NSC DP5380V Asynchronous scsi interface (asi) Datasheet

DP5380 Asynchronous SCSI Interface (ASI)
General Description
The DP5380 ASI is a CMOS device designed to provide a
low cost, high performance Small Computer Systems Interface. It complies with the ANS X3.131-1986 SCSI standard
as defined by the ANSI X3T9.2 committee. It can act as
both INITIATOR and TARGET, making it suitable for any
application. The ASI supports selection, reselection, arbitration and all other bus phases. High-current open-drain drivers on chip reduce application chip count by interfacing direct to the SCSI bus. An on-chip oscillator provides all timing delays.
The DP5380 is pin and program compatible with the NMOS
NCR5380 device. NCR5380 or AM5380 applications can
use it with no changes to hardware or software. The
DP5380 is available in a 40-pin DIP or a 44-pin PCC.
The ASI is intended to be used in a microprocessor based
application, and achieves maximum performance with a
DMA controller. The device is controlled by reading and
writing several internal registers. A standard non-multiplexed address and data bus easily fits any mP environment.
Data transfers can be performed by programmed-I/O, pseudo-DMA or via a DMA controller. The ASI easily interfaces
Connection Diagram
to a DMA controller using normal or Block Mode. The ASI
can be used in either a polled or interrupt-driven environment.
Features
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
SCSI Interface
Supports TARGET and INITIATOR roles
Parity generation with optional checking
Arbitration support
Direct control/monitoring of all SCSI signals
High current outputs drive SCSI bus directly
Faster and improved timing
Very low SCSI bus loading
mP Interface
Memory or I/O-mapped control transfers
Programmed-I/O or DMA data transfers
Normal or Block-mode DMA
Fast DMA handshake timing
Table of Contents
1.0 FUNCTIONAL DESCRIPTION
2.0 PIN DESCRIPTION
3.0 REGISTER DESCRIPTION
4.0 DEVICE OPERATION
5.0 INTERRUPTS
6.0 RESET CONDITIONS
7.0 APPLICATION GUIDE
8.0 ABSOLUTE MAXIMUM RATINGS
9.0 DC ELECTRICAL CHARACTERISTICS
10.0 AC ELECTRICAL CHARACTERISTICS
A1 FLOWCHARTS
A2 REGISTER CHART
TL/F/9756 – 1
TRI-STATEÉ is a registered trademark of National Semiconductor Corporation.
PALÉ is a registered trademark of and used under license from Monolithic Memories, Inc.
C1995 National Semiconductor Corporation
TL/F/9756
RRD-B30M115/Printed in U. S. A.
DP5380 Asynchronous SCSI Interface (ASI)
May 1989
1.0 Functional Description
# Individual setting/resetting and monitoring of every SCSI
1.1 OVERVIEW
bus signal.
The ASI is designed to be used as a peripheral device in a
mP-based application and appears as a number of read/
write registers. Write registers are programmed to select desired functions. Status registers provide indication of operating conditions.
For best performance a DMA controller can be easily interfaced directly to the ASI. The ASI provides request/acknowledge and wait-state signals for the DMA interface.
The SCSI bus is easily controlled via the ASI registers. Any
bus signal may be asserted or deasserted via a bit in the
appropriate register, and the state of every signal is available by reading registers. This direct control over SCSI signals allows the user to implement all or part of the protocol
in firmware. The ASI provides hardware support for much of
the protocol.
The ASI provides the following SCSI support:
# Automatic release of the bus for BSY loss from a TARGET, SCSI RST, and lost arbitration.
# Automatic bus arbitrationÐthe mP has only to check for
highest priority.
# Selection or Reselection of any bus device. The ASI will
respond to both Selection and Reselection.
# Optional automatic monitoring of the BSY signal from a
TARGET with an interrupt after releasing control of the
bus.
Figure 1 shows an ASI in a typical application, a low cost
embedded SCSI disk controller. In this application the 8051
single-chip mP acts as the controller and the dual DMA
channels in the DP8475 allow one for the disk data and the
other for SCSI data. The PALÉ provides chip selection as
well as determining who has control of the bus. The advantage of using a mP with on-board ROM is that there is more
free time on the external bus.
# Programmed-I/O transfers for all eight information transfer types, with or without parity.
# Data transfers via DMA, in either block or non-block
mode. The DMA interface supports most devices.
TL/F/9756 – 2
FIGURE 1. ASI Application
2
1.0 Functional Description (Continued)
mode transfers use the READY output to control the speed
(insert wait-states). An End Of Process (EOP) input from the
DMA controller signals the ASI to halt DMA transfers. An
interrupt can be generated for DMA completion or an error
(see Section 5.0). All DMA data passes through the SCSI
data input and output registers, automatically selected during DMA cycles.
1.2 mP INTERFACE
Figure 2 shows a block diagram of the ASI. Key blocks within the ASI are Read/Write registers with associated decode
and control logic, interrupt and DMA logic, SCSI bus arbitration logic, SCSI drivers/receivers with parity and the SCSI
data input and output registers. The ASI has three interfaces, one to SCSI, one to a DMA controller and the third to a
mP. The internal registers control all operations of the ASI.
The mP interface consists of non-multiplexed address and
data busses with associated control signals. Address decode logic selects a register for reading or writing. The address lines A0–2 select the register for mP accesses while
for DMA accesses the address lines are ignored.
The register bank consists of twelve registers mapped into
an address space of eight locations. Upon an external chip
reset the registers are cleared (all zeroes).
1.4 SCSI INTERFACE
The ASI contains all logic required to interface directly to the
SCSI bus. Direct control and monitoring of all SCSI signals
is provided. The state of each SCSI signal may be determined by reading a register which continuously reflects the
state of the bus. Each signal may be asserted by writing a
ONE to the appropriate bit.
The ASI includes logic to automatically handle SCSI timing
sequences too fast for mP control. In particular there is
hardware support for DMA transfers, bus arbitration, selection/reselection, bus phase monitoring, BSY monitoring for
bus disconnection, bus reset and parity generation and
checking.
1.3 DMA INTERFACE
The DMA logic interfaces to single-cycle, block mode, flowthrough or fly-by controllers. Single byte transfers are accomplished via the DRQ/DACK handshake signals. Block
TL/F/9756 – 3
FIGURE 2. ASI Block Diagram
3
1.0 Functional Description (Continued)
The ASI incorporates high-current drivers and SCHMITT
trigger receivers for interfacing directly to the SCSI bus. This
feature reduces the chip count of any SCSI application.
The ASI arbitration logic controls arbitration for use of the
SCSI bus. The mP programs the SCSI device ID into the
ASI, then sets the ARBITRATE bit. The INITIATOR COMMAND REGISTER (ICR) is read to determine when arbitration has started and whether it is won or lost.
The BSY signal is continously monitored to detect bus disconnection and bus free phases. The ASI incorporates an
on-board oscillator to determine Bus Settle, Bus Free and
Arbitration Delays. The oscillator tolerance guarantees all
timing to be within the SCSI specification.
1.5 PARITY
The ASI provides for parity protection on the SCSI interface.
The data bus has eight data bits and one parity bit. The
parity may be enabled via a register bit. A parity error can be
programmed to cause an interrupt.
2.0 Pin Descriptions
Symbol
DIP
PCC
Type
Function
21
24
I
Chip Select: an active low enable for read or write operations, accessing the register
selected by A0 . . . 2.
30, 32, 33
33, 36, 37
I
Address 0 . . . 2: these three signals are used with CS, RD, and WR to address a
register for read or write.
RD
24
27
I
Read: an active low enable for reading an internal register selected by A0 . . . 2 and
enabled by CS. It also selects the Input Data Register when used with DACK.
WR
29
32
I
Write: an active low enable for writing an internal register selected by A0 . . . 2 and
enabled by CS. It also selects the Output Data Register when used with DACK.
RESET
28
31
I
Reset: an active low input with a Schmitt trigger. Clears all internal registers. (SCSI
RST unaffected).
D0 . . . 7
1, 40 – 34
2, 44–38
I/O
Data 0 . . . 7: bidirectional TRI-STATEÉ signals connecting the active high mP data
bus to the internal registers.
INT
23
26
O
Interrupt: an active high output to the mP when an error has occurred, an event
requires service or has completed.
DRQ
22
25
O
DMA Request: an active high output asserted when the data register is ready to read
or written. DRQ occurs only if DMA mode is enabled. The signal is cleared by DACK.
DACK
26
29
I
DMA Acknowledge: an active low input that resets DRQ and addresses the data
registers for input or output transfers. DACK is used instead of CS by the DMA
controller.
READY
25
28
O
Ready: an active high output used to control the speed of block mode DMA transfers.
Ready goes active when the chip is ready to send/receive data and remains inactive
after the transfer until the byte is sent or until the DMA mode bit is reset.
EOP
27
30
I
End Of Process: an active low signal that terminates a block of DMA transfers. It
should be asserted during the transfer of the last byte.
9 . . . 2, 10
10 . . . 3, 11
I/O
DB0 . . . 7, DBP: SCSI data bus with parity. DB7 is the MSB and is the highest priority
during arbitration. Parity is ODD. Parity is always generated and can be optionally
checked. Parity is not valid during arbitration.
RST
16
18
I/O
Reset: SCSI reset, monitored and can be set by ASI.
BSY
13
15
I/O
Busy: indicates the SCSI bus is being used. Can be driven by TARGET or
INITIATOR.
SEL
12
14
I/O
Select: used by the INITIATOR to select a TARGET or by the TARGET to reselect an
INITIATOR.
ACK
14
16
I/O
Acknowledge: driven by the INITIATOR and received by the TARGET as part of the
REQ/ACK handshake.
ATN
15
17
I/O
Attention: driven by the INITIATOR to indicate an attention condition to the
TARGET.
CS
A0 . . . 2
DB0 . . . 7
DBP
4
2.0 Pin Descriptions (Continued)
Symbol
DIP
PCC
Type
Function
REQ
20
22
I/O
Request: driven by the TARGET and received by the INITIATOR as part of the REQ/
ACK handshake.
I/O
17
19
I/O
Input/Output: driven by the TARGET to control the direction of transfers on the
SCSI bus. This signal also distinguishes between selection and reselection.
C/D
18
20
I/O
Command/Data: driven by the TARGET to indicate whether command or data bytes
are being transferred.
MSG
19
21
I/O
Message: driven by the TARGET during message phase to identify message bytes
on the bus.
VCC
GND
31
11
35
12, 13
Ð
VCC, GND: a 5V DC is required. Because of very large switching currents good
decoupling and power distribution is mandatory.
2.1 Connection Diagrams
Order Number DP5380N
See NS Package Number N40A
TL/F/9756 – 4
Order Number DP5380V
See NS Package Number V44A
TL/F/9756 – 5
5
3.0 Register Description
INITIATOR COMMAND REGISTER (ICR)
8 Bits
HA 1
Read-Write
This register is used to control the INITIATOR and some
other SCSI signals, and to monitor the progress of bus arbitration. Most of the SCSI signals may also be asserted in
TARGET mode. Bits 5 to 0 are reset when BSY is lost (see
MR2 description).
3.1 GENERAL
The DP5380 ASI is a register-based device with eight addressable locations. Some addresses have dual functions
depending upon whether they are being read from or written
to. Device operation is described in Section 4.
Figure 3.2 summarises the register map. Note that for registers reading or writing SCSI signals the SCSI name is used
for each bit. Although the SCSI bus is active low the registers invert the SCSI bus. This means an active SCSI signal
is represented by a ONE in a register and an inactive signal
by a ZERO.
Bit 7
RST
3.2 REGISTERS
OUTPUT DATA REGISTER (ODR)
8 Bits
HA 0
Write-Only
This is a transparent latch used to send data to the SCSI
bus. The register can be written by mP cycles or via DMA.
DMA writes automatically select the ODR at Hex Address 0
(HA 0). This register is also written with the ID bits required
during arbitration and selection/reselection phases. Data is
latched at the end of the write cycle.
Bit 7
DB6
DB5
DB4
DB3
DB2
DB1
Initiator Command Register
DB0
Output Data Register
CURRENT SCSI DATA (CSD)
8 Bits
HA 0
Read-Only
This register enables reading of the current SCSI data bus.
If SCSI parity checking is enabled it will be checked at the
beginning of the read cycle. The register is also used for mP
accesses of SCSI data during programmed-I/O or ID checking during arbitration. Parity is not valid during arbitration.
DMA transfers select the IDR (HA 6) instead of the CSD
register.
Bit 7
0
1
Deassert ATN.
Assert SCSI ATN signal. The MR2 TARGET MODE bit
must also be false to assert the signal.
Reading the ICR reflects the state of this bit.
SEL: Assert Select
Bit 2
0
1
Deassert SEL.
Assert SCSI SEL signal. Can be used in INITIATOR or
TARGET mode.
Reading the ICR reflects the state of this bit.
BSY: Assert Busy
Bit 3
Bit 0
DB7
DB6
DB5
DB4
DB3
DB2
DB1
TEST LA/DIFF ACK BSY SEL ATN DBUS
DBUS: Assert Data Bus
Bit 0
0 Disable SCSI data bus driving.
1 Enable contents of Output Data Register onto the SCSI
data bus. SCSI parity is also generated and driven on
DBP.
This bit should be set when transferring data out of the ASI
in either TARGET or INITIATOR mode, for both DMA or
programmed-I/O. In INITIATOR mode the drivers are only
enabled if: Mode Register 2 TARGET MODE bit is 0, and
I/O is false, and C/D, I/O, MSG match the contents of the
Target Command Register (phasematch is true). In TARGET mode only the MR2 bit needs to be set with this bit.
Reading the ICR reflects the state of this bit.
ATN: Assert Attention
Bit 1
Bit 0
DB7
Bit 0
DB0
0
Deassert BSY.
Assert SCSI BSY signal. Can be used in INITIATOR or
TARGET mode.
Reading the ICR reflects the state of this bit.
Current SCSI Data
1
Hex
Adr
Register
Mnemonic
Bits
R/W
0
0
1
2
3
4
4
5
5
6
6
7
7
Output Data Register
Current SCSI Data
Initator Command Register
Mode Register 2
Target Command Register
Select Enable Register
Current SCSI Bus Status
Bus and Status
Start DMA Send
Start DMA Target Receive
Input Data Register
Start DMA Initiator Receive
Reset Parity/Interrupts
ODR
CSD
ICR
MR2
TCR
SER
CSB
BSR
SDS
SDT
IDR
SDI
RPI
8
8
8
8
4
8
8
8
0
0
8
0
0
WO
RO
RW
RW
RW
WO
RO
RO
WO
WO
RO
WO
RO
FIGURE 3.2. Registers
6
3.0 Register Description (Continued)
ACK: Assert Acknowledge
0 Deassert ACK.
the Output Data Register should contain the SCSI device IDÐa single bit set only. The status of the arbitration process is given in the AIP and LA bits (6, 5) in the
Initiator Command Register.
DMA: DMA Mode
Bit 1
0 Disable DMA mode.
1 Enable DMA operation. This bit should be set then one
of address 5 to 7 written to start DMA. The TARGET
MODE bit in the ICR and the phase lines in the TCR
should have been set appropriately. The DBUS bit in
the ICR must be set for DMA operations. BSY must be
active in order to set this bit. The phase lines must
match the contents of the TCR during the actual transfers. In DMA mode ASI logic automatically controls the
REQ/ACK handshakes.
This bit should be reset by a mP write to stop any DMA
transfer. An EOP signal will not reset this bit. During
DMA, CS and DACK should not be active simultaneously.
This bit will be reset if BSY is lost during DMA mode.
Bit 4
1
Assert SCSI ACK signal. The MR2 TARGET MODE bit
must also be false to assert the signal.
Reading the ICR reflects the state of this bit.
DIFF: Differential Enable
Bit 5 Write
0 This bit must be reset to 0.
1 Do not use. Reserved for future use on a differential
pair device.
LA: Lost Arbitration
Bit 5 Read
0 Normally reset to 0 to show arbitration not lost or not
enabled.
1 Will be set when the ASI loses arbitation, i.e. when SEL
is true during arbitration AND the Assert SEL bit of this
register is false.
A 1 in this bit means the ASI has arbitrated for the bus,
asserted BSY and its ID on the data bus and another device
has asserted SEL. The ARBITRATE bit in MR2 must be set
to enable arbitration.
TEST: Test Mode Enable
Bit 6 Write
0 Output drivers are enabled.
1 Output drivers disabled.
AIP: Arbitration In Progress
Bit 6 Read
0 Normally 0 to show no arbitration in progress.
1 Set when the ASI has detected BUS FREE phase and
asserted BSY and the Output Data Register contents
onto the SCSI data bus. This bit remains set until arbitration is disabled.
RST: Assert RST
Bit 7
0
1
BSY: Monitor Busy
Bit 2
0 Disable BSY monitor.
1 Monitor SCSI BSY signal and interrupt when BSY goes
inactive. When this bit goes active the lower 6 bits of
the ICR are reset and all signals removed from the
SCSI bus. This is used to check for valid TARGET connection.
EOP: Enable EOP Interrupt
Bit 3
0 No interrupt for EOP.
1 Interrupt after valid EOP condition.
PINT: Enable SCSI Parity Interrupt
Bit 4
0 No interrupt on SCSI parity error.
1 When SCSI parity is enabled via the PCHK bit, setting
this bit enables an interrupt upon a SCSI parity error.
PCHK: Enable SCSI Parity Checking
Bit 5
0 No SCSI parity checking.
1 Enable checking of SCSI parity during read operations.
This applies to either programmed I/O or DMA mode.
TARG: Target Mode
Bit 6
0 Initiator Mode.
1 Target Mode.
BLK: Block Mode DMA
Bit 7
0 Non-block DMA.
1 When set along with DMA bit (1) enable block mode
DMA transfers. In block mode the READY line is used
to handshake each byte with the DMA controller instead of the DRQ/DACK handshake used in non-block
mode.
TARGET COMMAND REGISTER (TCR)
4 Bits
HA 3
Read-Write
This register is used to control TARGET SCSI signals and to
program the desired phase during INITIATOR mode. During
Deassert RST.
Assert SCSI RST signal. RST is asserted as long as this
bit is 1, or until a mP Reset (RESET).
After this bit is set the INT pin goes active and internal registers reset (except for the interrupt latch, MR2 TARGET
MODE bit, and this bit. Reading the ICR reflects the state of
this bit.
MODE REGISTER 2 (MR2)
8 Bits
HA2
Read-Write
This register is used to program basic operating conditions
in the ASI. Operation as TARGET or INITIATOR, DMA
mode and type as well as some interrupt controls are set via
this register. This is a Read/Write register and when read
the value reflects the state of each bit.
Bit 7
BLK
Bit 0
TARG PCHK PINT
EOP
BSY
DMA
ARB
Mode Register 2
ARB: Arbitrate
Bit 0
0 Disable arbitration.
1 Enable arbitration. The ASI will wait for a BUS FREE
phase then arbitrate for the bus. Before setting this bit
7
3.0 Register Description (Continued)
DMA transfers the SCSI phase lines (C/D, MSG, I/O) must
match the contents of the TCR for transfers to occur. A
phase mismatch halts DMA transfers and generates an interrupt.
Bit 7
x
BUS AND STATUS REGISTER (BSR)
8 Bits
HA 5
Read-Only
This read-only register is used to monitor SCSI signals not
included in the CSB, and internal status bits. This register is
read after an interrupt to determine the cause of an interrupt. Bit 0 or 1 are set to 1 if the SCSI signal is active.
Bit 0
x
x
x
REQ
MSG
C/D
I/O
Bit 7
Target Command Register
EDMA DRQ SPER
This is a read/write register and the value read reflects the
state of each bit, except bit 4–7 which always read 0.
I/O: Assert I/O
Bit 0
ACK: Acknowledge
0
1
Deassert MSG.
Assert SCSI MSG signal. The MR2 TARGET MODE bit
must also be active.
REQ: Assert REQ
Bit 3
0 Deassert REQ.
1 Assert SCSI REQ signal. The MR2 TARGET MODE bit
must also be active. This bit is used to handshake SCSI
data via programmed-I/O.
SELECT ENABLE REGISTER (SER)
8 Bits
HA 4
Write-Only
This write-only register is used to program the SCSI device
ID for the ASI to respond to during Selection or Reselection
Phases. Only one bit in the register should be set. When
SEL is true, BSY false and the SER ID bit active an interrupt
will occur.
This interrupt is reset or can be disabled by writing zero to
this register. Parity will also be checked during Selection or
Reselection if the PCHK bit in MR2 is set.
Bit 0
DB6
DB5
DB4
DB3
DB2
DB1
DB0
Select Enable Register
CURRENT SCSI BUS STATUS (CSB)
8 Bits
HA 4
Read-Only
This read-only register is used to monitor SCSI control signals and the SCSI parity bit. The SCSI lines are monitored
during programmed-I/O transfers and after an interrupt in
order to determine the cause. A bit is 1 if the corresponding
SCSI signal is active.
Bit 7
RST
Bit 0
BSY
REQ
MSG
C/D
I/O
SEL
PHSM BSY
ATN
ACK
Bit 0
This bit reflects the state of the SCSI ACK Signal.
Bit 1
ATN: Attention
This bit reflects the state of the SCSI ATN Signal.
BSY: Busy Error
Bit 2
0 No Error.
1 This SCSI BSY signal has become inactive while the
MR2 BSY (Monitor BSY) bit is set. This will cause an
interrupt, remove all ASI signals from the SCSI bus and
reset the DMA MODE bit in MR2.
PHSM: Phase Match
Bit 3
0 Phase Match. The SCSI C/D, I/O and MSG phase lines
are continuously compared with the corresponding bits
in the TCR. The result of this comparison is reflected in
this bit. This bit must be 1 (phase matches) for DMA
transfers. A phase mismatch will stop DMA transfers
and cause an interrupt.
INT: Interrupt Request
Bit 4
0 No Interrupt.
1 Interrupt request active. Set when an enabled interrupt
condition occurs. This bit reflects the state of the INT
pin. INT may be reset by performing a Reset Parity/Interrupt (RPI) function.
SPER: SCSI Parity Error
Bit 5
0 No SCSI parity error.
1 SCSI parity error occurred. This bit remains set once an
error occurs until the RPI function clears it. The PCHK
bit in MR2 must be set for a parity error to be checked
and registered.
DRQ: DMA Request
Bit 6
0 No DMA request.
1 DMA request active. This bit reflects the state of the
DRQ pin. DRQ is reset by asserting DACK during a
DMA cycle or by resetting the DMA bit in MR2. A Busy
error will reset the MR2 DMA bit and thus will also clear
DRQ. A phase mismatch will not reset DRQ.
EDMA: End of DMA
Bit 7
0 Not end of DMA.
1 Set when DACK, EOP and either RD or WR are active
simultaneously. Normally occurs when the last byte is
transferred by the DMA. During DMA send operations
the last byte transferred by the DMA may not have
been transferred on SCSI so REQ and ACK should be
monitored to verify when the last SCSI transfer is complete. This bit is reset when the MR2 DMA bit is reset.
Deassert I/O.
Assert SCSI I/O signal. The MR2 TARGET MODE bit
must also be active.
C/D: Assert C/D
Bit 1
0 Deassert C/D.
1 Assert SCSI C/D signal. The MR2 TARGET MODE bit
must also be active.
MSG: Assert MSG
Bit 2
Bit 7
INT
Bus & Status Register
0
1
DB7
Bit 0
DBP
Current SCSI Bus Status
8
3.0 Register Description (Continued)
START DMA SEND (SDS)
0 Bits
HA 5
Write-Only
This write-only register is used to start a DMA send operation. A write of don’t-care data should be the last thing done
by the mP. The MR2 DMA, BLK and TARG bits must have
been programmed previously.
Bit 7
x
Bit 0
x
x
x
x
x
x
x
Start DMA Send
START DMA TARGET RECEIVE (SDT)
0 Bits
HA 6
Write-Only
This write-only register is used to start a DMA Target Receive operation. Same comments as SDS apply.
INPUT DATA REGISTER (IDR)
8 Bits
HA 6
Read-Only
This read-only register contains the SCSI data last latched
during a DMA receive. Each byte from SCSI is latched into
this register automatically by the ASI DMA logic. A DMA
read (DACK and RD) automatically selects this register. Programmed-I/O SCSI data reads should use the CSD (HA8)
START DMA INITIATOR RECEIVE (SDI)
0 Bits
HA 7
Write-Only
This write-only register is used to start a DMA INITIATOR
Receive Operation. Same comments as SDS apply.
RESET PARITY/INTERRUPT (RPI)
0 Bits
HA 7
Read-Only
This read-only register is used to reset the parity and interrupt latches. Reading this register resets the SCSI parity,
Busy Loss and Interrupt Request latches.
TL/F/9756 – 6
FIGURE 4.2. mP Cycles
Each SCSI signal may be asserted by setting a bit in the
TCR or ICR. Setting the bit to 1 asserts the SCSI signal.
The following code demonstrates a byte transferred via programmed-I/O in INITIATOR mode.
À
/*Transfer one byte as Initiator*/
while (NOT (TCR:REQ));
/* wait till TARGET asserts REQ */
data 4 input (CSD);
/* parity is checked if enabled*/
output (ICR, Assert ACK);
while (TCR:REQ);
/* wait till TARGET deasserts REQ */
output (ICR, 0);
/* deassert ACK, ready for next byte */
Ó
4.0 Device Operation
4.4 ARBITRATION
This sub-section describes the arbitration support provided
by the ASI and how to program it.
Since the SCSI arbitration process requires signal sequencing too fast for mP’s, hardware support is provided by the
ASI. The arbitration process is enabled by bit 0 MR2 (ARB).
Prior to setting this bit the ODR should be programmed with
the device’s SCSI IDÐa single bit.
The ASI will monitor the bus for a BUS FREE phase. The
BSY signal is continuously monitored. If continuously inactive for at least a SCSI Bus Settle Delay (400 ns) and SEL is
inactive, a valid Bus Free Phase exists. After a period of
SCSI Bus Free Delay (800 ns) the ASI asserts BSY and the
ODR onto the SCSI data bus. The mP should poll the ICR to
determine when arbitration has started. The AIP bit in the
ICR is set when the Bus Free Phase is detected and the
EASI is beginning the Bus Free Delay. Following the Bus
Free Delay a 2.2 ms SCSI Arbitration Delay is required before examining the data bus to resolve the priorities of the
ID bits. This delay must be implemented in firmware. The
ICR Lost Arbitration (LA) bit must be examined to determine
whether arbitration is lost. The LA bit is set if another
4.1 GENERAL
This section describes overall operation of the ASI. More
detailed information of data transfers, interrupts and reset
conditions are covered in later sections. The operation description covers mP accesses, SCSI bus monitoring, arbitration, selection, reselection, programmed-I/O, DMA interrupts. Programming and timing details are covered.
For information regarding interfacing to mP’s and DMA controllers refer to Section 7.0.
In the descriptions following program examples are given in
pseudo-C. This processor-independent approach should be
clearest. These are backed up by flow charts in Appendix
A.1.
4.2 mP ACCESSES
The mP accesses the EASI via the CS, RD, WR and address
and data lines in order to read/write the registers. Figure 4.2
shows typical timing. Note the use of non-multiplexed address and data lines.
4.3 SCSI BUS MONITORING/DRIVING
The SCSI bus may be monitored or driven at any time. Each
bus signal is buffered and inverted by the ASI and can be
read via the CSB, BSR and CSD registers. An active SCSI
reads a 1 in the status registers.
9
4.0 Device Operation (Continued)
device asserts SEL during arbitration. If the LA bit is 0 the
data bus is read via the CSD register. The data is examined
to resolve ID priorities. If this device is the highest ID assert
SEL by setting ICR bit 2 to a 1. After waiting Bus Clear a
Bus Settle Delays (1200 ns) the Selection Phase begins.
These 2 delays must be implemented in firmware.
complished by monitoring and setting lines individually. Data
is output via the ODR and read in via the CSD register.
The following code shows INITIATOR and TARGET programming for two of these cases. See Appendix A.1 for
flowcharts.
Initiator Command Send
4.5 SELECTION/RESELECTION
The ASI can be used to select or reselect a device. The ASI
will also respond to selection or reselection.
À
MR2 4 monitor BSY
TCR 4 Command Phase /*02h*/
while (bytes) to do) À
while (REQ) inactive)
idle; /*CSB bit 5 4 0*/
if (BSR: phase match 44 0)
phase error;
else À
ODR 4 date byte;
ICR 4 Assert ACK;
while (REQ active)
idle; /*CSB bit 5 44 1*/
ICR 4 deassert ACK
/* byte transfer complete */
byte count Ð;
4.5.1 Selecting/Reselecting
Selection requires programming the ODR with the desired
and own device ID’s; the data bus via ICR DBUS (bit 0);
asserting ATN if required via ICR bit 1; asserting SEL via
ICR bit 2; then resetting the MR2 ARB bit.
The SER should have been cleared to zero before Selection/Reselection to ensure the ASI does not respond. If Reselection is desired the I/O line should also be asserted
before SEL via TCR bit 0.
Resetting the ARB bit causes the ASI to remove BSY and
the ODR from the data bus. Thus the ICR Assert data bus
bit is required to assert the bits for desired and own device
ID’s.
BSY is then monitored to determine when the device has
responded to (re)selection. If the device fails to respond an
error handler should sequence the ASI off the bus. If the
device responds the ICR DBUS and SEL bits should be reset to remove these signals. If this is a Reselection the ICR
BSY bit (3) should be set before removing the other signals.
The bus is now ready to handle Information Transfer Phases.
Ó
Ó
goto data phase;
Ó
Target Message Receive
4.5.2 (Re)Selection Response
The ASI responds to Selection or Reselection when the
SER is non-zero. A (re)selected interrupt is generated when
BSY is false for at least a Bus Settle Delay (400 ns); and
SEL is true AND any non-zero bit in the SER has its corresponding SCSI data bus bit active. A Selection is disabled
by zeroing the SER. If parity is supported it should be valid
during (re)selection so must be checked via the SPE bit (5)
in the BSR. SCSI specification states that (re)selection is
not valid if more than 2 data bits are active. This condition is
checked by reading the CSD.
When the selection interrupt occurs it is determined by reading the BSR and CSB registers. There is no dedicated
status bit for (re)selection so it must be determined by the
absence of other interrupts, and the active state of the SEL
signal. Reselection occurs when I/O is also active. See
Section 6.0.
À
/* assumed Assert BSY already set in ICR */
MR2 4 TARG MODE OR PARITY CHECK OR
PARITY INTERRUPT;
TCR 4 Message Out phase; /*06h*/
delay (Bus Settle);
TCR 4 Assert REQ;
while (ACK inactive)
idle; /* BSR bit 0 */
data e CSD; /* parity is latched */
if (BSR: parity error)
error routine;
else À
TCR 4 deassert REQ;
while (ACK active)
idle;
4.6 MONITORING BSY
While an INITIATOR is connected to a TARGET the TARGET must maintain an active BSY signal. During DMA operations the BSY signal is monitored by the ASI and will halt
operations if it goes inactive. To enable BSY to be monitored at other times the MR2 BSY bit (2) should be set. An
interrupt will be generated if BSY goes inactive while MR2
BSY is set.
This interrupt sets bit 2 in the BSR.
Ó
/* message done, can change to next
phase */
Ó
4.8 NON-BLOCK DMA TRANSFERS
Data transfers may be effected by DMA. This method
should be used for optimum performance. Two methods of
DMA are available-block and non-block mode. This section
describes non-block mode transfers.
4.7 COMMAND/MESSAGE/STATUS TRANSFERS
Command message and status bytes are transferred using
programmed-I/O. The SCSI REQ/ACK handshake is ac-
10
4.0 Device Operation (Continued)
The interface to the DMA controller uses the DRQ, DACK,
EOP lines in non-block mode. Each byte is requested (DRQ)
and ack’d (DACK). Representative timing for a DMA read is
shown in Figure 4.8.1.
if(BSR:Busy error OR NOT
(BSR:End of DMA))
error routine;
else À
MR2 4 04h;
ICR 4 0;
/*DMA End*/
/*reset DMA bit*/
Ó
Ó
Initiator Receive
/*DATA IN PHASE*/
À
Program DMA Controller;
TCR 4 01h;
/*phase*/
MR2 4 3Eh;
SDI 4 0;
/*Start DMA Init
Rx*/
while (NOT interrupt)
idle;
/*no need to wait for last SCSI handshake
done since DMA done implies it is
checked*/
if(BSR:parity error OR BSR: busy error
TL/F/9756 – 7
FIGURE 4.8.1. Non-Block DMA Timing
4.8.1. NON-BLOCK DMA
DMA operation involves programming the ASI with the setup parameters, initiating the DMA cycles and checking for
correct operation when the completion interrupt is received.
The DMA controller should be programmed with the data
byte count and the memory start address. Methods of halting a DMA operation are covered in Section 4.11.
Setting up the ASI requires enabling or disabling the following: Data bus driving, DMA mode enable, BSY monitoring,
EOP interrupt, parity checking, parity interrupt, TARGET
Mode, bus phase.
Once set up DMA should be initiated by writing to address 5,
6, or 7 as appropriate. The DMA controller should assert
EOP during the transfer of the last byte, although this may
be done by the mP if the DMA transfers (n b 1) bytes and
the mP transfers the last byte. See the application guide for
more details (Section 7.0).
Upon completion the mP should check the following as required: End of DMA, Parity Error, Phase Match, Busy Error.
The end of DMA occurs as a response to EOP. SCSI transfers may still be underway so REQ and ACK must still be
checked to establish when the final byte is finished.
The code below shows programming of the ASI in each of
the four DMA cases. One of these cases is shown in a flow
diagram in Appendix A.
Initiator Send
or NOT (BSR End of DMA)
do error routines;
/*End of DMA*/
else À
while (CSD:REQ)
idle; /*wait for REQ inactive
to deassert ACK*/
MR2 4 04h;
Ó
Ó
Target Receive
/*DATA OUT PHASE*/
À
Program DMA Controller;
TCR 4 0;
/*phase*/
ICR 4 08h;
MR2 4 7Ah;
/*check parity*/
SDT 4 0;
/*Start DMA Targ Rx*/
while (not interrupt)
idle;
/*when End of DMA occurs the last byte
has been read and checked*/
if(BSR:parity error OR NOT(BSR: End of DMA)
error routine;
À
else
/*End of DMA*/
while (BSR:ACK)
idle;
/*Not True End of DMA, so wait until SCSI
bus inactive before changing phase*/
MR2 4 40h;
change phase as required;
/*DATA OUT PHASE*/
À
Program DMA Controller;
TCR 4 00h;
/*phase*/
ICR 4 01h;
/*Assert DBUS*/
MR2 4 0Eh;
SDS 4 00;
/*Start DMA Send*/
while (NOT interrupt)
idle;
while (CSD:REQ)
idle
/*wait for last
SCSI byte
transfer so phase
is checked*/
Ó
Ó
11
4.0 Device Operation (Continued)
Target Send
4.9 BLOCK MODE DMA TRANSFERS
/*DATA IN PHASE*/
In Block Mode the DMA interface uses the DRQ, DACK,
EOP and READY lines, DRQ is asserted once at the beginning of transfers and deasserted once DACK is received.
DACK should be asserted continuously for the duration of
all the transfer. EOP should be asserted during the last
DMA byte signal when the next DMA byte transfers. The
ASI asserts the READY signal when the next DMA byte
should be transferred.
As for non-block mode the End of DMA interrupt is just
EOP, also in block mode receive the ASI does not return
READY to an active signal after EOP. This means external
logic must gate off READY if the mP is not to be locked up.
For more details see Section 7.0.
The block mode is intended for systems where the overhead of handing the system busses to and from the mP and
DMA controller is too great. The block mode handshake is
not necessarily faster than non-block (it may be) but the
overall transfer rate is improved once the bus exchange
overhead is removed. Of course the mP is prevented from
executing for the whole DMA operation.
If a phase mismatch occurs the READY signal is left in the
inactive state. The DMA controller must hand back the bus
to the mP and the inactive READY signal may need to be
gated off.
When performing DMA as an INITIATOR the EOP signal
does not deassert ACK on the SCSI bus. Firmware must
determine when REQ is inactive after the last SCSI transfer
then reset the MR2 DMA bit to deassert ACK.
À
Program DMA Controller;
TCR 4 01h;
/*phase*/
ICR 4 09h;
MR2 4 4Ah;
SDS 4 0;
/*Start DMA Send*/
while (NOT interrupt)
idle;
if(NOT(BSR:End of DMA)
error;
else À
/*DMA end*/
repeat À
while (CSB:REQ OR BSR:ACK)
loop count 4 3;
loop count Ð;Ó /*decrement*/
until (loop count 44 0);
MR2 4 40h;
Change phase as required;
Ó
Ó
Some explanation of the final part of Target Send is required. In this type of DMA operation it is very difficult to
exactly determine the True End of DMA simply detecting
REQ and ACK simultaneously inactive is not enough.
Reference to Figure 4.8.2 will help to understand the following text.
Programming the ASI in block mode is the same as nonblock mode except bit 7 in MR2 should also be set.
4.10 PSEUDO DMA
The system design can utilize ASI DMA logic for non-data
transfers. This removes the need to poll REQ/ACK and program the assertion/deassertion of the handshake signal.
The mP can emulate a DMA controller by asserting DACK
and EOP signals. DRQ may be sampled by reading the
BSR. In most cases the chip decode logic can be adapted
to this use for little or no cost. See Section 7.0 for further
details.
4.11 HALTING A DMA OPERATION
There are three ways to halt a DMA operation apart from a
chip or SCSI reset. These methods are: EOP, phase mismatch and resetting the DMA MODE bit in MR2.
TL/F/9756–8
FIGURE 4.8.2. Target Send DMA
As shown in Figure 4.8.2 ACK going active causes the DRQ
for the next byte and also REQ to go inactive. ACK going
inactive allows REQ to go active for the next byte. If the
INITIATOR is slow removing ACK the mP may sample the
SCSI bus after the EOP interrupt at point A. Here both REQ
and ACK will be inactive, but there is one more byte to
transfer on SCSI. Due to chip timing delays this condition
will not last more than 200 ns. A safe way to determine the
True End of DMA is to sample REQ and ACK and ONLY
when both are inactive in three successive samples will the
mP be at point B in the figure.
4.11.1 End Of Process
EOP is asserted for a minimum period during the last DMA
cycle. The EOP signal generates the End of DMA interrupt.
EOP does not cause the MR2 DMA mode bit to be reset.
4.11.2 DMA Phase Mismatch
If a REQ goes active while there is a phase mismatch the
DMA will be halted and an interrupt generated. The ASI will
stop driving the SCSI bus when the mismatch occurs. A
phase mismatch is when the TCR phase bits do not match
the SCSI bus values.
4.11.3 DMA Mode Bit
If EOP is not used the best method is to reset the MR2 DMA
Mode bit. This bit may be reset at any time, and should be
reset after an End of DMA interrupt or a phase mismatch.
12
Bit 7
4.0 Device Operation (Continued)
Resetting the bit disables all DMA logic and thus should
only be reset at the True End of DMA condition. Additionally
all DMA logic is reset so this bit must be reset then set again
to carry out the next DMA phase.
5.1 OVERVIEW
Before individually describing each interrupt an explanation
of the use of interrupts is required.
5.2 USING INTERRUPTS
Interrupts are controlled by bits in MR2 if control is provided.
Not all interrupts can be disabled under software control.
When an interrupt occurs both the BSR and CSD register
must be read and analysed to determine the source of interrupt. Since status is NOT provided for each interrupt great
care should be exercised when determining the interrupt
source.
1
EDMA DRQ SPER
1
x
x
INT PHSM BSY
BSR
x
x
ATN
ACK
Bit 7
RST
BSY
REQ
x
x
MSG C/D
CSD
x
0
x
I/O
SEL
DBP
Bit 0
0
x
EDMA DRQ SPER
1
0
x
INT PHSM BSY
BSR
x
x
ATN
ACK
Bit 7
Bit 0
0
x
x
RST
BSY
REQ
x
x
MSG C/D
CSD
x
0
x
I/O
SEL
DBP
5.6 BUSY LOSS
If bit 2 MR2 is set the SCSI BSY signal is monitored and an
interrupt is generated if BSY is continuously inactive for at
least a BUS SETTLE DELAY (400 ns). This interrupt may be
reset by reading HA 7. Following an interrupt the BSR and
CSD should contain the values shown below, where usually
CSD e 00.
Bit 0
0
1
x
RST
BSY
REQ
x
x
MSG C/D
CSD
x
0
x
I/O
SEL
DBP
Bit 7
x
Bit 7
x
EDMA DRQ SPER
1
x
x
x
x
INT PHSM BSY
BSR
0
x
ATN
ACK
1
x
1
INT PHSM BSY
BSR
0
x
ATN
ACK
Bit 7
Bit 0
0
0
x
RST
BSY
REQ
x
x
MSG C/D
CSD
x
x
x
I/O
SEL
DBP
5.7 (RE)SELECTION
An interrupt will be generated when: SEL is active, BSY is
inactive, and the device ID is true. The device ID is determined by the value in the SER. If ANY non-zero bit in the
SER has its corresponding SCSI data bit active during selection the device ID is true. If I/O is active this is a reselection. The interrupt is disabled by writing all zeros to the SER,
and reset by reading HA 7.
Bit 0
x
Bit 0
EDMA DRQ SPER
5.4 END OF DMA
If EOP is asserted during a DMA transfer bit 7 of the BSR
will be set and an interrupt generated if bit 3 of MR2 is 1.
EOP is recognized when EOP, DACK and either IOR or IOW
are all simultaneously active for a minimum period. The interrupt may be reset by reading HA 7. Following an interrupt
the BSR and CSD should contain the values shown below.
1
x
x
Bit 0
x
1
Bit 7
5.3 SCSI PARITY ERROR
If SCSI parity checking is enabled via MR2 bit 5 an interrupt
can occur as a result of a read from CSD, a selection/
(re)selection, or a DMA receive operation. The parity error
bit (bit 5) in the BSR will be set if checking is enabled. An
interrupt will occur if Enable Parity Interrupt (bit 4) of MR2 is
set. The interrupt is reset by reading HA7. Following an interrupt the BSR and CSD should contain the values shown
below.
x
0
5.5 DMA PHASE MISMATCH
When the SCSI REQ goes active during a DMA operation
the contents of the TCR are compared with the SCSI phase
lines C/D, MSG and I/O. If the two do not match an interrupt is generated. This interrupt will occur as long as the
MR2 DMA bit is set (bit 1), i.e. it cannot be masked. The
mismatch removes the ASI from driving the SCSI data bus.
The interrupt may reset by reading HA 7. Following an interrupt the BSR and CSD should contain the values shown
below.
5.0 Interrupts
Bit 7
Bit 0
13
sets all logic. This action does not create an interrupt or
generate a SCSI reset.
5.0 Interrupts (Continued)
If SCSI parity checking is enabled it will be checked and
should be valid. Following an interrupt the BSR and CSD
should contain the values shown below.
Bit 7
0
6.3 EXTERNAL SCSI RESET
When a SCSI RST is applied externally the ASI resets all
registers and logic and issues an interrupt. The only register
bits not affected are the Assert RST bit (bit 7) in the ICR and
the TARGET Mode bit (bit 6) in MR2.
Bit 0
0
0
EDMA DRQ SPER
1
x
0
INT PHSM BSY
BSR
x
0
ATN
ACK
Bit 7
6.4 SCSI RESET ISSUED
When the mP sets the Assert RST bit in the ICR the RST
signal goes active. Since the ASI monitors RST also the
same reset actions as in 6.3 apply. The SCSI RST signal will
remain active as long as bit 7 in the ICR is setÐi.e. until
programmed 0 or a chip RESET occurs.
Bit 0
0
0
0
RST
BSY
REQ
0
0
MSG C/D
CSD
0
1
x
I/O
SEL
DBP
7.0 Application Guide
This section is intended to show the interface between the
mP, ASI and DMA controller (DMAC). Figure 7.1 shows a
general interface when the ASI and DMAC are I/O-mapped
devices. This configuration will implement a 2 to 2.5M
Bytes/sec SCSI port using 2 cycle compressed timing from
the 5 MHz DMAC.
6.0 Reset Conditions
6.1 GENERAL
There are three ways to reset the ASI; mP chip RESET,
SCSI bus reset applied externally, SCSI bus reset issued by
the ASI.
Using a faster DMAC and memory may allow the ASI to
operate at a higher rateÐbut of course any system will be
limited by the available DMA rate from the SCSI device currently connected to. The interface shown has several features that are examined more closely in the following text.
6.2 CHIP RESET
When the RESET signal is asserted for the required duration the ASI clears ALL internal registers and therefore re-
TL/F/9756 – 9
FIGURE 7.1. mP/ASI/DMA Interface
14
7.0 Application Guide (Continued)
In DMA mode the ASI generates all SCSI handshakes. At all
other times the mP is responsible for REQ/ACK handshakes. Using pseudo-DMA may reduce mP overhead.
When doing DMA transfers via BLOCK MODE and an error
occurs, the ASI may not deassert the READY signal. For
some DMA controllers this may lock the bus, so the PAL
asserts READY and EOP to the DMA if an interrupt occurs
while READY is false. This completes the current DMA cycle and prevents further DMA for the rest of the block thus
allowing the bus to be handed back to the mP for servicing.
The PAL generates RD and WR strobes while the mP is bus
master, but the DMAC provides the strobes while it is bus
master so the PAL outputs are TRI-STATE.
The PAL details are shown in Figure 7.2 with the signal
definitions and equations following.
All the interface signal requirements are satisfied by a PAL
device. The memory interface is not shown, only the relevant DMAC and mP lines are included.
The ASI data and address lines connect directly to the mP/
DMAC busses. The DRQ output from the ASI goes direct to
the DMAC. The EOP output from the DMAC goes to the ASI
input, but can also be asserted via the PAL since the DMAC
output is open-drain.
The PAL is programmed so that the mP can access the ASI
in three ways. The three access types are: Register R/W,
DMA R/W, DMA with EOP. Examination of the PAL equations below shows how the mP may perform any of the three
basic access types simply by accessing the ASI at different
I/O address slots. This enables the mP to simulate a DMAC
(pseudo-DMA). DMA mode may then be used for all information transfer phases.
TL/F/9756 – 10
FIGURE 7.2. Interface PAL
15
7.0 Application Guide (Continued)
CSASI 4 IORQ*A7*A6*A5*A4*AEN; ASI reg R/W chip select
ADACK 4 IORQ*A7*A6*A5*A4*RD; mP pseudo-DMA cycle
IORQ*A7*A6*A5*A4*WR
0IORQ*A7*A6*A5*A4*RD; mP pseudo-DMA with EOP
0IORQ*A7*A6*A5*A4*WR
0DDACK;
; DMAC DMA cycle
IF(AEN)AEOP 4 I0RQ*A7*A6*A5*A4*RD; mP pseudo-DMA with EOP
0IORQ*A7*A6*A5*A4*WR a DEOP* AREADY
IF(DDACK*AREADY*INT)DEOP 4 DDACK*AREADY*INT
;DMA cycle with error
CSDMA 4 I0RQ*A7*A6*A5*A4
;DMAC register R/W
DREADY 4 AREADY*INT
;ASI not READY and not INT
;ASI not READY and DMA cycle active
0AREADY*DDACK
IF(AEN)I0R 4 I0RQ*RD
;mP I/O Read cycle
;mP I/O Write cycle
IF(AEN)I0W 4 I0RQ*WR
IF(AEN)MEMR 4 I0RQ*RD
;mP memory Read cycle
;mP memory Write cycle
IF(AEN)MEMW 4 I0RQ*WR
FIGURE 7.3. PAL Equations
The mP and DMA signals are defined below
A7–A4
I0RQ
RD
WR
AEN
DDACK
CSDMA
DREADY
IOR, IOW
MEMR, MEMW
Address bus
Memory I/O cycle select
Read Strobe
Write Strobe
High DMA address enable asserted by DMAC
DMAC DMA Acknowledge
DMA Chip Select
Ready signal to DMACÐinserts wait-states when low
I/O data strobes to/from DMAC
Memory data strobe from DMAC
16
8.0 Absolute Maximum Ratings*
Storage Temperature Range (TSTG)
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales
Office/Distributors for availability and specifications.
Supply Voltage (VCC)
DC Input Voltage (VIN)
DC Output Voltage (VOUT)
b 65§ C to a 150§ C
Power Dissipation (PD)
500 mW
Lead Temperature (TL) (Soldering, 10 sec)
Electro-Static Discharge Rating
b 0.5V to a 7.0V
b 0.5V to VCC a 0.5V
b 0.5V to VCC a 0.5V
260§ C
2 kV
*Absolute maximum ratings are those values beyond which damage to the
device may occur.
9.0 DC Electrical Characteristics (VCC e 5.0V g 10% unless otherwise specified) TA e 0§ C to a 70§ C
Symbol
Parameter
Conditions
Typ
Limit
Units
VIH
Minimum High Level
Input Voltage
2.0
V
VIL
Maximum Low Level
Input Voltage
0.8
V
VOH1
VOH2
Minimum High Level
Output Voltage
VCC b 0.1
2.4
V
V
VOL1
VOL2
VOL3
Maximum Low Level
Output Voltage
0.5
0.1
0.4
V
V
V
IIN
Maximum Input Current
VIN e VCC or GND
g1
mA
IOZ
Maximum TRI-STATE Output
Leakage Current
VOUT e VCC or GND
g 10
mA
ICC
Supply Current
VIN e VCC or GND
SCSI Inputs e 3V
4
mA
lIOUT e 20 mA
lIOUTl e 4.0 mA
SCSI Bus Pins: lIOLl e 48 mA
Other Pins: lIOLl e 20 mA
lIOLl e 8.0 mA
2.5
Capacitance TA e 25§ C, f e 1 MHz
Symbol
Parameter (Note 3)
Typ
Units
CIN
COUT
Input Capacitance
5
pF
Output Capacitance
7
pF
AC Test Conditions
Input Pulse Level
GND to 3.0V
Input Rise and Fall Times
6 ns
Input/Output Reference Levels
1.3V
TRI-STATE Reference Levels
(Note 2)
TL/F/9756 – 11
Active Low a 0.5V
Active High b 0.5V
Note 1: CL e 50 pF including jig and scope capacitance.
Note 2: S1 e Open for push-pull outputs.
S1 e VCC for active low to TRI-STATE.
S1 e GND for active high to TRI-STATE.
Note 3: This parameter is not 100% tested.
17
10.0 AC Electrical Characteristics all parameters are preliminary and subject to change without notice
Symbol
DP5380
Parameter
Min
bfas
BSY False to Arbitrate Start
bfbc
BSY False to Bus Clear
rst
RESET Pulse Width
stbc
SEL True to Bus Clear
1200
Typ
Units
Max
2200
800
150
ns
ns
ns
500
ns
10.1 ARBITRATION
TL/F/9756 – 12
10.2 mP RESET
TL/F/9756 – 13
18
10.0 AC Electrical Characteristics
all parameters are preliminary and subject to change without notice (Continued)
Symbol
DP5380
Parameter
Min
Typ
Units
Max
ahr
Address Hold from End of Read Enable (Note 1)
10
ns
ahw
Address Hold from End of Write Enable (Note 2)
10
ns
as
Address Setup to Read or Write Enable (Notes 1, 2)
10
ns
csh
CS Hold from End of RD or WR
0
ns
dhr
Data Hold from End of Read Enable (Notes 1, 3)
10
dhw
mP Data Hold Time from End of WR
20
dsw
Data Setup to End of Write Enable
50
rdv
Data Valid from Read Enable (Note 1)
ww
Write Enable Width (Note 2)
60
ns
100
60
ns
ns
ns
ns
Note 1: Read enable (mP) is CS and RD active.
Note 2: Write enable (mP) is CS and WR active.
Note 3: This includes the RC delay inherent in the tests’ method. These signals typically turn off after 25 ns enabling other devices to drive these lines with no
contention.
10.3 mP WRITE
TL/F/9756 – 14
10.4 mP READ
TL/F/9756 – 15
19
10.0 AC Electrical Characteristics (Continued)
10.5 DMA WRITE (NON-BLOCK MODE) TARGET SEND
TL/F/9756 – 16
Symbol
DP5380
Parameter
Min
Typ
Units
Max
afrt
ACK False to REQ True (DACK or WR False)
120
ns
atdt
ACK True to DRQ True (Target)
90
ns
atrf
ACK True to REQ False (Target)
dfdt
DACK False to DRQ True
dfrt
DACK False to REQ True (ACK False)
dhwr
DMA Data Hold Time from End of WR
dkhw
dsrt
115
30
90
ns
ns
110
ns
30
ns
DACK Hold from End of WR
0
ns
SCSI Data Setup to REQ True (Target Send) (Note 1)
40
ns
dswd
Data Setup to End of DMA Write Enable
50
ns
dtdf
DACK True to DRQ False
eop
Width of EOP Pulse (Note 2)
40
ns
wwn
DMA Non-Block Mode Write Enable Width (Note 3)
60
ns
100
Note 1: EOP, DACK, RD/WR must all be true for recognition of EOP.
Note 2: Write enable (DMA) is DACK and WR active.
20
ns
10.0 AC Electrical Characteristics (Continued)
10.6 DMA WRITE (NON-BLOCK MODE) INITIATOR SEND
TL/F/9756 – 17
Symbol
DP5380
Parameter
Min
Typ
90
Units
Max
dfaf
DACK False to ACK False (Non-Block Initiator Send)
dfdt
DACK False to DRQ True
30
dhi
SCSI Data Hold from Write EnableÐInitiator
15
dhwr
DMA Data Hold Time from End of WR
30
ns
dkhw
DACK Hold from End of WR
0
ns
dswd
Data Setup to End of DMA Write Enable
50
ns
dtdf
DACK True to DRQ False
eop
Width of EOP Pulse (Note 1)
rfdt
120
ns
ns
ns
100
ns
REQ False to DRQ True
100
ns
rtat
REQ True to ACK True (Initiator Send)
100
ns
wwn
DMA Non-Block Mode Write Enable Width (Note 2)
40
Note 1: EOP, DACK, RD/WR must all be true for recognition of EOP.
Note 2: Write enable (DMA) is DACK and WR active.
21
60
ns
ns
10.0 AC Electrical Characteristics (Continued)
10.7 DMA READ (NON-BLOCK MODE) TARGET RECEIVE
TL/F/9756 – 18
Symbol
DP5380
Parameter
Min
Typ
Units
Max
afrt
ACK False to REQ True (DACK or WR False)
120
ns
atdt
ACK True to DRQ True (Target)
90
ns
atrf
ACK True to REQ False (Target)
115
ns
ddv
DMA Data Valid from Read Enable (Note 1)
90
ns
dfdt
DACK False to DRQ True
dfrt
DACK False to REQ True (ACK False)
dhr
Data Hold from End of Read Enable (Notes 1, 2)
10
dhra
SCSI Data Hold from REQ or ACK True (Receive)
30
ns
dkhr
DACK Hold from End of RD
0
ns
dsra
SCSI Data Setup Time to REQ or ACK True (Receive)
20
ns
dtdf
DACK True to DRQ False
eop
Width of EOP Pulse (Note 4)
30
90
ns
110
ns
60
ns
100
40
ns
ns
Note 1: Read enable (DMA) is DACK and RD active.
Note 2: This includes the RC delay inherent in the tests’ method. These signals typically turn off after 25 ns enabling other devices to drive these lines with no
contention.
Note 3: EOP, DACK, RD/WR must all be true for recognition of EOP.
22
10.0 AC Electrical Characteristics (Continued)
10.8 DMA READ (NON-BLOCK MODE) INITIATOR RECEIVE
TL/F/9756 – 19
Symbol
DP5380
Parameter
Min
Typ
Units
Max
ddv
DMA Data Valid from Read Enable (Note 1)
90
dfaf
DACK False to ACK False (REQ False, Non-block, In rx)
120
dfdt
DACK False to DRQ True
30
dhr
Data Hold from End of Read Enable (Notes 1, 2)
10
dhra
SCSI Data Hold from REQ or ACK True (Receive)
30
ns
dkhr
DACK Hold from End of RD
0
ns
dsra
SCSI Data Setup Time to REQ or ACK True (Receive)
20
dtdf
DACK True to DRQ False
eop
Width of EOP Pulse (Note 3)
rfaf
REQ False to ACK False (DACK False)
100
rtat
REQ True to ACK True (Initiator Receive)
100
ns
rtdt
REQ True to DRQ True
120
ns
90
ns
ns
ns
60
ns
ns
100
40
ns
ns
ns
Note 1: Read enable (DMA) is DACK and RD active.
Note 2: This includes the RC delay inherent in the tests’ method. These signals typically turn off after 25 ns enabling other devices to drive these lines with no
contention.
Note 3: EOP, DACK, RD/WR must all be true for recognition of EOP.
23
10.0 AC Electrical Characteristics (Continued)
10.9 DMA WRITE (BLOCK MODE) TARGET SEND
TL/F/9756 – 20
Symbol
DP5380
Parameter
Min
Typ
Units
Max
afrt
ACK False to REQ True (DACK or WR False)
120
ns
atrf
ACK True to REQ False (Target)
115
ns
atrt
ACK True to READY True (Block Mode Target Send)
110
ns
dhat
SCSI Data Hold from ACK True
40
dhwr
DMA Data Hold Time from End of WR
30
ns
dsrt
SCSI Data Setup to REQ True
50
ns
dswd
Data Setup to End of DMA Write Enable
50
ns
dtdf
DACK True to DRQ False
eop
Width of EOP Pulse (Note 1)
40
rtwf
READY true to WR False
60
wfrf
WR False to READY False
wfrt
WR False to REQ True (ACK False)
wwb
DMA Write Enable Width (Note 2)
ns
100
ns
100
120
60
Note 1: EOP, DACK, RD, WR must all be true for recognition of EOP.
Note 2: Write enable (DMA) is DACK and WR active.
24
ns
ns
ns
ns
ns
10.0 AC Electrical Characteristics (Continued)
10.10 DMA WRITE (BLOCK MODE) INITIATOR SEND
TL/F/9756 – 21
Symbol
DP5380
Parameter
Min
Typ
Units
Max
dhi
SCSI Data Hold from Write EnableÐInitiator
15
ns
dhwr
DMA Data Hold Time from End of WR
30
ns
dswd
Data Setup to End of DMA Write Enable
50
ns
dtdf
DACK True to DRQ False
eop
Width of EOP Pulse (Note 2)
100
rfyt
REQ False to READY True
80
rtat
REQ True to ACK True
100
rtwf
READY True to WR False
wfaf
WR False to ACK False (REQ False)
wfrf
WR False to READY False
wwb
DMA Write Enable Width (Note 1)
40
60
60
Note 1: Write enable (DMA) is DACK and WR active.
Note 2: EOP, DACK, RD/WR must all be true for recognition of EOP.
25
ns
ns
ns
ns
ns
120
ns
100
ns
ns
10.0 AC Electrical Characteristics (Continued)
10.11 DMA READ (BLOCK MODE) TARGET RECEIVE
TL/F/9756 – 22
Symbol
DP5380
Parameter
Min
Typ
Units
Max
afrt
ACK False to REQ True (DACK or WR False)
120
ns
atrf
ACK True to REQ False
115
ns
atyt
ACK True to READY True
110
ns
ddv
DMA Data Valid from Read Enable (Note 1)
90
ns
dhr
Data Hold from End of Read Enable (Notes 1, 2)
10
dhra
SCSI Data Hold from REQ or ACK True
30
ns
dsra
SCSI Data Setup Time to REQ or ACK True
20
ns
60
100
ns
dtdf
DACK True to DRQ False
eop
Width of EOP Pulse (Note 3)
rfrt
RD False to REQ True (ACK False)
100
ns
rfyf
RD False to READY False
110
ns
rydv
READY True to Data Valid
35
ns
40
ns
ns
Note 1: Read enable (DMA) is DACK and RD active.
Note 2: This includes the RC delay inherent in the tests’ method. These signals typically turn off after 25 ns enabling other devices to drive these lines with no
contention.
Note 3: EOP, DACK, RD/WR must all be active for recognition of EOP.
26
10.0 AC Electrical Characteristics (Continued)
10.12 DMA READ (BLOCK MODE) INITIATOR RECEIVE
TL/F/9756 – 23
Symbol
DP5380
Parameter
Min
Typ
Units
Max
ddv
DMA Data Valid from Read Enable (Note 1)
90
dhr
Data Hold from End of Read Enable (Notes 1, 2)
10
dhra
SCSI Data Hold from REQ or ACK True
30
dsra
SCSI Data Setup Time to REQ or ACK True
20
dtdf
DACK True to DRQ False
eop
Width of EOP Pulse (Note 3)
rdaf
RD False to ACK False (REQ False)
125
rfaf
REQ False to ACK False (DACK False)
100
ns
rfyf
RD False to READY True False
110
ns
rtat2
REQ True to ACK True
100
ns
rtyt
REQ True to READY True
75
ns
rydv
READY True to Data Valid
35
ns
60
ns
ns
ns
ns
100
40
ns
ns
ns
Note 1: Read enable (DMA) is DACK and RD active.
Note 2: This includes the RC delay inherent in the tests’ method. These signals typically turn off after 25 ns enabling other devices to drive these lines with no
contention.
Note 3: EOP, DACK, RD/WR must all be active for recognition of EOP.
27
Appendix A1
Arbitration and (Re)Selection
TL/F/9756 – 25
*Only set ATN if Select with ATN is desired.
TL/F/9756–24
28
Appendix A1 (Continued)
Command Transfer (Initiator)
Command Transfer (Target)
TL/F/9756 – 26
TL/F/9756 – 27
29
Appendix A2
Register Chart
READ
Bit 7
DB7
Current SCSI Data (CSD)
DB6
Bit 7
RST
AIP
LA
0
0
DB1
BSY
SEL
EOP
BSY
0
REQ
REQ
MSG
C/D
INT
DB5
DB4
DB3
DMA
I/O
DB2
x
x
x
x
DB7
I/O
SEL
DBP
BLK
x
TARG PCHK PINT
DB7
x
x
x
x
Bit 0
Bit 7
x
x
X e Unknown
x
BSY
SEL
EOP
BSY
x
REQ
MSG
DB5
DB4
DB3
DB2
x
x
x
x
x
x
x
ATN DBUS
Bit 0
DMA
ARB
Bit 0
C/D
I/O
DB1
DB0
Bit 0
x
x
DB0
Bit 0
Bit 0
x
Start DMA Target Receive (SDT)
x
Bit 0
x
x
Start DMA Initiator Receive (SDI)ÐMode N Bit 0
x
X e Don’t Care
30
DB1
Start DMA Send (SDS)
Bit 7
DB0
DB2
Select Enable Register (SER)
DB6
Bit 7
ACK
DB3
Target Command Register (TCR)
Bit 7
Bit 0
x
DB4
Mode Register 2 (MR2)
Bit 7
Bit 0
DB1
DB5
Bit 0
Initiator Command Register (ICR)
Bit 7
Bit 0
ATN
DB6
RST TEST DIFF EN ACK
ARB
C/D
Output Data Register (ODR)
Bit 7
Bit 0
Reset Parity/Interrupt (RPI)ÐMode N
x
DB0
Bit 0
Input Data Register (IDR)
DB6
Bit 7
ATN DBUS
MSG
PHSM BSY
Bit 0
Bit 0
Bus and Status Register (BSR)
Bit 7
x
DB2
Current SCSI Bus Status (CSB)
BSY
EDMA DRQ SPER
Bit 7
DB3
Target Command Register (TCR)
Bit 7
DB7
ACK
TARG PCHK PINT
Bit 7
RST
DB4
Mode Register 2 (MR2)
Bit 7
0
DB5
Initiator Command Register (ICR)
Bit 7
BLK
WRITE
x
x
x
x
x
x
Physical Dimensions inches (millimeters)
Molded Dual-In-Line Package (N)
Order Number DP5380N
NS Package Number N40A
31
DP5380 Asynchronous SCSI Interface (ASI)
Physical Dimensions inches (millimeters) (Continued)
Lit. Ý 102926
Plastic Chip Carrier (V)
Order Number DP5380V
NS Package Number V44A
LIFE SUPPORT POLICY
NATIONAL’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT
DEVICES OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT OF NATIONAL
SEMICONDUCTOR CORPORATION. As used herein:
1. Life support devices or systems are devices or
systems which, (a) are intended for surgical implant
into the body, or (b) support or sustain life, and whose
failure to perform, when properly used in accordance
with instructions for use provided in the labeling, can
be reasonably expected to result in a significant injury
to the user.
National Semiconductor
Corporation
1111 West Bardin Road
Arlington, TX 76017
Tel: 1(800) 272-9959
Fax: 1(800) 737-7018
2. A critical component is any component of a life
support device or system whose failure to perform can
be reasonably expected to cause the failure of the life
support device or system, or to affect its safety or
effectiveness.
National Semiconductor
Europe
Fax: (a49) 0-180-530 85 86
Email: cnjwge @ tevm2.nsc.com
Deutsch Tel: (a49) 0-180-530 85 85
English Tel: (a49) 0-180-532 78 32
Fran3ais Tel: (a49) 0-180-532 93 58
Italiano Tel: (a49) 0-180-534 16 80
National Semiconductor
Hong Kong Ltd.
13th Floor, Straight Block,
Ocean Centre, 5 Canton Rd.
Tsimshatsui, Kowloon
Hong Kong
Tel: (852) 2737-1600
Fax: (852) 2736-9960
National Semiconductor
Japan Ltd.
Tel: 81-043-299-2309
Fax: 81-043-299-2408
National does not assume any responsibility for use of any circuitry described, no circuit patent licenses are implied and National reserves the right at any time without notice to change said circuitry and specifications.
Similar pages