INTEL 8259A

8259A
PROGRAMMABLE INTERRUPT CONTROLLER
(8259A/8259A-2)
Y
8086, 8088 Compatible
Y
Single a 5V Supply (No Clocks)
Y
MCS-80, MCS-85 Compatible
Y
Y
Eight-Level Priority Controller
Available in 28-Pin DIP and 28-Lead
PLCC Package
Y
Expandable to 64 Levels
Y
Programmable Interrupt Modes
Y
Individual Request Mask Capability
(See Packaging Spec., Order Ý231369)
Y
Available in EXPRESS
Ð Standard Temperature Range
Ð Extended Temperature Range
The Intel 8259A Programmable Interrupt Controller handles up to eight vectored priority interrupts for the CPU.
It is cascadable for up to 64 vectored priority interrupts without additional circuitry. It is packaged in a 28-pin
DIP, uses NMOS technology and requires a single a 5V supply. Circuitry is static, requiring no clock input.
The 8259A is designed to minimize the software and real time overhead in handling multi-level priority interrupts. It has several modes, permitting optimization for a variety of system requirements.
The 8259A is fully upward compatible with the Intel 8259. Software originally written for the 8259 will operate
the 8259A in all 8259 equivalent modes (MCS-80/85, Non-Buffered, Edge Triggered).
DIP
231468 – 2
PLCC
231468 – 31
231468 – 1
Figure 1. Block Diagram
December 1988
Figure 2. Pin
Configurations
Order Number: 231468-003
8259A
Table 1. Pin Description
Pin No.
Type
VCC
Symbol
28
I
SUPPLY: a 5V Supply.
GND
14
I
GROUND
CS
1
I
CHIP SELECT: A low on this pin enables RD and WR communication
between the CPU and the 8259A. INTA functions are independent of
CS.
WR
2
I
WRITE: A low on this pin when CS is low enables the 8259A to accept
command words from the CPU.
RD
3
I
READ: A low on this pin when CS is low enables the 8259A to release
status onto the data bus for the CPU.
4–11
I/O
BIDIRECTIONAL DATA BUS: Control, status and interrupt-vector
information is transferred via this bus.
12, 13, 15
I/O
CASCADE LINES: The CAS lines form a private 8259A bus to control
a multiple 8259A structure. These pins are outputs for a master 8259A
and inputs for a slave 8259A.
SP/EN
16
I/O
SLAVE PROGRAM/ENABLE BUFFER: This is a dual function pin.
When in the Buffered Mode it can be used as an output to control
buffer transceivers (EN). When not in the buffered mode it is used as
an input to designate a master (SP e 1) or slave (SP e 0).
INT
17
O
INTERRUPT: This pin goes high whenever a valid interrupt request is
asserted. It is used to interrupt the CPU, thus it is connected to the
CPU’s interrupt pin.
18–25
I
INTERRUPT REQUESTS: Asynchronous inputs. An interrupt request
is executed by raising an IR input (low to high), and holding it high until
it is acknowledged (Edge Triggered Mode), or just by a high level on an
IR input (Level Triggered Mode).
INTA
26
I
INTERRUPT ACKNOWLEDGE: This pin is used to enable 8259A
interrupt-vector data onto the data bus by a sequence of interrupt
acknowledge pulses issued by the CPU.
A0
27
I
AO ADDRESS LINE: This pin acts in conjunction with the CS, WR, and
RD pins. It is used by the 8259A to decipher various Command Words
the CPU writes and status the CPU wishes to read. It is typically
connected to the CPU A0 address line (A1 for 8086, 8088).
D7 –D0
CAS0 –CAS2
IR0 –IR7
2
Name and Function
8259A
FUNCTIONAL DESCRIPTION
Interrupts in Microcomputer Systems
Microcomputer system design requires that I.O devices such as keyboards, displays, sensors and other components receive servicing in a an efficient
manner so that large amounts of the total system
tasks can be assumed by the microcomputer with
little or no effect on throughput.
The most common method of servicing such devices is the Polled approach. This is where the processor must test each device in sequence and in effect
‘‘ask’’ each one if it needs servicing. It is easy to see
that a large portion of the main program is looping
through this continuous polling cycle and that such a
method would have a serious detrimental effect on
system throughput, thus limiting the tasks that could
be assumed by the microcomputer and reducing the
cost effectiveness of using such devices.
A more desirable method would be one that would
allow the microprocessor to be executing its main
program and only stop to service peripheral devices
when it is told to do so by the device itself. In effect,
the method would provide an external asynchronous
input that would inform the processor that it should
complete whatever instruction that is currently being
executed and fetch a new routine that will service
the requesting device. Once this servicing is complete, however, the processor would resume exactly
where it left off.
231468 – 3
Figure 3a. Polled Method
This method is called Interrupt . It is easy to see that
system throughput would drastically increase, and
thus more tasks could be assumed by the microcomputer to further enhance its cost effectiveness.
The Programmable Interrupt Controller (PIC) functions as an overall manager in an Interrupt-Driven
system environment. It accepts requests from the
peripheral equipment, determines which of the incoming requests is of the highest importance (priority), ascertains whether the incoming request has a
higher priority value than the level currently being
serviced, and issues an interrupt to the CPU based
on this determination.
Each peripheral device or structure usually has a
special program or ‘‘routine’’ that is associated with
its specific functional or operational requirements;
this is referred to as a ‘‘service routine’’. The PIC,
after issuing an Interrupt to the CPU, must somehow
input information into the CPU that can ‘‘point’’ the
Program Counter to the service routine associated
with the requesting device. This ‘‘pointer’’ is an address in a vectoring table and will often be referred
to, in this document, as vectoring data.
231468 – 4
Figure 3b. Interrupt Method
3
8259A
The 8259A is a device specifically designed for use
in real time, interrupt driven microcomputer systems.
It manages eight levels or requests and has built-in
features for expandability to other 8259A’s (up to 64
levels). It is programmed by the system’s software
as an I/O peripheral. A selection of priority modes is
available to the programmer so that the manner in
which the requests are processed by the 8259A can
be configured to match his system requirements.
The priority modes can be changed or reconfigured
dynamically at any time during the main program.
This means that the complete interrupt structure can
be defined as required, based on the total system
environment.
INTERRUPT REQUEST REGISTER (IRR) AND
IN-SERVICE REGISTER (ISR)
The interrupts at the IR input lines are handled by
two registers in cascade, the Interrupt Request Register (IRR) and the In-Service (ISR). The IRR is used
to store all the interrupt levels which are requesting
service; and the ISR is used to store all the interrupt
levels which are being serviced.
PRIORITY RESOLVER
This logic block determines the priorites of the bits
set in the IRR. The highest priority is selected and
strobed into the corresponding bit of the ISR during
INTA pulse.
INTA (INTERRUPT ACKNOWLEDGE)
INTA pulses will cause the 8259A to release vectoring information onto the data bus. The format of this
data depends on the system mode (mPM) of the
8259A.
DATA BUS BUFFER
This 3-state, bidirectional 8-bit buffer is used to interface the 8259A to the system Data Bus. Control
words and status information are transferred
through the Data Bus Buffer.
READ/WRITE CONTROL LOGIC
The function of this block is to accept OUTput commands from the CPU. It contains the Initialization
Command Word (ICW) registers and Operation
Command Word (OCW) registers which store the
various control formats for device operation. This
function block also allows the status of the 8259A to
be transferred onto the Data Bus.
CS (CHIP SELECT)
A LOW on this input enables the 8259A. No reading
or writing of the chip will occur unless the device is
selected.
WR (WRITE)
INTERRUPT MASK REGISTER (IMR)
The IMR stores the bits which mask the interrupt
lines to be masked. The IMR operates on the IRR.
Masking of a higher priority input will not affect the
interrupt request lines of lower quality.
INT (INTERRUPT)
This output goes directly to the CPU interrupt input.
The VOH level on this line is designed to be fully
compatible with the 8080A, 8085A and 8086 input
levels.
A LOW on this input enables the CPU to write control words (ICWs and OCWs) to the 8259A.
RD (READ)
A LOW on this input enables the 8259A to send the
status of the Interrupt Request Register (IRR), In
Service Register (ISR), the Interrupt Mask Register
(IMR), or the Interrupt level onto the Data Bus.
A0
This input signal is used in conjunction with WR and
RD signals to write commands into the various command registers, as well as reading the various status
registers of the chip. This line can be tied directly to
one of the address lines.
4
8259A
231468 – 5
Figure 4a. 8259A Block Diagram
5
8259A
231468 – 6
Figure 4b. 8259A Block Diagram
6
8259A
THE CASCADE BUFFER/COMPARATOR
This function block stores and compares the IDs of
all 8259A’s used in the system. The associated
three I/O pins (CAS0-2) are outputs when the 8259A
is used as a master and are inputs when the 8259A
is used as a slave. As a master, the 8259A sends
the ID of the interrupting slave device onto the
CAS0–2 lines. The slave thus selected will send its
preprogrammed subroutine address onto the Data
Bus during the next one or two consecutive INTA
pulses. (See section ‘‘Cascading the 8259A’’.)
INTERRUPT SEQUENCE
The powerful features of the 8259A in a microcomputer system are its programmability and the interrupt routine addressing capability. The latter allows
direct or indirect jumping to the specific interrupt routine requested without any polling of the interrupting
devices. The normal sequence of events during an
interrupt depends on the type of CPU being used.
The events occur as follows in an MCS-80/85 system:
1. One or more of the INTERRUPT REQUEST lines
(IR7–0) are raised high, setting the corresponding IRR bit(s).
2. The 8259A evaluates these requests, and sends
an INT to the CPU, if appropriate.
3. The CPU acknowledges the INT and responds
with an INTA pulse.
4. Upon receiving an INTA from the CPU group, the
highest priority ISR bit is set, and the corresponding IRR bit is reset. The 8259A will also release a
CALL instruction code (11001101) onto the 8-bit
Data Bus through its D7–0 pins.
5. This CALL instruction will initiate two more INTA
pulses to be sent to the 8259A from the CPU
group.
6. These two INTA pulses allow the 8259A to release its preprogrammed subroutine address
onto the Data Bus. The lower 8-bit address is re-
leased at the first INTA pulse and the higher 8-bit
address is released at the second INTA pulse.
7. This completes the 3-byte CALL instruction released by the 8259A. In the AEOI mode the ISR
bit is reset at the end of the third INTA pulse.
Otherwise, the ISR bit remains set until an appropriate EOI command is issued at the end of the
interrupt sequence.
The events occuring in an 8086 system are the
same until step 4.
4. Upon receiving an INTA from the CPU group, the
highest priority ISR bit is set and the corresponding IRR bit is reset. The 8259A does not drive the
Data Bus during this cycle.
5. The 8086 will initiate a second INTA pulse. During this pulse, the 8259A releases an 8-bit pointer
onto the Data Bus where it is read by the CPU.
6. This completes the interrupt cycle. In the AEOI
mode the ISR bit is reset at the end of the second INTA pulse. Otherwise, the ISR bit remains
set until an appropriate EOI command is issued
at the end of the interrupt subroutine.
If no interrupt request is present at step 4 of either
sequence (i.e., the request was too short in duration)
the 8259A will issue an interrupt level 7. Both the
vectoring bytes and the CAS lines will look like an
interrupt level 7 was requested.
When the 8259A PIC receives an interrupt, INT becomes active and an interrupt acknowledge cycle is
started. If a higher priority interrupt occurs between
the two INTA pulses, the INT line goes inactive immediately after the second INTA pulse. After an unspecified amount of time the INT line is activated
again to signify the higher priority interrupt waiting
for service. This inactive time is not specified and
can vary between parts. The designer should be
aware of this consideration when designing a system which uses the 8259A. It is recommended that
proper asynchronous design techniques be followed.
7
8259A
231468 – 7
Figure 4c. 8259A Block Diagram
INTERRUPT SEQUENCE OUTPUTS
MCS-80, MCS-85
This sequence is timed by three INTA pulses. During
the first INTA pulse the CALL opcode is enabled
onto the data bus.
Content of First Interrupt Vector Byte
D7 D6 D5 D4 D3 D2 D1 D0
CALL CODE
231468 – 8
Figure 5. 8259A Interface to
Standard System Bus
8
1
1
0
0
1
1
0
1
During the second INTA pulse the lower address of
the appropriate service routine is enabled onto the
data bus. When Interval e 4 bits A5 –A7 are programmed, while A0 –A4 are automatically inserted by
the 8259A. When Interval e 8 only A6 and A7 are
programmed, while A0 –A5 are automatically inserted.
8259A
Content of Second Interrupt Vector Byte
IR
Interval e 4
D7
D6
D5
D4
D3
D2
D1
D0
7
A7
A6
A5
1
1
1
0
0
6
A7
A6
A5
1
1
0
0
0
5
A7
A6
A5
1
0
1
0
0
4
A7
A6
A5
1
0
0
0
0
3
A7
A6
A5
0
1
1
0
0
2
A7
A6
A5
0
1
0
0
0
1
A7
A6
A5
0
0
1
0
0
0
A7
A6
A5
IR
0
0
0
0
0
Interval e 8
D7
D6
D5
D4
D3
D2
D1
D0
7
A7
A6
1
1
1
0
0
0
6
A7
A6
1
1
0
0
0
0
5
A7
A6
1
0
1
0
0
0
4
A7
A6
1
0
0
0
0
0
3
A7
A6
0
1
1
0
0
0
2
A7
A6
0
1
0
0
0
0
1
A7
A6
0
0
1
0
0
0
0
A7
A6
0
0
0
0
0
0
During the third INTA pulse the higher address of the
appropriate service routine, which was programmed
as byte 2 of the initialization sequence (A8 –A15), is
enabled onto the bus.
Content of Third Interrupt Vector Byte
D7
D6
D5
D4
D3
D2
D1 D0
A15
A14
A13
A12
A11
A10
A9
A8
8086, 8088
8086 mode is similar to MCS-80 mode except that
only two Interrupt Acknowledge cycles are issued by
the processor and no CALL opcode is sent to the
processor. The first interrupt acknowledge cycle is
similar to that of MCS-80, 85 systems in that the
8259A uses it to internally freeze the state of the
interrupts for priority resolution and as a master it
issues the interrupt code on the cascade lines at the
end of the INTA pulse. On this first cycle it does not
issue any data to the processor and leaves its data
bus buffers disabled. On the second interrupt acknowledge cycle in 8086 mode the master (or slave
if so programmed) will send a byte of data to the
processor with the acknowledged interrupt code
composed as follows (note the state of the ADI
mode control is ignored and A5 –A11 are unused in
8086 mode):
Content of Interrupt Vector Byte
for 8086 System Mode
D7
D6
D5
D4
D3
D2
D1
D0
IR7
T7
T6
T5
T4
T3
1
1
1
IR6
T7
T6
T5
T4
T3
1
1
0
IR5
T7
T6
T5
T4
T3
1
0
1
IR4
T7
T6
T5
T4
T3
1
0
0
IR3
T7
T6
T5
T4
T3
0
1
1
IR2
T7
T6
T5
T4
T3
0
1
0
IR1
T7
T6
T5
T4
T3
0
0
1
IR0
T7
T6
T5
T4
T3
0
0
0
PROGRAMMING THE 8259A
The 8259A accepts two types of command words
generated by the CPU:
1. Initialization Command Words (ICWs): Before
normal operation can begin, each 8259A in the
system must be brought to a starting pointÐby a
sequence of 2 to 4 bytes timed by WR pulses.
2. Operation Command Words (OCWs): These are
the command words which command the 8259A
to operate in various interrupt modes. These
modes are:
a. Fully nested mode
b. Rotating priority mode
c. Special mask mode
d. Polled mode
The OCWs can be written into the 8259A anytime
after initialization.
INITIALIZATION COMMAND WORDS
(ICWS)
General
Whenever a command is issued with A0 e 0 and D4
e 1, this is interpreted as Initialization Command
Word 1 (ICW1). ICW1 starts the intiitalization sequence during which the following automatically occur.
a. The edge sense circuit is reset, which means that
following initialization, an interrupt request (IR) input must make a low-to-high transistion to generate an interrupt.
9
8259A
b. The Interrupt Mask Register is cleared.
c. IR7 input is assigned priority 7.
d. The slave mode address is set to 7.
e. Special Mask Mode is cleared and Status Read is
set to IRR.
f. If IC4 e 0, then all functions selected in ICW4
are set to zero. (Non-Buffered mode*, no AutoEOI, MCS-80, 85 system).
*NOTE:
Master/Slave in ICW4 is only used in the buffered
mode.
Initialization Command Words 1 and 2
(ICW1, ICW2)
case SNGL e 0. It will load the 8-bit slave register.
The functions of this register are:
a. In the master mode (either when SP e 1, or in
buffered mode when M/S e 1 in ICW4) a ‘‘1’’ is
set for each slave in the system. The master then
will release byte 1 of the call sequence (for MCS80/85 system) and will enable the corresponding
slave to release bytes 2 and 3 (for 8086 only byte
2) through the cascade lines.
b. In the slave mode (either when SP e 0, or if BUF
e 1 and M/S e 0 in ICW4) bits 2 – 0 identify the
slave. The slave compares its cascade input with
these bits and, if they are equal, bytes 2 and 3 of
the call sequence (or just byte 2 for 8086) are
released by it on the Data Bus.
A5 –A15: Page starting address of service routines .
In an MCS 80/85 system, the 8 request levels will
generate CALLs to 8 locations equally spaced in
memory. These can be programmed to be spaced at
intervals of 4 or 8 memory locations, thus the 8 routines will occupy a page of 32 or 64 bytes, respectively.
The address format is 2 bytes long (A0 –A15). When
the routine interval is 4, A0 –A4 are automatically inserted by the 8259A, while A5 –A15 are programmed
externally. When the routine interval is 8, A0 –A5 are
automatically inserted by the 8259A, while A6 –A15
are programmed externally.
The 8-byte interval will maintain compatibility with
current software, while the 4-byte interval is best for
a compact jump table.
In an 8086 system A15 –A11 are inserted in the five
most significant bits of the vectoring byte and the
8259A sets the three least significant bits according
to the interrupt level. A10 –A5 are ignored and ADI
(Address interval) has no effect.
LTIM: If LTIM e 1, then the 8259A will operate in
the level interrupt mode. Edge detect logic
on the interrupt inputs will be disabled.
ADI:
CALL address interval. ADI e 1 then interval e 4; ADI e 0 then interval e 8.
SNGL: Single. Means that this is the only 8259A in
the system. If SNGL e 1 no ICW3 will be
issued.
IC4:
If this bit is setÐICW4 has to be read. If
ICW4 is not needed, set IC4 e 0.
231468 – 9
Initialization Command Word 3 (ICW3)
This word is read only when there is more than one
8259A in the system and cascading is used, in which
10
Figure 6. Initialization Sequence
8259A
Initialization Command Word 4 (ICW4)
SFNM: If SFNM e 1 the special fully nested mode
is programmed.
BUF: If BUF e 1 the buffered mode is programmed. In buffered mode SP/EN becomes an enable output and the master/
slave determination is by M/S.
M/S:
If buffered mode is selected: M/S e 1
means the 8259A is programmed to be a
AEOI:
mPM:
master, M/S e 0 means the 8259A is programmed to be a slave. If BUF e 0, M/S
has no function.
If AEOI e 1 the automatic end of interrupt
mode is programmed.
Microprocessor mode: mPM e 0 sets the
8259A for MCS-80, 85 system operation,
mPM e 1 sets the 8259A for 8086 system
operation.
231468 – 10
231468 – 11
Figure 7. Initialization Command Word Format
11
8259A
231468 – 12
231468 – 13
231468 – 14
NOTE:
Slave ID is equal to the corresponding master IR input.
Figure 7. Initialization Command Word Format (Continued)
12
8259A
OPERATION COMMAND WORDS
(OCWS)
After the Initialization Command Words (ICWs) are
programmed into the 8259A, the chip is ready to accept interrupt requests at its input lines. However,
during the 8259A operation, a selection of algorithms can command the 8259A to operate in various modes through the Operation Command Words
(OCWs).
Operation Control Words (OCWs)
A0
D7
D6
OCW1
D5 D4 D3 D2 D1 D0
1
M7
M6
M5
0
R
SL
M4 M3 M2 M1 M0
OCW2
EOI
0 0 L2
L1
L0
0
RR
RIS
OCW3
0
0
ESMM
SMM
1
P
231468 – 15
231468 – 16
Figure 8. Operation Command Word Format
13
8259A
Operation Control Word 1 (OCW1)
Operation Control Word 2 (OCW2)
OCW1 sets and clears the mask bits in the interrupt
Mask Register (IMR). M7 –M0 represent the eight
mask bits. M e 1 indicates the channel is masked
(inhibited), M e 0 indicates the channel is enabled.
R, SL, EOIÐThese three bits control the Rotate and
End of Interrupt modes and combinations of the two.
A chart of these combinations can be found on the
Operation Command Word Format.
L2, L1, L0ÐThese bits determine the interrupt level
acted upon when the SL bit is active.
231468 – 17
Figure 8. Operation Command Word Format (Continued)
14
8259A
Operation Control Word 3 (OCW3)
ESMMÐEnable Special Mask Mode. When this bit
is set to 1 it enables the SMM bit to set or reset the
Special Mask Mode. When ESMM e 0 the SMM bit
becomes a ‘‘don’t care’’.
SMMÐSpecial Mask Mode. If ESMM e 1 and SMM
e 1 the 8259A will enter Special Mask Mode. If
ESMM e 1 and SMM e 0 the 8259A will revert to
normal mask mode. When ESMM e 0, SMM has no
effect.
Fully Nested Mode
This mode is entered after initialization unless another mode is programmed. The interrupt requests are
ordered in priority from 0 through 7 (0 highest).
When an interrupt is acknowledged the highest priority request is determined and its vector placed on
the bus. Additionally, a bit of the Interrupt Service
register (ISO-7) is set. This bit remains set until the
microprocessor issues an End of Interrupt (EOI)
command immediately before returning from the
service routine, or if AEOI (Automatic End of Interrupt) bit is set, until the trailing edge of the last INTA.
While the IS bit is set, all further interrupts of the
same or lower priority are inhibited, while higher levels will generate an interrupt (which will be acknowledged only if the microprocessor internal Interupt
enable flip-flop has been re-enabled through software).
After the initialization sequence, IR0 has the highest
prioirity and IR7 the lowest. Priorities can be
changed, as will be explained, in the rotating priority
mode.
End of Interrupt (EOI)
The In Service (IS) bit can be reset either automatically following the trailing edge of the last in sequence INTA pulse (when AEOI bit in ICW1 is set) or
by a command word that must be issued to the
8259A before returning from a service routine (EOI
command). An EOI command must be issued twice
if in the Cascade mode, once for the master and
once for the corresponding slave.
There are two forms of EOI command: Specific and
Non-Specific. When the 8259A is operated in modes
which perserve the fully nested structure, it can determine which IS bit to reset on EOI. When a NonSpecific EOI command is issued the 8259A will automatically reset the highest IS bit of those that are
set, since in the fully nested mode the highest IS
level was necessarily the last level acknowledged
and serviced. A non-specific EOI can be issued with
OCW2 (EOI e 1, SL e 0, R e 0).
When a mode is used which may disturb the fully
nested structure, the 8259A may no longer be able
to determine the last level acknowledged. In this
case a Specific End of Interrupt must be issued
which includes as part of the command the IS level
to be reset. A specific EOI can be issued with OCW2
(EOI e 1, SL e 1, R e 0, and L0 – L2 is the binary
level of the IS bit to be reset).
It should be noted that an IS bit that is masked by an
IMR bit will not be cleared by a non-specific EOI if
the 8259A is in the Special Mask Mode.
Automatic End of Interrupt (AEOI)
Mode
If AEOI e 1 in ICW4, then the 8259A will operate in
AEOI mode continuously until reprogrammed by
ICW4. in this mode the 8259A will automatically perform a non-specific EOI operation at the trailing
edge of the last interrupt acknowledge pulse (third
pulse in MCS-80/85, second in 8086). Note that
from a system standpoint, this mode should be used
only when a nested multilevel interrupt structure is
not required within a single 8259A.
The AEOI mode can only be used in a master 8259A
and not a slave. 8259As with a copyright date of
1985 or later will operate in the AEOI mode as a
master or a slave.
Automatic Rotation
(Equal Priority Devices)
In some applications there are a number of interrupting devices of equal priority. In this mode a device,
after being serviced, receives the lowest priority, so
a device requesting an interrupt will have to wait, in
the worst case until each of 7 other devices are
serviced at most once . For example, if the priority
and ‘‘in service’’ status is:
Before Rotate (IR4 the highest prioirity requiring
service)
‘‘IS’’ Status
231468 – 18
Priority Status
231468 – 19
15
8259A
After Rotate (IR4 was serviced, all other priorities
rotated correspondingly)
‘‘IS’’ Status
231468 – 20
Priority Status
231468 – 21
There are two ways to accomplish Automatic Rotation using OCW2, the Rotation on Non-Specific EOI
Command (R e 1, SL e 0, EOI e 1) and the Rotate in Automatic EOI Mode which is set by (R e 1,
SL e 0, EOI e 0) and cleared by (R e 0, SL e 0,
EOI e 0).
Specific Rotation
(Specific Priority)
The programmer can change priorities by programming the bottom priority and thus fixing all other priorities; i.e., if IR5 is programmed as the bottom priority device, then IR6 will have the highest one.
The Set Priority command is issued in OCW2 where:
R e 1, SL e 1, L0–L2 is the binary priority level
code of the bottom priority device.
Observe that in this mode internal status is updated
by software control during OCW2. However, it is independent of the End of Interrupt (EOI) command
(also executed by OCW2). Priority changes can be
executed during an EOI command by using the Rotate on Specific EOI command in OCW2 (R e 1, SL
e 1, EOI e 1 and LO–L2 e IR level to receive
bottom priority).
ture during its execution under software control. For
example, the routine may wish to inhibit lower priority requests for a portion of its execution but enable
some of them for another portion.
The difficulty here is that if an Interrupt Request is
acknowledged and an End of Interrupt command did
not reset its IS bit (i.e., while executing a service
routine), the 8259A would have inhibited all lower
priority requests with no easy way for the routine to
enable them.
That is where the Special Mask Mode comes in. In
the special Mask Mode, when a mask bit is set in
OCW1, it inhibits further interrupts at that level and
enables interrupts from all other levels (lower as well
as higher) that are not masked.
Thus, any interrupts may be selectively enabled by
loading the mask register.
The special Mask Mode is set by OWC3 where:
SSMM e 1, SMM e 1, and cleared where SSMM e
1, SMM e 0.
Poll Command
In Poll mode the INT output functions as it normally
does. The microprocessor should ignore this output.
This can be accomplished either by not connecting
the INT output or by masking interrupts within the
microprocessor, thereby disabling its interrupt input.
Service to devices is achieved by software using a
Poll command.
The Poll command is issued by setting P e ‘1’’ in
OCW3. The 8259A treats the next RD pulse to the
8259A (i.e., RD e 0, CS e 0) as an interrupt acknowledge, sets the appropriate IS bit if there is a
request, and reads the priority level. Interrupt is frozen from WR to RD.
The word enabled onto the data bus during RD is:
D7
D6
D5
D4
D3
D2
D1
D0
I
Interrupt Masks
Each Interrupt Request input can bem masked individually by the Interrupt Mask Register (IMR) programmed through OCW1. Each bit in the IMR masks
one interrupt channel if it is set (1). Bit 0 masks IR0,
Bit 1 masks IR1 and so forth. Masking an IR channel
does not affect the other channels operation.
Special Mask Mode
Some applications may require an interrupt service
routine to dynamically alter the system priority struc-
16
Ð
Ð
Ð
Ð
W2
W1
W0
W0 – W2: Binary code of the highest priority level
requesting service.
I: Equal to ‘‘1’’ if there is an interrupt.
This mode is useful if there is a routine command
common to several levels so that the INTA sequence is not needed (saves ROM space). Another
application is to use the poll mode to expand the
number of priority levels to more than 64.
Reading the 8259A Status
The input status of several internal registers can be
read to update the user information on the system.
8259A
NOTES:
231468 – 22
1. Master clear active only during ICW1.
2. FREEZE is active during INTA and poll sequences only.
3. Truth Table for a D-Latch.
C D
Q
Operation
1
0
Di
X
Di
Qn-1
Follow
Hold
Figure 9. Priority CellÐSimplified Logic Diagram
The following registers can be read via OCW3 (IRR
and ISR or OCW1 [IMR] ).
Interrupt Request Register (IRR): 8-bit register which
contains the levels requesting an interrupt to be acknowledged. The highest request level is reset from
the IRR when an interrupt is acknowledged. (Not affected by IMR.)
In-Service Register (ISR): 8-bit register which contains the priority levels that are being serviced. The
ISR is updated when an End of Interrupt Command
is issued.
Interrupt Mask Register: 8-bit register which contains the interrupt request lines which are masked.
There is no need to write an OCW3 before every
status read operation, as long as the status read
corresponds with the previous one; i.e., the 8259A
‘‘remembers’’ whether the IRR or ISR has been previously selected by the OCW3. This is not true when
poll is used.
After initialization the 8259A is set to IRR.
For reading the IMR, no OCW3 is needed. The output data bus will contain the IMR whenever RD is
active and A0 e 1 (OCW1).
Polling overrides status read when P e 1, RR e 1
in OCW3.
The IRR can be read when, prior to the RD pulse, a
Read Register Command is issued with OCW3 (RR
e 1, RIS e 0.)
Edge and Level Triggered Modes
The ISR can be read, when, prior to the RD pulse, a
Read Register Command is issued with OCW3 (RR
e 1, RIS e 1).
If LTIM e ‘0’, an interrupt request will be recognized
by a low to high transition on an IR input. The IR
input can remain high without generating another interrupt.
This mode is programmed using bit 3 in ICW1.
17
8259A
231468 – 23
Figure 10. IR Triggering Timing Requirements
If LTIM e ‘1’, an interrupt request will be recognized
by a ‘high’ level on IR Input, and there is no need for
an edge detection. The interrupt request must be
removed before the EOI command is issued or the
CPU interrupts is enabled to prevent a second interrupt from occurring.
The priority cell diagram shows a conceptual circuit
of the level sensitive and edge sensitive input circuitry of the 8259A. Be sure to note that the request
latch is a transparent D type latch.
In both the edge and level triggered modes the IR
inputs must remain high until after the falling edge of
the first INTA. If the IR input goes low before this
time a DEFAULT IR7 will occur when the CPU acknowledges the interrupt. This can be a useful safeguard for detecting interrupts caused by spurious
noise glitches on the IR inputs. To implement this
feature the IR7 routine is used for ‘‘clean up’’ simply
executing a return instruction, thus ignoring the interrupt. If IR7 is needed for other purposes a default
IR7 can still be detected by reading the ISR. A normal IR7 interrupt will set the corresponding ISR bit, a
default IR7 won’t. If a default IR7 routine occurs during a normal IR7 routine, however, the ISR will remain set. In this case it is necessary to keep track of
whether or not the IR7 routine was previously entered. If another IR7 occurs it is a default.
The Special Fully Nest Mode
This mode will be used in the case of a big system
where cascading is used, and the priority has to be
conserved within each slave. In this case the fully
nested mode will be programmed to the master (us-
18
ing ICW4). This mode is similar to the normal nested
mode with the following exceptions:
a. When an interrupt request from a certain slave is
in service this slave is not locked out from the
master’s priority logic and further interrupt requests from higher priority IR’s within the slave
will be recognized by the master and will initiate
interrupts to the processor. (In the normal nested
mode a slave is masked out when its request is in
service and no higher requests from the same
slave can be serviced.)
b. When exiting the Interrupt Service routine the
software has to check whether the interrupt serviced was the only one from that slave. This is
done by sending a non-specific End of Interrupt
(EOI) command to the slave and then reading its
In-Service register and checking for zero. If it is
empty, a non-specific EOI can be sent to the
master too. If not, no EOI should be sent.
Buffered Mode
When the 8259A is used in a large system where
bus driving buffers are required on the data bus and
the cascading mode is used, there exists the problem of enabling buffers.
The buffered mode will structure the 8259A to send
an enable signal on SP/EN to enable the buffers. In
this mode, whenever the 8259A’s data bus outputs
are enabled, the SP/EN output becomes active.
This modification forces the use of software programming to determine whether the 8259A is a master or a slave. Bit 3 in ICW4 programs the buffered
mode, and bit 2 in ICW4 determines whether it is a
master or a slave.
8259A
CASCADE MODE
The 8259A can be easily interconnected in a system
of one master with up to eight slaves to handle up to
64 priority levels.
The master controls the slaves through the 3 line
cascade bus. The cascade bus acts like chip selects
to the slaves during the INTA sequence.
In a cascade configuration, the slave interrupt outputs are connected to the master interrupt request
inputs. When a slave request line is activated and
afterwards acknowledged, the master will enable the
corresponding slave to release the device routine
address during bytes 2 and 3 of INTA. (Byte 2 only
for 8086/8088).
The cascade bus lines are normally low and will contain the slave address code from the trailing edge of
the first INTA pulse to the trailing edge of the third
pulse. Each 8259A in the system must follow a separate initialization sequence and can be programmed to work in a different mode. An EOI command must be issued twice: once for the master and
once for the corresponding slave. An address decoder is required to activate the Chip Select (CS)
input of each 8259A.
The cascade lines of the Master 8259A are activated only for slave inputs, non-slave inputs leave the
cascade line inactive (low).
231468 – 24
Figure 11. Cascading the 8259A
19
8259A
ABSOLUTE MAXIMUM RATINGS*
NOTICE: This is a production data sheet. The specifications are subject to change without notice.
Ambient Temperature Under Bias ÀÀÀÀÀÀ0§ C to 70§ C
Storage Temperature ÀÀÀÀÀÀÀÀÀÀ b 65§ C to a 150§ C
Voltage on Any Pin
with Respect to GroundÀÀÀÀÀÀÀÀÀÀ b 0.5V to a 7V
Power Dissipation ÀÀÀÀÀÀÀÀÀÀÀÀÀÀÀÀÀÀÀÀÀÀÀÀÀÀÀ1W
D.C. CHARACTERISTICS
Symbol
*WARNING: Stressing the device beyond the ‘‘Absolute
Maximum Ratings’’ may cause permanent damage.
These are stress ratings only. Operation beyond the
‘‘Operating Conditions’’ is not recommended and extended exposure beyond the ‘‘Operating Conditions’’
may affect device reliability.
TA e 0§ C to 70§ C, VCC e 5V g 10%
Parameter
Min
Max
Units
Test Conditions
VIL
Input Low Voltage
b 0.5
VIH
Input High Voltage
2.0*
0.8
V
VCC a 0.5V
V
VOL
Output Low Voltage
0.45
V
IOL e 2.2 mA
VOH
Output High Voltage
2.4
V
IOH e b 400 mA
VOH(INT)
Interrupt Output High
Voltage
3.5
V
IOH e b 100 mA
2.4
ILI
Input Load Current
b 10
ILOL
Output Leakage Current
b 10
ICC
VCC Supply Current
ILIR
IR Input Load Current
V
IOH e b 400 mA
a 10
mA
0V s VIN s VCC
a 10
mA
0.45V s VOUT s VCC
85
mA
b 300
mA
VIN e 0
10
mA
VIN e VCC
*NOTE:
For Extended Temperature EXPRESS VIH e 2.3V.
CAPACITANCE
Symbol
TA e 25§ C; VCC e GND e 0V
Parameter
Min
Typ
Max
Unit
Test Conditions
CIN
Input Capacitance
10
pF
fc e 1 MHz
CI/O
I/O Capacitance
20
pF
Unmeasured Pins Returned to VSS
20
8259A
A.C. CHARACTERISTICS
TA e 0§ C to 70§ C, VCC e 5V g 10%
TIMING REQUIREMENTS
Symbol
8259A
Parameter
Min
v
u
TAHRL
AO/CS Setup to RD/INTA
TRHAX
AO/CS Hold after RD/INTA
TRLRH
RD Pulse Width
TAHWL
AO/CS Setup to WR
TWHAX
v
AO/CS Hold after WRu
TWLWH
WR Pulse Width
TDVWH
Data Setup to WR
TWHDX
Data Hold after WR
TJLJH
TCVIAL
Max
8259A-2
Min
Units
0
0
ns
0
0
ns
235
160
ns
0
0
ns
0
0
ns
290
190
ns
240
160
ns
0
0
ns
Interrupt Request Width (Low)
100
100
ns
Cascade Setup to Second or Third
INTA (Slave Only)
55
40
ns
End of RD to Next RD
End of INTA to Next INTA within
an INTA Sequence Only
160
100
ns
TWHWL
End of WR to Next WR
190
100
ns
*TCHCL
End of Command to Next Command
(Not Same Command Type)
500
150
ns
End of INTA Sequence to Next
INTA Sequence.
500
300
u
u
v
TRHRL
Test Conditions
Max
See Note 1
*Worst case timing for TCHCL in an actual microprocessor system is typically much greater than 500 ns (i.e. 8085A e
1.6 ms, 8085A-2 e 1 ms, 8086 e 1 ms, 8086-2 e 625 ns)
NOTE:
This is the low time required to clear the input latch in the edge triggered mode.
TIMING RESPONSES
Symbol
8259A
Parameter
Min
v
TRLDV
Data Valid from RD/INTA
TRHDZ
Data Float after RD/INTA
TJHIH
Interrupt Output Delay
TIALCV
Cascade Valid from First INTA
(Master Only)
TRLEL
Enable Active from RD
Max
8259A-2
Min
200
Units
120
ns
85
ns
350
300
ns
565
360
ns
125
100
ns
TRHEH
v or INTAv
Enable Inactive from RDu or INTAu
150
150
ns
TAHDV
Data Valid from Stable Address
200
200
ns
TCVDV
Cascade Valid to Valid Data
300
200
ns
u
10
v
100
10
Test Conditions
Max
C of Data Bus e
100 pF
C of Data Bus
Max Test C e 100 pF
Min Test C e 15 pF
CINT e 100 pF
CCASCADE e 100 pF
21
8259A
A.C. TESTING INPUT/OUTPUT WAVEFORM
A.C. TESTING LOAD CIRCUIT
231468 – 25
A.C. Testing: Inputs are driven at 2.4V for a logic ‘‘1’’ and 0.45V
for a logic ‘‘0’’. Timing measurements are made at 2.0V for a logic
‘‘1’’ and 0.8V for a logic ‘‘0’’.
231468 – 26
CL e 100 pF
CL Includes Jig Capacitance
WAVEFORMS
WRITE
231468 – 27
22
8259A
WAVEFORMS (Continued)
READ/INTA
231468 – 28
OTHER TIMING
231468 – 29
23
8259A
WAVEFORMS
(Continued)
INTA SEQUENCE
231468 – 30
NOTES:
Interrupt output must remain HIGH at least until leading edge of first INTA.
1. Cycle 1 in 8086, 8088 systems, the Data Bus is not active.
Data Sheet Revision Review
The following changes have been made since revision 2 of the 8259A data sheet.
1. The first paragraph of the Poll Command section was rewritten to clarify the status of the INT pin.
2. A paragraph was added to the Interrupt Sequence section to indicate the status of the INT pin during
multiple interrupts.
3. A reference to PLCC packaging was added.
4. All references to the 8259A-8 have been deleted.
INTEL CORPORATION, 2200 Mission College Blvd., Santa Clara, CA 95052; Tel. (408) 765-8080
INTEL CORPORATION (U.K.) Ltd., Swindon, United Kingdom; Tel. (0793) 696 000
INTEL JAPAN k.k., Ibaraki-ken; Tel. 029747-8511
Printed in U.S.A./xxxx/1196/B10M/xx xx