NSC PC87410VLK

PC87410 PCI-IDE Interface Controller
General Description
The PCI-IDE Interface Controller is designed to interface the
IDE drive directly onto the PCI bus. It provides write posting
and read pre-fetches, allowing the CPU to run concurrently
with IDE cycles. It connects IDE drIves ‘‘gluelessly’’ into the
PCI bus and supports faster ATA devices using modes 1, 2
and 3 through PIO accesses. It supports dual IDE channels
for up to four drives, and works seamlessly with the National
Semiconductor’s SuperI/OTM family of products.
A full suite of software drives included with device are fully
tested with DOS 5.0–6.x, Windows 3.x–4.x, Windows NT,
OS/2 2.x, Novell Netware 3.1x–4.x, and SCO UNIX 3.x.
Y
Y
Y
Y
Y
Y
Y
Key Features
Y
Y
Y
Y
Fully compatible with PCI specifications rev 2.0 (April,
1993)
Programmable Base Address registers
Interfaces with the 32 bits PCI local bus to IDE drives
Support IDE PIO timing mode 0, 1, 2 of ANSI ATA
specifications
Y
Y
Y
Support Mode 3 (11 MB/s) timing proposal on enhanced IDE (IDE-2 or ATA-2) specifications
Two IDE-2 channel supported (each channel supports 2
devices)
Supports primary IDE or secondary IDE address
16-Byte FIFO provide 4-level Posted Write and Read
ahead buffers per channel for concurrent system
operation
Programmable command and recovery timing for reads
and writes per channel
Independent timings for command registers and data
registers
Slew rate controlled output directly interface with IDE
devices
Supports either IRQ14/15 or INTAÝ/BÝ
Hardware and Software chip enable/disable capability
100 pin PQFP package, NO other glue logic needed
and 12 mA transceivers are built in
Block Diagram
TL/F/12073 – 1
TRI-STATEÉ is a registered trademark of National Semiconductor Corporation.
SuperI/OTM is a trademark of National Semiconductor Corporation
C1995 National Semiconductor Corporation
TL/F/12073
RRD-B30M75/Printed in U. S. A.
PC87410 PCI-IDE Interface Controller
October 1994
Absolute Maximum Ratings 5V g 10%
Recommended Operating
Conditions
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales
Office/Distributors for availability and specifications.
Supply Voltage (VDD)
Input Voltage (VI)
Output Voltage (VO)
Storage Temperature (TSTG)
Lead Temperature (TL)
(Soldering, 10 seconds)
Supply Voltage
Operating Temperature (TA)
b 0.5V to a 7.0V
b 0.5V to VDD a 0.5V
Min Typ
4.5 5.0
0
Max
5.5
a 70
Units
V
§C
b 0.5V to VDD a 0.5V
b 65§ C to a 165§ C
a 260§ C
DC Electrical Characteristics
Symbol
VIL
Parameter
Conditions
Min
CMOS
TTL
VIH
VOH
VOL
Units
0.3VDD
V
0.8
V
0.7 VDD
TTL
IIL
Max
Input High Voltage
CMOS
IIH
Typ
Input Low Voltage
V
2.0
Input High Current
VIN e VDD
Input with Pull-Down
V
b 10
10
VIN e VDD
10
200
mA
Input Low Current
VIN e VSS
b 10
10
mA
Input with Pull-Down
VIN e VSS
b 10
mA
Type B8
IOH e 8 mA
2.4
Type B12
IOH e 12 mA
2.4
Type B8
IOL e 8 mA
0.4
V
0.4
V
10
mA
10
mA
Type B12
IOL e 12 mA
IOZ
Output TRI-STATE
Leakage Current
VOH e VSS
or VDD
IDD
VDD Average Supply
Current
No Load
b 200
b 10
2
mA
V
V
PCIÐBased System
TL/F/12073 – 2
Basic Configuration
The following diagram shows how the PCI-IDE Interface Controller is used in a system.
TL/F/12073 – 3
Note 1. Second IDE connector is optional
Note 2. Legacy header is needed under the following conditions:
a. The device is on a PCI adapter card.
b. IDE compatibility is required.
3
Connection Diagram
Plastic Quad Flatpak, EIAJ
TL/F/12073 – 4
Order Number PC87410VLK
See NS Package Number VLK100A
4
Pin Description
PCI Interface
Name
AD[31:0]
Type
IOL
I/O
8 mA
Description
MULTIPLEXED ADDRESS AND DATA. The direction of these pins are defined
below:
Phase
Address Phase
Data Phase
Read
Write
C/BE [3:0]
I
PAR
I/O
FRAMEÝ
input
output
input
COMMAND/BYTE ENABLE are multiplexed Bus command and Byte enables.
8 mA
I
PARITY is even parity across AD[31:0] and C/BE[3:0]. PAR is an input during
writes and an output during reads.
CYCLE FRAME is driven by the initiator to indicate the beginning and duration of
an access.
TRDYÝ
O/TRI-STATEÉ
IRDYÝ
I
STOPÝ
O/TRI-STATE
8 mA
STOP indicates that the current target is requesting the initiator to stop the current
transaction.
DEVSELÝ
O/TRI-STATE
8 mA
DEVICE SELECT, when actively drive, indicates the driving device has decoded
its adderss as the target of the current access.
IDSEL
12 mA
INITIATOR READY indicates that the initiator is ready to complete the current
data phase of the transaction.
I
PERRÝ
O/TRI-STATE
SERRÝ
O/TRI-STATE
INTAÝ, BÝ
O/TRI-STATE
TARGET READY indicates that the current data phase of the transaction is ready
to be completed.
INITIALIZATION DEVICE SELECT is used as a chip select during configuration
read and write transactions.
8 mA
PARITY ERROR is used for reporting data parity errors during all PCI transactions
except a Special Cycle. PERRÝ is an output during writes and an input during
reads.
8 mA
SYSTEM ERROR is used for reporting address parity errors, data parity errors on
the Special Cycle command, or any other system error where the result will be
castrophic. When reporting address parity errors, SERRÝ is an output. When
reporting data parity errors for the Special Cycle command, SERRÝ is an output
during writes and an input during needs.
8 mA, Slew
Rate Control
INTERRUPT. Interrupt request A and B
CLK
I
CLOCK. Up to 33 MHz PCI Clock
RSTÝ
I
RESET. PCI Reset
Power and Ground
Name
Type
Description
GND
I
VSS or GROUND
VCC
I
VDD or a 5V. Power to PCI buffers, core and IDE buffers.
Note: All signals are TTL except CH0ÐINT (Pin 48) and CH1ÐINT (Pin 87) are CMOS.
5
Pin Description (Continued)
IDE Interface
Type
IOL
Description
IDEÐD[15:0]
Name
I/O
12 mA, Slew
Rate Control
DRIVE DATA BUS. This is an 8- or 16-bit bi-direction data between the PCI-IDE
chip and the drive. The lower 8 bits are used for 8-bit transfers (e.g. command
registers, ECC bytes).
CH0ÐDA[2:0]
O
12 mA, Slew
Rate Control
CHANNEL 0 ADDRESS LINES. This is the 3-bit binary coded address asserted
by the host to access a register or data port in the drive.
CH1ÐDA [2:0]
O
12 mA, Slew
Rate Control
CHANNEL 1 ADDRESS LINES. This is the 3-bit binary coded address asserted
by the host to access a register or data port in the drive.
IORDY0
I
CHANNEL 0 I/O CHANNEL READY. This signal is negated to extend the disk
transfer cycle of any register access (read or write) when the drive is not ready
to respond to a data transfer request.
IORDY1
I
CHANNEL 1 I/O CHANNEL READY. This signal is negated to extend the disk
transfer cycle of any register access (read or write) when the drive is not ready
to respond to a data transfer request.
CH0ÐIORÝ
O
12 mA, Slew
Rate Control
CHANNEL 0 I/O READ. This is the read strobe signal. The falling edge of
CH0ÐIORÝ enables data from a register or the data port of the drive onto the
PCI bus.
CH0ÐIOWÝ
O
12 mA, Slew
Rate Control
Channel 0 I/O Read. This is the write strobe signal. The rising edge of CH0Ð
IOWÝ clocks data from the PCI-IDE chip into the register or the data port of the
drive.
CH1ÐIORÝ
O
12 mA, Slew
Rate Control
CHANNEL 1 I/O READ. This is the read strobe signal. The falling edge of the
CH1ÐIORÝ enables data from a register or the data port of the drive onto the
PCI bus.
CH1ÐIOWÝ
O
12 mA, Slew
Rate Control
CHANNEL 1 I/O WRITE. This is the write strobe signal. The rising edge of
CH1ÐIOWÝ clocks data from the PCI-IDE chip into the register or the data port
of the drive.
HDDRSTÝ
O
12 mA, Slew
Rate Control
DRIVE RESET. This signal from the PCI-IDE chip is triggered by RSTÝ or under
software control which generates IDE reset for a min time of 62 ms.
CH0ÐCS1Ý,
CH0ÐCS3Ý
O
12 mA, Slew
Rate Control
CHANNEL 0 CHIP SELECT 1 AND 3. CH0ÐCS1Ý is the chip select signal to
select the Command Block Register. CH0ÐCS3Ý is the chip select signal to
select the Control Block Register.
CH1ÐCS1Ý,
CH1ÐCS3Ý
O
12 mA, Slew
Rate Control
CHANNEL 1 CHIP SELECT 1 AND 3. CH1ÐCS1Ý is the chip select signal to
select the Command Block Registers. CH1ÐCS3Ý is the chip select to select
the Control Block Registers.
CH0ÐINT
CH1ÐINT
I
CHANNEL INTERRUPTS. These signals are used to interrupt the host system.
CH0ÐINT is asserted only when the drive(s) on channel 0 has a pending
interrupt, and the host has cleared nIEN in the Device Control Register. CH1Ð
INT is asserted only when the drive(s) on channel 1 has a pending interrupt, and
the host has cleared nIEN in the Device Control Register.
ENABLE
I
CHIP ENABLE PIN. Logic low will disable this chip. If this pin is tied to Logic
High or not connected then the chip is enabled.
HEADER
I
HEADER PIN. See page 13.
IRQ14
O/TRI-STATE
8 mA, Slew
Rate Control
The output of this pin is equivalent to ISA IRQ14 if HEADER is ‘‘not connected’’
or Logic High. However, this pin will go to TRI-STATE if HEADER is tied to Logic
low.
IRQ15
O/TRI-STATE
8 mA, Slew
Rate Control
The output of this pin is equivalent to ISA IRQ15 if HEADER is ‘‘Not connected’’
or Logic High. However, this pin will go to TRI-STATE if HEADER is tied to Logic
low.
6
Configuration Registers The configuration register map is shown in Table I.
TABLE I
Reg. Ý
(in HEX)
Description
R/W
00
R
VENDOR ID (100Bh)
02 – 3
R
DEVICE ID (D001h)
04 – 5
R/W
COMMAND REGISTER. The command register provides coarse control over a device’s ability to generate and
respond to PCI cycles.
bit 0Ðcontrols the response to the I/O space accesses specified in the Base Address Register. Default value is
determined by the ENABLE pin.
1: Chip enable
0: Chip enable
bit 6Ð allows the controller to detect parity errors on the PCI bus and report these errors to the system.
1: enable parity checking
0: disable parity checking (default)
bit 8Ðallows the controller to detect system errors on the PCI bus and report these errors to the system.
1: enable system error checking
0: disable system error checking (default)
06
R/W
STATUS REGISTER. This register is used to record status information for PCI bus related events. ‘‘Reads’’
from this register behaves normally. However, ‘‘write’’ to this register is slightly different respect to the ordinary
register. This register can be reset but not set. In order to reset this register, a logical High need to write to the
corresponding bit. For details, please check P.156 of the PCI specification 2.0 (April 30, 1993).
bit 9–10: These bit encode the timing of DEVSELÝ. (read only)
00: fast
01: medium, Default
bit 14: 1 means system error
bit 15: This bit will be set by a device whenever that device detects a data parity error. This bit is disabled when
parity error handling is disabled. A logical one means detection of parity error. Please check P. 157 of the PCI
specification 2.0 (April 30, 1993).
Reg. Ý
(in HEX)
R/W
Description
08
R
REV. ID (00h)
09
R
PROGRAMMING INTERFACE, default is 00h
0A
R
SUB-CLASS CODE, default is 01h (means IDE controller)
0B
R
BASIC CLASS CODE, default is 01h (means mass storage)
0C – 0D
0E
Not Used
R
HEADER TYPE, default is 00h
10 – 13
R/W
BASE ADDRESS REGISTERS 0. For Primary IDE Data Control Ports (Default: 000001F0h – 000001F7h)
bit0: fixed to 1
bit1: fixed to 0
bit2: fixed to 0
14 – 17
R/W
BASE ADDRESS REGISTERS 1. For Primary IDE Control Status Ports (Default: 000003F6h) Note: only ‘‘3F6’’
byte is accessible
bit0: fixed to 1
bit1: fixed to 0
18 – 1B
R/W
BASE ADDRESS REGISTER 2. For Secondary IDE Data Control Ports. (Default: 00000170h – 0000177h)
bit0: fixed to 1
bit1: fixed to 0
bit2: fixed to 0
1C – 1F
R/W
BASE ADDRESS REGISTER 3. For Secondary IDE Control Status Ports. (Default: 00000376h) Note: only
‘‘376’’ byte is accessible
bit0: fixed to 1
bit1: fixed to 0
7
Configuration Registers The configuration register map is shown in Table I. (Continued)
TABLE I (Continued)
Reg. Ý
(in HEX)
R/W
20 – 27
Description
Not used.
3C
R/W
3D
R
INTERRUPT LINE, default is 0Eh
INTERRUPT PIN
Default is 00h if HEADER pin is HIGH
Default is 01h if HEADER pin is LOW
3E – 3F
Not used
40
IDE CHANNEL 0 TIMING CONTROL REGISTER. This register is the cycle control register for 1F0h port.
Default is set at B5H. (Note 1)
bit 7, 6:
address/chip select setup time
00
1 PCI clk
01
2 PCI clk
10
3 PCI clk
(default)
11
4 PCI clk
bit 5 4 3:
address/chip select/write data hold time
000
1 PCI clk
001
2 PCI clk
010
3 PCI clk
011
4 PCI clk
100
5 PCI clk
101
6 PCI clk
110
8 PCI clk
(default)
111
12 PCI clk
bit 2 1 0:
Command active time
000
2 PCI clk
(Note 3)
001
3 PCI clk
010
4 PCI clk
011
5 PCI clk
100
6 PCI clk
101
8 PCI clk
(default)
110
12 PCI clk
111
16 PCI clk
41
W/O
42
Bit 7 is
R/W,
others
are W/O
IDE CHANNEL 0 READÐAHEAD COUNTER, LOW BYTE.
It provides values for loading bit0–bit7 of readÐahead counter.
bit0:
bit0 of the readÐahead counter
bit1:
bit1 of the readÐahead counter
bit2:
bit2 of the readÐahead counter
bit3:
bit3 of the readÐahead counter
bit4:
bit4 of the readÐahead counter
bit5:
bit5 of the readÐahead counter
bit6:
bit6 of the readÐahead counter
bit7:
bit7 of the readÐahead counter
IDE CHANNEL 9 READÐAHEAD COUNTER, HIGH BYTE.
It provides values for loading bit8–bit9 readÐahead counter.
bit0:
bit8 of the readÐahead counter
bit1:
bit9 of the readÐahead counter
bit7:
readÐahead function control
1: enable
0: disable (default)
8
Configuration Registers The configuration register map is shown in Table I. (Continued)
TABLE I (Continued)
Reg. Ý
(in HEX)
R/W
Description
43
IDE CHANNEL 0 FUNCTION REGISTER.
bit3:
channel 0 I/O decode enable bit
1: enable (default)
0: disable
bit2:
IORDY0 function control
1: enable
0: disable (default)
bit1:
CH0ÐINT status (read only)
1: interrupt pending
0: no interrupt pending
bit0:
CH0ÐINT request to be masked or not
1: be masked
0: not be masked (default)
44
IDE CHANNEL 1 TIMING CONTROL REGISTER. This register is the cycle control register for 170h port.
Default is set at B5h. (Note 1)
bit 7, 6:
address/chip select setup time
00
1 PCI clk
01
2 PCI clk
10
3 PCI clk
(default)
11
4 PCI clk
bit 5 4 3: address/chip select/write data hold time
000
1 PCI clk
001
2 PCI clk
010
3 PCI clk
011
4 PCI clk
100
5 PCI clk
101
6 PCI clk
110
8 PCI clk
(default)
111
12 PCI clk
bit 2 1 0: Command active time
000
2 PCI clk
001
3 PCI clk
010
4 PCI clk
011
5 PCI clk
100
6 PCI clk
101
8 PCI clk
(default)
110
12 PCI clk
111
16 PCI clk
45
W/O
IDE CHANNEL 1 READÐAHEAD COUNTER, LOW BYTE.
It provides values for loading bit0– bit7 of readÐahead counter.
bit0:
bit0 of the readÐahead counter
bit1:
bit1 of the readÐahead counter
bit2:
bit2 of the readÐahead counter
bit3:
bit3 of the readÐahead counter
bit4:
bit4 of the readÐahead counter
bit5:
bit5 of the readÐahead counter
bit6:
bit6 of the readÐahead counter
bit7:
bit7 of the readÐahead counter
9
Configuration Registers The configuration register map is shown in Table I. (Continued)
TABLE I (Continued)
Reg. Ý
(in HEX)
46
R/W
Bit 7 is
R/W,
others
are W/O
Description
IDE CHANNEL 1 READÐAHEAD COUNTER, HIGH BYTE.
It provides values for loading bit8–bit9 of readÐahead counter
bit0:
bit8 of the readÐahead counter
bit1:
bit9 of the readÐahead counter
bit7:
readÐahead function control
1: enable
0: disable (default)
47
IDE CHANNEL 1 FUNCTION REGISTER.
bit3:
channel 1 I/O decode enable bit
1: enable (default)
0: disable
bit2:
IORDY1 function control
1: enable
0: disable (default)
bit1:
CH1ÐINT status (read only)
1: interrupt pending
0: no interrupt pending
bit0:
CH1ÐINT request to be masked or not
1: be masked
0: not be masked (default)
48
PCI CONTROL REGISTER.
bit3:
host posted write cycle timing select
1: min. 1 wait state (default)
0: min. 0 wait state (Note 2)
bit2:
active HDDRSTÝ output active control
1: activate HDDRSTÝ(default)
0: No action
bit1:
DEVSELÝ timing select
1: medium (default)
0: fast
bit0:
Header for IDE support on PCI is present or not
1: present
0: absent, Default
Values is determined by the ‘‘Header Pin’’.
49 – 4F
Not used.
Note 1: Total cycle time is calculated by adding setup time, hold time, and active time plus 1 clk.
Note 2: When 0 wait state is used then DEVSELÝ timing select bit should be set to 0 (fast).
Note 3: If register 40 is 00, then IORDY0 should be disabled.
If register 44 is 00, then IORDY1 should be disabled.
10
Relation Table for INTAÝ, INTBÝ, IRQ14/15 with HEADER and channel I/O base registers
Condition
Outcome
When chip is disabled (HEADER is ‘‘don’t care’’) and
the setting of channel 0/1 I/O base register setting is
‘‘don’t care’’
IRQ14: off
IRQ15: off
INTAÝ: off
INTBÝ: off16
HEADER is absent (Note 1), chip is enabled and
the setting of channel 0/1 I/O base register setting is
‘‘don’t care’’
IRQ14: off
IRQ15: off
INTAÝ: inversion of CH0ÐINT, if CH0ÐINT is not
masked by the bit0 of register 43h.
Otherwise, it is at TRI-STATE.
INTBÝ: inversion of CH1ÐINT, if CH1ÐINT is not
masked by the bit0 of register 47h.
Otherwise, it is at TRI-STATE.
HEADER is present, chip is enabled
Channel 0 I/O is set at ‘‘primary IDE port’’
IRQ14: same value of CH0ÐINT, if CH0ÐINT is not
masked by the bit0 of register 43h.
Otherwise, it is at TRI-STATE.
HEADER is present, chip is enabled
Channel 0 I/O is set at ‘‘other I/O port’’
INTAÝ: inversion of CH0ÐINT, if CH0ÐINT is not
masked by the bit0 of register 43h.
Otherwise, it is at TRI-STATE.
IRQ14: off
HEADER is present, chip is enabled
Channel 1 I/O is set at ‘‘secondary IDE port’’
IRQ15: same value of CH1ÐINT, if CH1ÐINT is not
masked by the bit0 of register 47h.
Otherwise, it is at TRI-STATE.
HEADER is present, chip is enabled
Channel 1 I/O is set at ‘‘other I/O port’’
INTAÝ: inversion of CH1ÐINT, if CH1ÐINT is not
masked by the bit0 of register 47h.
Otherwise, it is at TRI-STATE.
IRQ15: TRI-STATE
HEADER is present, chip is enabled
Channel 0 is not primary port and
Channel 1 is not secondary port
IRQ14: TRI-STATE
IRQ15: TRI-STATE
INTAÝ: Inversion of ORed value of CH0ÐINT and
CH1ÐINT, if none of the CH0ÐINT and CH1ÐINT is
masked by the bit0 of their respective registers.
Otherwise, it is at TRI-STATE.
Note: INTBÝ is always at TRI-STATE when HEADER is present.
Note 1: HEADER absent means Logic Low.
11
Timing Specification
Symbol
Parameter
Conditions
Min
Max
Units
t0
CLK period
30
t1
PCI signals input setup time (Note)
7
t2
PCI signals CLK to output valid
6
12
ns
t3
CLK to
CHxÐDA[2:0], CHxÐCS1, 3Ý,
CHxÐIORÝ, CHxÐIOWÝ, IDEÐD[15:0] valid
6
15
ns
t4
IORDYx setup time to CLK rising
6
ns
t5
IORDYx hold time from CLK rising
0
ns
t6
CHxÐDA[2:0], CHxÐCS1, 3Ý setup
time to CHxÐIORÝ, CHxÐIOWÝ falling
1
4
CLK
t7
CHxÐIORÝ, CHxÐIOWÝ active
pulse width
2
16
CLK
t8
CHxÐDA[2:0], CHxÐCS1, 3Ý hold
time from CHxÐIORÝ, ChxÐIOWÝ rising
1
12
CLK
t9
IDEÐD[15:0] read data setup time
to CLK rising
10
ns
t10
IDEÐD[15:0] read data hold time
from CLK rising
0
ns
t11
CLK to AD[31:0] read data valid delay
0
14
ns
t12
CHxÐDA[2:0], CHxÐCS1, 3Ý setup
time to CHxÐIORÝ, CHxÐIOWÝ falling
(Non Data Cycle)
4
4
CLK
CHxÐDA[2:0], CHxÐCS1, 3Ý hold
time from CHxÐIORÝ, CHxÐIOWÝ
rising (Non Data Cycle)
5
6
CLK
CHxÐIORÝ, CHxÐIOWÝ, active pulse
width (Non Data Cycle)
15
16
CLK
t13
t14
Note: If fast decode is enabled, the address setup time (t1 min) is 12 ns.
12
ns
ns
Timing Diagrams
Configuration Register Read Cycle
Configuration Register Write Cycle
TL/F/12073 – 5
TL/F/12073 – 6
Read Ahead Cycles (Read Buffer Miss)
TL/F/12073 – 7
13
Timing Diagrams (Continued)
Read Ahead Cycles (read buffer hit)
TL/F/12073 – 8
PCI Posted Write Cycles (medium decode)
TL/F/12073 – 9
14
Timing Diagrams (Continued)
PCI Posted Write Cycles (fast decode)
TL/F/12073 – 10
IDE Non Data Cycles (read or write)
TL/F/12073 – 11
15
PC87410 PCI-IDE Interface Controller
Physical Dimensions inches (millimeters)
100-Lead (14m x 20 mm) Molded Quad Flat Package, EIAJ
Order Number PC87410VLK
NS Package Number VLK100A
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