interrupt request is generated. The DMAC can
be activated and data transfer performed when the RDF flag in SCSSR is set to 1. When receive
data less than the receive trigger number is read from the receive data register (SCFRDR) by the
DMAC, 1 is read from the RDF flag, after which 0 is written to it to clear it.
When the ER flag in SCSSR is set to 1, an ERI interrupt request is generated.
When the BRK flag in SCSSR is set to 1, a BRI interrupt request is generated.
The TXI interrupt indicates that transmit data can be written, and the RXI interrupt indicates that
there is receive data in SCFRDR.
Table 16.10 SCIF Interrupt Sources
Interrupt
Source
Description
DMAC
Activation
Priority on
Reset Release
ERI
Interrupt initiated by receive error flag (ER)
Not possible
High
RXI
Interrupt initiated by receive data FIFO full flag
(RDF) or data ready flag (DR)
Possible
(RDF only)
BRI
Interrupt initiated by break flag (BRK)
Not possible
TXI
Interrupt initiated by transmit FIFO data empty
flag (TDFE)
Possible
Low
See section 4, Exception Handling, for priorities and the relationship to non-SCIF interrupts.
Rev. 5.00, 09/03, page 550 of 760
16.5
Usage Notes
Note the following when using the SCIF.
1. SCFTDR Writing and TDFE Flag: The TDFE flag in the serial status register (SCSSR) is set
when the number of transmit data bytes written in the transmit FIFO data register (SCFTDR) has
fallen below the transmit trigger number set by bits TTRG1 and TTRG0 in the FIFO control
register (SCFCR). After TDFE is set, transmit data up to the number of empty bytes in SCFTDR
can be written, allowing efficient continuous transmission.
However, if the number of data bytes written to SCFTDR is equal to or less than the transmit
trigger number, the TDFE flag will be set to 1 again even after having been cleared to 0. TDFE
clearing should therefore be carried out after data exceeding the specified transmit trigger number
has been written to SCFTDR.
The number of transmit data bytes in SCFTDR can be found from the upper 8 bits of the FIFO
data count register (SCFDR).
2. SCFRDR Reading and RDF Flag: The RDF flag in the serial status register (SCSSR) is set
when the number of receive data bytes in the receive FIFO data register (SCFRDR) has become
equal to or greater than the receive trigger number set by bits RTRG1 and RTRG0 in the FIFO
control register (SCFCR). After RDF is set, receive data equivalent to the trigger number can be
read from SCFRDR, allowing efficient continuous reception.
However, if the number of data bytes in SCFRDR exceeds the trigger number, the RDF flag will
be set to 1 again even after having been cleared to 0. RDF should therefore be cleared to 0 after
being read as 1 after all the receive data has been read.
The number of receive data bytes in SCFRDR can be found from the lower 8 bits of the FIFO data
count register (SCFDR).
3. Break Detection and Processing: Break signals can be detected by reading the RxD pin
directly when a framing error (FER) is detected. In the break state the input from the RxD pin
consists of all 0s, so the FER flag is set and the parity error flag (PER) may also be set. Note that,
although transfer of receive data to SCFRDR is halted in the break state, the SCIF receiver
continues to operate, so if the BRK flag is cleared to 0 it will be set to 1 again.
4. Sending a Break Signal: The I/O condition and level of the TxD pin are determined by the
SCP4DT bit in the port SC data register (SCPDR) and bits SCP4MD0 and SCP4MD1 in the port
SC control register (SCPCR). This feature can be used to send a break signal.
To send a break signal during serial transmission, clear the SCP4DT bit to 0 (designating low
level), then set the SCP4MD0 and SCP4MD1 bits to 0 and 1, respectively, and finally clear the TE
bit to 0 (halting transmission). When the TE bit is cleared to 0, the transmitter is initialized
regardless of the current transmission state, and 0 is output from the TxD pin.
Rev. 5.00, 09/03, page 551 of 760
5. TEND Flag and TE Bit Processing: The TEND flag is set to 1 during transmission of the stop
bit of the last data. Consequently, if the TE bit is cleared to 0 immediately after setting of the
TEND flag has been confirmed, the stop bit will be in the process of transmission and will not be
transmitted normally. Therefore, the TE bit should not be cleared to 0 for at least 0.5 serial clock
cycles (or 1.5 cycles if two stop bits are used) after setting of the TEND flag is confirmed.
6. Receive Data Sampling Timing and Receive Margin: The SCIF operates on a base clock
with a frequency of 16 times the transfer rate. In reception, the SCIF synchronizes internally with
the fall of the start bit, which it samples on the base clock. Receive data is latched at the rising
edge of the eighth base clock pulse. The timing is shown in figure 16.13.
16 clocks
8 clocks
0 1 2 3 4 5 6 7 8 9 10111213 1415 0 1 2 3 4 5 6 7 8 9 10111213 1415 0 1 2 3 4 5
Base clock
−7.5 clocks
Receive
data (RxD)
+7.5 clocks
Start bit
D0
D1
Synchronization
sampling
timing
Data
sampling
timing
Figure 16.13 Receive Data Sampling Timing in Asynchronous Mode
The receive margin in asynchronous mode can therefore be expressed as shown in equation 1.
Equation 1:
M = 0.5 −
Where:
1
D − 0.5
(1 + F) × 100%
− (L − 0.5) F −
2N
N
M: Receive margin (%)
N: Ratio of clock frequency to bit rate (N = 16)
D: Clock duty cycle (D = 0 to 1.0)
L: Frame length (L = 9 to 12)
F: Absolute deviation of clock frequency
From equation 1, if F = 0 and D = 0.5, the receive margin is 46.875%, as given by equation 2.
Rev. 5.00, 09/03, page 552 of 760
Equation 2:
When D = 0.5 and F = 0:
M = (0.5 – 1/(2 × 16)) × 100%
= 46.875%
This is a theoretical value. A reasonable margin to allow in system designs is 20% to 30%.
Rev. 5.00, 09/03, page 553 of 760
Rev. 5.00, 09/03, page 554 of 760
Section 17 IrDA
17.1
Overview
The SH7709S has an on-chip Infrared Data Association (IrDA) interface which is based on the
IrDA 1.0 system and can perform infrared communication. It also can be used as the SCIF by
making register settings.
17.1.1
Features
• Conforms to the IrDA 1.0 system
• Asynchronous serial communication
 Data length: 8 bits
 Stop bit length: 1 bit
 Parity bit: None
• On-chip 16-stage FIFO buffers for both transmit and receive operations
• On-chip baud rate generator with selectable bit rates
• Guard functions to protect the receiver during transmission
• Clock supply halted to reduce power consumption when not using the IrDA interface
Rev. 5.00, 09/03, page 555 of 760
17.1.2
Block Diagram
Figure 17.1 shows a block diagram of the IrDA.
Clock input
SCK
TxD
Transfer clock
TxD1
Modulation unit
SCIF
RxD
Demodulation unit
RxD1
IrDA
Switching IrDA/SCIF
Legend
SCIF: Serial communication interface with FIFO
Figure 17.1 Block Diagram of IrDA
Rev. 5.00, 09/03, page 556 of 760
Figures 17.2 to 17.4 show the IrDA I/O port pins.
SCIF pin I/O and data control is performed by bits 7 to 4 of SCPCR and bits 3 and 2 of SCPDR.
For details, see section 14.2.8, SC Port Control Register (SCPCR)/SC Port Data Register
(SCPDR).
Reset
R
D
SCP3MD0
Q
C
Internal data bus
PCRW
Reset
R
Q
D
SCP3MD1
C
IrDA
PCRW
Clock input enable
Reset
SCPT[3]/SCK1
R
Q
D
SCP3DT1
C
PDRW
Output enable
Serial clock output
PDRR*
Serial clock input
Legend
PDRW: SCPDR write
PDRR: SCPDR read
PCRW: SCPCR write
Note: * When reading the SCK1 pin, the CKE1 and CKE0 bits in SCSCR to 0, and
set the SCP3MD1 bit in SCPCR to 1 (see section 14.2.8, SC Port Control
Register (SCPCR)/SC Port Data Register (SCPDR)).
Figure 17.2 SCPT[3]/SCK1 Pin
Rev. 5.00, 09/03, page 557 of 760
Reset
R
D
SCP2MD0
Q
C
PCRW
Reset
Internal data bus
R
Q
D
SCP2MD1
C
PCRW
Reset
SCPT[2]/TxD1
R
Q
D
SCP2DT1
C
IrDA
PDRW
Output enable
Serial
transfer
output
Legend
PCRW: SCPCR write
PDRW: SCPDR write
Figure 17.3 SCPT[2]/TxD1 Pin
Rev. 5.00, 09/03, page 558 of 760
IrDA
SCPT[2]/RxD1
Serial
receive
data
Internal data bus
PDRR*
Legend
PDRR: SCPDR read
Note: * When reading the RxD1 pin, set the RE bit in SCSCR to 1.
Figure 17.4 SCPT[2]/RxD1 Pin
17.1.3
Pin Configuration
The IrDA has the serial pins summarized in table 17.1.
Table 17.1 IrDA Pins
Pin Name
Signal Name
I/O
Function
Serial clock pin
SCK1
I/O
Clock I/O
Receive data pin
RxD1
Input
Receive data input
Transmit data pin
TxD1
Output
Transmit data output
Note: Clock input from the serial clock pin cannot be set in IrDA mode.
Rev. 5.00, 09/03, page 559 of 760
17.1.4
Register Configuration
The IrDA has the internal registers shown in table 17.2. These registers select IrDA or SCIF
mode, specify the data format and a bit rate, and control the transmit and receive units.
Table 17.2 IrDA Registers
Access
Size
Register Name
Abbreviation
R/W
Initial Value
Address
Serial mode register 1
SCSMR1
R/W
H'00
H'04000140
8 bits
2
(H'A4000140)*
Bit rate register 1
SCBRR1
R/W
H'FF
H'04000142
8 bits
2
(H'A4000142)*
Serial control register 1
SCSCR1
R/W
H'00
H'04000144
8 bits
2
(H'A4000144)*
Transmit FIFO data register 1
SCFTDR1
W
—
H'04000146
8 bits
2
(H'A4000146)*
Serial status register 1
SCSSR1
R/(W)* H'0060
H'04000148
16 bits
2
(H'A4000148)*
Receive FIFO data register 1
SCFRDR1
R
Undefined
H'0400014A
8 bits
2
(H'A400014A)*
FIFO control register 1
SCFCR1
R/W
H'00
H'0400014C
8 bits
2
(H'A400014C)*
FIFO data count register 1
SCFDR1
R
H'0000
H'0400014E
16 bits
2
(H'A400014E)*
1
Notes: These registers are located in area 1 of physical space. Therefore, when the cache is on,
either access these registers from the P2 area of logical space or else make an appropriate
setting using the MMU so that these registers are not cached.
1. Only 0 can be written to clear the flag.
2. When address translation by the MMU does not apply, the address in parentheses
should be used.
Rev. 5.00, 09/03, page 560 of 760
17.2
Register Description
Specifications of the registers in the IrDA are the same as those in the SCIF except for the serial
mode register described below. Therefore, refer to section 16, Serial Communication Interface
with FIFO (SCIF), for details of these registers.
17.2.1
Serial Mode Register (SCSMR)
Bit:
Initial value:
R/W:
7
6
5
4
3
2
1
0
IRMOD
ICK3
ICK2
ICK1
ICK0
PSEL
CKS1
CKS0
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
SCSMR is an 8-bit register that selects IrDA or SCIF mode, specifies the SCIF serial
communication format, selects the IrDA output pulse width, and selects the baud rate generator
clock source.
This module operates as IrDA when the IRMOD bit is set to 1. At this time, bits 3 to 6 are fixed at
0. This register functions in the same way as the SCSMR register in the SCIF when the IRMOD
bit is cleared to 0; therefore, this module can also operate as an SCIF.
SCSMR is initialized to H'00 by a power-on reset or manual reset, when the module is stopped by
the module standby function, and in standby mode.
Bit 7—IrDA Mode (IRMOD): Selects whether this module operates as an IrDA serial
communication interface or as an SCIF.
Bit 7: IRMOD
Description
0
Operates as an SCIF
1*
Operates as an IrDA
(Initial value)
Note: * Do not set the CKE1 bit in the serial control register (SCSCRT) to 1 if the IRMCD bit is set
to 1.
Rev. 5.00, 09/03, page 561 of 760
Bits 6 to 3—Ir Clock Select Bits (ICK3 to ICK0)
Bit 2—Output Pulse Width Select (PSEL): PSEL selects an IrDA output pulse width that is 3/16
of the bit length for 115 kbps or 3/16 of the bit length for the selected baud rate.
The Ir clock select bits should be set properly to fix the output pulse width at 3/16 of the bit length
for 115 kbps by setting the PSEL bit to 1.
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Description
ICK3
ICK2
ICK1
ICK0
PSEL
Pulse width: 3/16 of 115 kbps bit length
ICK3
ICK2
ICK1
ICK0
1
Don’t
care
Don’t
care
Don’t
care
Don’t
care
0
Pulse width: 3/16 of bit length
It is necessary to generate a fixed clock pulse, IRCLK, by dividing the Pφ clock by 1/2N + 2 (with
the value of N determined by the setting of ICK3–ICK0).
Example:
Pφ clock: 14.7456 MHz
IRCLK: 921.6 kHz (fixed)
N: Setting of ICK3–ICK0 (0 ≤ N ≤ 15)
N≥
Pφ
2XIRCLK
−1≥7
Accordingly, N is 7.
Bits 1 and 0—Clock Select 1 and 0 (CKS1, CKS0): Select the internal baud rate generator clock
source. Pφ, Pφ/4, Pφ/16, or Pφ/64 can be selected by setting the CKS1 and CKS0 bits.
Refer to section 14.2.9, Bit Rate Register (SCBRR), for the relationship between the clock source,
the bit rate register set value, and the baud rate.
Bit 1: CKS1
Bit 0: CKS0
Description
0
0
Pφ clock
0
1
Pφ/4 clock
1
0
Pφ/16
1
1
Pφ/64
Note: Pφ: Peripheral clock
Rev. 5.00, 09/03, page 562 of 760
(Initial value)
17.3
Operation Description
The IrDA module can perform infrared communication conforming to IrDA 1.0 by connecting
infrared transmit/receive units. The serial communication interface unit includes a 16-stage FIFO
buffer in the transmit unit and the receive unit, allowing CPU overhead to be reduced and
continuous high-speed communication to be performed. This module also supports DMAC data
transfer. The IrDA module differs from the SCIF described in section 16, Serial Communication
Interface with FIFO (SCIF) in that it does not include modem control signals RTS and CTS.
Refer to section 16.3, Operation, for SCIF mode operation.
17.3.1
Overview
The IrDA module modifies TxD/RxD transmit/receive data waveforms to satisfy the IrDA 1.0
specification for infrared communication.
In the IrDA 1.0 specification, communication is first performed at a speed of 9600 bps, and the
communication speed is changed. However, the communication rate cannot be automatically
changed in this module, so the communication speed should be confirmed, and the appropriate
speed set for this module by software.
Note: In IrDA mode, reception cannot be performed when the TE bit in the serial control register
(SCSCR) is set to 1 (enabling transmission). When performing reception, clear the TE bit
in SCSCR to 0.
As the SH7709S's RxD1 pin is active-high in IrDA mode, a (Schmidt) inverter must be
inserted when connecting an active-low IrDA module.
The RxD1 pin is active-low in SCIF mode.
17.3.2
Transmitting
In the case of a serial output signal (UART frame) from the SCIF, its waveforms are modified and
the signal is converted into the IR frame serial output signal by the IrDA module, as shown in
figure 17.5.
When serial data is 0, a pulse of 3/16 the IR frame bit width is generated and output. When serial
data is 1, no pulse is output.
An infrared LED is driven by this signal demodulated to 3/16 width.
Rev. 5.00, 09/03, page 563 of 760
17.3.3
Receiving
Received 3/16 IR frame bit-width pulses are demodulated and converted to a UART frame, as
shown in figure 17.5.
Demodulation to 0 is performed for pulse output, and demodulation to 1 is performed for no pulse
output.
UART frame
Data
Start bit
0
1
0
1
0
Stop bit
0
1
Transmit
1
0
1
Receive
IR frame
Data
Start bit
0
1
0
Bit cycle
1
0
Stop bit
0
1
1
3/16-bit cycle
pulse width
Figure 17.5 Transmit/Receive Operation
Rev. 5.00, 09/03, page 564 of 760
0
1
Section 18 Pin Function Controller
18.1
Overview
The pin function controller (PFC) is composed of registers for selecting the function of
multiplexed pins and the input/output direction. The pin function and input/output direction can be
selected for each pin individually without regard to the operating mode of the chip. Table 18.1
lists the multiplexed pins.
Table 18.1 List of Multiplexed Pins
Port
Port Function
(Related Module)
Other Function
(Related Module)
A
PTA7 input/output (port)
D23 input/output (data bus)
A
PTA6 input/output (port)
D22 input/output (data bus)
A
PTA5 input/output (port)
D21 input/output (data bus)
A
PTA4 input/output (port)
D20 input/output (data bus)
A
PTA3 input/output (port)
D19 input/output (data bus)
A
PTA2 input/output (port)
D18 input/output (data bus)
A
PTA1 input/output (port)
D17 input/output (data bus)
A
PTA0 input/output (port)
D16 input/output (data bus)
B
PTB7 input/output (port)
D31 input/output (data bus)
B
PTB6 input/output (port)
D30 input/output (data bus)
B
PTB5 input/output (port)
D29 input/output (data bus)
B
PTB4 input/output (port)
D28 input/output (data bus)
B
PTB3 input/output (port)
D27 input/output (data bus)
B
PTB2 input/output (port)
D26 input/output (data bus)
B
PTB1 input/output (port)
D25 input/output (data bus)
B
PTB0 input/output (port)
D24 input/output (data bus)
C
PTC7 input/output (port)/PINT7 input (INTC)
MCS7 output (BSC)
C
PTC6 input/output (port)/PINT6 input (INTC)
MCS6 output (BSC)
C
PTC5 input/output (port)/PINT5 input (INTC)
MCS5 output (BSC)
C
PTC4 input/output (port)/PINT4 input (INTC)
MCS4 output (BSC)
C
PTC3 input/output (port)/PINT3 input (INTC)
MCS3 output (BSC)
C
PTC2 input/output (port)/PINT2 input (INTC)
MCS2 output (BSC)
C
PTC1 input/output (port)/PINT1 input (INTC)
MCS1 output (BSC)
Rev. 5.00, 09/03, page 565 of 760
Port
Port Function
(Related Module)
Other Function
(Related Module)
C
PTC0 input/output (port)/PINT0 input (INTC)
MCS0 output (BSC)
D
PTD7 input/output (port)
DACK1 output (DMAC)
D
PTD6 input (port)
DREQ1 input (DMAC)
D
PTD5 input/output (port)
DACK0 output (DMAC)
D
PTD4 input (port)
DREQ0 input (DMAC)
D
PTD3 input/output (port)
WAKEUP output (WTC)
D
PTD2 input/output (port)
RESETOUT output
D
PTD1 input/output (port)
DRAK0 output (DMAC)
D
PTD0 input/output (port)
DRAK1 output (DMAC)
E
PTE7 input/output (port)
AUDSYNC output (AUD)
E
PTE6 input/output (port)
—
E
PTE5 input/output (port)
CE2B output (PCMCIA)
E
PTE4 input/output (port)
CE2A output (PCMCIA)
E
PTE3 input/output (port)
—
E
PTE2 input/output (port)
RAS3U output (BSC)
E
PTE1 input/output (port)
—
E
PTE0 input/output (port)
TDO output (UDI)
F
PTF7 input (port)/PINT15 input (INTC)
TRST input (AUD, UDI)
F
PTF6 input (port)/PINT14 input (INTC)
TMS input (UDI)
F
PTF5 input (port)/PINT13 input (INTC)
TD1 input (UDI)
F
PTF4 input (port)/PINT12 input (INTC)
TCK input (UDI)
F
PTF3 input (port)/PINT11 input (INTC)
IRLS3 input (INTC)
F
PTF2 input (port)/PINT10 input (INTC)
IRLS2 input (INTC)
F
PTF1 input (port)/PINT9 input (INTC)
IRLS1 input (INTC)
F
PTF0 input (port)/PINT8 input (INTC)
IRLS0 input (INTC)
G
PTG7 input (port)
IOIS16 input (PCMCIA)
G
PTG6 input (port)
ASEMD0 input (AUD, UDI)
G
PTG5 input (port)
ASEBRKAK output (AUD)
G
PTG4 input (port)
CKIO2 output (CPG)
G
PTG3 input (port)
AUDATA3 output (AUD)
G
PTG2 input (port)
AUDATA2 output (AUD)
Rev. 5.00, 09/03, page 566 of 760
Port
Port Function
(Related Module)
Other Function
(Related Module)
G
PTG1 input (port)
AUDATA1 output (AUD)
G
PTG0 input (port)
AUDATA0 output (AUD)
H
PTH7 input/output (port)
TCLK input/output (TMU)
H
PTH6 input (port)
AUDCK input (AUD)
H
PTH5 input (port)
ADTRG input (ADC)
H
PTH4 input (port)/IRQ4 input (INTC)
IRQ4 input (INTC)
H
PTH3 input (port)/IRQ3 input (INTC)
IRQ3 input (INTC)
H
PTH2 input (port)/IRQ2 input (INTC)
IRQ2 input (INTC)
H
PTH1 input (port)/IRQ1 input (INTC)
IRQ1 input (INTC)
H
PTH0 input (port)/IRQ0 input (INTC)
IRQ0 input (INTC)
J
PTJ7 input/output (port)
STATUS1 output (CPG)
J
PTJ6 input/output (port)
STATUS0 output (CPG)
J
PTJ5 input/output (port)
—
J
PTJ4 input/output (port)
—
J
PTJ3 input/output (port)
CASU output (BSC)
J
PTJ2 input/output (port)
CASL output (BSC)
J
PTJ1 input/output (port)
—
J
PTJ0 input/output (port)
RAS3L output (BSC)
K
PTK7 input/output (port)
WE3 output (BSC)/DQMUU output
(BSC)/ICIOWR output (BSC)
K
PTK6 input/output (port)
WE2 output (BSC)/DQMUL output
(BSC)/ICIORD output (BSC)
K
PTK5 input/output (port)
CKE output (BSC)
K
PTK4 input/output (port)
BS output (BSC)
K
PTK3 input/output (port)
CS5 output (BSC)/CE1A output (BSC)
K
PTK2 input/output (port)
CS4 output (BSC)
K
PTK1 input/output (port)
CS3 output (BSC)
K
PTK0 input/output (port)
CS2 output (BSC)
L
PTL7 input (port)
AN7 input (ADC)/DA0 output (DAC)
L
PTL6 input (port)
AN6 input (ADC)/DA1 output (DAC)
L
PTL5 input (port)
AN5 input (ADC)
Rev. 5.00, 09/03, page 567 of 760
Port
Port Function
(Related Module)
Other Function
(Related Module)
L
PTL4 input (port)
AN4 input (ADC)
L
PTL3 input (port)
AN3 input (ADC)
L
PTL2 input (port)
AN2 input (ADC)
L
PTL1 input (port)
AN1 input (ADC)
L
PTL0 input (port)
AN0 input (ADC)
SCPT
SCPT7 input (port)/IRQ5 input (INTC)
CTS2 input (UART ch 3)/IRQ5 input (INTC)
SCPT
SCPT6 input/output (port)
RTS2 output (UART ch 3)
SCPT
SCPT5 input/output (port)
SCK2 input/output (UART ch 3)
SCPT
SCPT4 input (port)
RxD2 input (UART ch 3)
SCPT4 output (port)
TxD2 output (UART ch 3)
SCPT3 input/output (port)
SCK1 input/output (UART ch 2)
SCPT
SCPT
SCPT2 input (port)
RxD1 input (UART ch 2)
SCPT2 output (port)
TxD1 output (UART ch 2)
SCPT
SCPT1 input/output (port)
SCK0 input/output (UART ch 1)
SCPT
SCPT0 input (port)
RxD0 input (UART ch 1)
SCPT0 output (port)
TxD0 output (UART ch 1)
Note:
SCPT0, SCPT2, and SCPT4 have the same data register to be accessed although they
have different input pins and output pins.
Rev. 5.00, 09/03, page 568 of 760
18.2
Register Configuration
Table 18.2 summarizes the registers of the pin function controller.
Table 18.2 Pin Function Controller Registers
Access
Size
Name
Abbreviation
R/W
Initial Value
Address
Port A control register
PACR
R/W
H'0000
H'04000100
(H'A4000100)*
16
Port B control register
PBCR
R/W
H'0000
H'04000102
(H'A4000102)*
16
Port C control register
PCCR
R/W
H'AAAA
H'04000104
(H'A4000104)*
16
Port D control register
PDCR
R/W
H'AA8A
H'04000106
(H'A4000106)*
16
Port E control register
PECR
R/W
H'AAAA/H'2AA8
H'04000108
(H'A4000108)*
16
Port F control register
PFCR
R/W
H'AAAA/H'00AA
H'0400010A
(H'A400010A)*
16
Port G control register
PGCR
R/W
H'AAAA/H'A200
H'0400010C
(H'A400010C)*
16
Port H control register
PHCR
R/W
H'AAAA/H'8AAA
H'0400010E
(H'A400010E)*
16
Port J control register
PJCR
R/W
H'0000
H'04000110
(H'A4000110)*
16
Port K control register
PKCR
R/W
H'0000
H'04000112
(H'A4000112)*
16
Port L control register
PLCR
R/W
H'0000
H'04000114
(H'A4000114)*
16
SC port control register
SCPCR
R/W
H'A888
H'04000116
(H'A4000116)*
16
Notes: 1. The initial value of the port E, F, G, and H control registers depends on the state of the
ASEMD0 pin.
If a low level is input at the ASEMD0 pin while the RESETP pin is asserted, ASE mode
is entered; if a high level is input, normal mode is entered. See section 22, User
Debugging Interface (UDI), for more information on the UDI.
2. These registers are located in area 1 of physical space. Therefore, when the cache is
on, either access these registers from the P2 area of logical space or else make an
appropriate setting using the MMU so that these registers are not cached.
* When address translation by the MMU does not apply, the address in parentheses
should be used.
Rev. 5.00, 09/03, page 569 of 760
18.3
Register Descriptions
18.3.1
Port A Control Register (PACR)
Bit:
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
PA7 PA7 PA6 PA6 PA5 PA5 PA4 PA4 PA3 PA3 PA2 PA2 PA1 PA1 PA0 PA0
MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0
Initial value:
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
R/W: R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W
The port A control register (PACR) is a 16-bit readable/writable register that selects the pin
functions. PACR is initialized to H'0000 by a power-on reset, but is not initialized by a manual
reset, in standby mode, or in sleep mode.
Bits 15 and 14—PA7 Mode 1 and 0 (PA7MD1, PA7MD0)
Bits 13 and 12—PA6 Mode 1 and 0 (PA6MD1, PA6MD0)
Bits 11 and 10—PA5 Mode 1 and 0 (PA5MD1, PA5MD0)
Bits 9 and 8—PA4 Mode 1 and 0 (PA4MD1, PA4MD0)
Bits 7 and 6—PA3 Mode 1 and 0 (PA3MD1, PA3MD0)
Bits 5 and 4—PA2 Mode 1 and 0 (PA2MD1, PA2MD0)
Bits 3 and 2—PA1 Mode 1 and 0 (PA1MD1, PA1MD0)
Bits 1 and 0—PA0 Mode 1 and 0 (PA0MD1, PA0MD0)
These bits select the pin functions and perform input pull-up MOS control.
Bit (2n + 1)
Bit 2n
PAnMD1
PAnMD0
Pin Function
0
0
Other function (see table 18.1)
0
1
Port output
1
0
Port input (Pull-up MOS: on)
1
1
Port input (Pull-up MOS: off)
(Initial value)
(n = 0 to 7)
Rev. 5.00, 09/03, page 570 of 760
18.3.2
Port B Control Register (PBCR)
Bit:
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
PB7 PB7 PB6 PB6 PB5 PB5 PB4 PB4 PB3 PB3 PB2 PB2 PB1 PB1 PB0 PB0
MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0
Initial value:
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
R/W: R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W
The port B control register (PBCR) is a 16-bit readable/writable register that selects the pin
functions. PBCR is initialized to H'0000 by a power-on reset, but is not initialized by a manual
reset, in standby mode, or in sleep mode.
Bits 15 and 14—PB7 Mode 1 and 0 (PB7MD1, PB7MD0)
Bits 13 and 12—PB6 Mode 1 and 0 (PB6MD1, PB6MD0)
Bits 11 and 10—PB5 Mode 1 and 0 (PB5MD1, PB5MD0)
Bits 9 and 8—PB4 Mode 1 and 0 (PB4MD1, PB4MD0)
Bits 7 and 6—PB3 Mode 1 and 0 (PB3MD1, PB3MD0)
Bits 5 and 4—PB2 Mode 1 and 0 (PB2MD1, PB2MD0)
Bits 3 and 2—PB1 Mode 1 and 0 (PB1MD1, PB1MD0)
Bits 1 and 0—PB0 Mode 1 and 0 (PB0MD1, PB0MD0)
These bits select the pin functions and perform input pull-up MOS control.
Bit (2n + 1)
Bit 2n
PBnMD1
PBnMD0
Pin Function
0
0
Other function (see table 18.1)
0
1
Port output
1
0
Port input (Pull-up MOS: on)
1
1
Port input (Pull-up MOS: off)
(Initial value)
(n = 0 to 7)
Rev. 5.00, 09/03, page 571 of 760
18.3.3
Port C Control Register (PCCR)
Bit:
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
PC7 PC7 PC6 PC6 PC5 PC5 PC4 PC4 PC3 PC3 PC2 PC2 PC1 PC1 PC0 PC0
MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0
Initial value:
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
R/W: R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W
The port C control register (PCCR) is a 16-bit readable/writable register that selects the pin
functions. PCCR is initialized to H'AAAA by a power-on reset, but is not initialized by a manual
reset, in standby mode, or in sleep mode.
Bits 15 and 14—PC7 Mode 1 and 0 (PC7MD1, PC7MD0)
Bits 13 and 12—PB6 Mode 1 and 0 (PC6MD1, PC6MD0)
Bits 11 and 10—PC5 Mode 1 and 0 (PC5MD1, PC5MD0)
Bits 9 and 8—PC4 Mode 1 and 0 (PC4MD1, PC4MD0)
Bits 7 and 6—PC3 Mode 1 and 0 (PC3MD1, PC3MD0)
Bits 5 and 4—PC2 Mode 1 and 0 (PC2MD1, PC2MD0)
Bits 3 and 2—PC1 Mode 1 and 0 (PC1MD1, PC1MD0)
Bits 1 and 0—PC0 Mode 1 and 0 (PC0MD1, PC0MD0)
These bits select the pin functions and perform input pull-up MOS control.
Bit (2n + 1)
Bit 2n
PCnMD1
PCnMD0
Pin Function
0
0
Other function (see table 18.1)
0
1
Port output
1
0
Port input (Pull-up MOS: on)
1
1
Port input (Pull-up MOS: off)
(Initial value)
(n = 0 to 7)
Rev. 5.00, 09/03, page 572 of 760
18.3.4
Port D Control Register (PDCR)
Bit:
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
PD7 PD7 PD6 PD6 PD5 PD5 PD4 PD4 PD3 PD3 PD2 PD2 PD1 PD1 PD0 PD0
MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0
Initial value:
1
0
1
0
1
0
1
0
1
0
0
0
1
0
1
0
R/W: R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W
The port D control register (PDCR) is a 16-bit readable/writable register that selects the pin
functions. PDCR is initialized to H'AA8A by a power-on reset, but is not initialized by a manual
reset, in standby mode, or in sleep mode.
Bits 15 and 14—PD7 Mode 1 and 0 (PD7MD1, PD7MD0)
Bits 11 and 10—PD5 Mode 1 and 0 (PD5MD1, PD5MD0)
Bits 7 and 6—PD3 Mode 1 and 0 (PD3MD1, PD3MD0)
Bits 5 and 4—PD2 Mode 1 and 0 (PD2MD1, PD2MD0)
Bits 3 and 2—PD1 Mode 1 and 0 (PD1MD1, PD1MD0)
Bits 1 and 0—PD0 Mode 1 and 0 (PD0MD1, PD0MD0)
These bits select the pin functions and perform input pull-up MOS control.
Bit (2n + 1)
Bit 2n
PDnMD1
PDnMD0
Pin Function
0
0
Other function (see table 18.1)
0
1
Port output
1
0
Port input (Pull-up MOS: on)
1
1
Port input (Pull-up MOS: off)
(Initial value) (n = 2)
(Initial value) (n = 0, 1, 3, 5, 7)
(n = 0 to 3, 5, 7)
Bits 13 and 12—PD6 Mode 1 and 0 (PD6MD1, PD6MD0)
Bits 9 and 8—PD4 Mode 1 and 0 (PD4MD1, PD4MD0)
These bits select the pin functions and perform input pull-up MOS control.
Bit (2n + 1)
Bit 2n
PDnMD1
PDnMD0
Pin Function
0
0
Other function (see table 18.1)
0
1
Reserved
1
0
Port input (Pull-up MOS: on)
1
1
Port input (Pull-up MOS: off)
(Initial value)
(n = 4, 6)
Rev. 5.00, 09/03, page 573 of 760
18.3.5
Port E Control Register (PECR)
Bit:
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
PE7 PE7 PE6 PE6 PE5 PE5 PE4 PE4 PE3 PE3 PE2 PE2 PE1 PE1 PE0 PE0
MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0
Initial value:
1/0
0
1
0
1
0
1
0
1
0
1
0
1
0
1/0
0
R/W: R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W
The port E control register (PECR) is a 16-bit readable/writable register that selects the pin
functions. PECR is initialized to H'AAAA (ASEMD0 = 1) or H'2AA8 (ASEMD0 = 0) by a
power-on reset, but is not initialized by a manual reset, in software standby mode, or in sleep
mode.
Bits 15 and 14—PE7 Mode 1 and 0 (PE7MD1, PE7MD0)
Bits 13 and 12—PE6 Mode 1 and 0 (PE6MD1, PE6MD0)
Bits 11 and 10—PE5 Mode 1 and 0 (PE5MD1, PE5MD0)
Bits 9 and 8—PE4 Mode 1 and 0 (PE4MD1, PE4MD0)
Bits 7 and 6—PE3 Mode 1 and 0 (PE3MD1, PE3MD0)
Bits 5 and 4—PE2 Mode 1 and 0 (PE2MD1, PE2MD0)
Bits 3 and 2—PE1 Mode 1 and 0 (PE1MD1, PE1MD0)
Bits 1 and 0—PE0 Mode 1 and 0 (PE0MD1, PE0MD0)
These bits select the pin functions and perform input pull-up MOS control.
Bit (2n + 1)
Bit 2n
PEnMD1
PEnMD0
Pin Function
0
0
Reserved (n = 0, 7) (see table 18.1)
0
1
Port output
1
0
Port input (Pull-up MOS: on)
1
1
Port input (Pull-up MOS: off)
(Initial value) (ASEMD0 = 0)
(Initial value) (ASEMD0 = 1)
(n = 0, 7)
Bit (2n + 1)
Bit 2n
PEnMD1
PEnMD0
Pin Function
0
0
Other function (n = 2, 4, 5) (see table 18.1), Reserved (n = 1, 3, 6)
0
1
Port output
1
0
Port input (Pull-up MOS: on)
1
1
Port input (Pull-up MOS: off)
(Initial value)
(n = 1 to 6)
Rev. 5.00, 09/03, page 574 of 760
18.3.6
Port F Control Register (PFCR)
Bit:
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
PF7 PF7 PF6 PF6 PF5 PF5 PF4 PF4 PF3 PF3 PF2 PF2 PF1 PF1 PF0 PF0
MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0
Initial value:
1/0
0
1/0
0
1/0
0
1/0
0
1
0
1
0
1
0
1
0
R/W: R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W
The port F control register (PFCR) is a 16-bit readable/writable register that selects the pin
functions. PFCR is initialized to H'AAAA (ASEMD0 = 1) or H'00AA (ASEMD0 = 0) by a poweron reset, but is not initialized by a manual reset, in standby mode, or in sleep mode.
Bits 15 and 14—PF7 Mode 1 and 0 (PF7MD1, PF7MD0)
Bits 13 and 12—PF6 Mode 1 and 0 (PF6MD1, PF6MD0)
Bits 11 and 10—PF5 Mode 1 and 0 (PF5MD1, PF5MD0)
Bits 9 and 8—PF4 Mode 1 and 0 (PF4MD1, PF4MD0)
Bits 7 and 6—PF3 Mode 1 and 0 (PF3MD1, PF3MD0)
Bits 5 and 4—PF2 Mode 1 and 0 (PF2MD1, PF2MD0)
Bits 3 and 2—PF1 Mode 1 and 0 (PF1MD1, PF1MD0)
Bits 1 and 0—PF0 Mode 1 and 0 (PF0MD1, PF0MD0)
These bits select the pin functions and perform input pull-up MOS control.
Bit (2n + 1)
Bit 2n
PFnMD1
PFnMD0
Pin Function
0
0
Other function (see table 18.1)
0
1
Reserved
1
0
Port input (Pull-up MOS: on)
1
1
Port input (Pull-up MOS: off)
(Initial value) (ASEMD0 = 0)
(Initial value) (ASEMD0 = 1)
(n = 4 to 7)
Bit (2n + 1)
Bit 2n
PFnMD1
PFnMD0
Pin Function
0
0
Other function (see table 18.1)
0
1
Reserved
1
0
Port input (Pull-up MOS: on)
1
1
Port input (Pull-up MOS: off)
(Initial value)
(n = 0 to 3)
Rev. 5.00, 09/03, page 575 of 760
18.3.7
Port G Control Register (PGCR)
Bit:
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
PG7 PG7 PG6 PG6 PG5 PG5 PG4 PG4 PG3 PG3 PG2 PG2 PG1 PG1 PG0 PG0
MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0
Initial value:
1
0
1
0
1/0
0
1
0
1/0
0
1/0
0
1/0
0
1/0
0
R/W: R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W
The port G control register (PGCR) is a 16-bit readable/writable register that selects the pin
functions. PGCR is initialized to H'AAAA (ASEMD0 = 1) or H'A200 (ASEMD0 = 0) by a poweron reset, but is not initialized by a manual reset, in standby mode, or in sleep mode.
Bits 15 and 14—PG7 Mode 1 and 0 (PG7MD1, PG7MD0)
Bits 13 and 12—PG6 Mode 1 and 0 (PG6MD1, PG6MD0)
Bits 11 and 10—PG5 Mode 1 and 0 (PG5MD1, PG5MD0)
Bits 9 and 8—PG4 Mode 1 and 0 (PG4MD1, PG4MD0)
Bits 7 and 6—PG3 Mode 1 and 0 (PG3MD1, PG3MD0)
Bits 5 and 4—PG2 Mode 1 and 0 (PG2MD1, PG2MD0)
Bits 3 and 2—PG1 Mode 1 and 0 (PG1MD1, PG1MD0)
Bits 1 and 0—PG0 Mode 1 and 0 (PG0MD1, PG0MD0)
These bits select the pin functions and perform input pull-up MOS control.
Rev. 5.00, 09/03, page 576 of 760
Bit (2n + 1)
Bit 2n
PGnMD1
PGnMD0
Pin Function
0
0
Other function (n = 1–3, 5) (see table 18.1)
(Initial value) (ASEMD0 = 0)
0
1
Reserved
1
0
Port input (Pull-up MOS: on)
1
1
Port input (Pull-up MOS: off)
(Initial value) (ASEMD0 = 1)
(n = 1 to 3, 5)
Bit (2n + 1)
Bit 2n
PGnMD1
PGnMD0
0
0
Other function (n = 4, 6, 7) (see table 18.1)
0
1
Reserved
1
0
Port input (Pull-up MOS: on)
1
1
Port input (Pull-up MOS: off)
Pin Function
(Initial value)*
(n = 4, 6, 7)
Note: * When n = 6, ASEMD0/PTG6 functions as ASEMD0 input while the reset signal is
asserted, and as PTG6 input immediately after the reset signal is nagated.
Bit 3
Bit 0
PG1MD1*
PG0MD0
0
0
Other function (see table 18.1)
0
1
Reserved
1
0
Port input (Pull-up MOS: on)
1
1
Port input (Pull-up MOS: off)
Pin Function
(Initial value) ASEMD0 = 0
(Initial value) ASEMD0 = 1
Note: * Controlled by PG1MD1 (bit 3), not PG0MD1 (bit 1).
18.3.8
Port H Control Register (PHCR)
Bit:
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
PH7 PH7 PH6 PH6 PH5 PH5 PH4 PH4 PH3 PH3 PH2 PH2 PH1 PH1 PH0 PH0
MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0
Initial value:
1
0
1/0
0
1
0
1
0
1
0
1
0
1
0
1
0
R/W: R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W
The port H control register (PHCR) is a 16-bit readable/writable register that selects the pin
functions. PHCR is initialized to H'AAAA (ASEMD0 = 1) or H'8AAA (ASEMD0 = 0) by a
power-on reset, but is not initialized by a manual reset, in standby mode, or in sleep mode.
Rev. 5.00, 09/03, page 577 of 760
Bits 15 and 14—PH7 Mode 1, 0 (PH7MD1, PH7MD0): These bits select the pin functions and
perform input pull-up MOS control.
Bit 15
Bit 14
PH7MD1
PH7MD0
Pin Function
0
0
Other function (see table 18.1)
0
1
Port output
1
0
Port input (Pull-up MOS: on)
1
1
Port input (Pull-up MOS: off)
(Initial value)
Bits 13 and 12—PH6 Mode 1 and 0 (PH6MD1, PH6MD0)
Bits 11 and 10—PH5 Mode 1 and 0 (PH5MD1, PH5MD0)
Bits 9 and 8—PH4 Mode 1 and 0 (PH4MD1, PH4MD0)
Bits 7 and 6—PH3 Mode 1 and 0 (PH3MD1, PH3MD0)
Bits 5 and 4—PH2 Mode 1 and 0 (PH2MD1, PH2MD0)
Bits 3 and 2—PH1 Mode 1 and 0 (PH1MD1, PH1MD0)
Bits 1 and 0—PH0 Mode 1 and 0 (PH0MD1, PH0MD0)
These bits select the pin functions and perform input pull-up MOS control.
Bit 13
Bit 12
PH6MD1
PH6MD0
0
0
Other function (see table 18.1)
0
1
Reserved
1
0
Port input (Pull-up MOS: on)
1
1
Port input (Pull-up MOS: off)
Bit (2n + 1)
Bit 2n
PHnMD1
PHnMD0
Pin Function
0
0
Other function (see table 18.1)
0
1
Reserved
1
0
Port input (Pull-up MOS: on)
1
1
Port input (Pull-up MOS: off)
Pin Function
(Initial value) (ASEMD0 = 0)
(Initial value) (ASEMD0 = 1)
(Initial value)
(n = 0 to 5)
Rev. 5.00, 09/03, page 578 of 760
18.3.9
Port J Control Register (PJCR)
Bit:
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
PJ7 PJ7 PJ6 PJ6 PJ5 PJ5 PJ4 PJ4 PJ3 PJ3 PJ2 PJ2 PJ1 PJ1 PJ0 PJ0
MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0
Initial value:
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
R/W: R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W
The port J control register (PJCR) is a 16-bit readable/writable register that selects the pin
functions. PJCR is initialized to H'0000 by a power-on reset, but is not initialized by a manual
reset, in standby mode, or in sleep mode.
Bits 15 and 14—PJ7 Mode 1 and 0 (PJ7MD1, PJ7MD0)
Bits 13 and 12—PJ6 Mode 1 and 0 (PJ6MD1, PJ6MD0)
Bits 11 and 10—PJ5 Mode 1 and 0 (PJ5MD1, PJ5MD0)
Bits 9 and 8—PJ4 Mode 1 and 0 (PJ4MD1, PJ4MD0)
Bits 7 and 6—PJ3 Mode 1 and 0 (PJ3MD1, PJ3MD0)
Bits 5 and 4—PJ2 Mode 1 and 0 (PJ2MD1, PJ2MD0)
Bits 3 and 2—PJ1 Mode 1 and 0 (PJ1MD1, PJ1MD0)
Bits 1 and 0—PJ0 Mode 1 and 0 (PJ0MD1, PJ0MD0)
These bits select the pin functions and perform input pull-up MOS control.
Bit (2n + 1)
Bit 2n
PJnMD1
PJnMD0
Pin Function
0
0
Other function (n = 0, 2, 3, 6, 7) (see table 18.1),
Reserved (n = 1, 4, 5)
0
1
Port output
1
0
Port input (Pull-up MOS: on)
1
1
Port input (Pull-up MOS: off)
(Initial value)
(n = 0 to 7)
Rev. 5.00, 09/03, page 579 of 760
18.3.10 Port K Control Register (PKCR)
Bit:
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
PK7 PK7 PK6 PK6 PK5 PK5 PK4 PK4 PK3 PK3 PK2 PK2 PK1 PK1 PK0 PK0
MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0
Initial value:
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
R/W: R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W
The port K control register (PKCR) is a 16-bit readable/writable register that selects the pin
functions. PKCR is initialized to H'0000 by a power-on reset, but is not initialized by a manual
reset, in standby mode, or in sleep mode.
Bits 15 and 14—PK7 Mode 1 and 0 (PK7MD1, PK7MD0)
Bits 13 and 12—PK6 Mode 1 and 0 (PK6MD1, PK6MD0)
Bits 11 and 10—PK5 Mode 1 and 0 (PK5MD1, PK5MD0)
Bits 9 and 8—PK4 Mode 1 and 0 (PK4MD1, PK4MD0)
Bits 7 and 6—PK3 Mode 1 and 0 (PK3MD1, PK3MD0)
Bits 5 and 4—PK2 Mode 1 and 0 (PK2MD1, PK2MD0)
Bits 3 and 2—PK1 Mode 1 and 0 (PK1MD1, PK1MD0)
Bits 1 and 0—PK0 Mode 1 and 0 (PK0MD1, PK0MD0)
These bits select the pin functions and perform input pull-up MOS control.
Bit (2n + 1)
Bit 2n
PKnMD1
PKnMD0
Pin Function
0
0
Other function (see table 18.1)
0
1
Port output
1
0
Port input (Pull-up MOS: on)
1
1
Port input (Pull-up MOS: off)
(Initial value)
(n = 0 to 7)
Rev. 5.00, 09/03, page 580 of 760
18.3.11 Port L Control Register (PLCR)
Bit:
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
PL7 PL7 PL6 PL6 PL5 PL5 PL4 PL4 PL3 PL3 PL2 PL2 PL1 PL1 PL0 PL0
MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0
Initial value:
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
R/W: R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W
The port L control register (PLCR) is a 16-bit readable/writable register that selects the pin
functions. PLCR is initialized to H'0000 by a power-on reset, but is not initialized by a manual
reset, in standby mode, or in sleep mode.
Bits 15 and 14—PL7 Mode 1 and 0 (PL7MD1, PL7MD0)
Bits 13 and 12—PL6 Mode 1 and 0 (PL6MD1, PL6MD0)
Bits 11 and 10—PL5 Mode 1 and 0 (PL5MD1, PL5MD0)
Bits 9 and 8—PL4 Mode 1 and 0 (PL4MD1, PL4MD0)
Bits 7 and 6—PL3 Mode 1 and 0 (PL3MD1, PL3MD0)
Bits 5 and 4—PL2 Mode 1 and 0 (PL2MD1, PL2MD0)
Bits 3 and 2—PL1 Mode 1 and 0 (PL1MD1, PL1MD0)
Bits 1 and 0—PL0 Mode 1 and 0 (PL0MD1, PL0MD0)
These bits select the pin functions and perform input pull-up MOS control.
Bit (2n + 1)
Bit 2n
PLnMD1
PLnMD0
Pin Function
0
0
Other function (see table 18.1)
0
1
Reserved
1
0
Port input (Pull-up MOS: on)
1
1
Port input (Pull-up MOS: off)
(Initial value)
(n = 0 to 7)
When the DA0 and DA1 pins are used as the D/A converter outputs or when PTL7 and PTL6 are
used in the “other function” state, PLCR should by kept at its initial value.
Rev. 5.00, 09/03, page 581 of 760
18.3.12 SC Port Control Register (SCPCR)
Bit:
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
SCP7 SCP7 SCP6 SCP6 SCP5 SCP5 SCP4 SCP4 SCP3 SCP3 SCP2 SCP2 SCP1 SCP1 SCP0 SCP0
MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0 MD1 MD0
Initial value:
1
0
1
0
1
0
0
0
1
0
0
0
1
0
0
0
R/W: R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W R/W
The SC port control register (SCPCR) is a 16-bit readable/writable register that selects the pin
functions. The setting of SCPCR is valid only when transmit/receive operations are disabled in the
SCSCR register. SCPCR is initialized to H'A888 by a power-on reset, but is not initialized by a
manual reset, in standby mode, or in sleep mode. When the TE bit in SCSCR is set to 1, the “other
function” output state has a higher priority than the SCPCR setting for the TxD[2:0] pins. When
the RE bit in SCSCR is set to 1, the input state has a higher priority than the SCPCR setting for the
RxD[2:0] pins.
Bits 15 and 14—SCP7 Mode 1 and 0 (SCP7MD1, SCP7MD0): These bits select the pin
function and perform input pull-up MOS control.
Bit 15
Bit 14
SCP7MD1
SCP7MD0
0
0
Other function (see table 18.1)
0
1
Reserved
1
0
Port input (Pull-up MOS: on)
1
1
Port input (Pull-up MOS: off)
Pin Function
(Initial value)
Bits 13, 12—SCP6 Mode 1, 0 (SCP6MD1, SCP6MD0): These bits select the pin function and
perform input pull-up MOS control.
Bit 13
Bit 12
SCP6MD1
SCP6MD0
Pin Function
0
0
Other function (see table 18.1)
0
1
Port output
1
0
Port input (Pull-up MOS: on)
1
1
Port input (Pull-up MOS: off)
Rev. 5.00, 09/03, page 582 of 760
(Initial value)
Bits 11 and 10—SCP5 Mode 1 and 0 (SCP5MD1, SCP5MD0): These bits select the pin
functions and perform input pull-up MOS control.
Bit 11
Bit 10
SCP5MD1
SCP5MD0
Pin Function
0
0
Other function (see table 18.1)
0
1
Port output
1
0
Port input (Pull-up MOS: on)
1
1
Port input (Pull-up MOS: off)
(Initial value)
Bits 9 and 8—SCP4 Mode 1 and 0 (SCP4MD1, SCP4MD0): These bits select the pin function
and perform input pull-up MOS control.
Bit 9
Bit 8
SCP4MD1
SCP4MD0
Pin Function
0
0
Transmit data output 2 (TxD2)
Receive data input 2 (RxD2)
(Initial value)
0
1
General output (SCPT[4] output pin)
Receive data input 2 (RxD2)
1
0
SCPT[4] input pin pull-up (input pin)
Transmit data output 2 (TxD2)
1
1
General input (SCPT[4] input pin)
Transmit data output 2 (TxD2)
Note: There is no SCPT[4] simultaneous I/O combination because one bit (SCP4DT) is accessed
using two pins, TxD2 and RxD2.
When port input is set (bit SCPnMD1 is set to 1) and when the TE bit in SCSCR is set to 1, the
TxD2 pin is in the output state. When the TE bit is cleared to 0, the TxD2 pin goes to the highimpedance state.
Bits 7 and 6—SCP3 Mode 1 and 0 (SCP3MD1, SCP3MD0): These bits select the pin function
and perform input pull-up MOS control.
Bit 7
Bit 6
SCP3MD1
SCP3MD0
Pin Function
0
0
Other function (see table 18.1)
0
1
Port output
1
0
Port input (Pull-up MOS: on)
1
1
Port input (Pull-up MOS: off)
(Initial value)
Rev. 5.00, 09/03, page 583 of 760
Bits 5 and 4—SCP2 Mode 1 and 0 (SCP2MD1, SCP2MD0): These bits select the pin function
and perform input pull-up MOS control.
Bit 5
Bit 4
SCP2MD1
SCP2MD0
Pin Function
0
0
Transmit data output 1 (TxD1)
Receive data input 1 (RxD1)
0
1
General output (SCPT[2] output pin)
Receive data input 1 (RxD1)
1
0
SCPT[2] input pin pull-up (input pin)
Transmit data output 1 (TxD1)
1
1
General input (SCPT[2] input pin)
Transmit data output 1 (TxD1)
(Initial value)
Note: There is no SCPT[2] simultaneous I/O combination because one bit (SCP2DT) is accessed
using two pins, TxD1 and RxD1.
When port input is set (bit SCPnMD1 is set to 1) and when the TE bit in SCSCR is set to 1, the
TxD1 pin is in the output state. When the TE bit is cleared to 0, the TxD1 pin goes to the highimpedance state.
Bits 3 and 2—SCP1 Mode 1 and 0 (SCP1MD1, SCP1MD0): These bits select the pin function
and perform input pull-up MOS control.
Bit 3
Bit 2
SCP1MD1
SCP1MD0
Pin Function
0
0
Other function (see table 18.1)
0
1
Port output
1
0
Port input (Pull-up MOS: on)
1
1
Port input (Pull-up MOS: off)
Rev. 5.00, 09/03, page 584 of 760
(Initial value)
Bits 1 and 0—SCP0 Mode 1 and 0 (SCP0MD1, SCP0MD0): These bits select the pin function
and perform input pull-up MOS control.
Bit 1
Bit 0
SCP0MD1
SCP0MD0
Pin Function
0
0
Transmit data output 0 (TxD0)
Receive data input 0 (RxD0)
(Initial value)
0
1
General output (SCPT[0] output pin)
Receive data input 0 (RxD0)
1
0
SCPT[0] input pin pull-up (input pin)
Transmit data output 0 (TxD0)
1
1
General input (SCPT[0] input pin)
Transmit data output 0 (TxD0)
Note: There is no SCPT[0] simultaneous I/O combination because one bit (SCP0DT) is accessed
using two pins, TxD0 and RxD0.
When port input is set (bit SCPnMD1 is set to 1) and when the TE bit in SCSCR is set to 1, the
TxD0 pin is in the output state. When the TE bit is cleared to 0, the TxD0 pin goes to the highimpedance state.
Rev. 5.00, 09/03, page 585 of 760
Rev. 5.00, 09/03, page 586 of 760
Section 19 I/O Ports
19.1
Overview
The SH7709S has twelve 8-bit ports (ports A to L and SC). All port pins are multiplexed with
other pin functions (the pin function controller (PFC) handles the selection of pin functions and
pull-up MOS control). Each port has a data register which stores data for the pins.
19.2
Port A
Port A is an 8-bit input/output port with the pin configuration shown in figure 19.1. Each pin has
an input pull-up MOS, which is controlled by the port A control register (PACR) in the PFC.
PTA7 (input/output) / D23 (input/output)
PTA6 (input/output) / D22 (input/output)
PTA5 (input/output) / D21 (input/output)
Port A
PTA4 (input/output) / D20 (input/output)
PTA3 (input/output) / D19 (input/output)
PTA2 (input/output) / D18 (input/output)
PTA1 (input/output) / D17 (input/output)
PTA0 (input/output) / D16 (input/output)
Figure 19.1 Port A
19.2.1
Register Description
Table 19.1 summarizes the port A register.
Table 19.1 Port A Register
Name
Abbreviation
R/W
Initial Value
Address
Access Size
Port A data register
PADR
R/W
H'00
H'04000120
8
(H'A4000120)*
Notes: This register is located in area 1 of physical space. Therefore, when the cache is on, either
access this register from the P2 area of logical space or else make an appropriate setting
using the MMU so that this register is not cached.
* When address translation by the MMU does not apply, the address in parentheses
should be used.
Rev. 5.00, 09/03, page 587 of 760
19.2.2
Port A Data Register (PADR)
Bit:
7
6
5
4
3
2
1
0
PA7DT
PA6DT
PA5DT
PA4DT
PA3DT
PA2DT
PA1DT
PA0DT
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Initial value:
R/W:
The port A data register (PADR) is an 8-bit readable/writable register that stores data for pins
PTA7 to PTA0. Bits PA7DT to PA0DT correspond to pins PTA7 to PTA0. When the pin function
is general output port, if the port is read the value of the corresponding PADR bit is returned
directly. When the function is general input port, if the port is read the corresponding pin level is
read. Table 19.2 shows the function of PADR.
PADR is initialized to H'00 by a power-on reset. It retains its previous value in standby mode and
sleep mode, and in a manual reset.
Table 19.2 Port A Data Register (PADR) Read/Write Operations
PAnMD1
PAnMD0
Pin State
Read
Write
0
0
Other function
(See table 18.1)
PADR value
Value is written to PADR, but does not
affect pin state
1
Output
PADR value
Write value is output from pin
0
Input (Pull-up
MOS on)
Pin state
Value is written to PADR, but does not
affect pin state
1
Input (Pull-up
MOS off)
Pin state
Value is written to PADR, but does not
affect pin state
1
(n = 7 to 0)
Rev. 5.00, 09/03, page 588 of 760
19.3
Port B
Port B is an 8-bit input/output port with the pin configuration shown in figure 19.2. Each pin has
an input pull-up MOS, which is controlled by the port B control register (PBCR) in the PFC.
PTB7 (input/output) / D31 (input/output)
PTB6 (input/output) / D30 (input/output)
PTB5 (input/output) / D29 (input/output)
Port B
PTB4 (input/output) / D28 (input/output)
PTB3 (input/output) / D27 (input/output)
PTB2 (input/output) / D26 (input/output)
PTB1 (input/output) / D25 (input/output)
PTB0 (input/output) / D24 (input/output)
Figure 19.2 Port B
19.3.1
Register Description
Table 19.3 summarizes the port B register.
Table 19.3 Port B Register
Name
Abbreviation
R/W
Initial Value
Address
Access Size
Port B data register
PBDR
R/W
H'00
H'04000122
(H'A4000122)*
8
Notes: This register is located in area 1 of physical space. Therefore, when the cache is on, either
access this register from the P2 area of logical space or else make an appropriate setting
using the MMU so that this register is not cached.
* When address translation by the MMU does not apply, the address in parentheses
should be used.
Rev. 5.00, 09/03, page 589 of 760
19.3.2
Port B Data Register (PBDR)
Bit:
7
6
5
4
3
2
1
0
PB7DT
PB6DT
PB5DT
PB4DT
PB3DT
PB2DT
PB1DT
PB0DT
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Initial value:
R/W:
The port B data register (PBDR) is an 8-bit readable/writable register that stores data for pins
PTB7 to PTB0. Bits PB7DT to PB0DT correspond to pins PTB7 to PTB0. When the pin function
is general output port, if the port is read the value of the corresponding PBDR bit is returned
directly. When the function is general input port, if the port is read the corresponding pin level is
read. Table 19.4 shows the function of PBDR.
PBDR is initialized to H'00 by a power-on reset. It retains its previous value in standby mode and
sleep mode, and in a manual reset.
Table 19.4 Port B Data Register (PBDR) Read/Write Operations
PBnMD1
PBnMD0
Pin State
Read
Write
0
0
Other function
(See table 18.1)
PBDR value
Value is written to PBDR, but does not
affect pin state
1
Output
PBDR value
Write value is output from pin
1
0
Input (Pull-up
MOS on)
Pin state
Value is written to PBDR, but does not
affect pin state
1
Input (Pull-up
MOS off)
Pin state
Value is written to PBDR, but does not
affect pin state
(n = 7 to 0)
Rev. 5.00, 09/03, page 590 of 760
19.4
Port C
Port C is an 8-bit input/output port with the pin configuration shown in figure 19.3. Each pin has
an input pull-up MOS, which is controlled by the port C control register (PCCR) in the PFC.
PTC7 (input/output) / PINT7 (input) / MSC7 (output)
PTC6 (input/output) / PINT6 (input) / MSC6 (output)
PTC5 (input/output) / PINT5 (input) / MSC5 (output)
PTC4 (input/output) / PINT4 (input) / MSC4 (output)
Port C
PTC3 (input/output) / PINT3 (input) / MSC3 (output)
PTC2 (input/output) / PINT2 (input) / MSC2 (output)
PTC1 (input/output) / PINT1 (input) / MSC1 (output)
PTC0 (input/output) / PINT0 (input) / MSC0 (output)
Figure 19.3 Port C
19.4.1
Register Description
Table 19.5 summarizes the port C register.
Table 19.5 Port C Register
Name
Abbreviation
R/W
Initial Value
Address
Access Size
Port C data register
PCDR
R/W
H'00
H'04000124
(H'A4000124)*
8
Notes: This register is located in area 1 of physical space. Therefore, when the cache is on, either
access this register from the P2 area of logical space or else make an appropriate setting
using the MMU so that this register is not cached.
* When address translation by the MMU does not apply, the address in parentheses
should be used.
Rev. 5.00, 09/03, page 591 of 760
19.4.2
Port C Data Register (PCDR)
Bit:
7
6
5
4
3
2
1
0
PC7DT
PC6DT
PC5DT
PC4DT
PC3DT
PC2DT
PC1DT
PC0DT
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Initial value:
R/W:
The port C data register (PCDR) is an 8-bit readable/writable register that stores data for pins
PTC7 to PTC0. Bits PC7DT to PC0DT correspond to pins PTC7 to PTC0. When the pin function
is general output port, if the port is read, the value of the corresponding PCDR bit is returned
directly. When the function is general input port, if the port is read, the corresponding pin level is
read. Table 19.6 shows the function of PCDR.
PCDR is initialized to H'00 by a power-on reset, after which the general input port function (pullup MOS on) is set as the initial pin function, and the corresponding pin levels are read.
PCDR retains its previous value in standby mode and sleep mode, and in a manual reset.
Table 19.6 Port C Data Register (PCDR) Read/Write Operations
PCnMD1
PCnMD0
Pin State
Read
Write
0
0
Other function
(see table 18.1)
PCDR value
Value is written to PCDR, but does not
affect pin state
1
Output
PCDR value
Write value is output from pin
0
Input (Pull-up
MOS on)
Pin state
Value is written to PCDR, but does not
affect pin state
1
Input (Pull-up
MOS off)
Pin state
Value is written to PCDR, but does not
affect pin state
1
(n = 7 to 0)
Rev. 5.00, 09/03, page 592 of 760
19.5
Port D
Port D comprises a 6-bit input/output port and 2-bit input port with the pin configuration shown in
figure 19.4. Each pin has an input pull-up MOS, which is controlled by the port D control register
(PDCR) in the PFC.
PTD7 (input/output) / DACK1 (output)
PTD6 (input) / DREQ1 (input)
PTD5 (input/output) / DACK0 (output)
Port D
PTD4 (input) / DREQ0 (input)
PTD3 (input/output) / WAKEUP (output)
PTD2 (input/output) / RESETOUT (output)
PTD1 (input/output) / DRAK0 (output)
PTD0 (input/output) / DRAK1 (output)
Figure 19.4 Port D
19.5.1
Register Description
Table 19.7 summarizes the port D register.
Table 19.7 Port D Register
Name
Abbreviation
R/W
Initial Value
Address
Access Size
Port D data register
PDDR
R/W or R
B'0*0*0000
H'04000126
8
1
(H'A4000126)*
Notes: This register is located in area 1 of physical space. Therefore, when the cache is on, either
access this register from the P2 area of logical space or else make an appropriate setting
using the MMU so that this register is not cached.
* Means no value.
*1 When address translation by the MMU does not apply, the address in parentheses
should be used.
Rev. 5.00, 09/03, page 593 of 760
19.5.2
Port D Data Register (PDDR)
Bit:
7
6
5
4
3
2
1
0
PD7DT
PD6DT
PD5DT
PD4DT
PD3DT
PD2DT
PD1DT
PD0DT
0
*
0
*
0
0
0
0
R/W
R
R/W
R
R/W
R/W
R/W
R/W
Initial value:
R/W:
Note: * Undefined
The port D data register (PDDR) is a 6-bit readable/writable and 2-bit read-only register that stores
data for pins PTD7 to PTD0. Bits PD7DT to PD0DT correspond to pins PTD7 to PTD0. When the
pin function is general output port, if the port is read, the value of the corresponding PDDR bit is
returned directly. When the function is general input port, if the port is read, the corresponding pin
level is read. Table 19.8 shows the function of PDDR.
PDDR is initialized to B'0*0*0000 by a power-on reset. After initialization, the general input port
function (pull-up MOS on) is set as the initial pin function, and the corresponding pin levels are
read from bits PD7DT—PD3DT, PD1DT, and PD0DT. PDDR retains its previous value in
standby mode and sleep mode, and in a manual reset.
Note that the low level is read if bits 6 and 4 are read except in general-purpose input.
Table 19.8 Port D Data Register (PDDR) Read/Write Operations
PDnMD1
PDnMD0
Pin State
Read
Write
0
0
Other function
(see table 18.1)
PDDR value
Value is written to PDDR, but does not
affect pin state
1
Output
PDDR value
Write value is output from pin
0
Input (Pull-up
MOS on)
Pin state
Value is written to PDDR, but does not
affect pin state
1
Input (Pull-up
MOS off)
Pin state
Value is written to PDDR, but does not
affect pin state
1
(n = 0, 1, 2, 3, 5, 7)
PDnMD1
PDnMD0
Pin State
Read
Write
0
0
Other function
(see table 18.1)
Low level
Ignored (no effect on pin state)
1
Reserved
Low level
Ignored (no effect on pin state)
0
Input (Pull-up
MOS on)
Pin state
Ignored (no effect on pin state)
1
Input (Pull-up
MOS off)
Pin state
Ignored (no effect on pin state)
1
(n = 4, 6)
Rev. 5.00, 09/03, page 594 of 760
19.6
Port E
Port E is an 8-bit input/output port with the pin configuration shown in figure 19.5. Each pin has
an input pull-up MOS, which is controlled by the port E control register (PECR) in the PFC.
PTE7 (input/output) / AUDSYNC (output)
PTE6 (input/output)
PTE5 (input/output) / CE2B (output)
Port E
PTE4 (input/output) / CE2A (output)
PTE3 (input/output)
PTE2 (input/output) / RAS3U (output)
PTE1 (input/output)
PTE0 (input/output) / TDO (output)
Figure 19.5 Port E
19.6.1
Register Description
Table 19.9 summarizes the port E register.
Table 19.9 Port E Register
Name
Abbreviation
R/W
Initial Value
Address
Access Size
Port E data register
PEDR
R/W
H'00
H'04000128
(H'A4000128)*
8
Notes: This register is located in area 1 of physical space. Therefore, when the cache is on, either
access this register from the P2 area of logical space or else make an appropriate setting
using the MMU so that this register is not cached.
* When address translation by the MMU does not apply, the address in parentheses
should be used.
Rev. 5.00, 09/03, page 595 of 760
19.6.2
Port E Data Register (PEDR)
Bit:
7
6
5
4
3
2
1
0
PE7DT
PE6DT
PE5DT
PE4DT
PE3DT
PE2DT
PE1DT
PE0DT
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Initial value:
R/W:
The port E data register (PEDR) is an 8-bit readable/writable register that stores data for pins
PTE7 to PTE0. Bits PE7DT to PE0DT correspond to pins PTE7 to PTE0. When the pin function is
general output port, if the port is read the value of the corresponding PEDR bit is returned directly.
When the function is general input port, if the port is read the corresponding pin level is read.
Table 19.10 shows the function of PEDR.
PEDR is initialized to H'00 by a power-on reset, after which the general input port function (pullup MOS on) is set as the initial pin function, and the corresponding pin levels are read. It retains
its previous value in standby mode and sleep mode, and in a manual reset.
Table 19.10 Port E Data Register (PEDR) Read/Write Operations
PEnMD1
PEnMD0
Pin State
Read
Write
0
0
Other function
(see table 18.1)
PEDR value
Value is written to PEDR, but does not
affect pin state
1
Output
PEDR value
Write value is output from pin
0
Input (Pull-up
MOS on)
Pin state
Value is written to PEDR, but does not
affect pin state
1
Input (Pull-up
MOS off)
Pin state
Value is written to PEDR, but does not
affect pin state
1
(n = 0 to 7)
Rev. 5.00, 09/03, page 596 of 760
19.7
Port F
Port F is an 8-bit input port with the pin configuration shown in figure 19.6. Each pin has an input
pull-up MOS, which is controlled by the port F control register (PFCR) in the PFC.
PTF7 (input) / PINT15 (input) / TRST (input)
PTF6 (input) / PINT14 (input) / TMS (input)
PTF5 (input) / PINT13 (input) / TDI (input)
Port F
PTF4 (input) / PINT12 (input) / TCK (input)
PTF3 (input) / PINT11 (input) / IRLS3 (input)
PTF2 (input) / PINT10 (input) / IRSL2 (input)
PTF1 (input) / PINT9 (input) / IRLS1 (input)
PTF0 (input) / PINT8 (input) / IRLS0 (input)
Figure 19.6 Port F
19.7.1
Register Description
Table 19.11 summarizes the port F register.
Table 19.11 Port F Register
Name
Abbreviation
R/W
Initial Value
Address
Access Size
Port F data register
PFDR
R
H'**
H'0400012A
8
1
(H'A400012A)*
Notes: This register is located in area 1 of physical space. Therefore, when the cache is on, either
access this register from the P2 area of logical space or else make an appropriate setting
using the MMU so that this register is not cached.
* Means no value.
*1 When address translation by the MMU does not apply, the address in parentheses
should be used.
Rev. 5.00, 09/03, page 597 of 760
19.7.2
Port F Data Register (PFDR)
Bit:
7
6
5
4
3
2
1
0
PF7DT
PF6DT
PF5DT
PF4DT
PF3DT
PF2DT
PF1DT
PF0DT
Initial value:
*
*
*
*
*
*
*
*
R/W:
R
R
R
R
R
R
R
R
Note: * Undefined
The port F data register (PFDR) is an 8-bit read-only register that stores data for pins PTF7 to
PTF0. Bits PF7DT to PF0DT correspond to pins PTF7 to PTF0. When the function is general
input port, if the port is read the corresponding pin level is read. Table 19.12 shows the function of
PFDR.
PFDR is initialized by a power-on reset, after which the general input port function (pull-up MOS
on) is set as the initial pin function, and the corresponding pin levels are read.
Table 19.12 Port F Data Register (PFDR) Read/Write Operations
PFnMD1
PFnMD0
Pin State
Read
Write
0
0
Other function
(see table 18.1)
H'00
Ignored (no effect on pin state)
1
Reserved
H'00
Ignored (no effect on pin state)
1
0
Input (Pull-up
MOS on)
Pin state
Ignored (no effect on pin state)
1
Input (Pull-up
MOS off)
Pin state
Ignored (no effect on pin state)
(n = 0 to 7)
Rev. 5.00, 09/03, page 598 of 760
19.8
Port G
Port G comprises a 5-bit input/output port and 3-bit input port with the pin configuration shown in
figure 19.7. Each pin has an input pull-up MOS, which is controlled by the port G control register
(PGCR) in the PFC.
PTG7 (input) / IOIS16 (input)
PTG6 (input) / ASEMD0 (input)
PTG5 (input) / ASEBRKAK (output)
Port G
PTG4 (input) / CKIO2 (output)
PTG3 (input) / AUDATA3 (input/output)
PTG2 (input) / AUDATA2 (input/output)
PTG1 (input) / AUDATA1 (input/output)
PTG0 (input) / AUDATA0 (input/output)
Figure 19.7 Port G
19.8.1
Register Description
Table 19.13 summarizes the port G register.
Table 19.13 Port G Register
Name
Abbreviation
R/W
Initial Value
Address
Access Size
Port G data register
PGDR
R/W
H'**
H'0400012C
8
1
(H'A400012C)*
Notes: This register is located in area 1 of physical space. Therefore, when the cache is on, either
access this register from the P2 area of logical space or else make an appropriate setting
using the MMU so that this register is not cached.
* Means no value.
*1 When address translation by the MMU does not apply, the address in parentheses
should be used.
Rev. 5.00, 09/03, page 599 of 760
19.8.2
Port G Data Register (PGDR)
Bit:
7
6
5
4
3
2
1
0
PG7DT
PG6DT
PG5DT
PG4DT
PG3DT
PG2DT
PG1DT
PG0DT
Initial value:
*
*
*
*
*
*
*
*
R/W:
R
R
R
R
R
R
R
R
Note: * Undefined
The port G data register (PGDR) is an 8-bit read-only register that stores data for pins PTG7 to
PTG0. Bits PG7DT to PG0DT correspond to pins PTG7 to PTG0. When the function is general
input port, if the port is read the corresponding pin level is read. Table 19.14 shows the function of
PGDR.
PGDR is initialized by a power-on reset, after which the general input port function (pull-up MOS
on) is set as the initial pin function, and the corresponding pin levels are read.
Table 19.14 Port G Data Register (PGDR) Read/Write Operations
PGnMD1
PGnMD0
Pin State
Read
Write
0
0
Other function
(see table 18.1)
H'00
Ignored (no effect on pin state)
1
Reserved
H'00
Ignored (no effect on pin state)
1
0
Input (Pull-up
MOS on)
Pin state
Ignored (no effect on pin state)
1
Input (Pull-up
MOS off)
Pin state
Ignored (no effect on pin state)
(n = 0 to 7)
Rev. 5.00, 09/03, page 600 of 760
19.9
Port H
Port H comprises a 1-bit input/output port and 7-bit input port with the pin configuration shown in
figure 19.8. Each pin has an input pull-up MOS, which is controlled by the port H control register
(PHCR) in the PFC.
PTH7 (input/output) / TCLK (output)
PTH6 (input) / AUDCK (input)
PTH5 (input) / ADTRG (input)
Port H
PTH4 (input) / IRQ4 (input)
PTH3 (input) / IRQ3 (input)
PTH2 (input) / IRQ2 (input)
PTH1 (input) / IRQ1 (input)
PTH0 (input) / IRQ0 (input)
Figure 19.8 Port H
19.9.1
Register Description
Table 19.15 summarizes the port H register.
Table 19.15 Port H Register
Name
Abbreviation
R/W
Initial Value
Port H data register
PHDR
R/W or R B'0*******
Address
Access Size
H'0400012E
8
1
(H'A400012E)*
Notes: This register is located in area 1 of physical space. Therefore, when the cache is on, either
access this register from the P2 area of logical space or else make an appropriate setting
using the MMU so that this register is not cached.
* Means no value.
*1 When address translation by the MMU does not apply, the address in parentheses
should be used.
Rev. 5.00, 09/03, page 601 of 760
19.9.2
Port H Data Register (PHDR)
Bit:
7
6
5
4
3
2
1
0
PH7DT
PH6DT
PH5DT
PH4DT
PH3DT
PH2DT
PH1DT
PH0DT
0
*
*
*
*
*
*
*
R/W
R
R
R
R
R
R
R
Initial value:
R/W:
Note: * Undefined
The port H data register (PHDR) is a 1-bit readable/writable and 7-bit read-only register that stores
data for pins PTH7 to PTH0. Bits PH7DT to PH0DT correspond to pins PTH7 to PTH0. When the
pin function is general output port, if the port is read, the value of the corresponding PHDR bit is
returned directly. When the function is general input port, if the port is read, the corresponding pin
level is read. Table 19.16 shows the function of PHDR.
PHDR is initialized to B'0******* by a power-on reset, after which the general input port function
(pull-up MOS on) is set as the initial pin function, and the corresponding pin levels are read. It
retains its previous value in standby mode and sleep mode, and in a manual reset.
Note that the low level is read if bits 6 to 0 are read except in general-purpose input.
Table 19.16 Port H Data Register (PHDR) Read/Write Operations
PHnMD1
PHnMD0
Pin State
Read
Write
0
0
Other function
(see table 18.1)
PHDR value
Value is written to PHDR, but does not
affect pin state
1
Output
PHDR value
Write value is output from pin
0
Input (Pull-up
MOS on)
Pin state
Value is written to PHDR, but does not
affect pin state
1
Input (Pull-up
MOS off)
Pin state
Value is written to PHDR, but does not
affect pin state
1
(n = 7)
PHnMD1
PHnMD0
Pin State
Read
Write
0
0
Other function
(see table 18.1)
Low level
Ignored (no effect on pin state)
1
Reserved
Low level
Ignored (no effect on pin state)
1
0
Input (Pull-up
MOS on)
Pin state
Ignored (no effect on pin state)
1
Input (Pull-up
MOS off)
Pin state
Ignored (no effect on pin state)
(n = 0 to 6)
Rev. 5.00, 09/03, page 602 of 760
19.10
Port J
Port J is an 8-bit input/output port with the pin configuration shown in figure 19.9. Each pin has
an input pull-up MOS, which is controlled by the port J control register (PJCR) in the PFC.
PTJ7 (input/output) / STATUS1 (output)
PTJ6 (input/output) / STATUS0 (output)
PTJ5 (input/output)
Port J
PTJ4 (input/output)
PTJ3 (input/output) / CASU (output)
PTJ2 (input/output) / CASL (output)
PTJ1 (input/output)
PTJ0 (input/output) / RAS3L (output)
Figure 19.9 Port J
19.10.1 Register Description
Table 19.17 summarizes the port J register.
Table 19.17 Port J Register
Name
Abbreviation
R/W
Initial Value
Address
Access Size
Port J data register
PJDR
R/W
H'00
H'04000130
(H'A4000130)*
8
Notes: This register is located in area 1 of physical space. Therefore, when the cache is on, either
access this register from the P2 area of logical space or else make an appropriate setting
using the MMU so that this register is not cached.
* When address translation by the MMU does not apply, the address in parentheses
should be used.
Rev. 5.00, 09/03, page 603 of 760
19.10.2 Port J Data Register (PJDR)
Bit:
Initial value:
R/W:
7
6
5
4
3
2
1
0
PJ7DT
PJ6DT
PJ5DT
PJ4DT
PJ3DT
PJ2DT
PJ1DT
PJ0DT
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
The port J data register (PJDR) is an 8-bit readable/writable register that stores data for pins PTJ7
to PTJ0. Bits PJ7DT to PJ0DT correspond to pins PTJ7 to PTJ0. When the pin function is general
output port, if the port is read the value of the corresponding PJDR bit is returned directly. When
the function is general input port, if the port is read, the corresponding pin level is read. Table
19.18 shows the function of PJDR.
PJDR is initialized to H'00 by a power-on reset. It retains its previous value in software standby
mode and sleep mode, and in a manual reset.
Table 19.18 Port J Data Register (PJDR) Read/Write Operations
PJnMD1
PJnMD0
Pin State
Read
Write
0
0
Other function
(see table 18.1)
PJDR value
Value is written to PJDR, but does not
affect pin state
1
Output
PJDR value
Write value is output from pin
1
0
Input (Pull-up
MOS on)
Pin state
Value is written to PJDR, but does not
affect pin state
1
Input (Pull-up
MOS off)
Pin state
Value is written to PJDR, but does not
affect pin state
(n = 0 to 7)
Rev. 5.00, 09/03, page 604 of 760
19.11
Port K
Port K is an 8-bit input/output port with the pin configuration shown in figure 19.10. Each pin has
an input pull-up MOS, which is controlled by the port K control register (PKCR) in the PFC.
PTK7 (input/output) / WE3 (output) / DQMUU (output) / ICIOWR (output)
PTK6 (input/output) / WE2 (output) / DQMUL (output) / ICIORD (output)
PTK5 (input/output) / CKE (output)
Port K
PTK4 (input/output) / BS (output)
PTK3 (input/output) / CS5 (output) / CE1A (output)
PTK2 (input/output) / CS4 (output)
PTK1 (input/output) / CS3 (output)
PTK0 (input/output) / CS2 (output)
Figure 19.10 Port K
19.11.1 Register Description
Table 19.19 summarizes the port K register.
Table 19.19 Port K Register
Name
Abbreviation
R/W
Initial Value
Address
Access Size
Port K data register
PKDR
R/W
H'00
H'04000132
(H'A4000132)*
8
Notes: This register is located in area 1 of physical space. Therefore, when the cache is on, either
access this register from the P2 area of logical space or else make an appropriate setting
using the MMU so that this register is not cached.
* When address translation by the MMU does not apply, the address in parentheses
should be used.
Rev. 5.00, 09/03, page 605 of 760
19.11.2 Port K Data Register (PKDR)
Bit:
7
6
5
4
3
2
1
0
PK7DT
PK6DT
PK5DT
PK4DT
PK3DT
PK2DT
PK1DT
PK0DT
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Initial value:
R/W:
The port K data register (PKDR) is an 8-bit readable/writable register that stores data for pins
PTK7 to PTK0. Bits PK7DT to PK0DT correspond to pins PTK7 to PTK0. When the pin function
is general output port, if the port is read, the value of the corresponding PKDR bit is returned
directly. When the function is general input port, if the port is read, the corresponding pin level is
read. Table 19.20 shows the function of PKDR.
PKDR is initialized to H'00 by a power-on reset. It retains its previous value in standby mode and
sleep mode, and in a manual reset.
Table 19.20 Port K Data Register (PKDR) Read/Write Operations
PKnMD1
PKnMD0
Pin State
Read
Write
0
0
Other function
(see table 18.1)
PKDR value
Value is written to PKDR, but does not
affect pin state
1
Output
PKDR value
Write value is output from pin
1
0
Input (Pull-up
MOS on)
Pin state
Value is written to PKDR, but does not
affect pin state
1
Input (Pull-up
MOS off)
Pin state
Value is written to PKDR, but does not
affect pin state
(n = 0 to 7)
Rev. 5.00, 09/03, page 606 of 760
19.12
Port L
Port L is an 8-bit input port with the pin configuration shown in figure 19.11.
PTL7 (input) / AN7 (input) / DA0 (input)
PTL6 (input) / AN6 (input) / DA1 (input)
PTL5 (input) / AN5 (input)
PTL4 (input) / AN4 (input)
Port L
PTL3 (input) / AN3 (input)
PTL2 (input) / AN2 (input)
PTL1 (input) / AN1 (input)
PTL0 (input) / AN0 (input)
Figure 19.11 Port L
19.12.1 Register Description
Table 19.21 summarizes the port L register.
Table 19.21 Port L Register
Name
Abbreviation
R/W
Initial Value
Address
Access Size
Port L data register
PLDR
R
H'00
H'04000134
(H'A4000134)*
8
Notes: This register is located in area 1 of physical space. Therefore, when the cache is on, either
access this register from the P2 area of logical space or else make an appropriate setting
using the MMU so that this register is not cached.
* When address translation by the MMU does not apply, the address in parentheses
should be used.
Rev. 5.00, 09/03, page 607 of 760
19.12.2 Port L Data Register (PLDR)
Bit:
7
6
5
4
3
2
1
0
PL7DT
PL6DT
PL5DT
PL4DT
PL3DT
PL2DT
PL1DT
PL0DT
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R
R
R
R
R
R
R
The port L data register (PLDR) is an 8-bit read-only register that stores data for pins PTL7 to
PTL0. Bits PL7DT to PL0DT correspond to pins PTL7 to PTL0. When the function is general
input port, if the port is read, the corresponding pin level is read. Table 19.22 shows the function
of PLDR.
PKDR is initialized to H'00 by power-on reset. It retains its previous value in software standby
mode and sleep mode, and in a manual reset.
The port L is also used as an analog pin, therefore does not have a pull-up MOS.
Table 19.22 Port L Data Register (PLDR) Read/Write Operation
PLnMD1
PLnMD0
Pin State
Read
Write
0
0
Other function
(see table 18.1)
H'00
Ignored (no effect on pin state)
1
Reserved
H'00
Ignored (no effect on pin state)
0
Input
Pin state
Ignored (no effect on pin state)
1
Input
Pin state
Ignored (no effect on pin state)
1
(n = 0 to 7)
Rev. 5.00, 09/03, page 608 of 760
19.13
SC Port
The SC port comprises a 4-bit input/output port, 3-bit output port, and 4-bit input port with the pin
configuration shown in figure 19.12. Each pin has an input pull-up MOS, which is controlled by
the SC port control register (SCPCR) in the PFC.
SCPT7 (input) / CTS2 (input) / IRQ5 (input)
SCPT6 (input/output) / RTS2 (output)
SCPT5 (input/output) / SCK2 (input/output)
SCPT4 (input) / RxD2 (input)
SCPT4 (output) / TxD2 (output)
SC Port
SCPT3 (input/output) / SCK1 (input/output)
SCPT2 (input) / RxD1 (input)
SCPT2 (output) / TxD1 (output)
SCPT1 (input/output) / SCK0 (input/output)
SCPT0 (input) / RxD0 (input)
SCPT0 (output) / TxD0 (output)
Figure 19.12 SC Port
19.13.1 Register Description
Table 19.23 summarizes the SC port register.
Table 19.23 SC Port Register
Name
Abbreviation
R/W
Initial Value
Address
Access Size
SC Port data register
SCPDR
R/W or R
B'*0000000
H'04000136
8
1
(H'A4000136)*
Notes: This register is located in area 1 of physical space. Therefore, when the cache is on, either
access this register from the P2 area of logical space or else make an appropriate setting
using the MMU so that this register is not cached.
* Means no value.
*1 When address translation by the MMU does not apply, the address in parentheses
should be used.
Rev. 5.00, 09/03, page 609 of 760
19.13.2 SC Port Data Register (SCPDR)
Bit:
7
6
5
4
3
2
1
0
SCP7DT SCP6DT SCP5DT SCP4DT SCP3DT SCP2DT SCP1DT SCP0DT
Initial value:
*
0
0
0
0
0
0
0
R/W:
R
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Note: * Undefined
The SC port data register (SCPDR) is a 7-bit readable/writable and 1-bit read-only register that
stores data for pins SCPT7 to SCPT0. Bits SCP7DT to SCP0DT correspond to pins SCPT7 to
SCPT0. When the pin function is general output port, if the port is read, the value of the
corresponding SCPDR bit is returned directly. When the function is general input port, if the port
is read, the corresponding pin level is read. Table 19.24 shows the function of SCPDR.
SCPDR is initialized to B'*0000000 by a power-on reset. After initialization, the general input
port function (pull-up MOS on) is set as the initial pin function, and the corresponding pin levels
are read from bits SCP7DT—SCP5DT, SCP3DT, and SCP1DT. SCPDR retains its previous
value in standby mode and sleep mode, and in a manual reset.
Note that the low level is read if bit 7 is read except in general-purpose input.
When the pin states of the RxD2 to RxD0 of the SCP4DT, SCP2DT, and SCP0DT bits in SCPDR
are read while the TE and RE bits in SCSCR are not cleared to 0, the RE bit in SCSCR should be
set to 1. When the RE bit is set to 1, the RxD pins become an input state and their pin states can be
read prior to the SCPCR setting.
Rev. 5.00, 09/03, page 610 of 760
Table 19.24 Read/Write Operation of the SC Port Data Register (SCPDR)
SCPnMD1
SCPnMD0
Pin State
Read
Write
0
0
Other function
(see table 18.1)
SCPDR value
Value is written to SCPDR, but does
not affect pin state
1
Output
SCPDR value
Write value is output from pin
0
Input (Pull-up
MOS on)
Pin state
Value is written to SCPDR, but does
not affect pin state
1
Input (Pull-up
MOS off)
Pin state
Value is written to SCPDR, but does
not affect pin state
1
(n = 0 to 6)
SCPnMD1
SCPnMD0
Pin State
Read
Write
0
0
Other function
(see table 18.1)
Low level
Ignored (no effect on pin state)
1
Output
Low level
Ignored (no effect on pin state)
0
Input (Pull-up
MOS on)
Pin state
Ignored (no effect on pin state)
1
Input (Pull-up
MOS off)
Pin state
Ignored (no effect on pin state)
1
(n = 7)
Rev. 5.00, 09/03, page 611 of 760
Rev. 5.00, 09/03, page 612 of 760
Section 20 A/D Converter
20.1
Overview
The SH7709S includes a 10-bit successive-approximation A/D converter allowing selection of up
to eight analog input channels.
20.1.1
Features
A/D converter features are listed below.
• 10-bit resolution
• Eight input channels
• High-speed conversion
 Conversion time: maximum 15 µs per channel (Pφ = 33 MHz operation)
• Three conversion modes
 Single mode: A/D conversion on one channel
 Multi mode: A/D conversion on one to four channels
 Scan mode: Continuous A/D conversion on one to four channels
• Four 16-bit data registers
 A/D conversion results are transferred for storage into data registers corresponding to the
channels.
• Sample-and-hold function
• A/D conversion can be externally triggered
• A/D interrupt requested at the end of conversion
 At the end of A/D conversion, an A/D end interrupt (ADI) can be requested.
Rev. 5.00, 09/03, page 613 of 760
20.1.2
Block Diagram
Bus interface
Figure 20.1 shows a block diagram of the A/D converter.
Internal
data bus
ADCR
ADCSR
ADDRD
AVSS
ADDRC
10-bit
D/A
ADDRB
AVCC
ADDRA
Successive approximation register
Peripheral data bus
AN0
AN1
+
AN2
AN3
AN4
AN5
AN6
AN7
−
Analog
multiplexer
φ/8
Control circuit
φ/16
Comparator
Sample-andhold circuit
ADI
interrupt
signal
ADTRG
A/D converter
Legend
ADCR: A/D control register
ADCSR: A/D control/status register
ADDRA: A/D data register A
ADDRB: A/D data register B
ADDRC: A/D data register C
ADDRD: A/D data register D
Figure 20.1 Block Diagram of A/D Converter
Rev. 5.00, 09/03, page 614 of 760
20.1.3
Input Pins
Table 20.1 summarizes the A/D converter’s input pins. The eight analog input pins are divided
into two groups: group 0 (AN0 to AN3), and group 1 (AN4 to AN7). AVCC and AVSS are the
power supply inputs for the analog circuits in the A/D converter. AVcc also functions as the A/D
converter reference voltage pin.
Table 20.1 A/D Converter Pins
Pin Name
Abbreviation
I/O
Function
Analog power supply pin
AVcc
Input
Analog power supply
Analog ground pin
AVss
Input
Analog ground and reference voltage
Group 0 analog inputs
Analog input pin 0
AN0
Input
Analog input pin 1
AN1
Input
Analog input pin 2
AN2
Input
Analog input pin 3
AN3
Input
Analog input pin 4
AN4
Input
Analog input pin 5
AN5
Input
Analog input pin 6
AN6
Input
Analog input pin 7
AN7
Input
A/D external trigger input
pin
ADTRG
Input
Group1 analog inputs
External trigger input for starting A/D
conversion
Rev. 5.00, 09/03, page 615 of 760
20.1.4
Register Configuration
Table 20.2 summarizes the A/D converter’s registers.
Table 20.2 A/D Converter Registers
Name
Abbreviation
R/W
Initial Value
Address
A/D data register AH
ADDRAH
R
H'00
H'04000080
16, 8
2
(H'A4000080)*
A/D data register AL
ADDRAL
R
H'00
H'04000082
8
2
(H'A4000082)*
A/D data register BH
ADDRBH
R
H'00
H'04000084
16, 8
2
(H'A4000084)*
A/D data register BL
ADDRBL
R
H'00
H'04000086
8
2
(H'A4000086)*
A/D data register CH
ADDRCH
R
H'00
H'04000088
16, 8
2
(H'A4000088)*
A/D data register CL
ADDRCL
R
H'00
H'0400008A
8
2
(H'A400008A)*
A/D data register DH
ADDRDH
R
H'00
H'0400008C
16, 8
2
(H'A400008C)*
A/D data register DL
ADDRDL
R
H'00
H'0400008E
8
2
(H'A400008E)*
A/D control/status register
ADCSR
1
R/(W)* H'00
H'04000090
8
2
(H'A4000090)*
A/D control register
ADCR
R/W
H'04000092
8
2
(H'A4000092)*
H'07
Access size
Notes: These registers are located in area 1 of physical space. Therefore, when the cache is on,
either access these registers from the P2 area of logical space or else make an appropriate
setting using the MMU so that these registers are not cached.
1. Only 0 can be written to bit 7, to clear the flag.
2. When address translation by the MMU does not apply, the address in parentheses
should be used.
Rev. 5.00, 09/03, page 616 of 760
20.2
Register Descriptions
20.2.1
A/D Data Registers A to D (ADDRA to ADDRD)
Upper register: H
Bit:
7
6
5
4
3
2
1
0
AD9
AD8
AD7
AD6
AD5
AD4
AD3
AD2
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R
R
R
R
R
R
R
7
6
5
4
3
2
1
0
AD1
AD0
—
—
—
—
—
—
Initial value:
0
0
0
0
0
0
0
0
R/W:
R
R
R
R
R
R
R
R
Lower register: L
Bit:
n = A to D
The four A/D data registers (ADDRA to ADDRD) are 16-bit read-only registers that store the
results of A/D conversion.
An A/D conversion produces 10-bit data, which is transferred for storage into the A/D data
register corresponding to the selected channel. The upper 8 bits of the result are stored in the upper
byte (bits 7 to 0) of the A/D data register. The lower 2 bits are stored in the lower byte (bits 7 and
6). Bits 5 to 0 of an A/D data register are reserved bits that are always read as 0. Table 20.3
indicates the pairings of analog input channels and A/D data registers.
The A/D data registers are initialized to H'0000 by a reset and in standby mode.
Table 20.3 Analog Input Channels and A/D Data Registers
Analog Input Channel
Group 0
Group 1
A/D Data Register
AN0
AN4
ADDRA
AN1
AN5
ADDRB
AN2
AN6
ADDRC
AN3
AN7
ADDRD
Rev. 5.00, 09/03, page 617 of 760
20.2.2
A/D Control/Status Register (ADCSR)
Bit:
Initial value:
R/W:
7
6
5
4
3
2
1
0
ADF
ADIE
ADST
MULTI
CKS
CH2
CH1
CH0
0
0
0
0
0
0
0
0
R/(W)*
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Note: * Write 0 to clear the flag.
ADCSR is an 8-bit readable/writable register that selects the mode and controls the A/D converter.
ADCSR is initialized to H'00 by a reset and in standby mode.
Bit 7—A/D End Flag (ADF): Indicates the end of A/D conversion.
Bit 7: ADF
Description
0
[Clearing conditions]
(Initial value)
(1) Cleared by reading ADF while ADF = 1, then writing 0 to ADF
(2) Cleared when DMAC is activated by ADI interrupt and ADDR is read
1
[Setting conditions]
(1) Single mode: A/D conversion ends
(2) Multi mode: A/D conversion ends on all selected channels
(3) Scan mode: A/D conversion ends on all selected channels
Bit 6—A/D Interrupt Enable (ADIE): Enables or disables the interrupt (ADI) requested at the
end of A/D conversion. The ADIE bit should be set while the A/D conversion stops.
Bit 6: ADIE
Description
0
A/D end interrupt request (ADI) is disabled
1
A/D end interrupt request (ADI) is enabled
Rev. 5.00, 09/03, page 618 of 760
(Initial value)
Bit 5—A/D Start (ADST): Starts or stops A/D conversion. The ADST bit remains set to 1 during
A/D conversion. It can also be set to 1 by external trigger input at the ADTRG pin.
Bit 5: ADST
Description
0
A/D conversion is stopped
1
(1) Single mode: A/D conversion starts; ADST is automatically cleared to 0 when
conversion ends
(Initial value)
(2) Multi mode: A/D conversion starts; ADST is automatically cleared to 0 when
conversion ends on all selected channels
(3) Scan mode: A/D conversion starts and continues, cycling through the selected
channels, until ADST is cleared to 0 by software, by a reset, or by a transition
to standby mode
Bit 4—Multi Mode (MULTI): Selects single mode, multi mode or scan mode. For further
information on operation in these modes, see section 20.4, Operation.
Bit 4: MULTI
ADCR: Bit5: SCN Description
0
0
Single mode
(Initial value)
1
1
0
Multi mode
1
Scan mode
Bit 3—Clock Select (CKS): Selects the A/D conversion time. Clear the ADST bit to 0 before
changing the conversion time.
Bit 3:CKS
Description
0
Conversion time = 536 states (maximum)
1
Conversion time = 266 states (maximum)
(Initial value)
Rev. 5.00, 09/03, page 619 of 760
Bits 2 to 0—Channel Select 2 to 0 (CH2 to CH0): These bits and the MULTI bit select the
analog input channels. Clear the ADST bit to 0 before changing the channel selection.
Channel Selection
Description
CH2
CH1
CH0
Single Mode
(MULTI = 0)
Multi Mode and Scan
Mode (MULTI = 1)
0
0
0
AN0 (Initial value)
AN0
1
AN1
AN0, AN1
0
AN2
AN0 to AN2
1
AN3
AN0 to AN3
0
AN4
AN4
1
AN5
AN4, AN5
1
1
0
1
0
AN6
AN4 to AN6
1
AN7
AN4 to AN7
Rev. 5.00, 09/03, page 620 of 760
20.2.3
A/D Control Register (ADCR)
Bit:
7
6
5
TRGE1
TRGE0
SCN
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
Initial value:
R/W:
4
3
RESVD1 RESVD2
2
1
0
—
—
—
1
1
1
R
R
R
ADCR is an 8-bit readable/writable register that enables or disables external triggering of A/D
conversion. ADCR is initialized to H'07 by a reset and in standby mode.
Bit 7 and 6—Trigger Enable (TRGE1, TRGE0): Enables or disables external triggering of A/D
conversion.
The TRGE1 and TRGE0 bits should only be set when conversion is not in progress.
Bit 7: TRGE1
Bit 6: TRGE0
Description
0
0
A/D conversion does not start when an external trigger is input
0
1
1
0
1
1
(Initial value)
A/D conversion starts at the falling edge of an input signal from
the external trigger pin (ADTRG)
Bit 5—Scan Mode (SCN): Selects multi mode or scan mode when the MULTI bit is set to 1. See
the description of bit 4 in section 20.2.2, A/D Control/Status Register (ADCSR).
Bits 4 and 3—Reserved (RESVD1, RESVD2): These bits are always read as 0. The write value
should always be 0.
Bits 2 to 0—Reserved: These bits are always read as 1. The write value should always be 1.
Rev. 5.00, 09/03, page 621 of 760
20.3
Bus Master Interface
ADDRA to ADDRD are 16-bit registers, but they are connected to the bus master by the upper 8
bits of the 16-bit peripheral data bus. Therefore, although the upper byte can be accessed directly
by the bus master, the lower byte is read through an 8-bit temporary register (TEMP).
An A/D data register is read as follows. When the upper byte is read, the upper-byte value is
transferred directly to the bus master and the lower-byte value is transferred into TEMP. Next,
when the lower byte is read, the TEMP contents are transferred to the bus master.
When reading an A/D data register, always read the upper byte before the lower byte. It is possible
to read only the upper byte, but if only the lower byte is read, the read value is not guaranteed.
Figure 20.2 shows the data flow for access to an A/D data register.
See section 20.7.3, Access Size and Read Data.
Upper byte read
CPU
(H'AA)
Module internal data bus
Bus
interface
TEMP
[H'40]
ADDRn H
[H'AA]
ADDRn L
[H'40]
Lower byte read
CPU
(H'40)
Module internal data bus
Bus
interface
TEMP
[H'40]
ADDRn H
[H'AA]
ADDRn L
[H'40]
n = A to D
Figure 20.2 A/D Data Register Access Operation (Reading H'AA40)
Rev. 5.00, 09/03, page 622 of 760
20.4
Operation
The A/D converter operates by successive approximations with 10-bit resolution. It has three
operating modes: single mode, multi mode, and scan mode.
20.4.1
Single Mode (MULTI = 0)
Single mode should be selected when only one A/D conversion on one channel is required. A/D
conversion starts when the ADST bit is set to 1 by software, or by external trigger input. The
ADST bit remains set to 1 during A/D conversion and is automatically cleared to 0 when
conversion ends.
When conversion ends the ADF bit is set to 1. If the ADIE bit is also set to 1, an ADI interrupt is
requested at this time. To clear the ADF bit to 0, first read ADF when ADF = 1, then write 0 to the
ADF bit.
When the mode or analog input channel must be switched during A/D conversion, to prevent
incorrect operation, first clear the ADST bit to 0 in ADCSR to halt A/D conversion. After making
the necessary changes, set the ADST bit to 1 to start A/D conversion again. The ADST bit can be
set at the same time as the mode or channel is changed.
Typical operations when channel 1 (AN1) is selected in single mode are described next.
Figure 20.3 shows a timing diagram for this example. (The ADCSR register specifies bits in the
operation example.)
1. Single mode is selected (MULTI = 0), input channel AN1 is selected (CH2 = CH1 = 0, CH0 =
1), the A/D interrupt is enabled (ADIE = 1), and A/D conversion is started (ADST = 1).
2. When A/D conversion is completed, the result is transferred into ADDRB. At the same time
the ADF flag is set to 1, the ADST bit is cleared to 0, and the A/D converter becomes idle.
3. Since ADF = 1 and ADIE = 1, an ADI interrupt is requested.
4. The A/D interrupt handling routine starts.
5. The routine reads ADCSR, then writes 0 to the ADF flag.
6. The routine reads and processes the conversion result (ADDRB = 0).
7. Execution of the A/D interrupt handling routine ends. Then, when the ADST bit is set to 1,
A/D conversion starts and steps 2 to 7 are executed.
Rev. 5.00, 09/03, page 623 of 760
Note: * Vertical arrows ( ) indicate instruction execution by software.
Figure 20.3 Example of A/D Converter Operation (Single Mode, Channel 1 Selected)
Rev. 5.00, 09/03, page 624 of 760
Waiting
Waiting
Channel 3 (AN3)
operating
ADDRD
ADDRC
ADDRB
ADDRA
Set
Set
Waiting
A/D conversion 1
Waiting
Channel 2 (AN2)
operating
Channel 1 (AN1)
operating
Channel 0 (AN0)
operating
ADF
ADST A/D conversion starts
ADIE
Read result
A/D conversion result 1
Waiting
A/D conversion result 2
Clear*
Set
Read result
A/D conversion result 2
Waiting
Clear
20.4.2
Multi Mode (MULTI = 1, SCN = 0)
Multi mode should be selected when performing A/D conversions on one or more channels. When
the ADST bit is set to 1 by software or external trigger input, A/D conversion starts on the first
channel in the group (AN0 when CH2 = 0, AN4 when CH2 = 1). When two or more channels are
selected, after conversion of the first channel ends, conversion of the second channel (AN1 or
AN5) starts immediately. When A/D conversions end on the selected channels, the ADST bit is
cleared to 0. The conversion results are transferred for storage into the A/D data registers
corresponding to the channels.
When the mode or analog input channel selection must be changed during A/D conversion, to
prevent incorrect operation, first clear the ADST bit to 0 in ADCSR to halt A/D conversion. After
making the necessary changes, set the ADST bit to 1. A/D conversion will start again from the
first channel in the group. The ADST bit can be set at the same time as the mode or channel
selection is changed.
Typical operations when three channels in group 0 (AN0 to AN2) are selected in scan mode are
described next. Figure 20.4 shows a timing diagram for this example.
1. Multi mode is selected (MULTI = 1, SCN = 0), channel group 0 is selected (CH2 = 0), analog
input channels AN0 to AN2 are selected (CH1 = 1, CH0 = 0), and A/D conversion is started
(ADST = 1).
2. When A/D conversion of the first channel (AN0) is completed, the result is transferred into
ADDRA. Next, conversion of the second channel (AN1) starts automatically.
3. Conversion proceeds in the same way through the third channel (AN2).
4. When conversion of all selected channels (AN0 to AN2) is completed, the ADF flag is set to 1
and ADST bit is cleared to 0. If the ADIE bit is set to 1, an ADI interrupt is requested at this
time.
Rev. 5.00, 09/03, page 625 of 760
Note: * Vertical arrows ( ) indicate instruction execution by software.
Figure 20.4 Example of A/D Converter Operation (Multi Mode,
Channels AN0 to AN2 Selected)
Rev. 5.00, 09/03, page 626 of 760
Waiting
Waiting
Waiting
Channel 2 (AN2)
operating
Channel 3 (AN3)
operating
ADDRD
ADDRC
ADDRB
ADDRA
Set*
Waiting
Waiting
Clear
Waiting
Clear*
A/D conversion result 3
A/D conversion result 2
Transfer
A/D conversion result 1
A/D conversion 3
A/D conversion 2
Waiting
A/D conversion 1
Channel 1 (AN1)
operating
Channel 0 (AN0)
operating
ADF
ADST
A/D conversion
20.4.3
Scan Mode (MULTI = 1, SCN = 1)
Scan mode is useful for monitoring analog inputs in a group of one or more channels. When the
ADST bit in the A/D control/status register (ADCSR) is set to 1 by software or external trigger
input, A/D conversion starts on the first channel in the group (AN0 when CH2 = 0, AN4 when
CH2 = 1)). When two or more channels are selected, after conversion of the first channel ends,
conversion of the second channel (AN1 or AN5) starts immediately. A/D conversion continues
cyclically on the selected channels until the ADST bit is cleared to 0. The conversion results are
transferred for storage into the A/D data registers corresponding to the channels.
When the mode or analog input channel must be changed during analog conversion, to prevent
incorrect operation, first clear the ADST bit to 0 to halt A/D conversion. After making the
necessary changes, set the ADST bit to 1. A/D conversion will start again from the first channel
in the group. The ADST bit can be set at the same time as the mode or channel selection is
changed.
Typical operations when three channels (AN0 to AN2) in group 0 are selected in scan mode are
described next. Figure 20.5 shows a timing diagram for this example.
1. Scan mode is selected (MULTI = 1, SCN = 1), channel group 0 is selected (CH2 = 0), analog
input channels AN0 to AN2 are selected (CH1 = 1, CH0 = 0), and A/D conversion is started
(ADST = 1).
2. When A/D conversion of the first channel (AN0) is completed, the result is transferred into
ADDRA. Next, conversion of the second channel (AN1) starts automatically.
3. Conversion proceeds in the same way through the third channel (AN2).
4. When conversion of all the selected channels (AN0 to AN2) is completed, the ADF flag is set
to 1 and conversion of the first channel (AN0) starts again. If the ADIE bit is set to 1, an ADI
interrupt is requested at this time.
5. Steps 2 to 4 are repeated as long as the ADST bit remains set to 1. When the ADST bit is
cleared to 0, A/D conversion stops. After that, if the ADST bit is set to 1, A/D conversion
starts again from the first channel (AN0).
Rev. 5.00, 09/03, page 627 of 760
Figure 20.5 Example of A/D Converter Operation (Scan Mode,
Channels AN0 to AN2 Selected)
Rev. 5.00, 09/03, page 628 of 760
Waiting
Waiting
Waiting
Channel 1 (AN1)
operating
Channel 2 (AN2)
operating
Channel 3 (AN3)
operating
Notes: 1. Vertical arrows ( ) indicate instruction execution by software.
2. Data during conversion is ignored.
ADDRD
Waiting
Waiting
Waiting
Clear*1
A/D conversion result 4
A/D conversion 5
A/D conversion result 3
A/D conversion result 1
Waiting
A/D conversion 4
ADDRC
Transfer
A/D conversion 3
A/D conversion 2
Waiting
A/D conversion result 2
A/D conversion 1
Clear*1
ADDRB
ADDRA
Waiting
Channel 0 (AN0)
operating
ADF
ADST
Set*1
Continuous A/D conversion
20.4.4
Input Sampling and A/D Conversion Time
The A/D converter has a built-in sample-and-hold circuit. The A/D converter samples the analog
input at a time tD after the ADST bit is set to 1, then starts conversion. Figure 20.6 shows the A/D
conversion timing. Table 20.4 indicates the A/D conversion time.
As indicated in figure 20.6, the A/D conversion time includes tD and the input sampling time. The
length of tD varies depending on the timing of the write access to ADCSR. The total conversion
time therefore varies within the ranges indicated in table 20.4.
In multi mode and scan mode, the conversion time values given in table 20.4 apply to the first
conversion. In the second and subsequent conversions, the conversion time is fixed at 512 states
when CKS = 0 in ADCSR, or 256 states when CKS = 1. In both cases, the CKS bit should be set
according to the Pφ frequency so that the conversion time is within the range shown in table 23.10
in section 23, Electrical Characteristics.
*1
Pφ
Address
*2
Write
signal
Input sampling
timing
ADF
tD
tSPL
tCONV
Legend
tD
tSPL
tCONV
Notes:
A/D conversion start delay
Input sampling time
A/D conversion time
1. ADCSR write cycle
2. ADCSR address
Figure 20.6 A/D Conversion Timing
Rev. 5.00, 09/03, page 629 of 760
Table 20.4 A/D Conversion Time (Single Mode)
CKS = 0
CKS = 1
Symbol
Min
Typ
Max
Min
Typ
Max
A/D conversion start
delay
tD
17
—
28
10
—
17
Input sampling time
tSPL
—
129
—
—
65
—
A/D conversion time
tCONV
514
—
525
259
—
266
Note: Values in the table are numbers of states (tcyc).
20.4.5
External Trigger Input Timing
A/D conversion can be externally triggered. When the TRGE1 and TRGE0 bits are set to 1 in
ADCR, external trigger input is enabled at the ADTRG pin. A high-to-low transition at the
ADTRG pin sets the ADST bit to 1 in ADCSR, starting A/D conversion. Other operations,
regardless of the conversion mode, are the same as if the ADST bit had been set to 1 by software.
Figure 20.7 shows the timing.
Pφ
ADTRG
External
trigger signal
ADST
A/D conversion
Figure 20.7 External Trigger Input Timing
Rev. 5.00, 09/03, page 630 of 760
20.5
Interrupts
The A/D converter generates an interrupt (ADI) at the end of A/D conversion. The ADI interrupt
request can be enabled or disabled by the ADIE bit in ADCSR.
20.6
Definitions of A/D Conversion Accuracy
The A/D converter compares an analog value input from an analog input channel with its analog
reference value and converts it to 10-bit digital data. The absolute accuracy of this A/D conversion
is the deviation between the input analog value and the output digital value. It includes the
following errors:
• Offset error
• Full-scale error
• Quantization error
• Nonlinearity error
These four error quantities are explained below with reference to figure 20.8. In the figure, the 10
bits of the A/D converter have been simplified to 3 bits.
Offset error is the deviation between actual and ideal A/D conversion characteristics when the
digital output value changes from the minimum (zero voltage) 0000000000 (000 in the figure) to
000000001 (001 in the figure)(figure 20.8, item (1)). Full-scale error is the deviation between
actual and ideal A/D conversion characteristics when the digital output value changes from the
1111111110 (110 in the figure) to the maximum 1111111111 (111 in the figure)(figure 20.8, item
(2)). Quantization error is the intrinsic error of the A/D converter and is expressed as 1/2 LSB
(figure 20.8, item (3)). Nonlinearity error is the deviation between actual and ideal A/D conversion
characteristics between zero voltage and full-scale voltage (figure 20.8, item (4)). Note that it does
not include offset, full-scale, or quantization error.
Rev. 5.00, 09/03, page 631 of 760
Digital output
111
(2) Full-scale error
Digital output
Ideal A/D
conversion
characteristic
Ideal A/D
conversion
characteristic
110
101
100
(4) Nonlinearity
error
011
010
001
000
(3) Quantization
error
0 1/8 2/8 3/8 4/8 5/8 6/8 7/8 FS
Analog input
voltage
FS: Full-scale voltage
Actual A/D
convertion
characteristic
(1) Offset error
FS
Analog input
voltage
Figure 20.8 Definitions of A/D Conversion Accuracy
20.7
Usage Notes
When using the A/D converter, note the following points.
20.7.1
Setting Analog Input Voltage
• Analog Input Voltage Range: During A/D conversion, the voltages input to the analog input
pins ANn should be in the range AV SS ≤ ANn ≤ AVCC (n = 0 to 7).
• Relationships of AVCC and AVSS: AVCC and AVSS should be related as follows: AVCC =
VCC ± 0.3 V and AVSS = VSS.
20.7.2
Processing of Analog Input Pins
To prevent damage from voltage surges at the analog input pins (AN0 to AN7), connect an input
protection circuit like the one shown in figure 20.9. The circuit shown also includes an CR filter to
suppress noise. This circuit is shown as an example; the circuit constants should be selected
according to actual application conditions. Table 20.5 lists the analog input pin specifications and
figure 20.10 shows an equivalent circuit diagram of the analog input ports.
Rev. 5.00, 09/03, page 632 of 760
20.7.3
Access Size and Read Data
Table 20.6 shows the relationship between access size and read data. Note the read data obtained
with different access sizes, bus widths, and endian modes.
The case is shown here in which H'3FF is obtained when AV CC is input as an analog input. FF is
the data containing the upper 8 bits of the conversion result, and C0 is the data containing the
lower 2 bits.
AVCC
100 Ω
*
0.1 µF
SH7709S
AN0 to AN7
AVSS
Note: *
10 µF
0.01 µF
Figure 20.9 Example of Analog Input Protection Circuit
1.0 kΩ
AN0 to AN7
20 pF
1 MΩ
Figure 20.10 Analog Input Pin Equivalent Circuit
Rev. 5.00, 09/03, page 633 of 760
Table 20.5 Analog Input Pin Ratings
Item
Min
Max
Unit
Analog input capacitance
—
20
pF
Allowable signal-source impedance
—
5
kΩ
Table 20.6 Relationship between Access Size and Read Data
Bus Width
32 Bits (D31–D0)
Access
Size
16 Bits (D15–D0)
8 Bits (D7–D0)
Endian
Little
Big
Little
FFFFFFFF FFFFFFFF FFFF
FFFF
FF
FF
C0C0C0C0 C0C0C0C0 C0C0
C0C0
C0
C0
MOV.L#ADDRAH,R9
MOV.W@R9,R8
FFxxFFxx
FFxxFFxx
FFxx
FFxx
FF
xx
xx
FF
MOV.L#ADDRAL,R9
MOV.W@R9,R8
C0xxC0xx
C0xxC0xx
C0xx
C0xx
C0
xx
xx
C0
Longword MOV.L#ADDRAH,R9
access
MOV.L@R9,R8
FFxxC0xx
FFxxC0xx
Ffxx
C0xx
C0xx
FFxx
FF
xx
C0
xx
xx
C0
xx
FF
Byte
access
Word
access
Command
MOV.L#ADDRAH,R9
MOV.B@R9,R8
MOV.L#ADDRAL,R9
MOV.B@R9,R8
Big
Little
Big
In this table: #ADDRAH
.EQU
H'04000080
#ADDRAL
.EQU
H'04000082
Values are shown in hexadecimal for the case where read data is output to an
external device via R8.
Rev. 5.00, 09/03, page 634 of 760
Section 21 D/A Converter
21.1
Overview
The SH7709S includes a D/A converter with two channels.
21.1.1
Features
D/A converter features are listed below.
• Eight-bit resolution
• Two output channels
• Conversion time: maximum 10 µs (with 20-pF capacitive load)
• Output voltage: 0 V to AVcc
21.1.2
Block Diagram
Module data bus
Bus interface
Figure 21.1 shows a block diagram of the D/A converter.
On-chip
data bus
DA0
8-bit D/A
DACR
DA1
DADR0
DADR1
AVCC
AVSS
Control circuit
Legend
DACR: D/A control register
DADR0: D/A data register 0
DADR1: D/A data register 1
Figure 21.1 Block Diagram D/A Converter
Rev. 5.00, 09/03, page 635 of 760
21.1.3
I/O Pins
Table 21.1 summarizes the D/A converter’s input and output pins.
Table 21.1 D/A Converter Pins
Pin Name
Abbreviation
I/O
Function
Analog power supply pin
AVcc
Input
Analog power supply
Analog ground pin
AVss
Input
Analog ground and reference voltage
Analog output pin 0
DA0
Output
Analog output, channel 0
Analog output pin 1
DA1
Output
Analog output, channel 1
21.1.4
Register Configuration
Table 21.2 summarizes the D/A converter’s registers.
Table 21.2 D/A Converter Registers
1
Name
Abbreviation
R/W
Initial Value
Address*
D/A data register 0
DADR0
R/W
H'00
H'040000A0
2
(H'A40000A0)*
D/A data register 1
DADR1
R/W
H'00
H'040000A2
2
(H'A40000A2)*
D/A control register
DACR
R/W
H'1F
H'040000A4
2
(H'A40000A4)*
Notes: These registers are located in area 1 of physical space. Therefore, when the cache is on,
either access these registers from the P2 area of logical space or else make an appropriate
setting using the MMU so that these registers are not cached.
1. Lower 16 bits of the address
2. When address translation by the MMU does not apply, the address in parentheses
should be used.
Rev. 5.00, 09/03, page 636 of 760
21.2
Register Descriptions
21.2.1
D/A Data Registers 0 and 1 (DADR0/1)
Bit:
Initial value:
R/W:
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
The D/A data registers (DADR0 and DADR1) are 8-bit readable/writable registers that store the
data to be converted. When analog output is enabled, the D/A data register values are constantly
converted and output at the analog output pins.
The D/A data registers are initialized to H'00 by a reset.
21.2.2
D/A Control Register (DACR)
Bit:
Initial value:
R/W:
7
6
5
4
3
2
1
0
DAOE1
DAOE0
DAE
—
—
—
—
—
0
0
0
1
1
1
1
1
R/W
R/W
R/W
R
R
R
R
R
DACR is an 8-bit readable/writable register that controls the operation of the D/A converter.
DACR is initialized to H'1F by a reset.
Bit 7—D/A Output Enable 1 (DAOE1): Controls D/A conversion and analog output.
Bit 7: DAOE1
Description
0
DA1 analog output is disabled
1
Channel-1 D/A conversion and DA1 analog output are enabled
(Initial value)
Bit 6—D/A Output Enable 0 (DAOE0): Controls D/A conversion and analog output.
Bit 6: DAOE0
Description
0
DA0 analog output is disabled
1
Channel-0 D/A conversion and DA0 analog output are enabled
(Initial value)
Rev. 5.00, 09/03, page 637 of 760
Bit 5—D/A Enable (DAE): Controls D/A conversion, together with bits DAOE0 and DAOE1.
When the DAE bit is cleared to 0, D/A conversion is controlled independently in channels 0 and 1.
When the chip enters standby mode while D/A conversion is enabled, the D/A output is held and
the analog power-supply current is equivalent to that during D/A conversion. To reduce the analog
power-supply current in standby mode, clear the DAOE0 and DAOE1 bits and disable the D/A
output.
Bit 7: DAOE1
Bit 6: DAOE0
Bit 5: DAE
Description
0
0
—
D/A conversion is disabled in channels 0 and 1
(Initial value)
0
1
0
D/A conversion is enabled in channel 0
D/A conversion is disabled in channel 1
0
1
1
D/A conversion is enabled in channels 0 and 1
1
0
0
D/A conversion is disabled in channel 0
1
0
1
D/A conversion is enabled in channels 0 and 1
1
1
—
D/A conversion is enabled in channels 0 and 1
D/A conversion is enabled in channel 1
When the DAE bit is set to 1, even if bits DAOE0 and DAOE1 in DACR and the ADST bit in
ADCSR are cleared to 0, the same current is drawn from the analog power supply as during A/D
and D/A conversion.
Bits 4 to 0—Reserved: Read-only bits, always read as 1.
Rev. 5.00, 09/03, page 638 of 760
21.3
Operation
The D/A converter has two built-in D/A conversion circuits that can perform conversion
independently.
D/A conversion is performed constantly while enabled in DACR. If the DADR0 or DADR1 value
is modified, conversion of the new data begins immediately. The conversion results are output
when bits DAOE0 and DAOE1 are set to 1.
An example of D/A conversion on channel 0 is given next. Timing is indicated in figure 21.2.
1. Data to be converted is written in DADR0.
2. Bit DAOE0 is set to 1 in DACR. D/A conversion starts and DA0 becomes an output pin. The
converted result is output after the conversion time. The output value is (DADR0 contents/256)
× AVcc. Output of this conversion result continues until the value in DADR0 is modified or
the DAOE0 bit is cleared to 0.
3. If the DADR0 value is modified, conversion starts immediately, and the result is output after
the conversion time.
4. When the DAOE0 bit is cleared to 0, DA0 becomes an input pin.
DADR0
write cycle
DACR
write cycle
DADR0
write cycle
DACR
write cycle
φ
Address bus
Conversion data 1
DADR0
Conversion data 2
DAOE0
Conversion
result 2
Conversion
result 1
DA0
High-impedance state
tDCONV
tDCONV
Legend
tDCONV : D/A conversion time
Figure 21.2 Example of D/A Converter Operation
Rev. 5.00, 09/03, page 639 of 760
Rev. 5.00, 09/03, page 640 of 760
Section 22 User Debugging Interface
(UDI)
22.1
Overview
This LSI incorporates a User debugging interface (UDI) and advanced user debugger (AUD) for
program debugging.
22.2
User Debugging Interface (UDI)
The UDI (User debugging interface) performs on-chip debugging which is supported by this LSI.
The UDI described here is a serial interface which is compatible with JTAG (Joint Test Action
Group, IEEE Standard 1149.1 and IEEE Standard Test Access Port and Boundary-Scan
Architecture) specifications.
The UDI in the SH7709S supports a boundary scan mode, and is also used for emulator
connection.
When using an emulator, UDI functions should not be used. Refer to the emulator manual for the
method of connecting the emulator.
22.2.1
Pin Descriptions
TCK: UDI serial data input/output clock pin. Data is serially supplied to the UDI from the data
input pin (TDI), and output from the data output pin (TDO), in synchronization with this clock.
TMS: Mode select input pin. The state of the TAP control circuit is determined by changing this
signal in synchronization with TCK. The protocol complies with the JTAG standard (IEEE Std.
1149.1).
TRST: UDI reset input pin. Input is accepted asynchronously with respect to TCK, and when low,
the UDI is reset. See section 22.4.2, Reset Configuration, for more information.
TDI: UDI serial data input pin. Data transfer to the UDI is executed by changing this signal in
synchronization with TCK.
TDO: UDI serial data output pin. Data output from the UDI is executed by reading this signal in
synchronization with TCK.
ASEMD0: ASE mode select pin. If a low level is input at the ASEMD0 pin while the RESETP
pin is asserted, ASE mode is entered; if a high level is input, normal mode is entered. When using
on the user system alone, without an emulator and the UDI, hold this pin at high level. In ASE
Rev. 5.00, 09/03, page 641 of 760
mode, boundary scan and emulator functions can be used. The input level at the ASEMD0 pin
should be held for at least one cycle after RESETP negation.
ASEBRKAK:
KAK Dedicated emulator pin
22.2.2
Block Diagram
Figure 22.1 shows a block diagram of the UDI.
TDO
Shift register
SDBPR
SDBSR
TDI
SDIR
MUX
TCK
TMS
TAP controller
Decoder
TRST
Figure 22.1 Block Diagram of UDI
22.3
Register Descriptions
The UDI has the following registers.
• SDBPR: Bypass register
• SDIR: Instruction register
• SDBSR: Boundary scan register
Rev. 5.00, 09/03, page 642 of 760
Local
bus
Table 22.1 shows the UDI register configuration.
Table 22.1 UDI Registers
CPU Side
UDI Side
Name
Abbreviation
R/W
Size
Address
R/W
Size
Initial
Value*
Bypass register
SDBPR
—
—
—
R/W
1
Undefined
Instruction register
SDIR
R
16
H'04000200
R/W
16
H'FFFF
Boundary register
SDBSR
—
—
—
R/W
—
Undefined
Note: * Initialized when TRST pin is low or when TAP is in the test-logic-reset state.
22.3.1
Bypass Register (SDBPR)
The bypass register is a 1-bit register that cannot be accessed by the CPU. When SDIR is set to the
bypass mode, SDBPR is connected between UDI pins TDI and TDO.
22.3.2
Instruction Register (SDIR)
The instruction register (SDIR) is a 16-bit read-only register. The register is in bypass mode in its
initial state. It is initialized by TRST assertion or in the TAP test-logic-reset state, and can be
written to by the UDI irrespective of the CPU mode. Operation is not guaranteed if a reserved
command is set in this register
Bit:
15
14
13
12
11
10
9
8
TI3
TI2
TI1
TI0
—
—
—
—
Initial value:
1
1
1
1
1
1
1
1
Bit:
7
6
5
4
3
2
1
0
—
—
—
—
—
—
—
—
1
1
1
1
1
1
1
1
Initial value:
Bits 15 to 12—Test Instruction Bits (TI3 to TI0): Cannot be written by the CPU.
Rev. 5.00, 09/03, page 643 of 760
Table 22.2 UDI Commands
Bit 15 to 12
TI3
TI2
TI1
TI0
Description
0
0
0
0
EXTEST
0
1
0
0
SAMPLE/PRELOAD
0
1
0
1
Reserved
0
1
1
0
UDI reset negate
0
1
1
1
UDI reset assert
1
0
0
—
Reserved
1
0
1
—
UDI interrupt
1
1
0
—
Reserved
1
1
1
0
Reserved
1
1
1
1
Bypass mode
0
0
0
1
Recovery from sleep
(Initial value)
Bits 11 to 0—Reserved: These bits are always read as 1.
22.3.3
Boundary Scan Register (SDBSR)
The boundary scan register (SDBSR) is a shift register, located on the PAD, for controlling the
input/output pins of the SH7709S.
Using the EXTEST and SAMPLE/PRELOAD commands, a boundary scan test conforming to the
JTAG standard can be carried out. Table 22.3 shows the correspondence between the pins of this
LSI and boundary scan register bits.
Rev. 5.00, 09/03, page 644 of 760
Table 22.3 Pins of this LSI and Boundary Scan Register Bits
Bit
Pin Name
I/O
from TDI
Bit
Pin Name
I/O
308
D1
IN
338
D31/PTB7
IN
307
D0
IN
337
D30/PTB6
IN
306
MD1
IN
336
D29/PTB5
IN
305
MD2
IN
335
D28/PTB4
IN
304
NMI
IN
334
D27/PTB3
IN
303
IRQ0/IRL0/PTH0
IN
333
D26/PTB2
IN
302
IRQ1/IRL1/PTH1
IN
332
D25/PTB1
IN
301
IRQ2/IRL2/PTH2
IN
331
D24/PTB0
IN
300
IRQ3/IRL3/PTH3
IN
330
D23/PTA7
IN
299
IRQ4/PTH4
IN
329
D22/PTA6
IN
298
D31/PTB7
OUT
328
D21/PTA5
IN
297
D30/PTB6
OUT
327
D20/PTA4
IN
296
D29/PTB5
OUT
326
D19/PTA3
IN
295
D28/PTB4
OUT
325
D18/PTA2
IN
294
D27/PTB3
OUT
324
D17/PTA1
IN
293
D26/PTB2
OUT
323
D16/PTA0
IN
292
D25/PTB1
OUT
322
D15
IN
291
D24/PTB0
OUT
321
D14
IN
290
D23/PTA7
OUT
320
D13
IN
289
D22/PTA6
OUT
319
D12
IN
288
D21/PTA5
OUT
318
D11
IN
287
D20/PTA4
OUT
317
D10
IN
286
D19/PTA3
OUT
316
D9
IN
285
D18/PTA2
OUT
315
D8
IN
284
D17/PTA1
OUT
314
D7
IN
283
D16/PTA0
OUT
313
D6
IN
282
D15
OUT
312
D5
IN
281
D14
OUT
311
D4
IN
280
D13
OUT
310
D3
IN
279
D12
OUT
309
D2
IN
278
D11
OUT
Rev. 5.00, 09/03, page 645 of 760
Bit
Pin Name
I/O
Bit
Pin Name
I/O
277
D10
OUT
247
D12
Control
276
D9
OUT
246
D11
Control
275
D8
OUT
245
D10
Control
274
D7
OUT
244
D9
Control
273
D6
OUT
243
D8
Control
272
D5
OUT
242
D7
Control
271
D4
OUT
241
D6
Control
270
D3
OUT
240
D5
Control
269
D2
OUT
239
D4
Control
268
D1
OUT
238
D3
Control
267
D0
OUT
237
D2
Control
266
D31/PTB7
Control
236
D1
Control
265
D30/PTB6
Control
235
D0
Control
264
D29/PTB5
Control
234
BS/PTK4
IN
263
D28/PTB4
Control
233
WE2/DQMUL/ICIORD/
PTK6
IN
262
D27/PTB3
Control
232
WE3/DQMUU/ICIORD/
PTK7
IN
261
D26/PTB2
Control
231
AUDSYNC/PTE7
IN
260
D25/PTB1
Control
230
CS2/PTK0
IN
259
D24/PTB0
Control
229
CS3/PTK1
IN
258
D23/PTA7
Control
228
CS4/PTK2
IN
257
D22/PTA6
Control
227
CS5/CE1A/PTK3
IN
256
D21/PTA5
Control
226
CE2A/PTE4
IN
255
D20/PTA4
Control
225
CE2B/PTE5
IN
254
D19/PTA3
Control
224
A0
OUT
253
D18/PTA2
Control
223
A1
OUT
252
D17/PTA1
Control
222
A2
OUT
251
D16/PTA0
Control
221
A3
OUT
250
D15
Control
220
A4
OUT
249
D14
Control
219
A5
OUT
248
D13
Control
218
A6
OUT
Rev. 5.00, 09/03, page 646 of 760
Bit
Pin Name
I/O
Bit
Pin Name
I/O
217
A7
OUT
187
CS4/PTK2
OUT
216
A8
OUT
186
CS5/CE1A/PTK3
OUT
215
A9
OUT
185
CS6/CE1B
OUT
214
A10
OUT
184
CE2A/PTE4
OUT
213
A11
OUT
183
CE2B/PTE5
OUT
212
A12
OUT
182
A0
Control
211
A13
OUT
181
A1
Control
210
A14
OUT
180
A2
Control
209
A15
OUT
179
A3
Control
208
A16
OUT
178
A4
Control
207
A17
OUT
177
A5
Control
206
A18
OUT
176
A6
Control
205
A19
OUT
175
A7
Control
204
A20
OUT
174
A8
Control
203
A21
OUT
173
A9
Control
202
A22
OUT
172
A10
Control
201
A23
OUT
171
A11
Control
200
A24
OUT
170
A12
Control
199
A25
OUT
169
A13
Control
198
BS/PTK4
OUT
168
A14
Control
197
RD
OUT
167
A15
Control
196
WE0/DQMLL
OUT
166
A16
Control
195
WE1/DQMLU/WE
OUT
165
A17
Control
194
WE2/DQMUL/ICIORD/
PTK6
OUT
164
A18
Control
193
WE3/DQMUU/ICIOWR/
PTK7
OUT
163
A19
Control
192
RD/WR
OUT
162
A20
Control
191
AUDSYNC/PTE7
OUT
161
A21
Control
190
CS0/MCS0
OUT
160
A22
Control
189
CS2/PTK0
OUT
159
A23
Control
188
CS3/PTK1
OUT
158
A24
Control
Rev. 5.00, 09/03, page 647 of 760
Bit
Pin Name
I/O
Bit
Pin Name
I/O
157
A25
Control
127
BREQ
IN
156
BS/PTK4
Control
126
WAIT
IN
155
RD
Control
125
AUDCK/PTH6
IN
154
WE0/DQMLL
Control
124
IOIS16/PTG7
IN
153
WE1/DQMLU/WE
Control
123
ASEBRKAK/PTG5
IN
152
WE2/DQMUL/ICIORD/
PTK6
Control
122
CKIO2/PTG4
IN
151
WE3/DQMUU/ICIOWR/
PTK7
Control
121
AUDATA3/PTG3
IN
150
RD/WR
Control
120
AUDATA2/PTG2
IN
149
AUDSYNC/PTE7
Control
119
AUDATA1/PTG1
IN
148
CS0/MCS0
Control
118
AUDATA0/PTG0
IN
147
CS2/PTK0
Control
117
ADTRG/PTH5
IN
146
CS3/PTK1
Control
116
IRLS3/PTF3/PINT11
IN
145
CS4/PTK2
Control
115
IRLS2/PTF2/PINT10
IN
144
CS5/CE1A/PTK3
Control
114
IRLS1/PTF1/PINT9
IN
143
CS6/CE1B
Control
113
IRLS0/PTF0/PINT8
IN
142
CE2A/PTE4
Control
112
MD0
IN
141
CE2B/PTE5
Control
111
CKE/PTK5
OUT
140
CKE/PTK5
IN
110
RAS3L/PTJ0
OUT
139
RAS3L/PTJ0
IN
109
PTJ1
OUT
138
PTJ1
IN
108
CASL/PTJ2
OUT
137
CASL/PTJ2
IN
107
CASU/PTJ3
OUT
136
CASU/PTJ3
IN
106
PTJ4
OUT
135
PTJ4
IN
105
PTJ5
OUT
134
PTJ5
IN
104
DACK0/PTD5
OUT
133
DACK0/PTD5
IN
103
DACK1/PTD7
OUT
132
DACK1/PTD7
IN
102
PTE6
OUT
131
PTE6
IN
101
PTE3
OUT
130
PTE3
IN
100
RAS3U/PTE2
OUT
129
RAS3U/PTE2
IN
99
PTE1
OUT
128
PTE1
IN
98
BACK
OUT
Rev. 5.00, 09/03, page 648 of 760
Bit
Pin Name
I/O
Bit
Pin Name
I/O
97
ASEBRKAK/PTG5
OUT
65
RxD2/SCPT4
IN
96
AUDATA3/PTG3
OUT
64
WAKEUP/PTD3
IN
95
AUDATA2/PTG2
OUT
63
RESETOUT/PTD2
IN
94
AUDATA1/PTG1
OUT
62
DRAK0/PTD1
IN
93
AUDATA0/PTG0
OUT
61
DRAK1/PTD0
IN
92
CKE/PTK5
Control
60
DREQ0/PTD4
IN
91
RAS3L/PTJ0
Control
59
DREQ1/PTD6
IN
90
PTJ1
Control
58
RxD1/SCPT2
IN
89
CASL/PTJ2
Control
57
CTS2/IRQ5/SCPT7
IN
88
CASU/PTJ3
Control
56
MCS7/PTC7/PINT7
IN
87
PTJ4
Control
55
MCS6/PTC6/PINT6
IN
86
PTJ5
Control
54
MCS5/PTC5/PINT5
IN
85
DACK0/PTD5
Control
53
MCS4/PTC4/PINT4
IN
84
DACK1/PTD7
Control
52
MCS3/PTC3/PINT3
IN
83
PTE6
Control
51
MCS2/PTC2/PINT2
IN
82
PTE3
Control
50
MCS1/PTC1/PINT1
IN
81
RAS3U/PTE2
Control
49
MCS0/PTC0/PINT0
IN
80
PTE1
Control
48
MD3
IN
79
BACK
Control
47
MD4
IN
78
ASEBRKAK/PTG5
Control
46
MD5
IN
77
AUDATA3/PTG3
Control
45
STATUS0/PTJ6
OUT
76
AUDATA2/PTG2
Control
44
STATUS1/PTJ7
OUT
75
AUDATA1/PTG1
Control
43
TCLK/PTH7
OUT
74
AUDATA0/PTG0
Control
42
IRQOUT
OUT
73
STATUS0/PTJ6
IN
41
TxD0/SCPT0
OUT
72
STATUS1/PTJ7
IN
40
SCK0/SCPT1
OUT
71
TCLK/PTH7
IN
39
TxD1/SCPT2
OUT
70
SCK0/SCPT1
IN
38
SCK1/SCPT3
OUT
69
SCK1/SCPT3
IN
37
TxD2/SCPT4
OUT
68
SCK2/SCPT5
IN
36
SCK2/SCPT5
OUT
67
RTS2/SCPT6
IN
35
RTS2/SCPT6
OUT
66
RxD0/SCPT0
IN
34
MCS7/PTC7/PINT7
OUT
Rev. 5.00, 09/03, page 649 of 760
Bit
Pin Name
I/O
Bit
Pin Name
I/O
33
MCS6/PTC6/PINT6
OUT
15
SCK1/SCPT3
Control
32
MCS5/PTC5/PINT5
OUT
14
TxD2/SCPT4
Control
31
MCS4/PTC4/PINT4
OUT
13
SCK2/SCPT5
Control
30
WAKEUP/PTD3
OUT
12
RTS2/SCPT6
Control
29
RESETOUT/PTD2
OUT
11
MCS7/PTC7/PINT7
Control
28
MCS3/PTC3/PINT3
OUT
10
MCS6/PTC6/PINT6
Control
27
MCS2/PTC2/PINT2
OUT
9
MCS5/PTC5/PINT5
Control
26
MCS1/PTC1/PINT1
OUT
8
MCS4/PTC4/PINT4
Control
25
MCS0/PTC0/PINT0
OUT
7
WAKEUP/PTD3
Control
24
DRAK0/PTD1
OUT
6
RESETOUT/PTD2
Control
23
DRAK1/PTD0
OUT
5
MCS3/PTC3/PINT3
Control
22
STATUS0/PTJ6
Control
4
MCS2/PTC2/PINT2
Control
21
STATUS1/PTJ7
Control
3
MCS1/PTC1/PINT1
Control
20
TCLK/PTH7
Control
2
MCS0/PTC0/PINT0
Control
19
IRQOUT
Control
1
DRAK0/PTD1
Control
18
TxD0/SCPT0
Control
0
DRAK1/PTD0
Control
17
SCK0/SCPT1
Control
to TDO
16
TxD1/SCPT2
Control
Note: Control is an active-low signal.
When Control is driven low, the corresponding pin is driven by the value of OUT.
Rev. 5.00, 09/03, page 650 of 760
22.4
UDI Operation
22.4.1
TAP Controller
Figure 22.2 shows the internal states of the TAP controller. State transitions basically conform
with the JTAG standard.
1
Test-logic-reset
0
Run-test/idle
0
1
1
1
Select-DR-scan
Select-IR-scan
0
1
1
Capture-DR
0
Shift-DR
1
Capture-IR
0
0
Shift-IR
1
Exit1-DR
0
Pause-DR
1
0
0
Exit1-IR
0
0
Pause-IR
1
0
0
Exit2-DR
1
Exit2-IR
1
Update-DR
1
0
Update-IR
1
0
Figure 22.2 TAP Controller State Transitions
Note: The transition condition is the TMS value at the rising edge of TCK. The TDI value is
sampled at the rising edge of TCK; shifting occurs at the falling edge of TCK. The TDO
value changes at the TCK falling edge. The TDO is at high impedance, except with shiftDR (shift-SR) and shift-IR states. During the change to TRST = 0, there is a transition to
test-logic-reset asynchronously with TCK.
Rev. 5.00, 09/03, page 651 of 760
22.4.2
Reset Configuration
Table 22.4 Reset Configuration
ASEM
ASEMD0 *
RESET
ESETP
TRST
Chip State
High-level
Low-level
Low-level
Normal reset and UDI reset
High-level
Normal reset
Low-level
UDI reset only
High-level
Normal operation
2
Reset hold*
1
High-level
Low-level
Low-level
High-level
Low-level
High-level
3
ASE user mode* : Normal reset
3
ASE break mode* : RESETP assertion
masked
Low-level
UDI reset only
High-level
Normal operation
Notes: 1. Selects main chip mode or ASE mode
ASEMD0 = H, normal mode
ASEMD0 = L, ASE mode
Set ASEMD0 = H when using on the user system alone, without an emulator and the
UDI.
2. In ASE mode, reset hold is enabled by driving the RESETP and TRST pins low for a
constant cycle. In this state, the CPU does not start up, even if RESETP is driven high.
When TRST is driven high, UDI operation is enabled, but the CPU does not start up.
The reset hold state is cancelled by the following:
• Boot request from UDI
• Another RESETP assert (power-on reset)
3. There are two ASE modes, one for executing software in the emulator’s firmware (ASE
break mode) and one for executing user software (ASE user mode).
Rev. 5.00, 09/03, page 652 of 760
22.4.3
UDI Reset
An UDI reset is executed by setting an UDI reset assert command in SDIR. An UDI reset is of the
same kind as a power-on reset. An UDI reset is released by inputting an UDI reset negate
command.
SDIR
UDI reset assert
UDI reset negate
Chip internal reset
CPU state
Branch to H'A0000000
Figure 22.3 UDI Reset
22.4.4
UDI Interrupt
The UDI interrupt function generates an interrupt by setting a command from the UDI in the
SDIR. An UDI interrupt is a general exception/interrupt operation, resulting in a branch to an
address based on the VBR value plus offset, and with return by the RTE instruction. This interrupt
request has a fixed priority level of 15.
UDI interrupts are not accepted in sleep mode or standby mode.
22.4.5
Bypass
The JTAG-based bypass mode for the UDI pins can be selected by setting a command from the
UDI in SDIR.
22.4.6
Using UDI to Recover from Sleep Mode
It is possible to recover from sleep mode by setting a command (0001) from the UDI in SDIR.
Rev. 5.00, 09/03, page 653 of 760
22.5
Boundary Scan
A command can be set in SDIR by the UDI to place the UDI pins in the boundary scan mode
stipulated by JTAG.
22.5.1
Supported Instructions
This LSI supports the three essential instructions defined in the JTAG standard (BYPASS,
SAMPLE/PRELOAD, and EXTEST).
BYPASS: The BYPASS instruction is an essential standard instruction that operates the bypass
register. This instruction shortens the shift path to speed up serial data transfer involving other
chips on the printed circuit board. While this instruction is executing, the test circuit has no effect
on the system circuits. The instruction code is 1111.
SAMPLE/PRELOAD: The SAMPLE/PRELOAD instruction inputs values from this LSI's
internal circuitry to the boundary scan register, outputs values from the scan path, and loads data
onto the scan path. When this instruction is executing, this LSI's input pin signals are transmitted
directly to the internal circuitry, and internal circuit values are directly output externally from the
output pins. This LSI's system circuits are not affected by execution of this instruction. The
instruction code is 0100.
In a SAMPLE operation, a snapshot of a value to be transferred from an input pin to the internal
circuitry, or a value to be transferred from the internal circuitry to an output pin, is latched into the
boundary scan register and read from the scan path. Snapshot latching is performed in
synchronization with the rise of TCK in the Capture-DR state. Snapshot latching does not affect
normal operation of this LSI.
In a PRELOAD operation, an initial value is set in the parallel output latch of the boundary scan
register from the scan path prior to the EXTEST instruction. Without a PRELOAD operation,
when the EXTEST instruction was executed an undefined value would be output from the output
pin until completion of the initial scan sequence (transfer to the output latch) (with the EXTEST
instruction, the parallel output latch value is constantly output to the output pin).
EXTEST: This instruction is provided to test external circuitry when this LSI is mounted on a
printed circuit board. When this instruction is executed, output pins are used to output test data
(previously set by the SAMPLE/PRELOAD instruction) from the boundary scan register to the
printed circuit board, and input pins are used to latch test results into the boundary scan register
from the printed circuit board. If testing is carried out by using the EXTEST instruction N times,
the Nth test data is scanned-in when test data (N-1) is scanned out.
Rev. 5.00, 09/03, page 654 of 760
Data loaded into the output pin boundary scan register in the Capture-DR state is not used for
external circuit testing (it is replaced by a shift operation).
The instruction code is 0000.
22.5.2
Points for Attention
1. Boundary scan mode covers clock-related signals (EXTAL, EXTAL2, XTAL, XTAL2,
CKIO).
2. Boundary scan mode does not cover reset-related signals (RESETP, RESETM, CA).
3. Boundary scan mode does not cover UDI-related signals (TCK, TDI, TDO, TMS, TRST).
4. When a boundary scan test is carried out, ensure that the CKIO clock operates constantly.
The CKIO frequency range is as follows:
Minimum: 1 MHz
Maximum: Maximum frequency for respective clock mode specified in the CPG section
Set pins MD[2:0] to the clock mode to be used.
After powering on, wait for the CKIO clock to stabilize before performing a boundary scan
test.
5. Fix the RESETP pin low.
6. Fix the CA pin high, and the ASEMD0 pin low.
22.6
Usage Notes
1. An UDI command other than an UDI interrupt, once set, will not be modified as long as
another command is not re-issued from the UDI. An UDI interrupt command, however, will
be changed to a bypass command once set.
2. Because chip operations are suspended in standby mode, UDI commands are not accepted.
However, the TAP controller remains in operation at this time.
3. The UDI is used for emulator connection. Therefore, UDI functions cannot be used when
using an emulator.
22.7
Advanced User Debugger (AUD)
The AUD is a function exclusively for use by an emulator. Refer to the User's Manual for the
relevant emulator for details of the AUD.
Rev. 5.00, 09/03, page 655 of 760
Rev. 5.00, 09/03, page 656 of 760
Section 23 Electrical Characteristics
23.1
Absolute Maximum Ratings
Table 23.1 shows the absolute maximum ratings.
Table 23.1 Absolute Maximum Ratings
Item
Symbol
Rating
Unit
Power supply voltage (I/O)
VccQ
–0.3 to 4.2
V
Power supply voltage (internal) Vcc
Vcc – PLL1
Vcc – PLL2
Vcc – RTC
–0.3 to 2.5
V
Input voltage (except port L)
Vin
–0.3 to VccQ + 0.3
V
Input voltage (port L)
Vin
–0.3 to AVcc + 0.3
V
Analog power-supply voltage
AVcc
–0.3 to 4.6
V
Analog input voltage
VAN
–0.3 to AVcc + 0.3
V
Operating temperature
Topr
–20 to 75
°C
Storage temperature
Tstr
–55 to 125
°C
Caution: Operating the chip in excess of the absolute maximum rating may result in permanent
damage.
• Order of turning on 1.7 V/1.8 V/1.9 V/2.0 V power (Vcc, Vcc-PLL1, Vcc-PLL2, Vcc-RTC)
and 3.3 V power (VccQ, AVcc):
1. First turn on the 3.3 V power, then turn on the 1.7 V/1.8 V/1.9 V/2.0 V power within 1 ms.
This interval should be as short as possible.
2. Until voltage is applied to all power supplies, a low level is input at the RESETP pin, and
CKIO has operated for a maximum of 4 clock cycles, internal circuits remain unsettled, and
so pin states are also undefined. The system design must ensure that these undefined states
do not cause erroneous system operation. Note that the RESETP pin cannot receive a low
level signal while a low level signal is being input to the CA pin.
Waveforms at power-on are shown in the following figure.
Rev. 5.00, 09/03, page 657 of 760
(Max. 1 ms)
3.3 V
3.3 V power
1.7 V/1.8 V/1.9 V/2.0 V
1.7 V/1.8 V/1.9 V/2.0 V power
RESETP
Pin states undefined
All other pins*
Pin states undefined
Power-on reset state
Note: * Except power/GND, clock related, and analog pins
Power-On Sequence
• Power-off order
1. In the reverse order of powering-on, first turn off the 1.7 V/1.8 V/1.9 V/2.0 V power, then
turn off the 3.3 V power within 1 ms. This interval should be as short as possible.
2. Pin states are undefined while only the 1.7 V/1.8 V/1.9 V/2.0 V power is off. The system
design must ensure that these undefined states do not cause erroneous system operation.
Rev. 5.00, 09/03, page 658 of 760
23.2
DC Characteristics
Tables 23.2 and 23.3 list DC characteristics.
Table 23.2 DC Characteristics
Ta = –20 to 75°C
Item
Symbol
Min
Typ
Max
Unit
Power supply voltage
VccQ
3.0
3.3
3.6
V
Vcc,
1.85
2.00
2.15
200 MHz model*
Vcc-PLL1,
1.75
1.90
2.05
167 MHz model
Vcc-PLL2,
1.65
1.80
2.05
133 MHz model
Vcc-RTC
1.55
1.70
1.95
100 MHz model
—
410
680
330
540
Vcc = 1.9 V, Iφ = 167 MHz
—
250
410
Vcc = 1.8 V, Iφ = 133 MHz
—
190
310
Vcc = 1.7 V, Iφ = 100 MHz
IccQ
—
20
40
VccQ = 3.3 V, Bφ = 33 MHz
Icc
—
15
30
IccQ
—
10
20
*1 When there is no other
external bus cycle other
than the refresh cycle.
Current
dissipation
Normal
Icc
operation
Sleep
1
mode*
mA
Measurement Conditions
Vcc = 2.0 V, Iφ = 200 MHz
Vcc = 1.9 V,
VccQ = 3.3 V
Bφ = 33MHz
Standby
mode
Icc
—
40
120
IccQ
—
10
30
Icc
—
290
900
IccQ
—
10
30
µA
Ta = 25°C (RTC on)
VccQ = 3.3 V,
Vcc = 1.55 V to 2.15 V
Ta = 25°C (RTC off),
Crystal is not used.
VccQ = 3.3 V,
Vcc = 1.55 V to 2.15 V
Rev. 5.00, 09/03, page 659 of 760
Item
Symbol
Min
Typ
Max
VccQ
× 0.9
—
VccQ + V
0.3
EXTAL2
—
—
—
Port L
2.0
—
AVcc +
0.3
Other input
pins
2.0
—
VccQ +
0.3
Input high RESETP,
VIH
voltage
RESETM,
NMI, IRQ5 to
IRQ0, MD5
to MD0, IRL3
to IRL0,
IRLS3 to
IRLS0,
PINT15 to
PINT0,
ASEMD0,
ADTRG,
TRST,
EXTAL,
CKIO, RxD1,
CA
Rev. 5.00, 09/03, page 660 of 760
Unit
Measurement Conditions
When not connecting to a
crystal oscillator, connect to
Vcc.
Item
Symbol Min
Typ
Max
Unit
–0.3
—
VccQ
× 0.1
V
EXTAL2
—
—
—
Port L
–0.3
—
AVcc
× 0.2
Other input
pins
–0.3
—
VccQ
× 0.2
Input leak All input pins I Iin I
current
—
—
1.0
µA
Vin = 0.5 to VccQ–0.5 V
ThreeI/O, all
state leak output pins
current
(off
condition)
I Isti I
—
—
1.0
µA
Vin = 0.5 to VccQ–0.5 V
Output
high
voltage
VOH
2.4
—
—
V
VccQ = 3.0 V, IOH = –200 µA
2.0
—
—
VccQ = 3.0 V, IOH = –2 mA
VccQ = 3.6 V, IOL = 1.6 mA
Input low RESETP,
VIL
voltage
RESETM,
NMI,
IRQ5–IRQ0,
MD5–MD0,
IRL3 to IRL0,
IRLS3 to
IRLS0,
PINT15–
PINT0,
ASEMD0,
ADTRG,
TRST,
EXTAL,
CKIO, RxD1,
CA
All output
pins
When not connecting to a
crystal oscillator, connect to
Vcc.
Output low All output
voltage
pins
VOL
—
—
0.55
Pull-up
Port pin
resistance
Rpull
30
60
120
kΩ
Pin
capacity
C
—
—
10
pF
All pins
Measurement Conditions
Rev. 5.00, 09/03, page 661 of 760
Item
Symbol Min
Typ
Max
Unit
Analog
powersupply
voltage
AVcc
3.0
3.3
3.6
V
AIcc
—
0.8
2
mA
Analog
powersupply
During A/D
conversion
current
During A/D
and D/A
conversion
—
2.4
6
mA
Idle
—
1
20
µA
Measurement Conditions
Ta = 25°C
Notes: Even when PLL is not used, always connect Vcc-PLL1 and Vcc-PLL2 to Vcc and connect
Vss-PLL1 and Vss-PLL2 to Vss.
Even when RTC is not used, always supply power between Vcc-RTC and Vss-RTC.
AVcc must be under condition of VccQ – 0.3 V ≤ AVcc ≤ VccQ + 0.3 V. If the A/D and D/A
converters are not used, do not leave the AVcc and AVss pins open. Connect AVcc to
VccQ, and connect AVss to VssQ.
Current dissipation values shown are the values at which all output pins are without load
under conditions of VIH min = VccQ – 0.5 V, VIL max = 0.5 V.
The same voltage should be supplied to Vcc, Vcc-RTC, Vcc-PLL1, and Vcc-PLL2.
* If the IRL and IRLS interrupts are used, the minimum is 1.9 V.
Table 23.3 Permitted Output Current Values
VccQ = 3.3 ± 0.3 V, Vcc = 1.55 to 2.15 V, AVcc = 3.3 ± 0.3 V, Ta = –20 to 75°C
Item
Symbol
Min
Typ
Max
Unit
Output low-level permissible current (per pin)
IOL
—
—
2.0
mA
Output low-level permissible current (total)
∑ IOL
—
—
120
mA
Output high-level permissible current (per pin)
–IOH
—
—
2.0
mA
Output high-level permissible current (total)
∑ (–IOH)
—
—
40
mA
Caution: To ensure LSI reliability, do not exceed the value for output current given in table 23.3.
Rev. 5.00, 09/03, page 662 of 760
23.3
AC Characteristics
In general, inputting for this LSI should be clock synchronous. Keep the setup and hold times for
each input signal unless otherwise specified.
Table 23.4 Operating Frequency Range
VccQ = 3.3 ± 0.3 V, VccQ = 1.55 to 2.15 V, AVcc = 3.3 ± 0.3 V, Ta = –20 to 75°C
Item
Operating
frequency
CPU, cache, TLB
Symbol
Min
Typ
Max
Unit
Remarks
f
30
—
200
MHz
200 MHz model
25
External bus
30
—
167
167 MHz model
133
133 MHz model
100
100 MHz model
66.67
200 MHz model
25
Peripheral module
7.5
6.25
167 MHz model
133 MHz model
100 MHz model
—
33.34
200 MHz model
167 MHz model
133 MHz model
100 MHz model
Rev. 5.00, 09/03, page 663 of 760
23.3.1
Clock Timing
Table 23.5 Clock Timing
VccQ = 3.3 ± 0.3 V, Vcc = 1.55 to 2.15 V, AVcc = 3.3 ± 0.3 V, Ta = –20 to 75°C
Item
Symbol
Min
Max
Unit
Figure
EXTAL clock input frequency (clock mode 0)
fEX
25
66.67
MHz
23.1
EXTAL clock input cycle time (clock mode 0)
tEXcyc
15
40
ns
EXTAL clock input frequency (clock mode 1)
fEX
6.25
16.67
MHz
EXTAL clock input cycle time (clock mode 2)
tEXcyc
60
160
ns
EXTAL clock input low pulse width
tEXL
1.5
—
ns
EXTAL clock input high pulse width
tEXH
1.5
—
ns
EXTAL clock input rise time
tEXR
—
6
ns
EXTAL clock input fall time
tEXF
—
6
ns
CKIO clock input frequency
fCKI
20
66
MHz
CKIO clock input cycle time
tCKIcyc
15.2
40
ns
CKIO clock input low pulse width
tCKIL
1.5
—
ns
CKIO clock input high pulse width
tCKIH
1.5
—
ns
CKIO clock input rise time
tCKIR
—
6
ns
CKIO clock input fall time
tCKIF
—
6
ns
CKIO clock output frequency
fOP
25
66
MHz
CKIO clock output cycle time
tcyc
15.2
40
ns
CKIO clock output low pulse width
tCKOL
3
—
ns
CKIO clock output high pulse width
tCKOH
3
—
ns
CKIO clock output rise time
tCKOR
—
5
ns
CKIO clock output fall time
tCKOF
—
5
ns
CKIO2 clock output delay time
tCK2D
–3
3
ns
CKIO2 clock output rise time
tCK20R
—
7
ns
CKIO2 clock output fall time
tCK20F
—
7
ns
Power-on oscillation settling time
tOSC1
10
—
ms
23.4
RESETP setup time
tRESPS
20
—
ns
23.4, 23.5
RESETM setup time
tRESMS
6
—
ns
RESETP assert time
tRESPW
20
—
tcyc
RESETM assert time
tRESMW
20
—
tcyc
Standby return oscillation settling time 1
tOSC2
10
—
ms
23.5
Standby return oscillation settling time 2
tOSC3
10
—
ms
23.6
Standby return oscillation settling time 3
tOSC4
11
—
ms
23.7
PLL synchronization settling time 1
(standby canceled)
tPLL1
100
—
µs
23.8, 23.9
PLL synchronization settling time 2
(multiplication rete modified)
tPLL2
100
—
µs
23.10
IRQ/IRL interrupt determination time
(RTC used and standby mode)
tIRLSTB
100
—
µs
23.9
Rev. 5.00, 09/03, page 664 of 760
23.2
23.3
tEXcyc
tEXH
EXTAL*
(input)
1/2 VCCQ
tEXL
VIH
VIH
1/2 VCCQ
VIH
VIL
VIL
tEXF
tEXR
Note: * The clock input from the EXTAL pin.
Figure 23.1 EXTAL Clock Input Timing
tCKIcyc
tCKIH
CKIO
(input)
1/2 VCCQ
tCKIL
VIH
VIH
VIH
1/2 VCCQ
VIL
VIL
tCKIR
tCKIF
Figure 23.2 CKIO Clock Input Timing
tcyc
tCKOH
CKIO
(output)
1/2VCCQ
VOH
tCKOL
VOH
VOH
VOL
VOL
tCKOF
tCK2D
CKIO2
(output)
VOH
1/2VCCQ
tCKOR
tCK2D
VOH
VOH
VOL
VOL
tCK2OF
tCK2OR
Figure 23.3 CKIO Clock Output Timing
Rev. 5.00, 09/03, page 665 of 760
Stable oscillation
CKIO,
internal clock
VCC
VCC min
tRESPW
tOSC1
tRESPS
RESETP
Note: Oscillation settling time when built-in oscillator is used
Figure 23.4 Power-on Oscillation Settling Time
Stable oscillation
Standby
CKIO,
internal
clock
tOSC2
tRESPW/MW
tRESPS/MS
RESETP
RESETM
Note: Oscillation settling time when built-in oscillator is used in the oscillation off mode
Figure 23.5 Oscillation Settling Time at Standby Return (Return by Reset)
Rev. 5.00, 09/03, page 666 of 760
Standby
Stable oscillation
CKIO,
internal
clock
tOSC3
NMI
WAKEUP
Note: Oscillation settling time when built-in oscillator is used in the oscillation off mode
Figure 23.6 Oscillation Settling Time at Standby Return (Return by NMI)
Standby
Stable oscillation
CKIO,
internal
clock
tOSC4
IRL3 to IRL0
IRQ4 to IRQ0
PINT0/1
WAKEUP
Note: Oscillation settling time when built-in oscillator is used
in the oscillation off mode (only when RTC is used)
Figure 23.7 Oscillation Settling Time at Standby Return
(Return by IRQ4 to IRQ0, PINT0/1, IRL3 to IRL0)
Rev. 5.00, 09/03, page 667 of 760
Reset or NMI interrupt request
Stable input clock
Stable input clock
EXTAL input
or CKIO
input
PLL synchronization
tPLL1
PLL synchronization
PLL output,
CKIO output
Internal clock
STATUS 0
STATUS 1
Normal
Standby
Normal
Note: PLL oscillation settling time during the continued oscillation mode or
when clock is input from EXTAL pin or CKIO pin
Figure 23.8 PLL Synchronization Settling Time during Standby Recovery (Reset or NMI)
IRQ4 – IRQ0/IRL3 – IRL0 interrupt request
Stable input clock
Stable input clock
EXTAL input
or CKIO input
PLL synchronization
tIRLSTB
tPLL1
PLL synchronization
PLL output,
CKIO output
Internal clock
STATUS 0
STATUS 1
Normal
Standby
Normal
Note: PLL oscillation settling time during the continued oscillation mode or
when clock is input from EXTAL pin or CKIO pin
Figure 23.9 PLL Synchronization Settling Time during Standby Recovery
(IRQ/IRL or PINT0/PINT1 Interrupt)
Rev. 5.00, 09/03, page 668 of 760
Multiplication rate modified
EXTAL input*1
(CKIO input)
tPLL2
CKIO output*2
(PLL output)
Internal clock
Notes: 1. CKIO input in clock mode 7
2. PLL output in other than clock mode 7
Figure 23.10 PLL Synchronization Settling Time when Frequency Multiplication
Rate Modified
Rev. 5.00, 09/03, page 669 of 760
23.3.2
Control Signal Timing
Table 23.6 Control Signal Timing
Vcc = 3.3 ± 0.3 V, Vcc = 1.55 to 2.15 V, AVcc = 3.3 ± 0.3 V, Ta = –20 to 75°C
Item
Symbol
Min
Max
Unit
Figure
—
tcyc
23.11,
23.12
RESETP pulse width
1
RESETP setup time*
tRESPW
20
tRESPS
20
—
ns
RESETP hold time
tRESPH
4
—
ns
RESETM pulse width
tRESMW
3
20 *
—
tcyc
RESETM setup time
tRESMS
6
—
ns
RESETM hold time
tRESMH
34
—
ns
BREQ setup time
tBREQS
6
—
ns
BREQ hold time
1
NMI setup time *
tBREQH
4
—
ns
tNMIS
10
—
ns
NMI hold time
*2
23.14
23.12
tNMIH
4
—
ns
IRQ5–IRQ0 setup time *
tIRQS
10
—
ns
IRQ5–IRQ0 hold time
tIRQH
4
—
ns
IRQOUT delay time
tIRQOD
—
10
ns
23.13
BACK delay time
tBACKD
—
10
ns
23.14,
STATUS1, STATUS0 delay time
tSTD
—
10
ns
23.15
Bus tri-state delay time 1
tBOFF1
0
15
ns
Bus tri-state delay time 2
tBOFF2
0
15
ns
Bus buffer-on time 1
tBON1
0
15
ns
Bus buffer-on time 2
tBON2
0
15
ns
1
Notes: 1. RESETP, NMI, and IRQ5 to IRQ0 are asynchronous. Changes are detected at the
clock fall when the setup shown is used. When the setup cannot be used, detection
can be delayed until the next clock falls.
2. In the standby mode, tRESPW = tOSC1 (100 µs) when XTAL oscillation is continued and
tRESPW = tOSC2 (10 ms) when XTAL oscillation is off. In the sleep mode, tRESPW = tPLL1
(100 µs).
When the clock multiplication ratio is changed, tRESPW = tPLL1 (100 µs).
3. In the standby mode, tRESMW = tOSC2 (10 ms). In the sleep mode, RESETM must be kept
low until STATUS (0-1) changes to reset (HH). When the clock multiplication ratio is
changed, RESETM must be kept low until STATUS (0-1) changes to reset (HH).
Rev. 5.00, 09/03, page 670 of 760
CKIO
tRESPS/MS
tRESPS/MS
tRESPW/MW
RESETP
RESETM
Figure 23.11 Reset Input Timing
CKIO
tRESPH/MH
tRESPS/MS
VIH
RESETP
RESETM
VIL
tNMIH
tNMIS
VIH
NMI
VIL
tIRQH
tIRQS
VIH
IRQ5 to IRQ0
VIL
Figure 23.12 Interrupt Signal Input Timing
CKIO
tIRQOD
tIRQOD
IRQOUT
Figure 23.13 IRQOUT
QOUT Timing
Rev. 5.00, 09/03, page 671 of 760
CKIO
tBREQH tBREQS
tBREQH tBREQS
BREQ
tBACKD
tBACKD
BACK
RD, RD/WR,
RAS, CAS,
CSn, WEn, BS,
MCSn
tBOFF2
tBON2
tBOFF1
tBON1
A25 to A0,
D31 to D0
Figure 23.14 Bus Release Timing
Normal mode
Standby mode
Normal mode
CKIO
tSTD
tSTD
tBOFF2
tBON2
tBOFF1
tBON1
STATUS 0
STATUS 1
RD, RD/WR,
RAS, CAS,
CSn, WEn,
BS, MCSn
A25 to A0,
D31 to D0
Figure 23.15 Pin Drive Timing at Standby
Rev. 5.00, 09/03, page 672 of 760
23.3.3
AC Bus Timing
Table 23.7 Bus Timing
Clock Modes 0/1/2/7, VccQ = 3.3 ± 0.3 V, Vcc = 1.55 to 2.15 V, AVcc = 3.3 ± 0.3 V,
Ta = –20 to 75°C
Item
Symbol
Min
Max
Unit
Figure
Address delay time
tAD
1.5
12
ns
23.16–23.36, 23.39–23.46
Address setup time
1
Address hold time*
tAS
0
—
ns
23.16–23.18
tAH
4
—
ns
23.16–23.21
BS delay time
tBSD
—
10
ns
23.16–23.36, 23.40–23.46
CS delay time 1
tCSD1
0
10
ns
23.16–23.21, 23.40–23.46
CS delay time 2
tCSD2
—
10
ns
23.16–23.21
CS delay time
(SDRAM access)
tCSD3
1.5
10
ns
23.22–23.39
Read/write delay time
tRWD
1.5
10
ns
23.16–23.46, 23.39–23.46
Read/write hold time
tRWH
0
—
ns
23.16–23.21
Read strobe delay time
tRSD
—
10
ns
23.16–23.21 23.40–23.43
Read data setup time 1
tRDS1
6
—
ns
23.16–23.21, 23.40–23.46
Read data setup time 2
2
Read data hold time 1*
tRDS2
5
—
ns
23.22–23.25, 23.30–23.33
tRDH1
0
—
ns
23.16–23.21, 23.40–23.46
Read data hold time 2
tRDH2
1
—
ns
23.22–23.25, 23.30–23.33
Write enable delay time
tWED
—
10
ns
23.16–23.18, 23.40, 23.41
Write data delay time 1
tWDD1
—
14
ns
23.16–23.18, 23.40, 23.41, 23.44–23.46
Write data delay time 2
tWDD2
1.5
12
ns
23.26–23.29, 23.34–23.36
Write data hold time 1
tWDH1
1.5
—
ns
23.16–23.18, 23.40, 23.41, 23.44–23.46
Write data hold time 2
tWDH2
1.5
—
ns
23.26–23.29, 23.34–23.36
Write data hold time 3
tWDH3
2
—
ns
23.16–23.18
Write data hold time 4
tWDH4
2
—
ns
23.40, 23.41, 23.44–23.46
WAIT setup time
tWTS
5
—
ns
23.17–23.21, 23.41, 23.43, 23.45, 23.46
WAIT hold time
tWTH
0
—
ns
23.17–23.21, 23.41, 23.43, 23.45, 23.46
RAS delay time 2
tRASD2
1.5
10
ns
23.22–23.39
CAS delay time 2
tCASD2
1.5
10
ns
23.22–23.39
DQM delay time
tDQMD
1.5
10
ns
23.22–23.36
CKE delay time
tCKED
1.5
10
ns
23.38
Rev. 5.00, 09/03, page 673 of 760
Item
Symbol
Min
Max
Unit
Figure
ICIORD delay time
tICRSD
—
10
ns
23.44–23.46
ICIOWR delay time
tICWSD
—
10
ns
23.44–23.46
IOIS16 setup time
tIO16S
6
—
ns
23.45, 23.46
IOIS16 hold time
tIO16H
4
—
ns
23.45, 23.46
DACK delay time 1
tDAKD1
(Reference for CKIO rise)
—
10
ns
23.16–23.36, 23.39–23.46
DACK delay time 2
tDAKD2
(Reference for CKIO fall)
—
10
ns
23.16–23.22
Notes: 1. Specified based on the slowest negate timing for CSn, RD, or WEn
2. Specified based on whichever negate timing is faster, CSn or RD.
Rev. 5.00, 09/03, page 674 of 760
23.3.4
Basic Timing
T1
T2
CKIO
tAD
tAD
tAS
A25 to A0
tAH
tCSD1
tRWH
tCSD2
CSn
tRDH1
tRWD
tRWD
RD/WR
tAH
tRSD
tRSD
tRWH
RD
(read)
tRDH1
tRDS1
D31 to D0
(read)
tAH
tWED
tRWH
tWED
WEn
(write)
tWDH3
tWDD1
tWDH1
D31 to D0
(write)
tBSD
tBSD
BS
tDAKD1
tDAKD1
DACKn
Figure 23.16 Basic Bus Cycle (No Wait)
Rev. 5.00, 09/03, page 675 of 760
T1
Tw
T2
CKIO
tAD
tAD
tAS
A25 to A0
tAH
tCSD2
tCSD1
tRWH
CSn
tRDH1
tRWD
tRWD
RD/WR
tAH
tRSD
tRWH
tRSD
RD
(read)
tRDH1
tRDS1
D31 to D0
(read)
tWED
tAH
tWED
tRWH
WEn
(write)
tWDH3
tWDD1
tWDH1
D31 to D0
(write)
tBSD
tBSD
BS
tDAKD1
tDAKD1
DACKn
tWTS tWTH
WAIT
Figure 23.17 Basic Bus Cycle (One Wait)
Rev. 5.00, 09/03, page 676 of 760
T1
Tw
Tw
T2
CKIO
tAD
tAS
tAD
A25 to A0
tAH
tCSD1
tCSD2
tRWH
CSn
tRDH1
tRWD
tRWD
RD/WR
tAH
tRSD
tRSD
RD
(read)
tRWH
tRDH1
tRDS1
D31 to D0
(read)
tAH
tWED
tWED
WEn
(write)
tRWH
tWDH3
tWDD1
tWDH1
D31 to D0
(write)
tBSD
tBSD
BS
tDAKD2
tDAKD1
DACKn
tWTS tWTH
tWTS tWTH
WAIT
Figure 23.18 Basic Bus Cycle (External Wait, WAITSEL = 1)
Rev. 5.00, 09/03, page 677 of 760
23.3.5
Burst ROM Timing
T1
TB2
TB1
TB2
TB1
TB2
TB1
T2
CKIO
tAD
tAD
A25 to A4
tAD
tAD
A3 to A0
tAH
tCSD2
tCSD1
tRWH
CSn
tRDH1
tRWD
tRWD
RD/WR
tAH
tRSD
tRSD
tRSD tAH
tRSD tRWH
RD
tRDH1
tRDH1
tRDS
tRDS1
D31 to D0
tBSD
tBSD
tBSD
tBSD
BS
tDAKD1
tDAKD2
DACKn
tWTS tWTH
tWTS tWTH
tWTS tWTH
WAIT
Note: In the write cycle, the basic bus cycle, the basic bus cycle is performed.
Figure 23.19 Burst ROM Bus Cycle (No Wait)
Rev. 5.00, 09/03, page 678 of 760
T1
Tw
Tw
TB2
TB1
Tw
TB2
T2
T2
CKIO
tAD
tAD
A25 to A4
tAD
A3 to A0
tAH
tCSD2
tCSD1
tRWH
CSn
tRDH1
tRWD
tRWD
RD/WE
tAH
tRSD
tRSD tAH
tRSD
tRSD
tRSD
tRWH
RD
tRDH1
tRDH1
tRDS1
tRDH1
tRDS1
D31 to D0
tBSD
tBSD
tBSD
tBSD
BS
tDAKD1
tDAKD2
DACKn
tWTS tWTH
tWTS tWTH
WAIT
Note: In the write cycle, the basic bus cycle is performed.
Figure 23.20 Burst ROM Bus Cycle (Two Waits)
Rev. 5.00, 09/03, page 679 of 760
T1
Tw
Tw
TB2
TB1
TBw
T2
CKIO
tAD
tAD
A25 to A4
tAD
A3 to A0
tAH
tCSD2
tCSD1
tRWH
CSn
tRDH1
tRWD
tRWD
RD/WR
tAH
tRSD
tRSD1 tAH
tRSD1
tRSD tRWH
RD
tRDH1
tRDH1
tRDS1
tRDS
D31 to D0
tBSD
tBSD
tBSD
tBSD
BS
tDAKD2
tDAKD1
DACKn
tWTS tWTH
tWTS tWTH
tWTS tWTH
tWTS tWTH
WAIT
Note: In the write cycle, the basic bus cycle is performed.
Figure 23.21 Burst ROM Bus Cycle (External Wait, WAITSEL = 1)
Rev. 5.00, 09/03, page 680 of 760
23.3.6
Synchronous DRAM Timing
Tc1
Tr
(Tpc)
Tc2
CKIO
tAD
tAD
Row address
A25 to A16
tAD
A12 or A10
tAD
A15 to A0
Read A
command
Row address
tAD
tAD
tAD
Row address
tAD
Column address
tCSD3
tCSD3
tRWD
tRWD
CSn
RD/WR
tRASD2
tRASD2
RAS
tCASD2
tCASD2
CAS
tDQMD
tDQMD
DQMxx
tRDS2 tRDH2
D31 to D0
tBSD
tBSD
BS
CKE
(High)
tDAKD1
tDAKD1
DACKn
Figure 23.22 Synchronous DRAM Read Bus Cycle (RCD = 0, CAS Latency = 1, TPC = 0)
Rev. 5.00, 09/03, page 681 of 760
Tr
Trw
Trw
Tc1
Tcw
Td1
(Tpc)
(Tpc)
CKIO
tAD
tAD
A25 to A16
Row address
tAD
A12 or A10
tAD
Read A
command
Row address
tAD
tAD
Row address
A15 to A0
tAD
tAD
Column address
tCSD3
tCSD3
tRWD
tRWD
CSn
RD/WR
tRASD2
tRASD2
RAS
tCASD2
tCASD2
CAS
tDQMD
tDQMD
DQMxx
tRDS2 tRDH2
D31 to D0
tBSD
tBSD
BS
CKE
(High)
tDAKD1
tDAKD1
DACKn
Figure 23.23 Synchronous DRAM Read Bus Cycle (RCD = 2, CAS Latency = 2, TPC = 1)
Rev. 5.00, 09/03, page 682 of 760
Tr
Tc1
Tc2/Td1 Tc3/Td2
Tc4/Td3
Td4
(Tpc)
(Tpc)
CKIO
tAD
tAD
Row address
A25 to A16
tAD
tAD
Row
address
A12 or A10
tAD
A15 to A0
tAD
Read command
tAD
Row
address
tAD
Read A
command
tAD
Column address (1-4)
tCSD3
tCSD3
tRWD
tRWD
CSn
RD/WR
tRASD2
tRASD2
RAS
tCASD2
tCASD2
CAS
tDQMD
tDQMD
DQMxx
tRDS2 tRDH2
tRDS2 tRDH2
D31 to D0
tBSD
tBSD
BS
CKE
(High)
tDAKD1
tDAKD1
DACKn
Figure 23.24 Synchronous DRAM Read Bus Cycle (Burst Read (Single Read × 4), RCD = 0,
CAS Latency = 1, TPC = 1)
Rev. 5.00, 09/03, page 683 of 760
Tr
Trw
Tc1
Tc2
Tc3 Tc4/Td1 Td2
Td3
Td4
(Tpc)
CKIO
tAD
A25 to A16
tAD
Row address
tAD
A12 or A10
tAD
tAD
Row
address
tAD
Read command
tAD
A15 to A0
Row
address
tAD
tAD
tAD
Column address (1-4)
tCSD3
tCSD3
CSn
tRWD
tRWD
RD/WR
tRASD2
tRASD2
RAS
tCASD2
tCASD2
CAS
tDQMD
tDQMD
DQMxx
tRDS2 tRDH2
tRDS2 tRDH2
D31 to D0
(read)
tBSD
tBSD
BS
CKE
(High)
tDAKD1
tDAKD1
DACKn
Figure 23.25 Synchronous DRAM Read Bus Cycle (Burst Read (Single Read × 4), RCD = 1,
CAS Latency = 3, TPC = 0)
Rev. 5.00, 09/03, page 684 of 760
Tc1
Tr
(Trwl)
(Tpc)
CKIO
tAD
A25 to A16
tAD
Row address
tAD
A12 or A10
tAD
Row address
Write A
command
tAD
tAD
Row address
A15 to A0
tAD
tAD
Column address
tCSD3
tCSD3
CSn
tRWD
tRWD
tRASD2
tRASD2
tRWD
RD/WR
RAS
tCASD2
tCASD2
tDQMD
tDQMD
tWDD2
tWDH2
tBSD
tBSD
CAS
DQMxx
D31 to D0
BS
(High)
CKE
tDAKD1
tDAKD1
DACKn
Figure 23.26 Synchronous DRAM Write Bus Cycle (RCD = 0, TPC = 0, TRWL = 0)
Rev. 5.00, 09/03, page 685 of 760
Trw
Tr
Trw
Tc1
(Trwl)
(Trwl)
(Tpc)
(Tpc)
CKIO
tAD
A25 to A16
tAD
Row address
tAD
A12 or A10
A15 to A0
tAD
tAD
tAD
Write A
command
Row
address
tAD
tAD
tAD
tAD
Column
address
Row
address
tCSD1
tCSD1
CSn
tRWD
tRWD
tRWD
tCASD2
tCASD2
tDQMD
tDQMD
tWDD2
tWDH2
tBSD
tBSD
RD/WR
tRASD2
tRASD2
RAS
CAS
DQMxx
D31 to D0
BS
(High)
CKE
tDAKD1
tDAKD1
DACKn
Figure 23.27 Synchronous DRAM Write Bus Cycle (RCD = 2, TPC = 1, TRWL = 1)
Rev. 5.00, 09/03, page 686 of 760
Tr
Tc1
Tc2
Tc3
Tc4
(Trwl)
(Tpc)
(Tpc)
CKIO
tAD
A25 to A16
tAD
Row address
tAD
A12 or A10
A15 to A0
tAD
Row
address
tAD
tAD
tAD
Write command
tAD
Write A
command
tAD
Row
address
Column address (1-4)
tCSD3
tCSD3
CSn
tRWD
tRWD
tRWD
tRASD2
tRASD2
RD/WR
RAS
tCASD2
tCASD2
tDQMD
tDQMD
CAS
DQMxx
tWDD2
tWDD2
tWDH2
D31 to D0
tBSD
tBSD
BS
(High)
CKE
tDAKD1
tDAKD1
DACKn
Figure 23.28 Synchronous DRAM Write Bus Cycle (Burst Mode (Single Write × 4),
RCD = 0, TPC = 1, TRWL = 0)
Rev. 5.00, 09/03, page 687 of 760
Tr
Trw
Tc1
Tc2
Td4
Tc3
(Trwl)
(Tpc)
CKIO
tAD
tAD
Row address
A25 to A16
tAD
A12 or A10
A15 to A0
tAD
tAD
Row
address
tAD
tAD
Write command
tAD
Write A
command
tAD
Row
address
tCSD3
Column address (1-4)
tCSD3
CSn
tRWD
tRWD
tRWD
tCASD2
tCASD2
tDQMD
tDQMD
RD/WR
tRASD2
tRASD2
RAS
CAS
DQMxx
tWDD2
tWDD2
tWDH2
D31 to D0
tBSD
tBSD
BS
CKE
(High)
tDAKD1
tDAKD1
DACKn
Figure 23.29 Synchronous DRAM Write Bus Cycle (Burst Mode (Single Write × 4),
RCD = 1, TPC = 0, TRWL = 0)
Rev. 5.00, 09/03, page 688 of 760
Tnop
Tc1
Tc2/Td1 Tc3/Td2 Tc4/Td3
Td4
CKIO
tAD
tAD
A25 to A16
Row address
tAD
tAD
Read command
A12 or A10
tAD
tAD
Column address
A15 to A0
tCSD3
tCSD3
tRWD
tRWD
CSn
RD/WR
tRASD2
RAS
tCASD2
tCASD2
CAS
tDQMD
tDQMD
DQMxx
tRDS2 tRDH2
tRDS2 tRDH2
D31 to D0
tBSD
tBSD
BS
CKE
(High)
tDAKD1
tDAKD1
DACKn
Figure 23.30 Synchronous DRAM Burst Read Bus Cycle
(RAS Down, Same Row Address, CAS Latency = 1)
Rev. 5.00, 09/03, page 689 of 760
Tc1
Tc2
Tc3/Td1 Tc4/Td2
Td3
Td4
CKIO
tAD
tAD
A25 to A16
Row address
tAD
tAD
Read command
A12 or A10
tAD
tAD
A15 to A0
Column address
tCSD3
tCSD3
tRWD
tRWD
CSn
RD/WR
tRASD2
RAS
tCASD2
tCASD2
CAS
tDQMD
tDQMD
DQMxx
tRDS2 tRDH2
tRDS2 tRDH2
D31 to D0
tBSD
tBSD
BS
CKE
(High)
tDAKD1
tDAKD1
DACKn
Figure 23.31 Synchronous DRAM Burst Read Bus Cycle
(RAS Down, Same Row Address, CAS Latency = 2)
Rev. 5.00, 09/03, page 690 of 760
Tr
Tp
Tc1
Tc2/Td1
Tc3/Td2
Tc4/Td3
Td4
CKIO
tAD
tAD
Row address
A25 to A16
tAD
tAD
tAD
tAD
Row
address
A12 or A10
tAD
Read command
tAD
tAD
Row
address
A15 to A0
Column address
tCSD3
tCSD3
CSn
tRWD
tRWD
tRWD
RD/WR
tRASD2
tRASD2
RAS
tCASD2
tCASD2
CAS
tDQMD
tDQMD
tDQMD
DQMxx
tRDS2 tRDH2
tRDS2 tRDH2
D31 to D0
tBSD
tBSD
BS
CKE
(High)
tDAKD1
tDAKD1
DACKn
Figure 23.32 Synchronous DRAM Burst Read Bus Cycle
(RAS Down, Different Row Address, TPC = 0, RCD = 0, CAS Latency = 1)
Rev. 5.00, 09/03, page 691 of 760
Tp
Tpw
Tr
Tc1
Tc2/Td1
Tc3/Td2
Tc4/Td3
Td4
CKIO
tAD
tAD
Row address
A25 to A16
tAD
tAD
tAD
tAD
Row
address
A12 or A10
tAD
Read command
tAD
tAD
Row
address
A15 to A0
Column address
tCSD3
tCSD3
CSn
tRWD
tRWD
tRASD2
tRASD2
tRWD
RD/WR
tRASD2
tRASD2
RAS
tCASD2
tCASD2
CAS
tDQMD
tDQMD
tDQMD
DQMxx
tRDS2 tRDH2
tRDS2 tRDH2
D31 to D0
tBSD
tBSD
BS
CKE
(High)
tDAKD1
tDAKD1
DACKn
Figure 23.33 Synchronous DRAM Burst Read Bus Cycle
(RAS Down, Different Row Address, TPC = 1, RCD = 0, CAS Latency = 1)
Rev. 5.00, 09/03, page 692 of 760
Tc1
Tc2
Tc3
Tc4
CKIO
tAD
tAD
Row address
A25 to A16
tAD
tAD
Write command
A12 or A10
tAD
tAD
Column address
A15 to A0
tCSD3
tCSD3
tRWD
tRWD
tRASD2
tRASD2
tCASD2
tCASD2
tDQMD
tDQMD
tWDD2
tWDD2
tBSD
tBSD
CSn
RD/WR
RAS
CAS
DQMxx
D31 to D0
BS
CKE
(High)
tDAKD1
tDAKD1
DACKn
Figure 23.34 Synchronous DRAM Burst Write Bus Cycle
(RAS Down, Same Row Address)
Rev. 5.00, 09/03, page 693 of 760
Tr
Tp
Tc1
Tc2
Tc3
Tc4
CKIO
tAD
tAD
Row address
A25 to A16
tAD
tAD
Row
address
A12 or A10
tAD
Write command
tAD
Row
address
A15 to A0
tAD
tAD
tCSD3
tAD
Column address
tCSD3
CSn
tRWD
tRWD
tRWD
tRWD
RD/WR
tRASD2
tRASD2
RAS
tCASD2
tCASD2
tDQMD
tDQMD
tWDD2
tWDD2
tBSD
tBSD
CAS
tDQMD
DQMxx
D31 to D0
BS
CKE
(High)
tDAKD1
tDAKD1
DACKn
Figure 23.35 Synchronous DRAM Burst Write Bus Cycle
(RAS Down, Different Row Address, TPC = 0, RCD = 0)
Rev. 5.00, 09/03, page 694 of 760
Tp
Tpw
Tr
Trw
Tc1
Tc2
Tc3
Td4
CKIO
tAD
tAD
Row address
A25 to A16
tAD
tAD
tAD
tAD
Row
address
A12 or A10
tAD
tAD
Write command
tAD
Row
address
A15 to A0
tAD
Column address
tCSD3
tCSD3
CSn
tRWD
tRWD
tRASD2
tRASD2
tRWD
tRWD
tCASD2
tCASD2
tDQMD
tDQMD
tWDD2
tWDD2
tBSD
tBSD
RD/WR
tRASD2
tRASD2
RAS
CAS
tDQMD
DQMxx
D31 to D0
BS
CKE
(High)
tDAKD1
tDAKD1
DACKn
Figure 23.36 Synchronous DRAM Burst Write Bus Cycle
(RAS Down, Different Row Address, TPC = 1, RCD = 1)
Rev. 5.00, 09/03, page 695 of 760
Tp
Tpc
TRr
TRrw
TRrw
(Tpc)
(Tpc)
CKIO
CKE
(High)
tCSD3
tCSD3
tCSD3
tCSD3
tRASD2
tRASD2
tRASD2
tRASD2
tCASD2
tCASD2
CSn
RAS3x
CASxx
tRWD
tRWD
RD/WR
Figure 23.37 Synchronous DRAM Auto-Refresh Timing (TRAS = 1, TPC = 1)
Rev. 5.00, 09/03, page 696 of 760
Tp
Tpc
TRa1
(TRs2)
(TRs2)
TRs3
(Tpc)
(Tpc)
CKIO
t CKED
t CKED
CKE
t CSD3 t CSD3 t CSD3 t CSD3
CSn
t RASD2 t RASD2 t RASD2 t RASD2
RAS
t CASD2 t CASD2
CAS
t RWD
t RWD
t RWD
RD/WR
Figure 23.38 Synchronous DRAM Self-Refresh Cycle (TRAS = 1, TPC = 1)
Rev. 5.00, 09/03, page 697 of 760
TRp2
TRp1
TRp3
TRp4
TMw1
TMw2
TMw3
TMw4
CKIO
tAD
tAD
tAD
tAD
tAD
tAD
tAD
tAD
tAD
A13 or A11
tAD
tAD
A12 or A10
A11 to A2
or A9 to A2
tCSD3
tCSD3
CSn
tRWD
tRWD
tRWD
tRASD2
tRASD2
RD/WR
tRASD2
tRASD2
tCASD2
tCASD2
RAS
CASxx
D31 to D0
CKE
(High)
tDAKD1
tDAKD1
DACKn
Figure 23.39 Synchronous DRAM Mode Register Write Cycle
Rev. 5.00, 09/03, page 698 of 760
23.3.7
PCMCIA Timing
Tpcm1
Tpcm2
CKIO
tAD
tAD
tCSD1
tCSD1
tRWD
tRWD
A25 to A0
CExx
RD/WR
tRSD
tRSD
RD
(read)
tRDH1
tRDS1
D15 to D0
(read)
tWED
tWED
WE1
(write)
tWDH4
tWDH1
tWDD1
D15 to D0
(write)
tBSD
tBSD
BS
tDAKD1
tDAKD1
DACKn
Figure 23.40 PCMCIA Memory Bus Cycle (TED = 0, TEH = 0, No Wait)
Rev. 5.00, 09/03, page 699 of 760
Tpcm0
Tpcm0w
Tpcm1
Tpcm1w
Tpcm1w
Tpcm2
Tpcm2w
CKIO
tAD
tAD
tCSD1
tCSD1
tRWD
tRWD
A25 to A0
CExx
RD/WR
tRSD
tRSD
RD
(read)
tRDH1
tRDS1
D15 to D0
(read)
tWED
tWED
WE1
(write)
tWDH4
tWDD1
tWDH1
D15 to D0
(write)
tBSD
tBSD
BS
tDAKD1
tDAKD1
DACKn
tWTS tWTH tWTS tWTH
WAIT
Figure 23.41 PCMCIA Memory Bus Cycle
(TED = 2, TEH = 1, One Wait, External Wait, WAITSEL = 1)
Rev. 5.00, 09/03, page 700 of 760
Tpcm1
Tpcm2
Tpcm1
Tpcm2
Tpcm1
Tpcm2
Tpcm1
Tpcm2
CKIO
tAD
tAD
A25 to A4
tAD
tAD
tAD
tAD
A3 to A0
tCSD1
tCSD1
tRWD
tRWD
CExx
RD/WR
tRSD
tRSD
RD
(read)
tRSD
tRSD
tRDH1
tRDS1
tRDH1
tRDS1
D15 to D0
(read)
tBSD
tBSD
tBSD
tBSD
BS
tDAKD1
tDAKD1
DACKn
Note: Even though burst mode is set, write cycle operation is the same as in normal mode.
Figure 23.42 PCMCIA Memory Bus Cycle
(Burst Read, TED = 0, TEH = 0, No Wait)
Rev. 5.00, 09/03, page 701 of 760
Tpcm0 Tpcm1 Tpcm1w Tpcm1w Tpcm1w Tpcm2 Tpcm1 Tpcm1w Tpcm2 Tpcm2w
CKIO
tAD
tAD
A25 to A4
tAD
tAD
tAD
A3 to A0
tCSD1
tCSD1
tRWD
tRWD
CExx
RD/WR
tRSD
tRSD
RD
(read)
tRSD
tRSD
tRDH1
tRDH1
tRDS1
tRDS1
D15 to D0
(read)
tBSD
tBSD
tBSD
tBSD
BS
tDAKD1
tDAKD1
DACKn
tWTS tWTH
tWTS tWTH
tWTS tWTH
WAIT
Note: Even though burst mode is set, the write cycle operation is the same as in normal mode.
Figure 23.43 PCMCIA Memory Bus Cycle
(Burst Read, TED = 1, TEH = 1, Two Waits, Burst Pitch = 3, WAITSEL = 1)
Rev. 5.00, 09/03, page 702 of 760
Tpci1
Tpci2
CKIO
tAD
tAD
tCSD1
tCSD1
tRWD
tRWD
A25 to A0
CExx
RD/WR
tICRSD
tICRSD
ICIORD
(read)
tRDH1
tRDS1
D15 to D0
(read)
tICWSD
tICWSD
ICIOWR
(write)
tWDH4
tWDH1
tWDD1
D15 to D0
(write)
tBSD
tBSD
BS
tDAKD1
tDAKD1
DACKn
Figure 23.44 PCMCIA I/O Bus Cycle (TED = 0, TEH = 0, No Wait)
Rev. 5.00, 09/03, page 703 of 760
Tpci0
Tpci0w
Tpci1
Tpci1w
Tpci1w
Tpci2
Tpci2w
CKIO
tAD
tAD
tCSD1
tCSD1
tRWD
tRWD
A25 to A0
CExx
RD/WR
tICRSD
tICRSD
ICIORD
(read)
tRDH1
tRDS1
D15 to D0
(read)
tICWSD
tICWSD
ICIOWR
(write)
tWDH4
tWDH1
tWDD1
D15 to D0
(write)
tBSD
tBSD
BS
tDAKD1
tDAKD1
DACKn
tWTS tWTH
tWTS tWTH
WAIT
tIO16S tIO16H
IOIS16
Figure 23.45 PCMCIA I/O Bus Cycle
(TED = 2, TEH = 1, One Wait, External Wait, WAITSEL = 1)
Rev. 5.00, 09/03, page 704 of 760
Tpci0
Tpci1
Tpci1w
Tpci2
Tpci1
Tpci1w
Tpci2
Tpci2w
CKIO
tAD
tAD
A25 to A4
tAD
tAD
tAD
tCSD1
tCSD1
tCSD1
A0
CExx
tRWD
tRWD
RD/WR
tICRSD
tICRSD
ICIORD
(read)
tICRSD
tICRSD
tRDH1
tRDH1
tRDS1
tRDS1
D15 to D0
(read)
tICWSD
tICWSD
tICWSD
tICWSD
ICIOWR
(write)
tWDH4
tWDD1
tWDH4
tWDD1
tWDH1
D15 to D0
(write)
tBSD
tBSD
tBSD
tBSD
BS
tDAKD1
tDAKD1
DACKn
tWTS tWTH
tWTS tWTH
WAIT
tIO16S tIO16H
IOIS16
Figure 23.46 PCMCIA I/O Bus Cycle
(TED = 1, TEH = 1, One Wait, Bus Sizing, WAITSEL = 1)
Rev. 5.00, 09/03, page 705 of 760
23.3.8
Peripheral Module Signal Timing
Table 23.8 Peripheral Module Signal Timing
VccQ = 3.3 ± 0.3 V, Vcc = 1.55 to 2.15 V, AVcc = 3.3 ± 0.3 V, Ta = –20 to 75°C
Module
Item
Symbol
Min
Max
Unit
Figure
TMU,
RTC
Timer input setup time
tTCLKS
15
—
ns
23.47
Timer clock input setup time
tTCKS
15
—
Timer clock
pulse width
tTCKWH
1.5
—
SCI
Port
DMAC
Edge specification
23.48
Pcyc
tTCKWL
2.5
—
Oscillation settling time
tROSC
3
—
s
Input clock
cycle
tSCYC
4
—
Pcyc* 23.50
6
—
23.51
23.50
Both edge specification
Asynchronization
Clock synchronization
23.49
Input clock rise time
tSCKR
—
1.5
Input clock fall time
tSCKF
—
1.5
Input clock pulse width
tSCKW
0.4
0.6
tscyc
Transmission data delay time
tTXD
—
100
ns
23.51
Receive data setup time (clock
synchronization)
tRXS
100
—
Receive data hold time (clock
synchronization)
tRXH
100
—
RTS delay time
tRTSD
—
100
CTS setup time (clock synchronization)
tCTSS
100
—
CTS hold time (clock synchronization)
tCTSH
100
—
Output data delay time
tPORTD
—
17
ns
23.52
Input data setup time
tPORTS1
15
—
Input data hold time
tPORTH1
8
—
Input data setup time
tPORTS2
tcyc +
15
—
Input data hold time
tPORTH2
8
—
Input data setup time
tPORTS3
3 × tcyc —
+ 15
Input data hold time
tPORTH3
8
—
DREQ setup time
tDRQS
6
—
ns
23.53
DREQ hold time
tDREQH
4
—
tDRAKD
—
10
DRAK delay time
Note: * Pcyc is the P clock cycle.
Rev. 5.00, 09/03, page 706 of 760
23.54
CKIO
tTCLKS
TCLK
(input)
Figure 23.47 TCLK Input Timing
tTCKS
CKIO
tTCKS
TCLK
(input)
tTCKWL
tTCKWH
Figure 23.48 TCLK Clock Input Timing
Stable
oscillation
RTC crystal
oscillator
VCC
VCCmin
tROSC
Figure 23.49 Oscillation Settling Time at RTC Crystal Oscillator Power-on
tSCKW
SCK
(input)
tSCKR
tSCKF
tSCYC
Figure 23.50 SCK Input Clock Timing
Rev. 5.00, 09/03, page 707 of 760
tSCYC
SCK
tTXD
TxD
(data transmissiion)
RxD
(data
reception)
tRXS
tRXH
tCTSS
tCTSH
tRTSD
RTS
CTS
Figure 23.51 SCI I/O Timing in Clock Synchronous Mode
CKIO
tPORTS1 tPORTH1
PORT 7 to 0
(read)
(B:P clock ratio = 1:1)
tPORTS2 tPORTH2
PORT 7 to 0
(read)
(B:P clock ratio = 2:1)
tPORTS3 tPORTH3
PORT 7 to 0
(read)
(B:P clock ratio = 4:1)
tPORTD
PORT 7 to 0
(write)
Figure 23.52 I/O Port Timing
CKIO
tDREQS
tDREQH
DREQn
Figure 23.53 DREQ Input Timing
Rev. 5.00, 09/03, page 708 of 760
CKIO
tDRAKD
tDRAKD
DRAK0/1
Figure 23.54 DRAK Output Timing
23.3.9
UDI-Related Pin Timing
Table 23.9 UDI-Related Pin Timing
VccQ = 3.3 ± 0.3V, Vcc = 1.55 to 2.15 V, AVcc = 3.3 ± 0.3V, Ta = –20 to 75°C
Item
Symbol
Min
Max
Unit
Figure
TCK cycle time
tTCKCYC
50
—
ns
23.55
TCK high pulse width
tTCKH
12
—
ns
TCK low pulse width
tTCKL
12
—
ns
TCK rise/fall time
tTCKf
—
4
ns
TRST setup time
tTRSTS
12
—
ns
TRST hold time
tTRSTH
50
—
tcyc
TDI setup time
tTDIS
10
—
ns
TDI hold time
tTDIH
10
—
ns
TMS setup time
tTMSS
10
—
ns
TMS hold time
tTMSH
10
—
ns
TDO delay time
tTDOD
—
16
ns
ASEMD0 setup time
tASEMDH
12
—
ns
ASEMD0 hold time
tASEMDS
12
—
ns
23.56
23.57
23.58
tTCKCYC
tTCKH
tTCKL
VIH VIH
1/2VccQ
VIL VIL
tTCKf
VIH
1/2VccQ
tTCKf
Note: When clock is input from TCK pin
Figure 23.55 TCK Input Timing
Rev. 5.00, 09/03, page 709 of 760
RESETP
tTRSTS
tTRSTH
TRST
Figure 23.56 TRST Input Timing (Reset Hold)
TCK
tTCKCYC
tTDIS
tTDIH
tTMSS
tTMSH
TDI
TMS
tTDOD
TDO
Figure 23.57 UDI Data Transfer Timing
RESETP
tASEMD0S
tASEMD0H
ASEMD0
Figure 23.58 ASEMD0 Input Timing
Rev. 5.00, 09/03, page 710 of 760
23.3.10 AC Characteristics Measurement Conditions
• I/O signal reference level: VccQ/2 (VccQ = 3.3 ± 0.3 V, Vcc = 1.55 to 2.15 V)
• Input pulse level: Vss to 3.0 V (where RESETP, RESETM, ASEND0, IRLS3 to IRLS0, IRL3
to IRL0, ADTRG, PINT15 to PINT0, TRST, RxD1, CA, NMI, IRQ5–IRQ0, CKIO, and
MD5–MD0 are within Vss to Vcc)
• Input rise and fall times: 1 ns
IOL
DUT output
LSI output pin
VREF
CL
IOH
Notes: 1. CL is the total value that includes the capacitance of measurement
instruments, etc., and is set as follows for each pin.
30pF: CKIO, RAS, CAS, CS0, CS2–CS6, CE2A, CE2B, BACK
50pF: All other pins
2. IOL and IOH are the values shown in table 23.3.
Figure 23.59 Output Load Circuit
Rev. 5.00, 09/03, page 711 of 760
23.3.11
Delay Time Variation Due to Load Capacitance
A graph (reference data) of the variation in delay time when a load capacitance greater than that
stipulated (30 or 50 pF) is connected to this LSI's pins is shown below. The graph shown in figure
23.60 should be taken into consideration in the design process if the stipulated capacitance is
exceeded in connecting an external device.
If the connected load capacitance exceeds the range shown in figure 23.60, the graph will not be a
straight line.
Delay Time [ns]
+3
+2
+1
+0
+0
+10
+20
+30
+40
Load Capacitance [pF]
Figure 23.60 Load Capacitance vs. Delay Time
Rev. 5.00, 09/03, page 712 of 760
+50
23.4
A/D Converter Characteristics
Table 23.10 lists the A/D converter characteristics.
Table 23.10 A/D Converter Characteristics
VccQ = 3.3 ± 0.3 V, Vcc = 1.55 to 2.15 V, AVcc = 3.3 ± 0.3 V, Ta = –20 to 75°C
Item
Min
Typ
Max
Unit
Resolution
10
10
10
bits
Conversion time
15
—
—
µs
Analog input capacitance
—
—
20
pF
Permissible signal-source (singlesource) impedance
—
—
5
kΩ
Nonlinearity error
—
—
±3.0
LSB
Offset error
—
—
±2.0
LSB
Full-scale error
—
—
±2.0
LSB
Quantization error
—
—
±0.5
LSB
Absolute accuracy
—
—
±4.0
LSB
23.5
D/A Converter Characteristics
Table 23.11 lists the D/A converter characteristics.
Table 23.11 D/A Converter Characteristics
VccQ = 3.3 ± 0.3 V, Vcc = 1.55 to 2.15 V, AVcc = 3.3 ± 0.3 V, Ta = –20 to 75°C
Item
Min
Typ
Max
Unit
Test Conditions
Resolution
8
8
8
bits
Conversion time
—
—
10.0
µs
20-pF capacitive
load
Absolute accuracy
—
±2.5
±4.0
LSB
2-MΩ resistance
load
Rev. 5.00, 09/03, page 713 of 760
Rev. 5.00, 09/03, page 714 of 760
Appendix A Pin Functions
A.1
Pin States
Table A.1 shows pin states during resets, power-down states, and the bus-released state.
Table A.1
Pin States during Resets, Power-Down States, and Bus-Released State
Reset
Category
Pin
Clock
EXTAL
I
I
1
Standby
I
1
Sleep
I
1
Bus
Released
I
1
1
O*
1
IO*
O*
1
IO*
O*
1
IO*
O*
1
IO*
EXTAL2
I
I
I
I
I
XTAL2
O
O
O
O
O
CAP1, CAP2
—
—
—
—
—
RESETP
I
I
I
I
I
RESETM
I
I
I
I
I
BREQ
I
I
I
I
I
BACK
O
O
O
O
L
MD[5:0]
I
I
I
I
I
CKIO
CA
I
I
O
7
V*
OP*
OP*
OP*
OP*
I
I
I
I
V*
I
I
I
I
NMI
I
I
I
I
I
IRLS[3:0]/PTF[3:0]/
PINT[11:8]
V
I
IZ
I
I
MCS[7:0]/PTC[7:0]/
PINT[7:0]
V
OP*
STATUS[1:0]/PTJ[7:6]
Interrupt
Power-On Manual
Reset
Reset
O*
1
IO*
XTAL
System control
Power-Down
IRQ[3:0]/IRL[3:0]/
PTH[3:0]
IRQ[4]/ PTH[4]
7
I
2
2
I
2
10
I
2
2
ZH* K*
2
OP*
2
2
ZP*
TCK/PTF[4]/PINT[12]
IV
I
IZ
I
I
TDI/PTF[5]/PINT[13]
IV
I
IZ
I
I
TMS/PTF[6]/PINT[14]
IV
I
IZ
I
I
TRST/PTF[7]/PINT[15]
IV
I
IZ
I
I
IRQOUT
O
O
O
O
O
Rev. 5.00, 09/03, page 715 of 760
Reset
Power-Down
Category
Pin
Address bus
A[25:0]
Z
O
Data bus
D[15:0]
Z
D[23:16]/PTA[7:0]
Z
I
2
IP*
D[31:24]/PTB[7:0]
Z
IP*
CS0/MCS0
H
O
CS[2:4]/PTK[0:2]
H
CS5/CE1A/PTK[3]
H
CS6/CE1B
H
BS/PTK[4]
H
RAS3L/PTJ[0]
H
Bus control
DMAC
Sleep
Bus
Released
ZL*
O
Z
Z
2
ZK*
IO
2
IOP*
Z
2
ZP*
Standby
9
2
2
2
ZP*
OP*
2
OP*
2
ZP*
2
ZP*
10
O
2
OP*
Z
2
ZP*
ZK*
10
ZH*
IOP*
OP*
2
OP*
2
10
2
ZH* K*
10
2
ZH* K*
O
2
OP*
ZH*
10
2
ZH* K*
O
Z
2
2
ZOK*
3
ZOK*
3
OP*
2
OP*
2
ZOP*
3
ZOP*
2
ZOK*
3
ZOK*
3
OP*
2
OP*
2
ZOP*
3
ZOP*
ZH*
10
ZH*
O
Z
O
2
OP*
Z
2
ZP*
V
CASL/PTJ[2]
H
CASU/PTJ[3]
H
OP*
2
OP*
WE0/DQMLL
H
O
WE1/DQMLU/WE
H
10
WE2/DQMUL/ICIORD/
PTK[6]
H
O
2
OP*
WE3/DQMUU/ICIOWR/
PTK[7]
H
OP*
ZH* K*
RD/WR
H
O
RD
H
O
ZH*
10
ZH*
CKE/PTK[5]
H
OP*
WAIT
Z
DREQ0/PTD[4]
V
I
6
ZI*
V
2
OP*
DRAK0/PTD[1]
V
*2
DREQ1/PTD[6]
V
OP
6
ZI*
DACK1/PTD[7]
V
OP
*2
DRAK1/PTD[0]
V
OP*
TCLK/PTH[7]
V
ZP
Rev. 5.00, 09/03, page 716 of 760
2
OP*
2
OP*
RAS3U/PTE[2]
DACK0/PTD[5]
Timer
Power-On Manual
Reset
Reset
2
2
2
10
2
ZH* K*
10
2
2
3
3
2
OP*
ZP*
10
O
Z
OK*
2
OP*
OP*
Z
I
Z
Z
2
ZK*
I
I
ZH
*10
K
O
2
OP*
*2
Z
2
ZK*
10
Z
2
OP
*2
I
OP
2
ZH* K*
4
IOP*
2
2
OP*
2
OP*
I
*2
2
OP*
4
IOP*
2
OP*
2
OP*
4
IOP*
Reset
Category
Pin
SCI/Smart card RxD0/SCPT[0]
without FIFO
TxD0/SCPT[0]
Power-Down
Power-On Manual
Reset
Reset
6
Z
ZI*
Z
SCK0/SCPT[1]
V
RxD1/SCPT[2]
Z
TxD1/SCPT[2]
6
ZO*
2
ZP*
6
Bus
Released
Standby
Sleep
Z
2
ZK*
IZ*
5
OZ*
IZ*
5
OZ*
2
IOP*
5
IZ*
4
IOP*
5
IZ*
5
OZ*
4
IOP*
5
ZK*
5
4
Z
ZI*
6
ZO*
Z
2
ZK*
SCK1/SCPT[3]
V
*2
*2
OZ*
4
IOP*
SCIF with FIFO RxD2/SCPT[4]
Z
TxD2/SCPT[4]
Z
IZ*
5
OZ*
IZ*
5
OZ*
SCK2/SCPT[5]
V
ZO*
2
ZP*
Z
2
ZK*
2
4
RTS2/SCPT[6]
OP*
6
ZI*
IOP*
2
OP*
CTS2/IRQ5/SCPT[7]
V
7
V*
IOP*
2
OP*
AUDSYNC/PTE[7]
OV
OP*
2
OP*
2
SCIF/IrDA
with FIFO
Port
CE2B/PTE[5]
V
CE2A/PTE[4]
V
TDO/PTE[0]
OV
ZP
6
ZI*
6
2
ZK
5
ZK*
2
ZK*
I
I
5
5
4
I
2
OK*
10
2
ZH* K*
OP*
2
OP*
2
OP*
2
ZP*
2
ZH* K*
2
OK*
10
OP*
2
OP*
2
ZP*
2
OP*
OP*
2
OP*
2
2
2
IOIS16/PTG[7]
V
I
Z
I
I
PTG[5:0]
V
I
Z
I
I
V
7
V*
I
Z
I
I
I
I
WAKEUP/PTD[3]
V
IZ
2
OK*
I
2
OP*
2
OP*
RESETOUT/PTD[2]
O
OP*
ZK*
OP*
ZP*
2
OP*
OV
OK
OK
OK
OK
V
OI
OZ
OI
OI
OV
OI
OZ
OI
OI
I
I
Z
I
I
H
2
OP*
3
ZOK*
2
OP*
PTE[1]
V
OP
*2
*3
*2
PTE[6]
V
2
3
V
ZOK*
3
ZOK*
2
PTE[3]
OP*
2
OP*
OP*
2
OP*
ZOP*
3
ZOP*
PTJ[4]
H
2
3
2
PTJ[5]
H
ZOK*
3
ZOK*
OP*
2
OP*
ZOP*
3
ZOP*
AUDCK/PHT[6]
ADTRG/PTH[5]
AUDATA[3:0]/PTG[3:0]
CKIO2/PTG[4]
ASEBRKAK/PTG[5]
ASEMD0/PTG[6]
PTJ[1]
2
OP*
2
OP*
2
ZOK
2
OP
2
3
ZOP*
3
ZOP*
3
3
Rev. 5.00, 09/03, page 717 of 760
Reset
Category
Pin
Analog
AN[5:0]/PTL[5:0]
AN[6:7]/DA[1:0]/PTL[6:7]
I:
O:
H:
L:
Z:
P:
K:
V:
Power-Down
Power-On Manual
Reset
Reset
6
Z
ZI*
Z
ZI
*6
Standby
Sleep
Bus
Released
Z
11
OZ*
I
8
IO*
I
8
IO*
Input
Output
High-level output
Low-level output
High impedance
Input or output depending on register setting
Input pin is high impedance, output pin holds its state
I/O buffer off, pull-up MOS on
Notes: 1. Depending on the clock mode (MD2–MD0 setting).
2. K or P when the port function is used.
3. K or P when the port function is used. Z or O when the port function is not used
depending on register setting.
4. K or P when the port function is used. I or O when the port function is not used
depending on register setting.
5. Depending on register setting.
6. I or O when the port function is used.
7. Input Schmitt buffers of IRQ[5.0] and ADTRG on; other input buffers off.
8. O when DA output is enabled; otherwise I depending on register setting.
9. In standby mode, Z or L depending on register setting.
10. In standby mode, Z or H depending on register setting.
11. O when DA output is enabled; Z otherwise.
Rev. 5.00, 09/03, page 718 of 760
A.2
Pin Specifications
Table A.2 shows the pin specifications.
Table A.2
Pin Specifications
Pin
Pin No.
(FP-208C,
FP-208E)
Pin No.
(BP-240A)
I/O
Function
MD5
197
C6
I
Operating mode pin (endian mode)
MD4, MD3
196, 195
D6, A7
I
Operating mode pin (area 0 bus
width)
MD2 to MD0
2, 1, 144
C2, D2,G19
I
Operating mode pin (clock mode)
RAS3L/PTJ[0]
106
U18
PTJ[1]
107
U19
I/O
I/O port
CE2A/PTE[4]
103
V17
I/O
PCMCIA CE2A / I/O port
CE2B/PTE[5]
104
V16
I/O
PCMCIA CE2B / I/O port
RXD0/SCPT[0]
171
B13
I
Serial port 0 data input / input port
RXD1/SCPT[2]
172
C13
I
Serial port 1 data input / input port
I/O
RAS (SDRAM) / I/O port
RXD2/SCPT[4]
174
B12
I
Serial port 2 data input / input port
TXD0/SCPT[0]
164
C15
O
Serial port 0 data output / output port
TXD1/SCPT[2]
166
A14
O
Serial port 1 data output / output port
TXD2/SCPT[4]
168
C14
O
Serial port 2 data output / output port
SCK0/SCPT[1]
165
D15
I/O
Serial port 0 clock input/output / I/O
port
SCK1/SCPT[3]
167
B14
I/O
Serial port 1 clock input/output / I/O
port
SCK2/SCPT[5]
169
D14
I/O
Serial port 2 clock input/output / I/O
port
RTS2/SCPT[6]
170
A13
I/O
Serial port 2 transfer request / I/O
port
STATUS1/PTJ[7] 158
B17
I/O
Processor state / I/O port
STATUS0/PTJ[6] 157
B16
I/O
Processor state / I/O port
Rev. 5.00, 09/03, page 719 of 760
Pin
Pin No.
(FP-208C,
FP-208E)
Pin No.
(BP-240A)
I/O
Function
A25 to A0
86, 84, 82, 80,
78 to 72, 70,
68 to 60, 58,
56 to 53
V12, T12,
V11, W10,
V10, U9, T9,
V9, W9, T8,
U8, W8, U7,
V7, W7, T6,
U6, V6, W6,
T5, U5, W5,
W4, V5, V3,
V4
O
Address bus
D31 to D24/
F4, G1, G2,
G3, G4, H1,
H3, J1
I/O
Data bus / I/O port
PTB[7] to PTB[0]
13 to 18, 20,
22
D23 to D16/
PTA[7] to PTA[0]
23 to 26, 28,
30 to 32
J2, J4, J3, K2,
K1, L2, L1, M4
I/O
Data bus / I/O port
D15 to D0
34, 36 to 44,
46, 48 to 52
M2, N4, N3,
N2, N1, P4,
P3, P2, P1,
R4, T4, T3,
T1, R2, U2,T2
I/O
Data bus
MCS[7:0]/
PTC[7:0]/
PINT[7:0]
177 to
180,185 to
188
B11, D11,
C11, B10, D9,
B9, A9, D8
I/O
Mask ROM chip select / I/O port /
port interrupt request
WAKEUP/PTD[3] 182
D10
I/O
Wakeup / I/O port
RESETOUT/
PTD[2]
184
C9
I/O
Reset output / I/O port
DRAK0/PTD[1]
189
C8
I/O
DMA control pin / I/O port
DRAK1/PTD[0]
190
B8
I/O
DMA control pin / I/O port
DREQ0/PTD[4]
191
A8
I
DMA transfer request 0 / input port
DREQ1/PTD[6]
192
D7
I
DMA transfer request 1 / input port
AN[5:0]/PTL[5:0]
204 to 199
C4, A5, D4,
C5, D5, A6
I
Analog input pin / input port
AN[7:6]/DA[1:0]/
PTL[7:6]
207, 206
B3, B5
CS6/CE1B
102
V15
O
Chip select 6 / PCMCIA CE1B
CS5/CE1A/
PTK[3]
101
W16
I/O
Chip select 5 / PCMCIA CE2B / I/O
port
CS4/PTK[2]
100
U16
I/O
Chip select 4 / I/O port
CS3/PTK[1]
99
W15
I/O
Chip select 3 / I/O port
Rev. 5.00, 09/03, page 720 of 760
I/O
Analog I/O pin / input port
Pin
Pin No.
(FP-208C,
FP-208E)
Pin No.
(BP-240A)
I/O
Function
CS2/PTK[0]
98
T16
I/O
Chip select 2 / I/O port
CS0/MCS0
96
T15
O
Chip select 0 / Mask ROM chip
select 0
BS/PTK[4]
87
W12
I/O
Bus cycle start / I/O port
PTJ[5]
113
R17
I/O
I/O port
PTJ[4]
112
U17
I/O
I/O port
CASU/PTJ[3]
110
T17
I/O
CAS(SDRAM) / I/O port
CASL/PTJ[2]
108
R18
I/O
CAS(SDRAM) / I/O port
DACK0/PTD[5]
114
R16
I/O
DMA transfer strobe 0 / I/O port
DACK1/PTD[7]
115
P19
I/O
DMA transfer strobe 1 / I/O port
RD
88
T13
O
Read strobe pin
WE0/ DQMLL
89
U13
O
D7–D0 select signal/ DQM(SDRAM)
WE1/DQMLU/WE 90
V13
O
D15–D8 select signal /
DQM(SDRAM)/ PCMCIA
WE signal
WE2/DQMUL/
ICIORD/PTK[6]
91
W13
I/O
D23–D16 select signal /
DQM(SDRAM) / PCMCIA IORD
signal / I/O port
WE3/DQMUU/
ICIOWR/PTK[7]
92
T14
I/O
D31–D24 select signal
/DQM(SDRAM) / PCMCIA IOWR
signal / I/O port
RD/WR
93
U14
O
Read/write select signal
AUDSYNC/
PTE[7]
94
V14
I/O
AUD synchronous I/O port
PTE[6]
116
P18
I/O
I/O port
PTE[3]
117
P17
I/O
I/O port
RAS3U/PTE[2]
118
P16
I/O
RAS(SDRAM) / I/O port
PTE[1]
119
N19
I/O
I/O port
TDO/PTE[0]
120
N18
I/O
RESETM
124
M18
I
Manual reset input
Test data output I/O port
ADTRG/PTH[5]
125
M17
I
ADC trigger request / Input port
IOIS16/PTG[7]
126
M16
I
I/O for PC card / input port
ASMD0/PTG[6]
127
L19
I
ASE mode / input port
ASEBRKAK/
PTG[5]
128
L18
I
ASE break accept / input port
Rev. 5.00, 09/03, page 721 of 760
Pin No.
(FP-208C,
FP-208E)
Pin
Pin No.
(BP-240A)
I/O
Function
CKIO2/PTG[4]
129
L16
I/O
AUDATA[3]/
PTG[3]
130
L17
I
AUD data / input port
AUDATA[2]/
PTG[2]
131
K18
I
AUD data / input port
AUDATA[1]/
PTG[1]
133
K19
I
AUD data / input port
AUDATA[0]/
PTG[0]
135
J18
I
AUD data / input port
TRST/PTF[7]/
PINT[15]
136
J19
I
Test reset / input port / port interrupt
request
TMS/PTF[6]/
PINT[14]
137
H16
I
Test mode switch / input port / port
interrupt request
TDI/PTF[5]/
PINT[13]
138
H17
I
Test data input / input port / port
interrupt request
TCK/PTF[4]/
PINT[12]
139
H18
I
Test clock / input port / port interrupt
request
IRLS[3:0]/
PTF[3:0]/
PINT[11:8]
140 to 143
H19, G16,
G17, G18
I
External interrupt request / input port
/ port interrupt request
AUDCK/PTH[6]
151
D16
I
AUD clock / input port
WAIT
123
M19
I
Hardware wait request
BREQ
122
N16
I
Bus request
BACK
121
N17
O
Bus acknowledge
IRQOUT
160
A16
O
Interrupt / refresh request output
RESETP
193
C7
I
Power-on reset input
NMI
7
C3
I
Nonmaskable interrupt request
IRQ[3:0]/IRL[3:0]/ 11 to 8
PTH[3:0]
F2, F1, E4, E3
I
External interrupt request / external
interrupt source / input port
IRQ4/PTH[4]
12
F3
I
External interrupt request / input port
CTS2/IRQ5/
SCPT[7]
176
A11
I
Serial port 2 transfer enable /
external interrupt request / input port
TCLK/PTH[7]
159
B15
I/O
EXTAL
156
D18
I
External clock / crystal oscillator pin
XTAL
155
C18
O
Crystal oscillator pin
CAP1
146
F17
—
External capacitance pin (for PLL1)
CAP2
149
E16
—
External capacitance pin (for PLL2)
Rev. 5.00, 09/03, page 722 of 760
System clock output / input port
Clock I/O (for TMU/RTC) / I/O port
Pin No.
(FP-208C,
FP-208E)
Pin
Pin No.
(BP-240A)
I/O
Function
CKIO
162
A15
I/O
System clock I/O
XTAL2
4
D1
O
Crystal oscillator pin (for on-chip
RTC)
EXTAL2
5
D3
I
Crystal oscillator pin (for on-chip
RTC)
CKE/PTK[5]
105
T18
I/O
CK enable for SDRAM / I/O port
CA
194
B7
I
VCCQ
21, 35, 47, 59,
71, 85, 97,
111,
163, 183
H4, M1, R1,
U3, V8, U15,
R19, C17,
A10, U12
Power Power supply (3.3 V)
supply
VCC–RTC
3
E2
Power RTC oscillator power supply
supply (2.0/1.9/1.8/1.7 V)
VCC–PLL1
VCC–PLL2
145
150
F16,
E17
Power PLL power supply (2.0/1.9/1.8/1.7 V)
supply
AVCC
205
A4
Power Analog power supply (3.3 V)
supply
VSSQ
19, 33, 45, 57,
69, 83, 95,
109,
161, 181
H2, M3, R3,
T7, U4, W11,
W14, T19,
C16, C10
Power Power supply (0 V)
supply
VCC
29, 81, 134,
154, 175
L3, L4, U11,
T11, J17, J16,
E18, C19,
C12, D12
Power Internal power supply
supply (2.0/1.9/1.8/1.7 V)
VSS
27, 79, 132,
K3, K4, U10,
152, 153, 173 T10, K17,
K16, E19,
D17, D19,
A12, D13
Power Internal power supply (0 V)
supply
VSS–RTC
6
E1
Power RTC-oscillator power supply (0 V)
supply
VSS–PLL1
VSS–PLL2
147
148
F18
F19
Power PLL power supply (0 V)
supply
Setting hardware standby pin
Power Analog power supply (0 V)
supply
Note: Except in hardware standby mode, power must be supplied constantly to all power supply
pins. In hardware standby mode, power must be supplied to Vcc-RTC and Vss-RTC at
least.
AVSS
198, 208
B6, B4
Rev. 5.00, 09/03, page 723 of 760
A.3
Treatment of Unused Pins
• When RTC is not used
 EXTAL2:
Pull up (2.0/1.9/1.8/1.7 V)
 XTAL2:
Leave unconnected
 VCC–RTC:
Power supply (2.0/1.9/1.8/1.7 V)
 VSS–RTC:
Power supply (0 V)
• When PLL2 is not used
 CAP2:
Leave unconnected
 VCC–PLL2: Power supply (2.0/1.9/1.8/1.7 V)
 VSS–PLL2:
Power supply (0 V)
• When on-chip crystal oscillator is not used
 XTAL:
Leave unconnected
• When EXTAL pin is not used
 EXTAL:
Pull up (3.3 V)
• When A/D converter is not used
 AN[7:0]:
Leave unconnected
 AVCC:
Power supply (3.3 V)
 AVSS:
Power supply (0 V)
• When UDI is not used
 ASEMD0:
Pull up (3.3 V)
Rev. 5.00, 09/03, page 724 of 760
A.4
Pin States in Access to Each Address Space
Table A.3
Pin States (Ordinary Memory/Little Endian)
Pin
8-Bit Bus Width
Byte/Word/Longword Access
CS6 to CS2, CS0
RD
RD/WR
Enabled
R
16-Bit Bus Width
Byte Access
(Address 2n)
Enabled
Byte Access
(Address 2n + 1)
Enabled
Word/Longword
Access
Enabled
Low
Low
Low
Low
W High
High
High
High
R
High
High
High
High
W Low
Low
Low
Low
BS
Enabled
Enabled
Enabled
Enabled
RAS3U/PTE[2]
High
High
High
High
RAS3L/PTJ[0]
High
High
High
High
CASL/PTJ[2]
High
High
High
High
CASU/PTJ[3]
High
High
High
High
High
WE0/DQMLL
WE1/DQMLU/WE
WE2/DQMUL/
ICIORD/PTK[6]
WE3/DQMUU/
ICIOWR/PTK[7]
High
High
High
W Low
R
Low
High
Low
R
High
High
High
High
W High
High
Low
Low
R
High
High
High
High
W High
High
High
High
R
High
High
High
High
W High
High
High
High
CE2A/PTE[4]
High
High
High
High
CE2B/PTE[5]
High
High
High
High
CKE/PTK[5]
Disabled
Disabled
Disabled
Disabled
WAIT
Enabled*1
Enabled*1
Enabled*1
Enabled*1
IOIS16/PTG[7]
Disabled
Disabled
Disabled
Disabled
A25 to A0
Address
Address
Address
Address
D7 to D0
Valid data
Valid data
Invalid data
Valid data
D15 to D8
High-Z*2
Invalid data
Valid data
Valid data
D31 to D16
High-Z*2
High-Z*2
High-Z*2
High-Z*2
Rev. 5.00, 09/03, page 725 of 760
32-Bit Bus Width
Byte
Byte
Byte
Byte
Word
Word
Access
Access
Access Longword
Access
Access
Access
(Address (Address (Address (Address (Address (Address Access
4n)
4n + 1)
4n + 2)
4n + 3)
4n)
4n + 2)
Pin
CS6 to CS2, CS0
RD
RD/WR
R
Enabled
Enabled
Enabled
Enabled
Enabled
Enabled
Enabled
Low
Low
Low
Low
Low
Low
Low
W High
High
High
High
High
High
High
R
High
High
High
High
High
High
High
W Low
Low
Low
Low
Low
Low
Low
BS
Enabled
Enabled
Enabled
Enabled
Enabled
Enabled
Enabled
RAS3U/PTE[2]
High
High
High
High
High
High
High
RAS3L/PTJ[0]
High
High
High
High
High
High
High
CASL/PTJ[2]
High
High
High
High
High
High
High
High
High
High
High
High
High
High
High
High
High
High
High
High
High
W Low
High
High
High
Low
High
Low
R
CASU/PTJ[3]
WE0/DQMLL
WE1/DQMLU/WE
WE2/DQMUL/
ICIORD/PTK[6]
R
High
High
High
High
High
High
High
W High
Low
High
High
Low
High
Low
R
High
High
High
High
High
High
High
W High
High
Low
High
High
Low
Low
R
High
High
High
High
High
High
High
W High
High
High
Low
High
Low
Low
CE2A/PTE[4]
High
High
High
High
High
High
High
CE2B/PTE[5]
High
High
High
High
High
High
High
CKE/PTK[5]
Disabled
Disabled
Disabled
Disabled
Disabled
Disabled
Disabled
WAIT
Enabled*1
Enabled*1
Enabled*1
Enabled*1
Enabled*1
Enabled*1
Enabled*1
IOIS16/PTG[7]
Disabled
Disabled
Disabled
Disabled
Disabled
Disabled
Disabled
A25 to A0
Address
Address
Address
Address
Address
Address
Address
D7 to D0
Valid
data
Invalid
data
Invalid
data
Invalid
data
Valid
data
Invalid
data
Valid
data
D15 to D8
Invalid
data
Valid
data
Invalid
data
Invalid
data
Valid
data
Invalid
data
Valid
data
D23 to D16
Invalid
data
Invalid
data
Valid
data
Invalid
data
Invalid
data
Valid
data
Valid
data
D31 to D24
Invalid
data
Invalid
data
Invalid
data
Valid
data
Invalid
data
Valid
data
Valid
data
WE3/DQMUU/
ICIOWR/PTK[7]
Notes: 1. Disabled when WCR2 register wait setting is 0.
2. Unused data pins should be switched to the port function, or pulled up.
Rev. 5.00, 09/03, page 726 of 760
Table A.4
Pin States (Ordinary Memory/Big Endian)
8-Bit Bus Width
Pin
Byte/Word/Longword Access
CS6 to CS2, CS0
RD
RD/WR
R
16-Bit Bus Width
Byte Access
(Address 2n)
Byte Access
(Address 2n + 1)
Word/Longword
Access
Enabled
Enabled
Enabled
Enabled
Low
Low
Low
Low
W High
High
High
High
R
High
High
High
High
W Low
Low
Low
Low
BS
Enabled
Enabled
Enabled
Enabled
RAS3U/PTE[2]
High
High
High
High
RAS3L/PTJ[0]
High
High
High
High
CASL/PTJ[2]
High
High
High
High
High
High
High
High
High
High
High
High
W Low
High
Low
Low
R
High
High
High
High
W High
Low
High
Low
R
CASU/PTJ[3]
WE0/DQMLL
WE1/DQMLU/WE
WE2/DQMUL/
ICIORD/PTK[6]
WE3/DQMUU/
ICIOWR/PTK[7]
R
High
High
High
High
W High
High
High
High
R
High
High
High
High
W High
High
High
High
CE2A/PTE[4]
High
High
High
High
CE2B/PTE[5]
High
High
High
High
CKE/PTK[5]
Disabled
Disabled
Disabled
Disabled
WAIT
Enabled*1
Enabled*1
Enabled*1
Enabled*1
IOIS16/PTG[7]
Disabled
Disabled
Disabled
Disabled
A25 to A0
Address
Address
Address
Address
D7 to D0
Valid data
Invalid data
Valid data
Valid data
D15 to D8
High-Z*2
Valid data
Invalid data
Valid data
D31 to D16
High-Z*2
High-Z*2
High-Z*2
High-Z*2
Rev. 5.00, 09/03, page 727 of 760
32-Bit Bus Width
Byte
Byte
Byte
Byte
Word
Word
Access
Access
Access Longword
Access
Access
Access
(Address (Address (Address (Address (Address (Address Access
4n)
4n + 1)
4n + 2)
4n + 3)
4n)
4n + 2)
Pin
CS6 to CS2, CS0
RD
RD/WR
R
Enabled
Enabled
Enabled
Enabled
Enabled
Enabled
Enabled
Low
Low
Low
Low
Low
Low
Low
W High
High
High
High
High
High
High
R
High
High
High
High
High
High
High
W Low
Low
Low
Low
Low
Low
Low
BS
Enabled
Enabled
Enabled
Enabled
Enabled
Enabled
Enabled
RAS3U/PTE[2]
High
High
High
High
High
High
High
RAS3L/PTJ[0]
High
High
High
High
High
High
High
CASL/PTJ[2]
High
High
High
High
High
High
High
High
High
High
High
High
High
High
High
High
High
High
High
High
High
W High
High
High
Low
High
Low
Low
R
High
CASU/PTJ[3]
WE0/DQMLL
WE1/DQMLU/WE
R
High
High
High
High
High
High
W High
High
Low
High
High
Low
Low
R
High
High
High
High
High
High
W High
Low
High
High
Low
High
Low
R
High
High
High
High
High
High
High
W Low
High
High
High
Low
High
Low
CE2A/PTE[4]
High
High
High
High
High
High
High
CE2B/PTE[5]
High
High
High
High
High
High
High
CKE/PTK[5]
Disabled
Disabled
Disabled
Disabled
Disabled
Disabled
Disabled
WAIT
Enabled*1
Enabled*1
Enabled*1
Enabled*1
Enabled*1
Enabled*1
Enabled*1
IOIS16/PTG[7]
Disabled
Disabled
Disabled
Disabled
Disabled
Disabled
Disabled
A25 to A0
Address
Address
Address
Address
Address
Address
Address
D7 to D0
Invalid
data
Invalid
data
Invalid
data
Valid
data
Invalid
data
Valid
data
Valid
data
D15 to D8
Invalid
data
Invalid
data
Valid
data
Invalid
data
Invalid
data
Valid
data
Valid
dat
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