Intersil CS80C286-12 High performance microprocessor with memory management and protection Datasheet

80C286
®
High Performance Microprocessor
with Memory Management and Protection
January 28, 2008
Features
Description
• Compatible with NMOS 80286
• Wide Range of Clock Rates
- DC to 25MHz (80C286-25)
- DC to 20MHz (80C286-20)
- DC to 16MHz (80C286-16)
- DC to 12.5MHz (80C286-12)
- DC to 10MHz (80C286-10)
• Static CMOS Design for Low Power Operation
- ICCSB = 5mA Maximum
- ICCOP = 185mA Maximum (80C286-10)
220mA Maximum (80C286-12)
260mA Maximum (80C286-16)
310mA Maximum (80C286-20)
410mA Maximum (80C286-25)
• High Performance Processor (Up to 19 Times the 8086
Throughput)
• Large Address Space
• 16 Megabytes Physical/1 Gigabyte Virtual per Task
• Integrated Memory Management, Four-Level Memory
Protection and Support for Virtual Memory and Operating Systems
• Two 80C86 Upward Compatible Operating Modes
- 80C286 Real Address Mode
- PVAM
• Compatible with 80287 Numeric Data Co-Processor
• High Bandwidth Bus Interface (25 Megabyte/Sec)
• Available In
- 68 Pin PGA (Commercial, Industrial, and Military)
- 68 Pin PLCC (Commercial and Industrial)
The Intersil 80C286 is a static CMOS version of the NMOS
80286 microprocessor. The 80C286 is an advanced, highperformance microprocessor with specially optimized capabilities for multiple user and multi-tasking systems. The
80C286 has built-in memory protection that supports operating system and task isolation as well as program and data
privacy within tasks. A 25MHz 80C286 provides up to nineteen times the throughput of a standard 5MHz 8086. The
80C286 includes memory management capabilities that map
230 (one gigabyte) of virtual address space per task into 224
bytes (16 megabytes) of physical memory.
The 80C286 is upwardly compatible with 80C86 and 80C88
software (the 80C286 instruction set is a superset of the
80C86/80C88 instruction set). Using the 80C286 real
address mode, the 80C286 is object code compatible with
existing 80C86 and 80C88 software. In protected virtual
address mode, the 80C286 is source code compatible with
80C86 and 80C88 software but may require upgrading to
use virtual address as supported by the 80C286’s integrated
memory management and protection mechanism. Both
modes operate at full 80C286 performance and execute a
superset of the 80C86 and 80C88 instructions.
The 80C286 provides special operations to support the efficient implementation and execution of operating systems.
For example, one instruction can end execution of one task,
save its state, switch to a new task, load its state, and start
execution of the new task. The 80C286 also supports virtual
memory systems by providing a segment-not-present exception and restartable instructions.
Ordering Information
PACKAGE
PGA
PLCC
TEMP. RANGE
10MHz
0oC to +70oC
-
12.5MHz
CG80C286-12
16MHz
CG80C286-16
-40oC to +85oC
IG80C286-10
IG80C286-12
-
-55oC to +125oC
59629067801MXC
59629067802MXC
-
0oC to +70oC
-40oC to +85oC
IS80C286-10
20MHz
CG80C286-20
PKG. NO.
-
G68.B
-
-
G68.B
-
-
G68.B
CS80C286-12
CS80C286-16
CS80C286-20
IS80C286-12
IS80C286-16
IS80C286-20
CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures.
1-888-INTERSIL or 1-888-468-3774 | Intersil (and design) is a registered trademark of Intersil Americas Inc.
Copyright © Intersil Americas Inc. 2003-2008. All Rights Reserved
1
All other trademarks mentioned are the property of their respective owners.
25MHz
CS80C286-25
-
N68.95
N68.95
FN2947.3
80C286
Pinouts
D11
D12
D13
D14
D3
D4
D5
D6
D7
ERROR
39
41
43
45
47
49
51
34
36
38
40
42
44
46
48
50
53
52
ERROR
NC
A1
32
33
55
54
NC
BUSY
VCC
CLK
30
31
57
56
INTR
NC
A3
RESET
28
29
59
58
NMI
NC
A5
A4
26
27
61
60
PEREQ
VSS
A7
A6
24
25
63
62
READY
VCC
A9
A8
22
23
65
64
HLDA
HOLD
A11
A10
20
21
10
8
6
11
9
7
5
3
1
A21
A22
PEACK
S1
NC
A23
S0
PIN 1 INDICATOR
BHE
NC
12
13
VSS
LOCK
14
15
A19
NC
16
17
A20
68
19
A17
COD/INTA
A15
M/IO
A18
18
66
2
A12
A12
A14
A13
67
4
A16
A2
D15
D10
D2
37
D0
D9
D1
35
A0
D8
D0
VSS
68 LEAD PGA
Component Pad View - As viewed from underside of the component when mounted on the board.
VSS
D0
54
55
33
32
A1
A2
NC
INTR
56
57
31
30
CLK
VCC
NC
NMI
58
59
29
28
RESET
A3
VSS
PEREQ
60
61
27
26
A4
A5
VCC
READY
62
63
25
24
A6
A7
HOLD
HLDA
64
65
23
22
A8
A9
COD/INTA
M/IO
66
67
21
20
A10
A11
LOCK
NC
68
2
4
6
8
10
12
14
16
19
18
A12
A13
1
3
5
7
9
11
13
15
17
PIN 1 INDICATOR
A12
NC
A14
D8
D1
BUSY
A15
A0
A16
D9
D2
D0
A17
34
A18
D10
D3
36
A19
38
A20
D11
D4
40
A21
35
42
VSS
D12
D5
37
44
A22
39
46
A23
D13
D6
41
48
PEACK
43
50
S0
D14
D7
45
53
S1
47
52
NC
D15
49
ERROR
NC
51
NC
BHE
ERROR
68 LEAD PGA
P.C. Board View - As viewed from the component side of the P.C. board.
2
80C286
Pinouts
(Continued)
LOCK
M/IO
COD/INTA
HLDA
HOLD
READY
VCC
PEREQ
VSS
NMI
NC
INTR
NC
NC
BUSY
ERROR
NC
68 LEAD PLCC
P.C. Board View - As viewed from the component side of the P.C. board.
PIN 1 INDICATOR
MOLD MARK DOES NOT
INDICATE PIN 1
68 67 66 65 64 63 62 61 60 59 58 57 56 55 54 53 52
BHE
NC
NC
S1
S0
PEACK
A23
A22
VSS
A21
A20
A19
A18
A17
A16
A15
A14
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
51
50
49
48
47
46
45
44
43
42
41
40
39
38
37
36
35
D15
D7
D14
D6
D13
D5
D12
D4
D11
D3
D10
D2
D9
D1
D8
D0
VSS
A13
A12
A11
A10
A9
A8
A7
A6
A5
A4
A3
RESET
VCC
CLK
A2
A1
A0
18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34
Functional Diagram
ADDRESS UNIT (AU)
ADDRESS
LATCHES AND DRIVERS
SEGMENT
BASES
OFFSET
ADDER
PHYSICAL
ADDRESS
ADDER
PREFETCHER
PROCESSOR
EXTENSION
INTERFACE
BUS CONTROL
SEGMENT
LIMIT
SEGMENT
CHECKER
SIZES
DATA TRANSCEIVERS
6-BYTE
PREFETCH
QUEUE
ALU
A23 - A0,
BHE, M/IO
PEACK
PEREQ
READY,
HOLD,
S1, S0,
COD/INTA,
LOCK, HLDA
D15 - D0
BUS UNIT (BU)
RESET
REGISTERS CONTROL
3 DECODED
INSTRUCTION
INSTRUCTION
DECODER
QUEUE
INSTRUCTION
UNIT (IU)
CLK
VSS
VCC
EXECUTION UNIT (EU)
NMI
BUSY
INTR ERROR
3
80C286
Pin Descriptions
The following pin function descriptions are for the 80C286 microprocessor.
SYMBOL
PIN
NUMBER
TYPE
DESCRIPTION
CLK
31
I
SYSTEM CLOCK: provides the fundamental timing for the 80C286 system. It is divided by two inside
the 80C286 to generate the processor clock. The internal divide-by-two circuitry can be synchronized to an external clock generator by a LOW to HIGH transition on the RESET input.
D15 - D0
36 - 51
I/O
DATA BUS: inputs data during memory, I/O, and interrupt acknowledge read cycles; outputs data
during memory and I/O write cycles. The data bus is active HIGH and is held at high impedance to
the last valid logic level during bus hold acknowledge.
A23 - A0
7-8
10 - 28
32 - 43
O
ADDRESS BUS: outputs physical memory and I/O port addresses. A23 - A16 are LOW during I/O
transfers. A0 is LOW when data is to be transferred on pins D7 - D0 (see table below). The address
bus is active High and floats to three-state off during bus hold acknowledge.
BHE
1
O
BUS HIGH ENABLE: indicates transfer of data on the upper byte of the data bus, D15 - D8. Eight-bit
oriented devices assigned to the upper byte of the data bus would normally use BHE to condition chip
select functions. BHE is active LOW and floats to three-state OFF during bus hold acknowledge.
BHE AND A0 ENCODINGS
S1, S0
4, 5
O
BHE VALUE
A0 VALUE
0
0
Word transfer
0
1
Byte transfer on upper half of data bus (D15 - D8)
1
0
Byte transfer on lower half of data bus (D7 - D0)
1
1
Reserved
FUNCTION
BUS CYCLE STATUS: indicates initiation of a bus cycle and along with M/IO and COD/lNTA, defines the type of bus cycle. The bus is in a TS state whenever one or both are LOW. S1 and S0 are
active LOW and are held at a high impedance logic one during bus hold acknowledge.
80C286 BUS CYCLE STATUS DEFINITION
COD/INTA
M/IO
S1
S0
0(LOW)
0
0
0
Interrupt acknowledge
0
0
0
1
Reserved
0
0
1
0
Reserved
0
0
1
1
None; not a status cycle
0
1
0
0
If A1 = 1 then halt; else shutdown
0
1
0
1
Memory data read
0
1
1
0
Memory data write
0
1
1
1
None; not a status cycle
1(HIGH)
0
0
0
Reserved
1
0
0
1
I/O read
1
0
1
0
I/O write
1
0
1
1
None; not a status cycle
1
1
0
0
Reserved
1
1
0
1
Memory instruction read
1
1
1
0
Reserved
1
1
1
1
None; not a status cycle
4
BUS CYCLE INITIATED
80C286
Pin Descriptions
The following pin function descriptions are for the 80C286 microprocessor. (Continued)
SYMBOL
PIN
NUMBER
TYPE
DESCRIPTION
M/IO
67
O
MEMORY I/O SELECT: distinguishes memory access from I/O access. If HIGH during TS, a memory cycle or a halt/shutdown cycle is in progress. If LOW, an I/O cycle or an interrupt acknowledge
cycle is in progress. M/IO is held at high impedance to the last valid logic state during bus hold acknowledge.
COD/lNTA
66
O
CODE/INTERRUPT ACKNOWLEDGE: distinguishes instruction fetch cycles from memory data
read cycles. Also distinguishes interrupt acknowledge cycles from I/O cycles. COD/lNTA is held at
high impedance to the last valid logic state during bus hold acknowledge. Its timing is the same as
M/IO.
LOCK
68
O
BUS LOCK: indicates that other system bus masters are not to gain control of the system bus for
the current and following bus cycles. The LOCK signal may be activated explicitly by the “LOCK”
instruction prefix or automatically by 80C286 hardware during memory XCHG instructions, interrupt
acknowledge, or descriptor table access. LOCK is active LOW and is held at a high impedance logic
one during bus hold acknowledge.
READY
63
l
BUS READY: terminates a bus cycle. Bus cycles are extended without limit until terminated by
READY LOW. READY is an active LOW synchronous input requiring setup and hold times relative
to the system clock be met for correct operation. READY is ignored during bus hold acknowledge.
(See Note 1)
HOLD
HLDA
64
65
I
O
BUS HOLD REQUEST AND HOLD ACKNOWLEDGE: control ownership of the 80C286 local bus.
The HOLD input allows another local bus master to request control of the local bus. When control is
granted, the 80C286 will float its bus drivers and then activate HLDA, thus entering the bus hold acknowledge condition. The local bus will remain granted to the requesting master until HOLD becomes inactive which results in the 80C286 deactivating HLDA and regaining control of the local
bus. This terminates the bus hold acknowledge condition. HOLD may be asynchronous to the system clock. These signals are active HIGH. Note that HLDA never floats.
INTR
57
I
INTERRUPT REQUEST: requires the 80C286 to suspend its current program execution and service
a pending external request. Interrupt requests are masked whenever the interrupt enable bit in the
flag word is cleared. When the 80C286 responds to an interrupt request, it performs two interrupt
acknowledge bus cycles to read an 8-bit interrupt vector that identifies the source of the interrupt.
To ensure program interruption, INTR must remain active until an interrupt acknowledge bus cycle
is initiated. INTR is sampled at the beginning of each processor cycle and must be active HIGH at
least two processor cycles before the current instruction ends in order to interrupt before the next
instruction. INTR is level sensitive, active HIGH, and may be asynchronous to the system clock.
NMI
59
l
NON-MASKABLE INTERRUPT REQUEST: interrupts the 80C286 with an internally supplied vector
value of two. No interrupt acknowledge cycles are performed. The interrupt enable bit in the 80C286
flag word does not affect this input. The NMI input is active HIGH, may be asynchronous to the system clock, and is edge triggered after internal synchronization. For proper recognition, the input must
have been previously LOW for at least four system clock cycles and remain HIGH for at least four
system clock cycles.
PEREQ
PEACK
61
6
l
O
PROCESSOR EXTENSION OPERAND REQUEST AND ACKNOWLEDGE: extend the memory
management and protection capabilities of the 80C286 to processor extensions. The PEREQ input
requests the 80C286 to perform a data operand transfer for a processor extension. The PEACK output signals the processor extension when the requested operand is being transferred. PEREQ is active HIGH. PEACK is active LOW and is held at a high impedance logic one during bus hold
acknowledge. PEREQ may be asynchronous to the system clock.
BUSY
ERROR
54
53
l
I
PROCESSOR EXTENSION BUSY AND ERROR: indicates the operating condition of a processor
extension to the 80C286. An active BUSY input stops 80C286 program execution on WAIT and
some ESC instructions until BUSY becomes inactive (HIGH). The 80C286 may be interrupted while
waiting for BUSY to become inactive. An active ERROR input causes the 80C286 to perform a processor extension interrupt when executing WAIT or some ESC instructions. These inputs are active
LOW and may be asynchronous to the system clock.
5
80C286
Pin Descriptions
The following pin function descriptions are for the 80C286 microprocessor. (Continued)
SYMBOL
PIN
NUMBER
TYPE
DESCRIPTION
RESET
29
l
SYSTEM RESET: clears the internal logic of the 80C286 and is active HIGH. The 80C286 may be
reinitialize at any time with a LOW to HIGH transition on RESET which remains active for more than
16 system clock cycles. During RESET active, the output pins of the 80C286 enter the state shown
below.
80C286 PIN STATE DURING RESET
PIN VALUE
PIN NAMES
1 (HIGH)
S0, S1, PEACK, A23 - A0, BHE, LOCK
0 (LOW)
M/IO, COD/lNTA, HLDA (Note 2)
HIGH IMPEDANCE
D15 - D0
Operation of the 80C286 begins after a HlGH to LOW transition on RESET. The HIGH to LOW
transition of RESET must be synchronous to the system clock. Approximately 50 system clock
cycles are required by the 80C286 for internal initializations before the first bus cycle to fetch code
from the power-on execution address is performed. A LOW to HIGH transition of RESET
synchronous to the system clock will end a processor cycle at the second HIGH to LOW transition
of the system clock. The LOW to HIGH transition of RESET may be asynchronous to the system
clock; however, in this case it cannot be predetermined which phase of the processor clock will occur
during the next system clock period. Synchronous LOW to HIGH transitions of RESET are required
only for systems where the processor clock must be phase synchronous to another clock.
VSS
9, 35, 60
l
SYSTEM GROUND: are the ground pins (all must be connected to system ground).
VCC
30, 62
l
SYSTEM POWER: +5V power supply pins. A 0.1μF capacitor between pins 60 and 62 is recommended.
NOTES:
1. READY is an open-collector signal and should be pulled inactive with an appropriate resistor (620Ω at 10MHz and 12.5MHz, 470Ω at
16MHz, 390Ω at 20MHz, 270Ω at 25MHz).
2. HLDA is only Low if HOLD is inactive (Low).
3. All unused inputs should be pulled to their inactive state with pull up/down resistors.
Functional Description
Introduction
The Intersil 80C286 microprocessor is a static CMOS version of the NMOS 80286 microprocessor. The 80C286 is an
advanced, high-performance microprocessor with specially
optimized capabilities for multiple user and multi-tasking systems. Depending on the application, the 80C286's performance is up to nineteen times faster than the standard
5MHz 8086's, while providing complete upward software
compatibility with Intersil 80C86 and 80C88 CPU family.
The Functional Description describes the following: Static operation, the base 80C286 architecture common to both modes,
80C286 real address mode, and finally, protected mode.
Static Operation
The 80C286 is comprised of completely static circuitry.
Internal registers, counters, and latches are static and
require no refresh as with dynamic circuit design. This eliminates the minimum operating frequency restriction typically
placed on microprocessors. The CMOS 80C286 can operate from DC to the specified upper frequency limit. The
clock to the processor may be stopped at any point (either
phase one or phase two of the processor clock cycle) and
held there indefinitely. There is, however, a significant
decrease in power requirement if the clock is stopped in
phase two of the processor clock cycle. Details on the clock
relationships will be discussed in the Bus Operation section. The ability to stop the clock to the processor is especially useful for system debug or power critical applications.
The 80C286 operates in two modes: 80C286 real address
mode and protected virtual address mode. Both modes execute a superset of the 80C86 and 80C88 instruction set.
In 80C286 real address mode programs use real addresses
with up to one megabyte of address space. Programs use virtual addresses in protected virtual address mode, also called
protected mode. In protected mode, the 80C286 CPU automatically maps 1 gigabyte of virtual addresses per task into a 16
megabyte real address space. This mode also provides memory protection to isolate the operating system and ensure privacy of each tasks' programs and data. Both modes provide
the same base instruction set, registers and addressing modes.
6
80C286
The 80C286 can be single-stepped using only the CPU
clock. This state can be maintained as long as necessary.
Single step clock information allows simple interface circuitry
to provide critical information for system debug.
16-BIT
REGISTER
NAME
7
Static design also allows very low frequency operation
(down to DC). In a power critical situation, this can provide
low power operation since 80C286 power dissipation is
directly related to operating frequency. As the system frequency is reduced, so is the operating power until, ultimately, with the clock stopped in phase two of the processor
clock cycle, the 80C286 power requirement is the standby
current (5mA maximum).
BYTE
ADDRESSABLE
(8-BIT
REGISTER
NAMES
SHOWN)
SPECIAL
REGISTER
FUNCTIONS
07
0
AX
AH
AL
DX
DH
DL
CX
CH
CL
BX
BH
BL
MULTIPLY/DIVIDE
I/O INSTRUCTIONS
LOOP/SHIFT/REPEAT
COUNT
BASE REGISTERS
BP
SI
80C286 Base Architecture
INDEX REGISTERS
DI
The 80C86, 80C88, and 80C286 CPU family all contain the
same basic set of registers, instructions, and addressing
modes. The 80C286 processor is upwardly compatible with
the 80C86 and 80C88 CPU's.
STACK POINTER
SP
15
Register Set
GENERAL
REGISTERS
15
0
0
The 80C286 base architecture has fifteen registers as
shown in Figure 1. These registers are grouped into the following four categories.
CS
CODE SEGMENT
SELECTOR
DS
DATA SEGMENT
SELECTOR
GENERAL REGISTERS: Eight 16-bit general purpose registers used to contain arithmetic and logical operands. Four of
these (AX, BX, CX and DX) can be used either in their
entirety as 16-bit words or split into pairs of separate 8-bit
registers.
SS
STACK SEGMENT
SELECTOR
ES
EXTRA SEGMENT
SELECTOR
SEGMENT
REGISTERS
SEGMENT REGISTERS: Four 16-bit special purpose registers select, at any given time, the segments of memory that
are immediately addressable for code, stack and data. (For
usage, refer to Memory Organization.)
15
0
F
IP
BASE AND INDEX REGISTERS: Four of the general purpose registers may also be used to determine offset
addresses of operands in memory. These registers may
contain base addresses or indexes to particular locations
within a segment. The addressing mode determines the specific registers used for operand address calculations.
MSW
FLAGS
INSTRUCTION
POINTER
MACHINE
STATUS WORD
STATUS AND CONTROL
REGISTERS
FIGURE 1. REGISTER SET
STATUS AND CONTROL REGISTERS: Three 16-bit special purpose registers record or control certain aspects of the
80C286 processor state. These include the Flags register
and Machine Status Word register shown in Figure 2, and
the Instruction Pointer, which contains the offset address of
the next sequential instruction to be executed.
Flags Word Description
The Flags word (Flags) records specific characteristics of
the result of logical and arithmetic instructions (bits 0, 2, 4, 6,
7 and 11) and controls the operation of the 80C286 within a
given operating mode (bits 8 and 9). Flags is a 16-bit register. The function of the flag bits is given in Table 1.
7
80C286
STATUS FLAGS:
CARRY
PARITY
AUXILIARY CARRY
ZERO
SIGN
OVERFLOW
15
FLAGS:
14
13
NT
12
IOPL
11
OF
10
9
8
DF
IF
TF
7
SF
6
5
ZF
4
3
AF
2
1
PF
0
CF
CONTROL FLAGS:
TRAP FLAG
INTERRUPT ENABLE
DIRECTION FLAG
SPECIAL FIELDS:
I/O PRIVILEGE LEVEL
NESTED TASK FLAG
15
MSW:
RESERVED
3
2
1
0
TS
EM
MP
PE
TASK SWITCH
PROCESSOR EXTENSION EMULATED
MONITOR PROCESSOR EXTENSION
PROTECTION ENABLE
FIGURE 2. STATUS AND CONTROL REGISTER BIT FUNCTIONS
TABLE 1. FLAGS WORD BIT FUNCTIONS
BIT POSITION
NAME
FUNCTION
0
CF
Carry Flag - Set on high-order bit carry or borrow; cleared otherwise.
2
PF
Parity Flag - Set if low-order 8 bits of result contain an even number of 1 bits; cleared otherwise.
4
AF
Set on carry from or borrow to the low order four bits of AL; cleared otherwise.
6
ZF
Zero Flag - Set if result is zero; cleared otherwise.
7
SF
Sign Flag - Set equal to high-order bit of result (0 if positive, 1 if negative).
11
OF
Overflow Flag - Set if result is a too-large positive number or a too-small negative number (excluding
sign-bit) to fit in destination operand; cleared otherwise.
8
TF
Single Step Flag - Once set, a single step interrupt occurs after the next instruction executes. TF is
cleared by the single step interrupt.
9
IF
Interrupt-Enable Flag - When set, maskable interrupts will cause the CPU to transfer control to an interrupt vector specified location.
10
DF
Direction Flag - Causes string instructions to auto decrement the appropriate index registers when set.
Clearing DF causes auto increment.
8
80C286
Instruction Set
TABLE 2B. ARITHMETIC INSTRUCTIONS
The instruction set is divided into seven categories: data
transfer, arithmetic, string manipulation, shift/rotate/logical,
high level, processor control and control transfer instructions. These categories are summarized in Table 2.
ADDITION
An 80C286 instruction can reference zero, one, or two operands; where an operand may reside in a register, in the
instruction itself, or in memory. Zero-operand instructions
(e.g. NOP and HLT) are usually one byte long. One-operand
instructions (e.g. INC and DEC) are usually two bytes long
but some are encoded in only one byte. One-operand
instructions may reference a register or memory location.
Two-operand instructions permit the following six types of
instruction operations:
• Register to Register
• Memory to Register
• Immediate to Register
ADD
Add byte or word
ADC
Add byte or word with carry
INC
Increment byte or word by 1
AAA
ASClI adjust for addition
DAA
Decimal adjust for addition
SUBTRACTION
• Memory to Memory
• Register to Memory
• Immediate to Memory
SUB
Subtract byte or word
SBB
Subtract byte or word with borrow
DEC
Decrement byte or word by 1
NEG
Negate byte or word
CMP
Compare byte or word
AAS
ASClI adjust for subtraction
DAS
Decimal adjust for subtraction
Two-operand instructions (e.g. MOV and ADD) are usually
three to six bytes long. Memory to memory operations are
provided by a special class of string instructions requiring
one to three bytes. For detailed instruction formats and
encodings refer to the instruction set summary at the end of
this document.
MULTIPLICATION
TABLE 2A. DATA TRANSFER INSTRUCTIONS
GENERAL PURPOSE
MUL
Multiply byte or word unsigned
lMUL
Integer multiply byte or word
AAM
ASClI adjust for multiply
DIVISION
MOV
Move byte or word
DlV
Divide byte or word unsigned
PUSH
Push word onto stack
lDlV
Integer divide byte or word
Pop word off stack
AAD
ASClI adjust for division
PUSHA
Push all registers on stack
CBW
Convert byte to word
POPA
Pop all registers from stack
CWD
Convert word to doubleword
XCHG
Exchange byte or word
XLAT
Translate byte
POP
TABLE 2C. STRING INSTRUCTIONS
INPUT/OUTPUT
IN
OUT
Input byte or word
Output byte or word
ADDRESS OBJECT
LEA
Load effective address
LDS
Load pointer using DS
LES
Load pointer using ES
FLAG TRANSFER
LAHF
Load AH register from flags
SAHF
Store AH register in flags
PUSHF
POPF
MOVS
Move byte or word string
INS
Input bytes or word string
OUTS
Output bytes or word string
CMPS
Compare byte or word string
SCAS
Scan byte or word string
LODS
Load byte or word string
STOS
Store byte or word string
REP
REPE/REPZ
REPNE/REPNZ
Push flags onto stack
Pop flags off stack
9
Repeat
Repeat while equal/zero
Repeat while not equal/not zero
80C286
TABLE 2F. PROCESSOR CONTROL INSTRUCTIONS
TABLE 2D. SHIFT/ROTATE LOGICAL INSTRUCTIONS
FLAG OPERATIONS
LOGICALS
NOT
“Not” byte or word
STC
Set carry flag
AND
“And” byte or word
CLC
Clear carry flag
OR
“Inclusive or” byte or word
CMC
Complement carry flag
XOR
“Exclusive or” byte or word
STD
Set direction flag
TEST
“Test” byte or word
CLD
Clear direction flag
STl
Set interrupt enable flag
CLl
Clear interrupt enable flag
SHIFTS
SHL/SAL
Shift logical/arithmetic left byte or word
SHR
Shift logical right byte or word
SAR
Shift arithmetic right byte or word
EXTERNAL SYNCHRONIZATION
HLT
ROTATES
ROL
Rotate left byte or word
ROR
Rotate right byte or word
RCL
Rotate through carry left byte or word
RCR
Rotate through carry right byte or word
Halt until interrupt or reset
WAIT
Wait for TEST pin active
ESC
Escape to extension processor
LOCK
Lock bus during next instruction
NO OPERATION
NOP
No operation
EXECUTION ENVIRONMENT CONTROL
TABLE 2E. HIGH LEVEL INSTRUCTIONS
ENTER
Format stack for procedure entry
LEAVE
Restore stack for procedure exit
BOUND
Detects values outside prescribed range
LMSW
Load machine status word
SMSW
Store machine status word
TABLE 2G. PROGRAM TRANSFER INSTRUCTIONS
CONDITIONAL TRANSFERS
UNCONDITIONAL TRANSFERS
JA/JNBE
Jump if above/not below nor equal
CALL
Call procedure
JAE/JNB
Jump if above or equal/not below
RET
Return from procedure
JB/JNAE
Jump if below/not above nor equal
JMP
Jump
JBE/JNA
Jump if below or equal/not above
JC
JE/JZ
Jump if carry
ITERATION CONTROLS
Jump if equal/zero
LOOP
JG/JNLE
Jump if greater/not less nor equal
JGE/JNL
Jump if greater or equal/not less
LOOPE/LOOPZ
JL/JNGE
Jump if less/not greater nor equal
LOOPNE/LOOPNZ
JLE/JNG
Jump if less or equal/not greater
JCXZ
JNC
JNE/JNZ
JNO
JNP/JPO
Loop
Loop if equal/zero
Loop if not equal/not zero
Jump if register CX = 0
Jump if not carry
Jump if not equal/not zero
INTERRUPTS
Jump if not overflow
INT
Interrupt
Jump if not parity/parity odd
JNS
Jump if not sign
INTO
Interrupt if overflow
JO
Jump if overflow
lRET
Interrupt return
JP/JPE
JS
Jump if parity/parity even
Jump if sign
10
80C286
Memory Organization
Addressing Modes
Memory is organized as sets of variable-length segments. Each
segment is a linear contiguous sequence of up to 64K (216) 8bit bytes. Memory is addressed using a two-component
address (a pointer) that consists of a 16-bit segment selector
and a 16-bit offset. The segment selector indicates the desired
segment in memory. The offset component indicates the
desired byte address within the segment. (See Figure 3).
The 80C286 provides a total of eight addressing modes for
instructions to specify operands. Two addressing modes are
provided for instructions that operate on register or immediate operands:
REGISTER OPERAND MODE: The operand is located in
one of the 8 or 16-bit general registers.
IMMEDIATE OPERAND MODE: The operand is included in
the instruction.
All instructions that address operands in memory must specify the segment and the offset. For speed and compact
instruction encoding, segment selectors are usually stored in
the high speed segment registers. An instruction need specify only the desired segment register and offset in order to
address a memory operand.
Six modes are provided to specify the location of an operand in
a memory segment. A memory operand address consists of
two 16-bit components: segment selector and offset. The segment selector is supplied by a segment register either implicitly
chosen by the addressing mode or explicitly chosen by a segment override prefix. The offset is calculated by summing any
combination of the following three address elements:
POINTER
SEGMENT
31
OFFSET
16 15
the displacement (an 8 or 16-bit immediate value contained
in the instruction)
0
OPERAND
SELECTED
SELECTED
SEGMENT
the base (contents of either the BX or BP base registers)
the index (contents of either the SI or Dl index registers)
MEMORY
FIGURE 3. TWO COMPONENT ADDRESS
MODULE A
CODE
DATA
Most instructions need not explicitly specify which segment
register is used. The correct segment register is automatically chosen according to the rules of Table 3. These rules
follow the way programs are written (see Figure 4) as independent modules that require areas for code and data, a
stack, and access to external data areas.
MODULE B
CODE
CPU
DATA
CODE
DATA
Special segment override instruction prefixes allow the
implicit segment register selection rules to be overridden for
special cases. The stack, data and extra segments may
coincide for simple programs. To access operands not residing in one of the four immediately available segments, a full
32-bit pointer or a new segment selector must be loaded.
STACK
PROCESS
STACK
EXTRA
SEGMENT
REGISTERS
TABLE 3. SEGMENT REGISTER SELECTION RULES
MEMORY
REFERENCE
NEEDED
SEGMENT
REGISTER
USED
IMPLICIT SEGMENT
SELECTION RULE
Instructions
Code (CS)
Automatic with instruction prefetch
Stack
Stack (SS) All stack pushes and pops. Any
memory reference which uses BP
as a base register.
Local Data
Data (DS)
All data references except when
relative to stack or string destination
External
(Global) Data
Extra (ES)
Alternate data segment and
destination of string operation
PROCESS
DATA
BLOCK 1
PROCESS
DATA
BLOCK 2
MEMORY
FIGURE 4. SEGMENTED MEMORY HELPS STRUCTURE
SOFTWARE
Any carry out from the 16-bit addition is ignored. Eight-bit
displacements are sign extended to 16-bit values.
11
80C286
Combinations of these three address elements define the six
memory addressing modes, described below.
7
DIRECT MODE: The operand's offset is contained in the
instruction as an 8 or 16-bit displacement element.
SIGN BIT
MAGNITUDE
7
REGISTER INDIRECT MODE: The operand's offset is in
one of the registers SI, Dl, BX or BP.
MSB
MAGNITUDE
15 14 +1
BASED INDEXED MODE WITH DISPLACEMENT: The
operand's offset is the sum of a base register's contents, an
index register's contents, and an 8 or 16-bit displacement.
A signed binary numeric value contained in an 8bit byte or a 16-bit word. All operations assume a
2's complement representation. Signed 32 and
64-bit integers are supported using the 80287
Numeric Data Processor.
SIGNED 31
DOUBLE
WORD
(NOTE)
SIGN BIT
+3
15
MSB
+7
+6 +5
48 47
+4 +3
32 31
+2 +1
16 15
0
0
MSB
+1
0
0
MAGNITUDE
BINARY 7
CODED
DECIMAL
(BCD)
+N
0
7
BCD
DIGIT N
07
+N
BCD
DIGIT 1
7
0
0
0
+1
BCD
DIGIT 0
07
0
0
•••
ASCII
ASCII
CHARACTER1
ASCII
CHARACTERN
7
+N
7
0
PACKED
BCD
+1
ASCII
CHARACTER0
07
0
0
•••
MOST
SIGNIFICANT DIGIT
7/15
+N
0
7/15
LEAST
SIGNIFICANT DIGIT
+1
0 7/15 0
0
•••
STRING
A signed 32, 64 or 80-bit real number representation. (Floating point operands are supported using
the 80287 Numeric Processor extension).
+1
•••
7
A byte representation of alphanumeric and control
characters using the ASClI standard of character
representation.
A byte (packed) representation of two decimal
digits 0-9 storing one digit in each nibble of the
byte.
0
MSB
A contiguous sequence of bytes or words. A string
may contain from 1 byte to 64K bytes.
Packed
BCD:
0
UNSIGNED
WORD
A 32-bit quantity, composed of a segment selector component and an offset component. Each
component is a 16-bit word.
A byte (unpacked) representation of the decimal
digits 0-9.
+2 16 15 +1
MAGNITUDE
An unsigned binary numeric value contained in an
8-bit byte or 16-bit word.
BCD:
Floating
Point:
MSB
MAGNITUDE
The 80C286 directly supports the following data types:
ASClI:
SIGN BIT
SIGNED 63
QUAD
WORD
(NOTE)
SIGN BIT
Data Types
String:
0
MAGNITUDE
BASED INDEXED MODE: The operand's offset is the sum
of the contents of a base register and an index register.
Pointer:
0
8 7
SIGNED
WORD
INDEXED MODE: The operand's offset is the sum of an 8 or 16bit displacement and the contents of an index register (SI or Dl).
Ordinal:
0
UNSIGNED
BYTE
BASED MODE: The operand's offset is the sum of an 8 or
16-bit displacement and the contents of a base register (BX
or BP).
Integer:
0
SIGNED
BYTE
BYTE/WORD N BYTE/WORD 1
31
+3
BYTE/WORD 0
+1 16 15 +1
0
0
POINTER
Figure 5 graphically represents the data types supported by
the 80C286.
OFFSET
SELECTOR
79 +9
+8
+7
+6
+5
+4
+3
+2
+1
FLOATING
POINT (NOTE)
SIGN BIT
EXPONENT
MAGNITUDE
FIGURE 5. 80C286 SUPPORTED DATA TYPES
NOTE: Supported by 80C286/80C287 Numeric Data Processor
Configuration
12
0 0
80C286
TABLE 4. INTERRUPT VECTOR ASSIGNMENTS
FUNCTION
INTERRUPT
NUMBER
RELATED
INSTRUCTIONS
DOES RETURN ADDRESS
POINT TO INSTRUCTION
CAUSING EXCEPTION?
Divide Error Exception
0
DlV, lDlV
Single Step Interrupt
1
All
NMI Interrupt
2
INT 2 or NMI Pin
Breakpoint Interrupt
3
INT 3
INTO Detected Overflow Exception
4
INTO
No
BOUND Range Exceeded Exception
s
BOUND
Yes
Invalid Opcode Exception
6
Any Undefined Opcode
Yes
Processor Extension Not Available Exception
7
ESC or WAIT
Yes
Reserved - Do Not Use
Processor Extension Error Interrupt
Yes
8 - 15
16
Reserved
17 - 31
User Defined
32 - 255
ESC or WAIT
I/O Space
Maskable Interrupt (INTR)
The I/O space consists of 64K 8-bit ports, 32K 16-bit ports, or
a combination of the two. I/O instructions address the I/O
space with either an 8-bit port address, specified in the
instruction, or a 16-bit port address in the DX register. 8-bit
port addresses are zero extended such that A15-A8 are LOW.
I/O port addresses 00F8(H) through 00FF(H) are reserved.
The 80C286 provides a maskable hardware interrupt request
pin, INTR. Software enables this input by setting the interrupt
flag bit (IF) in the flag word. All 224 user-defined interrupt
sources can share this input, yet they can retain separate
interrupt handlers. An 8-bit vector read by the CPU during the
interrupt acknowledge sequence (discussed in System Interface section) identifies the source of the interrupt.
Interrupts
The processor automatically disables further maskable interrupts internally by resetting the IF as part of the response to
an interrupt or exception. The saved flag word will reflect the
enable status of the processor prior to the interrupt. Until the
flag word is restored to the flag register, the interrupt flag will
be zero unless specifically set. The interrupt return instruction includes restoring the flag word, thereby restoring the
original status of IF.
An interrupt transfers execution to a new program location.
The old program address (CS:lP) and machine state (Flags)
are saved on the stack to allow resumption of the interrupted
program. Interrupts fall into three classes: hardware initiated,
INT instructions, and instruction exceptions. Hardware initiated interrupts occur in response to an external input and
are classified as non-maskable or maskable. Programs may
cause an interrupt with an INT instruction. Instruction exceptions occur when an unusual condition which prevents further instruction processing is detected while attempting to
execute an instruction. The return address from an exception will always point to the instruction causing the exception
and include any leading instruction prefixes.
Non-Maskable Interrupt Request (NMI)
A non-maskable interrupt input (NMI) is also provided. NMI
has higher priority than INTR. A typical use of NMI would be
to activate a power failure routine. The activation of this input
causes an interrupt with an internally supplied vector value
of 2. No external interrupt acknowledge sequence is performed.
A table containing up to 256 pointers defines the proper
interrupt service routine for each interrupt. Interrupts 0-31,
some of which are used for instruction exceptions, are
reserved. For each interrupt, an 8-bit vector must be supplied to the 80C286 which identifies the appropriate table
entry. Exceptions supply the interrupt vector internally. INT
instructions contain or imply the vector and allow access to
all 256 interrupts. Maskable hardware initiated interrupts
supply the 8-bit vector to the CPU during an interrupt
acknowledge bus sequence. Nonmaskable hardware interrupts use a predefined internally supplied vector.
While executing the NMI servicing procedure, the 80C286
will service neither further NMI requests, INTR requests, nor
the processor extension segment overrun interrupt until an
interrupt return (lRET) instruction is executed or the CPU is
reset. If NMI occurs while currently servicing an NMI, its
presence will be saved for servicing after executing the first
IRET instruction. IF is cleared at the beginning of an NMI
interrupt to inhibit INTR interrupts.
13
80C286
Single Step Interrupt
Machine Status Word Description
The 80C286 has an internal interrupt that allows programs to
execute one instruction at a time. It is called the single step
interrupt and is controlled by the single step flag bit (TF) in the
flag word. Once this bit is set, an internal single step interrupt
will occur after the next instruction has been executed. The
interrupt clears the TF bit and uses an internally supplied vector of 1. The lRET instruction is used to set the TF bit and
transfer control to the next instruction to be single stepped.
The machine status word (MSW) records when a task switch
takes place and controls the operating mode of the 80C286.
It is a 16-bit register of which the lower four bits are used.
One bit places the CPU into protected mode, while the other
three bits, as shown in Table 7, control the processor extension interface. After RESET, this register contains FFF0(H)
which places the 80C286 in 80C286 real address mode.
TABLE 7. MSW BIT FUNCTIONS
Interrupt Priorities
When simultaneous interrupt requests occur, they are processed in a fixed order as shown in Table 5. Interrupt processing involves saving the flags, return address, and
setting CS:lP to point at the first instruction of the interrupt
handler. If another enabled interrupt should occur, it is processed before the next instruction of the current interrupt
handler is executed. The last interrupt processed is therefore
the first one serviced.
BIT
POSITION
NAME
FUNCTION
0
PE
Protected mode enable places the
80C286 into protected mode and cannot
be cleared except by RESET.
1
MP
Monitor processor extension allows WAIT
instructions to cause a processor extension not present exception (number 7).
2
EM
Emulate processor extension causes a
processor extension not present exception (number 7) on ESC instructions to allow emulating a processor extension.
3
TS
Task switched indicates the next instruction using a processor extension will
cause exception 7, allowing software to
test whether the current processor extension context belongs to the current task.
TABLE 5. INTERRUPT PROCESSING ORDER
ORDER
INTERRUPT
1
Instruction Exception
2
Single Step
3
NMI
4
Processor Extension Segment Overrun
5
INTR
6
INT Instruction
The LMSW and SMSW instructions can load and store the
MSW in real address mode. The recommended use of TS,
EM, and MP is shown in Table 8.
Initialization and Processor Reset
Halt
Processor initialization or start up is accomplished by driving
the RESET input pin HIGH. RESET forces the 80C286 to
terminate all execution and local bus activity. No instruction
or bus activity will occur as long as RESET is active. After
RESET becomes inactive, and an internal processing interval elapses, the 80C286 begins execution in real address
mode with the instruction at physical location FFFFF0(H).
RESET also sets some registers to predefined values as
shown in Table 6.
The HLT instruction stops program execution and prevents
the CPU from using the local bus until restarted. Either NMI,
INTR with IF = 1, or RESET will force the 80C286 out of halt.
If interrupted, the saved CS:IP will point to the next instruction after the HLT.
TABLE 6. 80C286 INITIAL REGISTER STATE AFTER RESET
Flag Word
0002(H)
Machine Status Word
FFF0(H)
Instruction Pointer
FFF0(H)
Code Segment
F000(H)
Data Segment
0000(H)
Extra Segment
0000(H)
Stack Segment
0000(H)
HOLD must not be active during the time from the leading
edge of the initial RESET to 34 CLKs after the trailing edge
of the initial RESET of an 80C286 system.
14
80C286
TABLE 8. RECOMMENDED MSW ENCODINGS FOR PROCESSOR EXTENSION CONTROL
TS
MP
EM
RECOMMENDED USE
INSTRUCTION
CAUSING
EXCEPTION 7
0
0
0
Initial encoding after RESET. 80C286 operation is identical to 80C86/88.
None
0
0
1
No processor extension is available. Software will emulate its function.
ESC
1
0
1
No processor extension is available. Software will emulate its function. The
current processor extension context may belong to another task.
ESC
0
1
0
A processor extension exists.
None
1
1
0
A processor extension exists. The current processor extension context may
belong to another task. The exception 7 on WAIT allows software to test for
an error pending from a previous processor extension operation.
ESC or WAIT
TABLE 9. REAL ADDRESS MODE ADDRESSING INTERRUPTS
FUNCTION
INTERRUPT
NUMBER
RETURN ADDRESS
BEFORE INSTRUCTION
Interrupt table limit too small exception
8
INT vector is not within table limit
Yes
Processor extension segment overrun
interrupt
9
ESC with memory operand extending beyond offset
FFFF(H)
No
Segment overrun exception
13
Word memory reference with offset = FFFF(H) or an
attempt to execute past the end of a segment
Yes
RELATED INSTRUCTIONS
80C286 Real Address Mode
The 80C286 executes a fully upward-compatible superset of
the 80C86 instruction set in real address mode. In real
address mode the 80C286 is object code compatible with
80C86 and 80C88 software. The real address mode architecture (registers and addressing modes) is exactly as
described in the 80C286 Base Architecture section of this
Functional Description.
in a segment does not use the full 64K bytes, the unused
end of the segment may be overlaid by another segment to
reduce physical memory requirements.
15
0
0000
OFFSET
ADDRESS
OFFSET
Memory Size
15
Physical memory is a contiguous array of up to 1,048,576
bytes (one megabyte) addressed by pins A0 through A19
and BHE. A20 through A23 should be ignored.
0
SEGMENT
SELECTOR
SEGMENT
ADDRESS
0000
Memory Addressing
In real address mode physical memory is a contiguous array
of up to 1,048,576 bytes (one megabyte) addressed by pin
A0 through A19 and BHE. Address bits A20-A23 may not
always be zero in real mode. A20-A23 should not be used by
the system while the 80C286 is operating in Real Mode.
ADDER
The selector portion of a pointer is interpreted as the upper
16-bits of a 20-bit segment address. The lower four bits of
the 20-bit segment address are always zero. Segment
addresses, therefore, begin on multiples of 16 bytes. See
Figure 6 for a graphic representation of address information.
19
0
20-BIT PHYSICAL
MEMORY ADDRESS
FIGURE 6. 80C286 REAL ADDRESS MODE ADDRESS
CALCULATION
All segments in real address mode are 64K bytes in size and
may be read, written, or executed. An exception or interrupt
can occur if data operands or instructions attempt to wrap
around the end of a segment (e.g. a word with its low order
byte at offset FFFF(H) and its high order byte at offset
0000(H)). If, in real address mode, the information contained
15
80C286
Reserved Memory Locations
Protected Mode Initialization
The 80C286 reserves two fixed areas of memory in real
address mode (see Figure 7); system initialization area and
interrupt table area. Locations from addresses FFFF0(H)
through FFFFF(H) are reserved for system initialization. Initial
execution begins at location FFFF0(H). Locations 00000(H)
through 003FF(H) are reserved for interrupt vectors.
To prepare the 80C286 for protected mode, the LIDT
instruction is used to load the 24-bit interrupt table base and
16-bit limit for the protected mode interrupt table. This
instruction can also set a base and limit for the interrupt vector table in real address mode. After reset, the interrupt table
base is initialized to 000000(H) and its size set to 03FF(H).
These values are compatible with 80C86 and 80C88 software. LIDT should only be executed in preparation for protected mode.
RESET BOOTSTRAP
PROGRAM JUMP
•
•
•
INTERRUPT POINTER
FOR VECTOR 255
•
•
•
INTERRUPT POINTER
FOR VECTOR 1
INTERRUPT POINTER
FOR VECTOR 0
FFFFFH
FFFF0H
Shutdown
Shutdown occurs when a severe error is detected that prevents
further instruction processing by the CPU. Shutdown and halt
are externally signalled via a halt bus operation. They can be
distinguished by A1 HIGH for halt and A1 LOW for shutdown. In
real address mode, shutdown can occur under two conditions:
3FFH
3FCH
7H
• Exceptions 8 or 13 happen and the IDT limit does not
include the interrupt vector.
4H
3H
0H
• A CALL INT or PUSH instruction attempts to wrap around
the stack segment when SP is not even.
INITIAL CS:IP VALUE IS F000:FFF0
An NMI input can bring the CPU out of shutdown if the IDT
limit is at least 000F(H) and SP is greater than 0005(H), otherwise shutdown can only be exited via the RESET input.
FIGURE 7. 80C286 REAL ADDRESS MODE INITIALLY
RESERVED MEMORY LOCATIONS
Interrupts
Table 9 shows the interrupt vectors reserved for exceptions
and interrupts which indicate an addressing error. The
exceptions leave the CPU in the state existing before
attempting to execute the failing instruction (except for
PUSH, POP, PUSHA, or POPA). Refer to the next section
on protected mode initialization for a discussion on exception 8.
16
80C286
Protected Virtual Address Mode
from the tables in memory. The 16-bit offset is added to the
segment base address to form the physical address as
shown in Figure 8. The tables are automatically referenced
by the CPU whenever a segment register is loaded with a
selector. All 80C286 instructions which load a segment register will reference the memory based tables without additional software. The memory based tables contain 8 byte
values called descriptors.
The 80C286 executes a fully upward-compatible superset of
the 80C86 instruction set in protected virtual address mode
(protected mode). Protected mode also provides memory
management and protection mechanisms and associated
instructions.
The 80C286 enters protected virtual address mode from real
address mode by setting the PE (Protection Enable) bit of
the machine status word with the Load Machine Status Word
(LMSW) instruction. Protected mode offers extended physical and virtual memory address space, memory protection
mechanisms, and new operations to support operating systems and virtual memory.
Descriptors
Descriptors define the use of memory. Special types of
descriptors also define new functions for transfer of control
and task switching. The 80C286 has segment descriptors for
code, stack and data segments, and system control descriptors for special system data segments and control transfer
operations. Descriptor accesses are performed as locked
bus operations to assure descriptor integrity in multi-processor systems.
All registers, instructions, and addressing modes described
in the 80C286 Base Architecture section of this Functional
Description remain the same. Programs for the 80C86,
80C88, and real address mode 80C286 can be run in protected mode; however, embedded constants for segment
selectors are different.
Code and Data Segment Descriptors (S = 1)
Besides segment base addresses, code and data descriptors
contain other segment attributes including segment size (1 to
64K bytes), access rights (read only, read/write, execute only,
and execute/read), and presence in memory (for virtual memory systems) (See Table 10). Any segment usage violating a
segment attribute indicated by the segment descriptor will prevent the memory cycle and cause an exception or interrupt.
Memory Size
The protected mode 80C286 provides a 1 gigabyte virtual
address space per task mapped into a 16 megabyte physical
address space defined by the address pins A23-A0 and
BHE. The virtual address space may be larger than the
physical address space since any use of an address that
does not map to a physical memory location will cause a
restartable exception.
7
+7
CPU
31
0 7
16 15
0
ACCESS
RIGHTS BYTE
POINTER SELECTOR OFFSET
PHYSICAL MEMORY
+5 P DPL S TYPE A
0
RESERVED †
+6
BASE 23 - 16
+4
+3
BASE 15 - 0
+1
LIMIT 15 - 0
15
8 7
+2
0
0
† MUST BE SET TO 0 FOR COMPATIBILITY WITH FUTURE UPGRADES
FIGURE 9. CODE OR DATA SEGMENT DESCRIPTOR
SEGMENT BASE
ADDRESS
23
0
SEGMENT
DESCRIPTOR
SEGMENT
Code and data (including stack data) are stored in two types
of segments: code segments and data segments. Both types
are identified and defined by segment descriptors (S = 1).
Code segments are identified by the executable (E) bit set to
1 in the descriptor access rights byte. The access rights byte
of both code and data segment descriptor types have three
fields in common: present (P) bit, Descriptor Privilege Level
(DPL), and accessed (A) bit. If P = 0, any attempted use of
this segment will cause a not-present exception. DPL specifies the privilege level of the segment descriptor. DPL controls when the descriptor may be used by a task (refer to
privilege discussion below). The A bit shows whether the
segment has been previously accessed for usage profiling, a
necessity for virtual memory systems. The CPU will always
set this bit when accessing the descriptor.
SEGMENT
DESCRIPTION
TABLE
PHYSICAL
ADDRESS
ADDER
MEMORY
OPERAND
FIGURE 8. PROTECTED MODE MEMORY ADDRESSING
Memory Addressing
As in real address mode, protected mode uses 32-bit pointers, consisting of 16-bit selector and offset components. The
selector, however, specifies an index into a memory resident
table rather than the upper 16-bits of a real memory address.
The 24-bit base address of the desired segment is obtained
17
80C286
TABLE 10. CODE AND DATA SEGMENT DESCRIPTOR FORMATS - ACCESS RIGHTS BYTE DEFINITION
BIT
POSITION
7
6-5
4
Present (P)
FUNCTION
P=1
Segment is mapped into physical memory.
P=0
No mapping to physical memory exits, base and limit are not used.
Descriptor Privilege
Level (DPL)
Segment privilege attribute used in privilege tests.
Segment Descriptor (S) S = 1
Code or Data (includes stacks) segment descriptor
S=0
System Segment Descriptor or Gate Descriptor
3
Executable (E)
E=0
Data segment descriptor type is:
2
Expansion Direction
(ED)
ED = 0
Expand up segment, offsets must be ≤ limit.
ED = 1
Expand down segment, offsets must be > limit.
Writable (W)
W=0
Data segment may not be written into.
W=1
Data segment may be written into.
1
Type
Field
Definition
NAME
3
Executable (E)
E=1
Code Segment Descriptor type is:
2
Conforming (C)
C=1
Code segment may only be executed when CPL ≥
DPL and CPL remains unchanged.
1
0
Readable (R)
Accessed (A)
If Data Segment
(S = 1, E = 0)
If Code Segment
(S = 1, E = 1)
R=0
Code segment may not be read.
R=1
Code segment may be read.
A=0
Segment has not been accessed.
A=1
Segment selector has been loaded into segment register or used by selector
test instructions.
18
80C286
Data segments (S = 1, E = 0) may be either read-only or readwrite as controlled by the W bit of the access rights byte.
Read-only (W = 0) data segments may not be written into.
Data segments may grow in two directions, as determined by
the Expansion Direction (ED) bit: upwards (ED = 0) for data
segments, and downwards (ED = 1) for a segment containing
a stack. The limit field for a data segment descriptor is interpreted differently depending on the ED bit (see Table 10).
TABLE 11. SYSTEM SEGMENT DESCRIPTOR FORMAT FIELDS
A code segment (S = 1, E = 1) may be execute-only or execute/read as determined by the Readable (R) bit. Code segments may never be written into and execute-only code
segments (R = 0) may not be read. A code segment may
also have an attribute called conforming (C). A conforming
code segment may be shared by programs that execute at
different privilege levels. The DPL of a conforming code segment defines the range of privilege levels at which the segment may be executed (refer to privilege discussion below).
The limit field identifies the last byte of a code segment.
NAME
VALUE
TYPE
1
Available Task State Segment (TSS)
2
Local Descriptor Table
3
Busy Task State Segment (TSS)
0
Descriptor contents are not valid
1
Descriptor contents are valid
P
DESCRIPTION
DPL
0-3
Descriptor Privilege Level
BASE
24-Bit
Number
Base Address of special system data
segment in real memory
LIMIT
16-Bit
Number
Offset of last byte in segment
System Segment Descriptors (S = 0, Type = 1-3)
Gate Descriptors (S = 0, Type = 4-7)
In addition to code and data segment descriptors, the protected mode 80C286 defines System Segment Descriptors.
These descriptors define special system data segments
which contain a table of descriptors (Local Descriptor Table
Descriptor) or segments which contain the execution state of
a task (Task State Segment Descriptor).
Gates are used to control access to entry points within the
target code segment. The gate descriptors are call gates,
task gates, interrupt gates and trap gates. Gates provide a
level of indirection between the source and destination of the
control transfer. This indirection allows the CPU to automatically perform protection checks and control entry point of the
destination. Call gates are used to change privilege levels
(see Privilege), task gates are used to perform a task switch,
and interrupt and trap gates are used to specify interrupt service routines. The interrupt gate disables interrupts (resets
IF) while the trap gate does not.
Table 11 gives the formats for the special system data segment descriptors. The descriptors contain a 24-bit base
address of the segment and a 16-bit limit. The access byte
defines the type of descriptor, its state and privilege level.
The descriptor contents are valid and the segment is in
physical memory if P = 1. If P = 0, the segment is not valid.
The DPL field is only used in Task State Segment descriptors and indicates the privilege level at which the descriptor
may be used (see Privilege). Since the Local Descriptor
Table descriptor may only be used by a special privileged
instruction, the DPL field is not used. Bit 4 of the access byte
is 0 to indicate that it is a system control descriptor. The type
field specifies the descriptor type as indicated in Table 11.
7
+7
0 7
0
BASE 23 - 16
TYPE
+3
BASE 15 - 0
+1
LIMIT 15 - 0
15
8 7
Exception 13 is generated when the gate is used if a destination selector does not refer to the correct descriptor type. The
word count field is used in the call gate descriptor to indicate
the number of parameters (0-31 words) to be automatically
copied from the caller’s stack to the stack of the called routine
when a control transfer changes privilege levels. The word
count field is not used by any other gate descriptor.
+6
RESERVED †
+5 P DPL 0
Table 12 shows the format of the gate descriptors. The
descriptor contains a destination pointer that points to the
descriptor of the target segment and the entry point offset.
The destination selector in an interrupt gate, trap gate, and
call gate must refer to a code segment descriptor. These gate
descriptors contain the entry point to prevent a program from
constructing and using an illegal entry point. Task gates may
only refer to a task state segment. Since task gates invoke a
task switch, the destination offset is not used in the task gate.
+4
+2
0
0
† MUST BE SET TO 0 FOR COMPATIBILITY WITH FUTURE UPGRADES
The access byte format is the same for all descriptors. P = 1
indicates that the gate contents are valid. P = 0 indicates the
contents are not valid and causes exception 11 if referenced. DPL is the descriptor privilege level and specifies
when this descriptor may be used by a task (refer to privilege
discussion below). Bit 4 must equal 0 to indicate a system
control descriptor. The type field specifies the descriptor type
as indicated in Table 12.
FIGURE 10. SYSTEM SEGMENT DESCRIPTOR
19
80C286
Segment Descriptor Cache Registers
PROGRAM VISIBLE
SEGMENT SELECTORS
A segment descriptor cache register is assigned to each of
the four segment registers (CS, SS, DS, ES). Segment
descriptors are automatically loaded (cached) into a segment descriptor cache register (Figure 12) whenever the
associated segment register is loaded with a selector.
CS
DS
SS
ES
Only segment descriptors may be loaded into segment
descriptor cache registers. Once loaded, all references to
that segment of memory use the cached descriptor information instead of reaccessing the descriptor. The descriptor
cache registers are not visible to programs. No instructions
exist to store their contents. They only change when a segment register is loaded.
7
0 7
PROGRAM INVISIBLE
ACCESS
RIGHTS
+3
+1
SEGMENT PHYSICAL
BASE ADDRESS
SEGMENT SIZE
+6
X X X WORD COUNT +4
4-0
X X +2
DESTINATION SELECTOR 15 - 0
+5 P DPL 0
0
0
RESERVED †
+7
15
SEGMENT REGISTERS
(LOADED BY PROGRAM)
TYPE
40 39
16 15
0
SEGMENT DESCRIPTOR CACHE REGISTERS
(AUTOMATICALLY LOADED BY CPU)
0
DESTINATION OFFSET 15 - 0
8 7
47
0
15
† MUST BE SET TO 0 FOR COMPATIBILITY WITH FUTURE UPGRADES
FIGURE 12. DESCRIPTOR CACHE REGISTERS
FIGURE 11. GATE DESCRIPTOR
SELECTOR
INDEX
TABLE 12. GATE DESCRIPTOR FORMAT FIELD
NAME
VALUE
TYPE
4
Call Gate
5
Task Gate
6
Interrupt Gate
7
Trap Gate
0
Descriptor Contents are not valid
1
Descriptor Contents are valid
P
15
DESCRIPTION
DPL
0-3
Descriptor Privilege Level
WORD
COUNT
0 - 31
Number of words to copy from callers
stack to called procedures stack. Only
used with call gate.
BITS
1-0
2
15 - 3
16-Bit
Offset
NAME
7
2 1
0
FUNCTION
Requested Privilege Level
(RPL)
Indicates Selector Privilege
Level Desired
Table Indicator (TI)
TI = 0 Use Global Descriptor Table (GDT)
TI = 1 Use Local Descriptor
Table (LDT)
Index
Select Descriptor Entry In
Table
FIGURE 13. SELECTOR FIELDS
Local and Global Descriptor Tables
Two tables of descriptors, called descriptor tables, contain all
descriptors accessible by a task at any given time. A descriptor
table is a linear array of up to 8192 descriptors. The upper 13
bits of the selector value are an index into a descriptor table.
Each table has a 24-bit base register to locate the descriptor
table in physical memory and a 16-bit limit register that confine
descriptor access to the defined limits of the table as shown in
Figure 14. A restartable exception (13) will occur if an attempt is
made to reference a descriptor outside the table limits.
DESTINATION 16-Bit Selector to the target code segment
SELECTOR Selector (call, interrupt or selector Trap Gate).
Selector to the target task state segment (Task Gate).
DESTINATION
OFFSET
8
TI RPL
Entry point within the target code segment
Selector Fields
One table, called the Global Descriptor table (GDT), contains descriptors available to all tasks. The other table,
called the Local Descriptor Table (LDT), contains descriptors
that can be private to a task. Each task may have its own private LDT. The GDT may contain all descriptor types except
interrupt and trap descriptors. The LDT may contain only
segment, task gate, and call gate descriptors. A segment
cannot be accessed by a task if its segment descriptor does
not exist in either descriptor table at the time of access.
A protected mode selector has three fields: descriptor entry
index, local or global descriptor table indicator (TI), and selector privilege (RPL) as shown in Figure 13. These fields select
one of two memory based tables of descriptors, select the
appropriate table entry and allow high-speed testing of the
selector's privilege attribute (refer to privilege discussion
below).
20
80C286
CPU
MEMORY
GATE FOR
INTERRUPT #n
0
GDT LIMIT
23
GDT
GATE FOR
INTERRUPT #n-1
GDT BASE
24-BIT PHYS AD
15
CPU
0
15
LDT
DESCR
SELECTOR
15
IDT LIMIT
LDT1
0
CURRENT
LDT
23
LDT BASE
24-BIT PHYS AD
0
FIGURE 16. INTERRUPT DESCRIPTOR TABLE DEFINITION
LDTn
Privilege
INCREASING
MEMORY
ADDRESS
PROGRAM INVISIBLE
(AUTOMATICALLY
LOADED
FROM LDT DESCR
WITHIN GDT)
The 80C286 has a four-level hierarchical privilege system
which controls the use of privileged instructions and access
to descriptors (and their associated segments) within a task.
Four-level privilege, as shown in Figure 17, is an extension
of the users/supervisor mode commonly found in minicomputers. The privilege levels are numbered 0 through 3. Level
0 is the most privileged level. Privilege levels provide protection within a task. (Tasks are isolated by providing private
LDT’s for each task.) Operating system routines, interrupt
handlers, and other system software can be included and
protected within the virtual address space of each task using
the four levels of privilege. Each task in the system has a
separate stack for each of its privilege levels.
FIGURE 14. LOCAL AND GLOBAL DESCRIPTOR TABLE
DEFINITION
The LGDT and LLDT instructions load the base and limit of
the global and local descriptor tables. LGDT and LLDT are
privileged, i.e. they may only be executed by trusted programs operating at level 0. The LGDT instruction loads a six
byte field containing the 16-bit table limit and 24-bit physical
base address of the Global Descriptor Table as shown in
Figure 15. The LDT instruction loads a selector which refers
to a Local Descriptor Table descriptor containing the base
address and limit for an LDT, as shown in Table 11.
7
0 7
+4
+3
BASE 15 - 0
+2
+1
LIMIT 15 - 0
0
15
8 7
Tasks, descriptors, and selectors have a privilege level
attribute that determines whether the descriptor may be
used. Task privilege affects the use of instructions and
descriptors. Descriptor and selector privilege only affect
access to the descriptor.
0
BASE 23 - 16
RESERVED †
+5
GATE FOR
INTERRUPT #1
GATE FOR
INTERRUPT #0
IDT BASE
LDT LIMIT
23
0
INTERRUPT
DESCRIPTOR
TABLE
(IDT)
INCREASING
MEMORY
ADDRESS
15
MEMORY
CPU
ENFORCED
SOFTWARE
INTERFACES
APPLICATIONS
0
OS EXTENSIONS
† MUST BE SET TO 0 FOR COMPATIBILITY WITH FUTURE UPGRADES
PL = 3
FIGURE 15. GLOBAL DESCRIPTOR TABLE AND INTERRUPT
DESCRlPTOR TABLE DATA TYPE
SYSTEM
SERVICES
Interrupt Descriptor Table
The protected mode 80C286 has a third descriptor table,
called the Interrupt Descriptor Table (IDT) (see Figure 16),
used to define up to 256 interrupts. It may contain only task
gates, interrupt gates and trap gates. The IDT (Interrupt
Descriptor Table) has a 24-bit physical base and 16-bit limit
register in the CPU. The privileged LlDT instruction loads
these registers with a six byte value of identical form to that
of the LGDT instruction (see Figure 16 and Protected Mode
lnitialization).
HIGH SPEED
OPERATING
SYSTEM
INTERFACE
References to IDT entries are made via INT instructions, external interrupt vectors, or exceptions. The IDT must be at least
256 bytes in size to allocate space for all reserved interrupts.
PL = 2
PL = 1
KERNAL
PL = 0
MOST
PRIVILEGED
NOTE: PL becomes numerically lower as privilege level increases.
FIGURE 17. HIERARCHICAL PRIVILEGE LEVELS
21
80C286
Task Privilege
A task always executes at one of the four privilege levels.
The task privilege level at any specific instant is called the
Current Privilege Level (CPL) and is defined by the lower
two bits of the CS register. CPL cannot change during execution in a single code segment. A task's CPL may only be
changed by control transfers through gate descriptors to a
new code segment (See Control Transfer). Tasks begin executing at the CPL value specified by the code segment
selector within TSS when the task is initiated via a task
switch operation (See Figure 18). A task executing at Level 0
can access all data segments defined in the GDT and the
task's LDT and is considered the most trusted level. A task
executing a Level 3 has the most restricted access to data
and is considered the least trusted level.
parameters passed to a more trusted procedure are not
allowed to use data at a more privileged level than the caller
(refer to pointer testing instructions).
Descriptor Access and Privilege Validation
Determining the ability of a task to access a segment
involves the type of segment to be accessed, the instruction
used, the type of descriptor used and CPL, RPL, and DPL.
The two basic types of segment accesses are control transfer (selectors loaded into CS) and data (selectors loaded into
DS, ES or SS).
Data Segment Access
Instructions that load selectors into DS and ES must refer to
a data segment descriptor or readable code segment
descriptor. The CPL of the task and the RPL of the selector
must be the same as or more privileged (numerically equal
to or lower than) than the descriptor DPL. In general, a task
can only access data segments at the same or less privileged levels than the CPL or RPL (whichever is numerically
higher) to prevent a program from accessing data it cannot
be trusted to use.
Descriptor Privilege
Descriptor privilege is specified by the Descriptor Privilege
Level (DPL) field of the descriptor access byte. DPL specifies
the least trusted task privilege level (CPL) at which a task may
access the descriptor. Descriptors with DPL = 0 are the most
protected. Only tasks executing at privilege level 0 (CPL = 0)
may access them. Descriptors with DPL = 3 are the least protected (i.e. have the least restricted access) since tasks can
access them when CPL = 0, 1, 2, or 3). This rule applies to all
descriptors, except LDT descriptors.
An exception to the rule is a readable conforming code segment. This type of code segment can be read from any privilege level.
Selector Privilege
If the privilege checks fail (e.g. DPL is numerically less than
the maximum of CPL and RPL) or an incorrect type of
descriptor is referenced (e.g. gate descriptor or execute only
code segment) exception 13 occurs. If the segment is not
present, exception 11 is generated.
Selector privilege is specified by the Requested Privilege
Level (RPL) field in the least significant two bits of a selector.
Selector RPL may establish a less trusted privilege level
than the current privilege level for the use of a selector. This
level is called the task's effective privilege level (EPL). RPL
can only reduce the scope of a task's access to data with
this selector. A task's effective privilege is the numeric maximum of RPL and CPL. A selector with RPL = 0 imposes no
additional restriction on its use while a selector with RPL = 3
can only refer to segments at privilege Level 3 regardless of
the task's CPL. RPL is generally used to verify that pointer
Instructions that load selectors into SS must refer to data
segment descriptors for writable data segments. The
descriptor privilege (DPL) and RPL must equal CPL. All
other descriptor types or a privilege level violation will cause
exception 13. A not present fault causes exception 12.
TABLE 13. DESCRlPTOR TYPES USED FOR CONTROL TRANSFER
CONTROL TRANSFER TYPES
OPERATION TYPES
DESCRIPTOR
REFERENCED
DESCRIPTOR
TABLE
Intersegment within the same privilege levels
JMP, CALL, RET, lRET (Note 4)
Code Segment
GDT/LDT
Intersegment to the same or higher privilege level interrupt
within task may change CPL
CALL
Call Gate
GDT/LDT
Interrupt Instruction, Exception
External Interrupt
Trap or Interrupt Gate
lDT
Intersegment to a lower privilege level (changes task CPL) RET, IRET (Note 4)
Code Segment
GDT/LDT
Task Switch
CALL, JMP
Task State Segment
GDT
CALL, JMP
Task Gate
GDT/LDT
lRET (Note 5)
Interrupt Instruction, Exception
External Interrupt
Task Gate
IDT
NOTES:
4. NT (Nested Task bit of flag word) = 0
5. NT (Nested Task bit of flag word) = 1
22
80C286
Control Transfer
Privilege Level Changes
Four types of control transfer can occur when a selector is
loaded into CS by a control transfer operation (see Table
13). Each transfer type can only occur if the operation which
loaded the selector references the correct descriptor type.
Any violation of these descriptor usage rules (e.g. JMP
through a call gate or RET to a Task State Segment) will
cause exception 13.
Any control transfer that changes CPL within the task,
causes a change of stacks as part of the operation. Initial
values of SS:SP for privilege levels 0, 1, and 2 are kept in
the task state segment (refer to Task Switch Operation).
During a JMP or CALL control transfer, the new stack pointer
is loaded into the SS and SP registers and the previous
stack pointer is pushed onto the new stack.
The ability to reference a descriptor for control transfer is
also subject to rules of privilege. A CALL or JUMP instruction
may only reference a code segment descriptor with DPL
equal to the task CPL or a conforming segment with DPL of
equal or greater privilege than CPL. The RPL of the selector
used to reference the code descriptor must have as much
privilege as CPL.
When returning to the original privilege level, its stack is
restored as part of the RET or IRET instruction operation.
For subroutine calls that pass parameters on the stack and
cross privilege levels, a fixed number of words, as specified
in the gate, are copied from the previous stack to the current
stack. The inter-segment RET instruction with a stack adjustment value will correctly restore the previous stack pointer
upon return.
RET and IRET instructions may only reference code segment descriptors with descriptor privilege equal to or less
privileged than the task CPL. The selector loaded into CS is
the return address from the stack. After the return, the selector RPL is the task's new CPL. If CPL changes, the old stack
pointer is popped after the return address.
Protection
The 80C286 includes mechanisms to protect critical instructions that effect the CPU execution state (e.g. HLT) and
code or data segments from improper usage. These protection mechanisms are grouped into three forms:
When a JMP or CALL references a Task State Segment
descriptor, the descriptor DPL must be the same or less privileged than the task's CPL. Reference to a valid Task State
Segment descriptor causes a task switch (see Task Switch
Operation). Reference to a Task State Segment descriptor
at a more privileged level than the task's CPL generates
exception 13.
• Restricted usage of segments (e.g. no write allowed to
read-only data segments). The only segments available for
use are defined by descriptors in the Local Descriptor Table
(LDT) and Global Descriptor Table (GDT).
• Restricted access to segments via the rules of privilege and
descriptor usage.
When an instruction or interrupt references a gate descriptor, the gate DPL must have the same or less privilege than
the task CPL. If DPL is at a more privileged level than CPL,
exception 13 occurs. If the destination selector contained in
the gate references a code segment descriptor, the code
segment descriptor DPL must be the same or more privileged than the task CPL. If not, Exception 13 is issued. After
the control transfer, the code segment descriptors DPL is the
task's new CPL. If the destination selector in the gate references a task state segment, a task switch is automatically
performed (see Task Switch Operation).
• Privileged instructions or operations that may only be executed at certain privilege levels as determined by the CPL
and I/O Privilege Level (lOPL). The lOPL is defined by bits
14 and 13 of the flag word.
These checks are performed for all instructions and can be
split into three categories: segment load checks (Table 14),
operand reference checks (Table 15), and privileged instruction checks (Table 16). Any violation of the rules shown will
result in an exception. A not-present exception related to the
stack segment causes exception 12.
The privilege rules on control transfer require:
TABLE 14. SEGMENT REGISTER LOAD CHECKS
• JMP or CALL direct to a code segment (code segment
descriptor) can only be a conforming segment with DPL of
equal or greater privilege than CPL or a non-conforming
segment at the same privilege level.
ERROR DESCRIPTION
• Interrupts within the task, or calls that may change privilege
levels, can only transfer control through a gate at the same
or a less privileged level than CPL to a code segment at the
same or more privileged level than CPL.
• Return instructions that don't switch tasks can only return
control to a code segment at the same or less privileged
level.
• Task switch can be performed by a call, jump or interrupt
which references either a task gate or task state segment at
the same or less privileged level.
23
EXCEPTION
NUMBER
Descriptor table limit exceeded
13
Segment descriptor not-present
11 or 12
Privilege rules violated
13
Invalid descriptor/segment type segment register
load:
- Read only data segment load to SS
- Special control descriptor load to DS, ES, SS
- Execute only Segment load to DS, ES, SS
- Data segment load to CS
- Read/Execute code segment load SS
13
80C286
address will not point at the ESC instruction that caused the
exception; however, the processor extension registers may
contain the address of the failing instruction.
TABLE 15. OPERAND REFERENCE CHECKS
EXCEPTION
NUMBER
ERROR DESCRIPTION
Write into code segment
13
Read from execute-only code segment
13
Write to read-only data segment
13
Segment limit exceeded (See Note)
These exceptions indicate a violation to privilege rules or
usage rules has occurred. Restart is generally not attempted
under those conditions.
All these checks are performed for all instructions and can
be split into three categories: segment load checks (Table
14), operand reference checks (Table 15), and privileged
instruction checks (Table 16). Any violation of the rules
shown will result in an exception. A not-present exception
causes exception 11 or 12 and is restartable.
12 or 13
NOTE: Carry out in offset calculations is ignored.
TABLE 16. PRIVILEGED INSTRUCTION CHECKS
SPECIAL OPERATIONS
EXCEPTION
NUMBER
ERROR DESCRIPTION
CPL ≠ 0 when executing the following instructions:
LIDT, LLDT, LGDT, LTR, LMSW, CTS, HLT
13
CPT > IOPL when executing the following
instructions:
INS, IN, OUTS, OUT, STI, CLI, LOCK
13
Task Switch Operation
The 80C286 provides a built-in task switch operation which
saves the entire 80C286 execution state (registers, address
space, and a link to the previous task), loads a new execution
state, and commences execution in the new task. Like gates,
the task switch operation is invoked by executing an inter-segment JMP or CALL instruction which refers to a Task State
Segment (TSS) or task gate descriptor in the GDT or LDT. An
INT instruction, exception, or external interrupt may also
invoke the task switch operation by selecting a task gate
descriptor in the associated IDT descriptor entry.
The lRET and POPF instructions do not perform some of
their defined functions if CPL is not of sufficient privilege
(numerically small enough). Precisely these are:
• The IF bit is not changed if CPL is greater than IOPL.
The TSS descriptor points at a segment (see Figure 18) containing the entire 80C286 execution state while a task gate
descriptor contains a TSS selector. The limit field of the
descriptor must be greater than 002B(H).
• The lOPL field of the flag word is not changed if CPL is
greater than 0.
No exceptions or other indication are given when these conditions occur.
Each task must have a TSS associated with it. The current
TSS is identified by a special register in the 80C286 called
the Task Register (TR). This register contains a selector
referring to the task state segment descriptor that defines
the current TSS. A hidden base and limit register associated
with TR are loaded whenever TR is loaded with a new selector. The IRET instruction is used to return control to the task
that called the current task or was interrupted. Bit 14 in the
flag register is called the Nested Task (NT) bit. It controls the
Exceptions
The 80C286 detects several types of exceptions and interrupts in protected mode (see Table 17). Most are restartable
after the exceptional condition is removed. Interrupt handlers
for most exceptions can read an error code, pushed on the
stack after the return address, that identifies the selector
involved (0 if none). The return address normally points to
the failing instruction including all leading prefixes. For a processor extension segment overrun exception, the return
TABLE 17. PROTECTED MODE EXCEPTIONS
INTERRUPT
VECTOR
FUNCTION
RETURN ADDRESS
AT FALLING
INSTRUCTION?
ALWAYS
RESTARTABLE?
ERROR CODE
ON STACK?
8
Double exception detected
Yes
No (Note 7)
Yes
9
Processor extension segment overrun
No
No (Note 7)
No
10
Invalid task state segment
Yes
Yes
Yes
11
Segment not present
Yes
Yes
Yes
12
Stack segment overrun or stack segment not present
Yes
Yes (Note 6)
Yes
13
General protection
Yes
No (Note 7)
Yes
NOTES:
6. When a PUSHA or POPA instruction attempts to wrap around the stack segment, the machine state after the exception will not be restartable
because stack segment wrap around is not permitted. This condition is identified by the value of the saved SP being either 0000(H), 0001(H),
FFFE(H), or FFFF(H).
7. These exceptions indicate a violation to privilege rules or usage rules has occurred. Restart is generally not attempted under those conditions.
24
80C286
function of the IRET instruction. If NT = 0, the IRET instruction performs the regular current task by popping values off
the stack; when NT = 1, IRET performs a task switch operation back to the previous task.
appropriate segment without risking an exception. A condition
flag (ZF) indicates whether use of the selector or segment will
cause an exception.
Double Fault and Shutdown
When a CALL, JMP, or INT instruction initiates a task switch,
the old (except for case of JMP) and new TSS will be
marked busy and the back link field of the new TSS set to
the old TSS selector. The NT bit of the new task is set by
CALL or INT initiated task switches. An interrupt that does
not cause a task switch will clear NT. NT may also be set or
cleared by POPF or IRET instructions.
If two separate exceptions are detected during a single
instruction execution, the 80C286 performs the double fault
exception (8). If an exception occurs during processing of
the double fault exception, the 80C286 will enter shutdown.
During shutdown no further instructions or exceptions are
processed. Either NMI (CPU remains in protected mode) or
RESET (CPU exits protected mode) can force the 80C286
out of shutdown. Shutdown is externally signalled via a
HALT bus operation with A1 LOW.
The task state segment is marked busy by changing the
descriptor type field from Type 1 to Type 3. Use of a selector that references a busy task state segment causes
Exception 13.
Protected Mode lnitialization
The 80C286 initially executes in real address mode after
RESET. To allow initialization code to be placed at the top of
physical memory. A23-20 will be HIGH when the 80C286
performs memory references relative to the CS register until
CS is changed. A23-20 will be zero for references to the DS,
ES, or SS segments. Changing CS in real address mode will
force A23-20 LOW whenever CS is used again. The initial
CS:lP value of F000:FFF0 provides 64K bytes of code space
for initialization code without changing CS.
Processor Extension Context Switching
The context of a processor extension is not changed by the
task switch operation. A processor extension context need
only be changed when a different task attempts to use the
processor extension (which still contains the context of a previous task). The 80C286 detects the first use of a processor
extension after a task switch by causing the processor extension not present exception (7). The interrupt handler may then
decide whether a context change is necessary.
Protected mode operation requires several registers to be
initialized. The GDT and IDT base registers must refer to a
valid GDT and IDT. After executing the LMSW instruction to
set PE, the 80C286 must immediately execute an intrasegment JMP instruction to clear the instruction queue of
instructions decoded in real address mode.
Whenever the 80C286 switches tasks, it sets the Task
Switched (TS) bit of the MSW. TS indicates that a processor extension context may belong to a different task than
the current one. The processor extension not present
exception (7) will occur when attempting to execute an
ESC or WAIT instruction if TS = 1 and a processor extension is present (MP = 1 in MSW).
To force the 80C286 CPU registers to match the initial protected mode state assumed by software, execute a JMP
instruction with a selector referring to the initial TSS used in
the system. This will load the task register, local descriptor
table register, segment registers and initial general register
state. The TR should point at a valid TSS since any task
switch operation involves saving the current task state.
Pointer Testing Instructions
The 80C286 provides several instructions to speed pointer
testing and consistency checks for maintaining system integrity (see Table 18). These instructions use the memory management hardware to verify that a selector value refers to an
TABLE 18. 80C286 POINTER TEST INSTRUCTIONS
INSTRUCTION
OPERANDS
FUNCTION
ARPL
Selector,
Register
Adjust Requested Privilege Level: adjusts the RPL of the selector to the numeric maximum of
current selector RPL value and the RPL value in the register. Set zero flag if selector RPL was
changed by ARPL.
VERR
Selector
VERify for Read: sets the zero flag if the segment referred to by the selector can be read.
VERW
Selector
VERify for Write: sets the zero flag if the segment referred to by the selector can be written.
LSL
Register,
Selector
Load Segment Limit: reads the segment limit into the register if privilege rules and descriptor type
allow. Set zero flag if successful.
LAR
Register,
Selector
Load Access Rights: reads the descriptor access rights byte into the register if privilege rules allow. Set zero flag if successful.
25
80C286
CPU
RESERVED
TASK REGISTER
TR
15
0
SYSTEM
SEGMENT
DESCRIPTOR
P D 0 TYPE
P
L
BASE 23 - 16
DESCRIPTION
1
An available task state segment.
May be used as the destination
of a task switch operation.
3
A busy task state segment. Cannot be used as the destination of
a task switch.
DESCRIPTION
BASE 15 - 0
PROGRAM INVISIBLE
15
TYPE
LIMIT 15 - 0
0
LIMIT
BASE
23
0
15
TASK
STATE
SEGMENT
0
BYTE
OFFSET
TASK LDT SELECTOR
42
DS SELECTOR
40
P
SS SELECTOR
38
1
Base and Limit fields are valid.
CS SELECTOR
36
ES SELECTOR
34
0
DI
32
Segment is not present in memory, Base and Limit are not defined.
SI
30
BP
28
SP
26
BX
24
DX
22
CX
20
AX
18
FLAG WORD
16
IP (ENTRY POINT)
14
SS FOR CPL 2
12
SP FOR CPL 2
10
SS FOR CPL 1
8
SP FOR CPL 1
6
SS FOR CPL 0
4
SP FOR CPL 0
2
CURRENT
TASK
STATE
INITIAL
STACKS
FOR CPL 0, 1, 2
BACK LINK SELECTOR TO TSS 0
FIGURE 18. TASK STATE SEGMENT AND TSS REGISTERS
System Interface
The 80C286 system interface appears in two forms: a local
bus and a system bus. The local bus consists of address,
data, status, and control signals at the pins of the CPU. A system bus is any buffered version of the local bus. A system bus
may also differ from the local bus in terms of coding of status
and control lines and/or timing and loading of signals.
Bus Interface Signals and Timing
The 80C286 microsystems local bus interfaces the 80C286 to
local memory and I/O components. The interface has 24
address lines, 16 data lines, and 8 status and control signals.
The 80C286 CPU, 82C284 clock generator, 82C288 bus
controller, 82289 bus arbiter, 82C86H/87H transceivers, and
82C82/83H latches provide a buffered and decoded system
bus interface. The 82C284 generates the system clock and
26
80C286
synchronizes READY and RESET. The 82C288 converts
bus operation status encoded by the 80C286 into command
and bus control signals. The 82289 bus arbiter generates
Multibus™ bus arbitration signals. These components can
provide the critical timing required for most system bus interfaces including the Multibus.
address. Byte transfers occur on either half of the 16-bit local
data bus. Even bytes are accessed over D7-0 while odd bytes
are transferred over D15-8. Even addressed words are transferred over D15-0 in one bus cycle, while odd addressed word
require two bus operations. The first transfers data on D15-8,
and the second transfers data on D7-0. Both byte data transfers occur automatically, transparent to software.
Bus Hold Circuitry
Two bus signals, A0 and BHE, control transfers over the
lower and upper halves of the data bus. Even address byte
transfers are indicated by A0 LOW and BHE HIGH. Odd
address byte transfers are indicated by A0 HlGH and BHE
LOW. Both A0 and BHE are LOW for even address word
transfers.
To avoid high current conditions caused by floating inputs to
CMOS devices, and to eliminate the need for pull-up/down
resistors, “bus-hold” circuitry has been used on the 80C286
pins 4-6, 36-51 and 66-68 (See Figure 19A and 19B). The
circuit shown in Figure 19A will maintain the last valid logic
state if no driving source is present (i.e. an unconnected pin
or a driving source which goes to a high impedance state).
The circuit shown in Figure 19B will maintain a high impedance logic one state if no driving source is present. To overdrive the “bus-hold” circuits, an external driver must be
capable of sinking or sourcing approximately 400 microamps
at valid input voltage levels. Since this “bus-hold” circuitry is
active and not a “resistive” type element, the associated
power supply current is negligible, and power dissipation is
significantly reduced when compared to the use of passive
pull-up resistors.
BOND
PAD
The I/O address space contains 64K addresses in both
modes. The I/O space is accessible as either bytes or words,
as is memory. Byte wide peripheral devices may be attached
to either the upper or lower byte of the data bus. Byte-wide I/O
devices attached to the upper data byte (D15-8) are accessed
with odd I/O addresses. Devices on the lower data byte are
accessed with even I/O addresses. An interrupt controller
such as Intersil's 82C59A must be connected to the lower
data byte (D7-0) for proper return of the interrupt vector.
Bus Operation
The 80C286 uses a double frequency system clock (CLK
input) to control bus timing. All signals on the local bus are
measured relative to the system CLK input. The CPU divides
the system clock by 2 to produce the internal processor
clock, which determines bus state. Each processor clock is
composed of two system clock cycles named phase 1 and
phase 2. The 82C284 clock generator output (PCLK) identifies the next phase of the processor clock. (See Figure 20.)
EXTERNAL
PIN
OUTPUT
DRIVER
INPUT
DRIVER
INPUT
PROTECTION
CIRCUITRY
ONE PROCESSOR CLOCK CYCLE
FIGURE 19A. BUS HOLD CIRCUITRY, PINS 36-51, 66, 67
ONE BUS T STATE
PHASE 1
OF PROCESSOR
CLOCK CYCLE
OUTPUT
DRIVER
CLK
BOND
PAD
VCC
INPUT
DRIVER
PHASE 2
OF PROCESSOR
CLOCK CYCLE
EXTERNAL
PIN
ONE SYSTEM
CLK CYCLE
P
PCLK
FIGURE 20. SYSTEM AND PROCESSOR CLOCK RELATIONSHIPS
Six types of bus operations are supported; memory read,
memory write, I/O read, I/O write, interrupt acknowledge,
and halt/shutdown. Data can be transferred at a maximum
rate of one word per two processor clock cycles.
INPUT
PROTECTION
CIRCUITRY
The 80C286 bus has three basic states: idle (TI), send status (TS), and perform command (TC). The 80C286 CPU also
has a fourth local bus state called hold (TH). TH indicates
that the 80C286 has surrendered control of the local bus to
another bus master in response to a HOLD request.
FIGURE 19B. BUS HOLD CIRCUITRY, PINS 4-6, 68
Physical Memory and I/O Interface
A maximum of 16 megabytes of physical memory can be
addressed in protected mode. One megabyte can be
addressed in real address mode. Memory is accessible as
bytes or words. Words consist of any two consecutive bytes
addressed with the least significant byte stored in the lowest
Each bus state is one processor clock long. Figure 21 shows
the four 80C286 local bus states and allowed transitions.
27
80C286
The address remains valid during phase 1 of the first TC to
guarantee hold time, relative to ALE, for the address latch
inputs.
RESET
HLDA
NEW CYCLE • HLDA
HLDA
HOLD
TH
Bus Control Signals
IDLE
TI
HLDA • NEW CYCLE
The 82C288 bus controller provides control signals; address
latch enable (ALE), Read/Write commands, data transmit/receive (DT/R), and data enable (DEN) that control the
address latches, data transceivers, write enable, and output
enable for memory and I/O systems.
READY • NEW CYCLE
NEW CYCLE
READY
HLDA • NEW CYCLE
ALWAYS
STATUS
TS
The Address Latch Enable (ALE) output determines when
the address may be latched. ALE provides at least one system CLK period of address hold time from the end of the previous bus operation until the address for the next bus
operation appears at the latch outputs. This address hold
time is required to support Multibus and common memory
systems.
COMMAND
TC
READY • NEW CYCLE
FIGURE 21. 80C286 BUS STATES
Bus States
The data bus transceivers are controlled by 82C288 outputs
Data Enable (DEN) and Data Transmit/Receive (DT/R). DEN
enables the data transceivers; while DT/R controls transceiver direction. DEN and DT/R are timed to prevent bus
contention between the bus master, data bus transceivers,
and system data bus transceivers.
The idle (TI) state indicates that no data transfers are in
progress or requested. The first active state TS is signaled
by status line S1 or S0 going LOW and identifying phase 1 of
the processor clock. During TS, the command encoding, the
address, and data (for a write operation) are available on the
80C286 output pins. The 82C288 bus controller decodes the
status signals and generates Multibus compatible read/write
command and local transceiver control signals.
Command Timing Controls
Two system timing customization options, command extension
and command delay, are provided on the 80C286 local bus.
After TS, the perform command (TC) state is entered. Memory or I/O devices respond to the bus operation during TC ,
either transferring read data to the CPU or accepting write
data. TC states may be repeated as often as necessary to
ensure sufficient time for the memory or I/O device to
respond. The READY signal determines whether TC is
repeated. A repeated TC state is called a wait state.
Command extension allows additional time for external
devices to respond to a command and is analogous to
inserting wait states on the 80C86. External logic can control
the duration of any bus operation such that the operation is
only as long as necessary. The READY input signal can
extend any bus operation for as long as necessary.
During hold (TH), the 80C286 will float all address, data, and
status output drivers enabling another bus master to use the
local bus. The 80C286 HOLD input signal is used to place
the 80C286 into the TH state. The 80C286 HLDA output signal indicates that the CPU has entered TH.
Command delay allows an increase of address or write data
setup time to system bus command active for any bus operation by delaying when the system bus command becomes
active. Command delay is controlled by the 82C288 CMDLY
input. After TS, the bus controller samples CMDLY at each
failing edge of CLK. If CMDLY is HIGH, the 82C288 will not
activate the command signal. When CMDLY is LOW, the
82C288 will activate the command signal. After the command becomes active, the CMDLY input is not sampled.
Pipelined Addressing
The 80C286 uses a local bus interface with pipelined timing
to allow as much time as possible for data access. Pipelined
timing allows a new bus operation to be initiated every two
processor cycles, while allowing each individual bus operation to last for three processor cycles.
When a command is delayed, the available response time
from command active to return read data or accept write
data is less. To customize system bus timing, an address
decoder can determine which bus operations require delaying the command. The CMDLY input does not affect the timing of ALE, DEN or DT/R.
The timing of the address outputs is pipelined such that the
address of the next bus operation becomes available during
the current bus operation. Or, in other words, the first clock of
the next bus operation is overlapped with the last clock of the
current bus operation. Therefore, address decode and routing
logic can operate in advance of the next bus operation.
Figure 23 illustrates four uses of CMDLY. Example 1 shows
delaying the read command two system CLKs for cycle N-1
and no delay for cycle N, and example 2 shows delaying the
read command one system CLK for cycle N-1 and one system CLK delay for cycle N.
External address latches may hold the address stable for the
entire bus operation, and provide additional AC and DC buffering.
The 80C286 does not maintain the address of the current bus
operation during all TC states. Instead, the address for the
next bus operation may be emitted during phase 2 of any TC .
28
80C286
READ BUS CYCLE N
TI
TS
φ1
READ BUS CYCLE N + 1
TC
φ2
φ1
TS
φ2
φ1
TC
φ2
φ1
φ2
CLK
PROC
CLK
2 PCLK CYCLE TRANSFER
2 PCLK CYCLE TRANSFER
2.5 CLOCK CYCLE ADDRESS TO DATA VALID
A23 - A0
VALID ADDR (N)
VALID ADDR (N + 1)
S0 • S1
READY
D15 - D0
VALID READ
DATA (N)
PIPELINING: VALID ADDRESS (N + 1) AVAILABLE IN LAST PHASE OF BUS CYCLE (N).
FIGURE 22. BASIC BUS CYCLE
29
VALID READ
DATA (N + 1)
80C286
READ CYCLE N -1
TS
φ1
READ CYCLE N
TC
φ2
φ1
TC
φ2
φ1
TS
φ2
φ1
TC
φ2
φ1
φ2
CLK
PROC
CLK
A23 - A0
VALID ADDR N
VALID ADDR (N-1)
S1 • S0
ALE
READY
RD
EX1
CMDLY
RD
EX2
CMDLY
FIGURE 23. CMDLY CONTROLS THE LEADING EDGE OF COMMAND SIGNAL
Bus Cycle Termination
the end of phase 1 of each TC. The state of SRDY is then
broadcast to the bus master and bus controller via the
READY output line.
At maximum transfer rates, the 80C286 bus alternates
between the status and command states. The bus status
signals become inactive after TS so that they may correctly
signal the start of the next bus operation after the completion
of the current cycle. No external indication of TC exists on
the 80C286 local bus. The bus master and bus controller
enter TC directly after TS and continue executing TC cycles
until terminated by the assertion of READY.
Asynchronous Ready
Many systems have devices or subsystems that are asynchronous to the system clock. As a result, their ready outputs cannot be guaranteed to meet the 82C284 SRDY setup
and hold time requirements. But the 82C284 asynchronous
ready input (ARDY) is designed to accept such signals. The
ARDY input is sampled at the beginning of each TC cycle by
82C284 synchronization logic. This provides one system
CLK cycle time to resolve its value before broadcasting it to
the bus master and bus controller.
READY Operation
The current bus master and 82C288 bus controller terminate
each bus operation simultaneously to achieve maximum bus
operation bandwidth. Both are informed in advance by
READY active (open-collector output from 82C284) which
identifies the last TC cycle of the current bus operation. The
bus master and bus controller must see the same sense of
the READY signal, thereby requiring READY to be synchronous to the system clock.
ARDY or ARDYEN must be HIGH at the end of TS. ARDY
cannot be used to terminate the bus cycle with no wait
states.
Each ready input of the 82C284 has an enable pin
(SRDYEN and ARDYEN) to select whether the current bus
operation will be terminated by the synchronous or asynchronous ready. Either of the ready inputs may terminate a
bus operation. These enable inputs are active low and have
the same timing as their respective ready inputs. Address
decode logic usually selects whether the current bus operation should be terminated by ARDY or SRDY.
Synchronous Ready
The 82C284 clock generator provides READY synchronization from both synchronous and asynchronous sources (see
Figure 24). The synchronous ready input (SRDY) of the
clock generator is sampled with the falling edge of CLK at
30
80C286
Data Bus Control
The CPU asserts an active lock signal during InterruptAcknowledge cycles, the XCHG instruction, and during
some descriptor accesses. Lock is also asserted when the
LOCK prefix is used. The LOCK prefix may be used with
the following ASM-286 assembly instructions; MOVS, INS
and OUTS. For bus cycles other than Interrupt-Acknowledge cycles, Lock will be active for the first and subsequent
cycles of a series of cycles to be locked. Lock will not be
shown active during the last cycle to be locked. For the
next-to-last cycle, Lock will become inactive at the end of
the first TC regardless of the number of wait states
inserted. For Interrupt-Acknowledge cycles, Lock will be
active for each cycle, and will become inactive at the end of
the first TC for each cycle regardless of the number of waitstates inserted.
Figures 25, 26, and 27 show how the DT/R, DEN, data bus,
and address signals operate for different combinations of
read, write, and idle bus operations. DT/R goes active
(LOW) for a read operation. DT/R remains HIGH before, during, and between write operations.
The data bus is driven with write data during the second
phase of TS . The delay in write data timing allows the read
data drivers, from a previous read cycle, sufficient time to
enter three-state OFF before the 80C286 CPU begins driving the local data bus for write operations. Write data will
always remain valid for one system clock past the last TC to
provide sufficient hold time for Multibus or other similar
memory or I/O systems. During write-read or write-idle
sequences the data bus enters a high impedance state during the second phase of the processor cycle after the last
TC . In a write-write sequence the data bus does not enter a
high impedance state between TC and TS.
Instruction Fetching
The 80C286 Bus Unit (BU) will fetch instructions ahead of
the current instruction being executed. This activity is called
prefetching. It occurs when the local bus would otherwise be
idle and obeys the following rules:
Bus Usage
The 80C286 local bus may be used for several functions:
instruction data transfers, data transfers by other bus masters, instruction fetching, processor extension data transfers, interrupt acknowledge, and halt/shutdown. This
section describes local bus activities which have special
signals or requirements. Note that I/O transfers take place
in exactly the same manner as memory transfers (i.e. to the
80C286 the timing, etc. of an I/O transfer is identical to a
memory transfer).
A prefetch bus operation starts when at least two bytes of
the 6-byte prefetch queue are empty.
The prefetcher normally performs word prefetches independent of the byte alignment of the code segment base in
physical memory.
The prefetcher will perform only a byte code fetch operation
for control transfers to an instruction beginning on a numerically odd physical address.
HOLD and HLDA
Prefetching stops whenever a control transfer or HLT
instruction is decoded by the lU and placed into the instruction queue.
HOLD and HLDA allow another bus master to gain control of
the local bus by placing the 80C286 bus into the TH state. The
sequence of events required to pass control between the
80C286 and another local bus master are shown in Figure 28.
In real address mode, the prefetcher may fetch up to 6 bytes
beyond the last control transfer or HLT instruction in a code
segment.
In this example, the 80C286 is initially in the TH state as
signaled by HLDA being active. Upon leaving TH, as signaled by HLDA going inactive, a write operation is started.
During the write operation another local bus master
requests the local bus from the 80C286 as shown by the
HOLD signal. After completing the write operation, the
80C286 performs one TI bus cycle, to guarantee write data
hold time, then enters TH as signaled by HLDA going
active.
In protected mode, the prefetcher will never cause a segment overrun exception. The prefetcher stops at the last
physical memory word of the code segment. Exception 13
will occur if the program attempts to execute beyond the last
full instruction in the code segment.
If the last byte of a code segment appears on an even physical memory address, the prefetcher will read the next physical byte of memory (perform a word code fetch). The value
of this byte is ignored and any attempt to execute it causes
exception 13.
The CMDLY signal and ARDY ready are used to start and
stop the write bus command, respectively. Note that SRDY
must be inactive or disabled by SRDYEN to guarantee
ARDY will terminate the cycle.
HOLD must not be active during the time from the leading
edge of RESET until 34 CLKs following the trailing edge of
RESET unless the 80C286 is in the Halt condition. To
ensure that the 80C286 remains in the Halt condition until
the processor Reset operation is complete, no interrupts
should occur after the execution of HLT until 34 CLKs after
the trailing edge of the RESET pulse.
LOCK
31
80C286
MEMORY CYCLE N - 1
TS
φ1
MEMORY CYCLE N
TC
φ2
φ1
TS
φ2
φ1
TC
φ2
φ1
TC
φ1
φ2
φ2
CLK
PROC
CLK
A23 - A0
VALID ADDR
VALID ADDR
VALID ADDR
S0 • S1
SRDY
READY
(SEE NOTE 9)
(SEE NOTE 8)
ARDY
(SEE NOTE 10)
NOTES:
8. SRDYEN is active low.
9. If SRDYEN is high, the state of SRDY will not effect READY.
10. ARDYEN is active low.
FIGURE 24. SYNCHRONOUS AND ASYNCHRONOUS READY
32
80C286
READ CYCLE
TI
TS
φ2
φ1
WRITE CYCLE
TC
φ2
φ1
TS
φ2
φ1
TC
φ2
φ1
TI
φ2
φ1
CLK
A23 - A0
VALID ADDR
VALID ADDR
S0 • S1
D15 - D0
VALID WRITE DATA
VALID
READ DATA
MRDC
MWTC
DEN
DT/R
FIGURE 25. BACK TO BACK READ-WRITE CYCLE
33
φ2
80C286
WRITE CYCLE
TI
READ CYCLE
TS
φ2
φ1
TC
φ2
φ1
TS
φ2
φ1
TC
φ2
φ1
TI
φ2
φ1
φ2
CLK
A23 - A0
VALID
VALID
S0 • S1
VALID
READ DATA
VALID WRITE DATA
D15 - D0
MRDC
MWTC
DEN
DT/R
FIGURE 26. BACK TO BACK WRITE-READ CYCLE
WRITE CYCLE N-1
TI
TS
φ2
φ1
WRITE CYCLE N
TC
φ2
φ1
TS
φ2
φ1
TC
φ2
φ1
TI
φ2
φ1
φ2
CLK
A23 - A0
VALID ADDR N-1
VALID ADDR N
S0 • S1
D15 - D0
VALID DATA N-1
VALID DATA N
MWTC
DEN
(HIGH)
DT/R
FIGURE 27. BACK TO BACK WRITE-WRITE CYCLE
Processor Extension Transfers
34
80C286
The Master Cascade Enable (MCE) signal of the 82C288 is
used to enable the cascade address drivers during INTA bus
operations (See Figure 29) onto the local address bus for
distribution to slave interrupt controllers via the system
address bus. The 80C286 emits the LOCK signal (active
LOW) during TS of the first INTA bus operation. A local bus
“hold” request will not be honored until the end of the second
INTA bus operation.
The processor extension interface uses I/O port addresses
00F8(H), and 00FC(H) which are part of the I/O port address
range reserved by Intersil. An ESC instruction with Machine
Status Word bits EM = 0 and TS = 0 will perform I/O bus
operations to one or more of these I/O port addresses independent of the value of lOPL and CPL.
ESC instructions with memory references enable the CPU to
accept PEREQ inputs for processor extension operand
transfers. The CPU will determine the operand starting
address and read/write status of the instruction. For each
operand transfer, two or three bus operations are performed,
one word transfer with I/O port address 00FA(H) and one or
two bus operations with memory. Three bus operations are
required for each word operand aligned on an odd byte
address.
Three idle processor clocks are provided by the 80C286
between INTA bus operations to allow for the minimum INTA
to INTA time and CAS (cascade address) out delay of the
82C59A. The second INTA bus operation must always have
at least one extra TC state added via logic controlling
READY. A23-A0 are in three-state OFF until after the first TC
state of the second INTA bus operation. This prevents bus
contention between the cascade address drivers and CPU
address drivers. The extra TC state allows time for the
80C286 to resume driving the address lines for subsequent
bus operations.
Interrupt Acknowledge Sequence
Figure 29 illustrates an interrupt acknowledge sequence performed by the 80C286 in response to an INTR input. An
interrupt acknowledge sequence consists of two INTA bus
operations. The first allows a master 82C59A Programmable
Interrupt Controller (PlC) to determine which if any of its
slaves should return the interrupt vector. An eight bit vector
is read on D0-D7 of the 80C286 during the second INTA bus
operation to select an interrupt handler routine from the
interrupt table.
35
80C286
BUS HOLD ACKNOWLEDGE
BUS CYCLE TYPE
TH
φ1
TH
φ2
φ1
TS
TH
φ2
φ1
BUS HOLD
ACKNOWLEDGE
WRITE CYCLE
φ2
φ1
TC
φ2
φ1
TC
φ2
φ1
TC
φ2
φ1
TI
φ2
φ1
TH
φ2
φ1
φ2
CLK
(SEE NOTE 15)
(SEE NOTE 14)
HOLD
(SEE NOTE 16)
HLDA
(SEE NOTE 11)
80C286
(SEE NOTE 11)
S1 • S0
(SEE NOTE 12)
A23 - A0
M/IO,
COD/INTA
VALID
(SEE NOTE 13)
BHE, LOCK
VALID
80C284
D15 - D0
VALID
SRDY +
SRDYEN
NOT READY NOT READY (SEE NOTE 17)
ARDY +
ARDYEN
NOT READY NOT READY
READY
CMDLY
DELAY ENABLE
(SEE NOTE 17)
80C288
MWTC
VOH
DT/R
DEN
ALE
TS - STATUS CYCLE
TC - COMMAND CYCLE
NOTES:
11. Status lines are held at a high impedance logic one by the 80C286 during a HOLD state.
12. Address, M/IO and COD/lNTA may start floating during any TC depending on when internal 80C286 bus arbiter decides to release bus
to external HOLD. The float starts in φ2 of TC.
13. BHE and LOCK may start floating after the end of any TC depending on when internal 80C286 bus arbiter decides to release bus to
external HOLD. The float starts in φ1 of TC.
14. The minimum HOLD to HLDA time is shown. Maximum is one TH longer.
15. The earliest HOLD time is shown. It will always allow a subsequent memory cycle if pending is shown.
16. The minimum HOLD to HLDA time is shown. Maximum is a function of the instruction, type of bus cycle and other machine state (i.e.,
Interrupts, Waits, Lock, etc.).
17. Asynchronous ready allows termination of the cycle. Synchronous ready does not signal ready in this example. Synchronous ready state
is ignored after ready is signaled via the asynchronous input.
FIGURE 28. MULTIBUS WRITE TERMINATED BY ASYNCHRONOUS READY WITH BUS HOLD
36
80C286
Local Bus Usage Priorities
System Configurations
The 80C286 local bus is shared among several internal units
and external HOLD requests. In case of simultaneous
requests, their relative priorities are:
The versatile bus structure of the 80C286 micro-system, with
a full complement of support chips, allows flexible configuration of a wide range of systems. The basic configuration,
shown in Figure 30, is similar to an 80C86 maximum mode
system. It includes the CPU plus an 82C59A interrupt controller, 82C284 clock generator, and the 82C288 Bus Controller. The 80C86 latches (82C82 and 82C83H) and
transceivers (82C86H and 82C87H) may be used in an
80C286 microsystem.
(Highest) Any transfers which assert LOCK either explicitly (via the LOCK instruction prefix) or implicitly (i.e. some segment descriptor accesses, an
interrupt acknowledge sequence, or an XCHG
with memory).
The second of the two byte bus operations
required for an odd aligned word operand.
As indicated by the dashed lines in Figure 30, the ability to
add processor extensions is an integral feature of 80C286
based microsystems. The processor extension interface
allows external hardware to perform special functions and
transfer data concurrent with CPU execution of other instructions. Full system integrity is maintained because the
80C286 supervises all data transfers and instruction execution for the processor extension.
The second or third cycle of a processor extension data transfer.
Local bus request via HOLD input.
Processor extension data operand transfer via
PEREQ input.
An 80C286 system which includes the 80287 numeric processor extension (NPX) uses this interface. The 80C286/80287
system has all the instructions and data types of an 80C86 or
80C88 with 8087 numeric processor extension. The 80287
NPX can perform numeric calculations and data transfers
concurrently with CPU program execution. Numerics code
and data have the same integrity as all other information protected by the 80C286 protection mechanism.
Data transfer performed by EU as part of an
instruction.
(Lowest)
An instruction prefetch request from BU. The
EU will inhibit prefetching two processor clocks
in advance of any data transfers to minimize
waiting by the EU for a prefetch to finish.
Halt or Shutdown Cycles
The 80C286 can overlap chip select decoding and address
propagation during the data transfer for the previous bus
operation. This information is latched into the 82C82/83H's
by ALE during the middle of a TS cycle. The latched chip
select and address information remains stable during the
bus operation while the next cycle's address is being
decoded and propagated into the system. Decode logic can
be implemented with a high speed PROM or PAL.
The 80C286 externally indicates halt or shutdown conditions
as a bus operation. These conditions occur due to a HLT
instruction or multiple protection exceptions while attempting
to execute one instruction. A halt or shutdown bus operation
is signalled when S1, S0 and COD/lNTA are LOW and M/IO
is HIGH. A1 HIGH indicates halt, and A1 LOW indicates
shutdown. The 82C288 bus controller does not issue ALE,
nor is READY required to terminate a halt or shutdown bus
operation.
The optional decode logic shown in Figure 30 takes advantage of the overlap between address and data of the 80C286
bus cycle to generate advanced memory and I/O select signals. This minimizes system performance degradation
caused by address propagation and decode delays. In addition to selecting memory and I/O, the advanced selects may
be used with configurations supporting local and system
buses to enable the appropriate bus interface for each bus
cycle. The COD/lNTA and M/IO signals are applied to the
decode logic to distinguish between interrupt, I/O, code, and
data bus cycles.
During halt or shutdown, the 80C286 may service PEREQ or
HOLD requests. A processor extension segment overrun
during shutdown will inhibit further service of PEREQ. Either
NMl or RESET will force the 80C286 out of either halt or
shutdown. An INTR, if interrupts are enabled, or a processor
extension segment overrun exception will also force the
80C286 out of halt.
By adding the 82289 bus arbiter chip the 80C286 provides a
Multibus system bus interface as shown in Figure 31. The
ALE output of the 82C288 for the Multibus bus is connected to
its CMDLY input to delay the start of commands one system
CLK as required to meet Multibus address and write data
setup times. This arrangement will add at least one extra TC
state to each bus operation which uses the Multibus.
A second 82C288 bus controller and additional latches and
transceivers could be added to the local bus of Figure 31.
This configuration allows the 80C286 to support an on-board
bus for local memory and peripherals, and the Multibus for
system bus interfacing.
37
80C286
INTA CYCLE 1
BUS CYCLE
TYPE
TS
TC
φ1
φ2
φ1
TC
TC
φ2
φ1
INTA CYCLE 2
φ2
φ1
TI
φ2
φ1
TI
TI
φ2
φ1
φ2
φ1
TS
φ2
φ1
TC
TC
φ2
φ1
φ2
φ1
TS
φ2
φ1
φ2
CLK
S1 • S0
M/IO,
COD/INTA
(SEE NOTE 21)
80C286
LOCK
(SEE NOTE 22)
(SEE NOTE 22)
DON’T CARE
A23 - A0
DON’T CARE
BHE
D15 - D0
(SEE NOTE 18)
PREVIOUS
WRITE CYCLE
VECTOR
(SEE NOTE 19)
(SEE NOTE 20)
READY
NOT READY
READY
NOT READY READY
INTA
82C288
MCE
ALE
DT/R
DEN
NOTES:
18. Data is ignored.
19. First INTA cycle should have at least one wait state inserted to meet 82C59A minimum INTA pulse width.
20. Second INTA cycle must have at least one wait state inserted since the CPA will not drive A23-A0, BHE, and LOCK until after the first TC
state. The CPU imposed one/clock delay prevents has contention between cascade address buffer being disabled by MCE ↓ and address
outputs.
21. Without the wait state, the 80C286 address will not be valid for a memory cycle started immediately after the second INTA cycle. The
82C59A also requires one wait state for minimum INTA pulse width.
22. LOCK is active for the first INTA cycle to prevent the 82289 from releasing the bus between INTA cycles in a multi-master system. LOCK
is also active for the second INTA cycle.
23. A23-A0 exits three-state OFF during φ2 of the second TC in the INTA cycle.
FIGURE 29. INTERRUPT ACKNOWLEDGE SEQUENCE
38
SYNC READY
ENABLE
ASYNC READY
ENABLE
RESET
VCC
39
PROCESSOR
EXTENSION
(OPTIONAL)
82C284
CLOCK
GENERATOR
SHDY RESET
SRDYEN
ARDY
ARDYEN
X1
S0
RES
S1
READY
PCLK
CLK
EFI
F/C
X2
VCC
M/IO
MRDC
MWTC
IORC
IOWC
INTA
ALE
MCE
DEN
DT/R
M/IO
LOCK
CLK
COD/INTA
READY
S1
A23 - A0
S0
NMI
BHE
HOLD
HLDA
ERROR
INTR
BUSY
PEACK
PEREQ
80C286
CPU
D15 - D0
RESET
S0
S1
READY
CLK
CMDLY
AEN
MB
82C288 BUS
CONTROLLER
A0
FIGURE 30. BASIC 80C286 SYSTEM CONFIGURATION
OE
82C86H
OR 82C87H
TRANSCEIVER
T
CS
INT
INTA
WR
RD
SP/EN
D0 - D7
82C59A
INTERRUPT
CONTROLLER
CAS0-2
82C82 OR
82C83H
LATCH
STB
OE
DECODE
(OPTIONAL)
DATA BUS
IR0 - IR7
CHIP SELECT
ADDRESS BUS
ADVANCED MEMORY
AND I/O CHIP SELECTS
MEMORY READ
MEMORY WRITE
I/O READ
I/O WRITE
INTERRUPT ACKNOWLEDGE
80C286
SYNC READY
ENABLE
ASYNC READY
ENABLE
RESET
VCC
S0
S1
READY
CLK
X1
40
FIGURE 31. MULTIBUS SYSTEM BUS INTERFACE
PROCESSOR
EXTENSION
(OPTIONAL)
82C284
CLOCK
GENERATOR
SRDY
RESET
SRDYEN
ARDY
ARDYEN
PCLK
EFI
F/C
RES
X2
VCC
VCC
RESET M/IO
LOCK
CLK
COD/INTA
READY
A23 - A0
S1
S0
BHE
NMI
HOLD
HLDA
ERROR
INTR
BUSY
PEACK
PEREQ
80C286
CPU
D15 - D0
MRDC
MWTC
IORC
CMDLY
IOWC
INTA
ALE
S0
MCE
S1
DEN
READY
CLK 82C288 DT/R
BUS CONTROLLER
M/IO
AEN
SYSB/RESB
BCLK
INIT
RESET
CBRQ
BREQ
ALWAYS BPRO
CBQLCK BPRN
S0
BUSY
S1
CBRQ
READY
LOCK
CLK
AEN
M/IO
82289
BUS ARBITER
MULTIBUS
BUS ARBITRATION
A0
CS
T
OE
82C87H
TRANSCEIVER
82C59A
INTERRUPT
CONTROLLER
D0 - D7
CAS0-2
INT
INTA
WR
RD
SP/EN
82C83H
LATCH
STB
OE
DATA BUS
IR0 - IR7
CHIP SELECT
ADDRESS BUS
MEMORY READ
MEMORY WRITE
I/O READ
I/O WRITE
INTERRUPT ACKNOWLEDGE
80C286
80C286
/
Absolute Maximum Ratings
Thermal Information
Supply Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ±8.0V
Input, Output or I/O Voltage Applied. . . . . GND -1.0V to VCC +1.0V
Storage Temperature Range . . . . . . . . . . . . . . . . . -65oC to +150oC
Junction Temperature, PGA . . . . . . . . . . . . . . . . . . . . . . . . . +175oC
PLCC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . +150oC
Lead Temperature (Soldering, 10s) . . . . . . . . . . . . . . . . . . . +300oC
(PLCC - Lead Tips Only)
Thermal Resistance (Typical)
θJA (oC/W)
θJC (oC/W)
PDIP Package . . . . . . . . . . . . . . . . . . .
35
6
CERDIP Package . . . . . . . . . . . . . . . .
33
9
Maximum Package Power Dissipation
PGA Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1.22W
PLCC Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.2W
Gate Count . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .22,500
CAUTION: Stresses above those listed in “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress only rating and operation
of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied.
Operating Conditions
Operating Temperature Range
I80C286-10, -12, -16, -20 . . . . . . . . . . . . . . . . . . -40oC to +85oC
C80C286-12, -16, -20, -25. . . . . . . . . . . . . . . . . . . . 0oC to +70oC
Operating Voltage Range
80C286-10, -12 . . . . . . . . . . . . . . . . . . . . . . . . . . . +4.5V to +5.5V
80C286-16, -20, -25 . . . . . . . . . . . . . . . . . . . . . +4.75V to +5.25V
DC Electrical Specifications VCC = +5V ± 10%, TA = 0oC to +70oC (C80C286-12), VCC = +5V ± 5%, TA = 0oC to +70oC
(C80C286-16, -20, -25), VCC = +5V ± 10%, TA = -40oC to +85oC (I80C286-10, -12), VCC = +5V ± 5%,
TA = -40oC to +85oC (I80C286-16, -20)
SYMBOL
PARAMETER
MIN
MAX
UNITS
TEST CONDITIONS
VIL
Input LOW Voltage
-0.5
0.8
V
VIH
Input HIGH Voltage
2.0
VCC +0.5
V
VILC
CLK Input LOW Voltage
-0.5
1.0
V
VIHC
CLK Input HIGH Voltage
3.6
VCC +0.5
V
VOL
Output LOW Voltage
-
0.4
V
IOL = 2.0mA
VOH
Output HIGH Voltage
3.0
VCC -0.4
-
V
IOH = -2.0mA, IOH = -100μA
II
Input Leakage Current
-10
10
μA
VIN = GND or VCC
Pins 29, 31, 57, 59, 61, 63-64
ISH
Input Sustaining Current on BUSY and
ERROR Pins
-30
-500
μA
VIN = GND (See Note 28)
IBHL
Input Sustaining Current LOW
38
200
μA
VIN = 1.0V (See Note 24)
IBHH
Input Sustaining Current HIGH
-50
-400
μA
VIN = 3.0V (See Note 25)
Output Leakage Current
-10
10
μA
VO = GND or VCC
Pins 1, 7-8, 10-28, 32-34
-
185
mA
80C286-10 (See Note 27)
-
220
mA
80C286-12 (See Note 27)
-
260
mA
80C286-16 (See Note 27)
-
310
mA
80C286-20 (See Note 27)
-
410
mA
80C286-25 (See Note 27)
-
5
mA
(See Note 26)
IO
ICCOP
ICCSB
Active Power Supply Current
Standby Power Supply Current
Capacitance TA = +25oC, All Measurements Referenced to Device GND
SYMBOL
PARAMETER
TYP
UNITS
10
pF
CCLK
CLK Input Capacitance
CIN
Other Input Capacitance
10
pF
CI/O
I/O Capacitance
10
pF
TEST CONDITIONS
FREQ = 1MHz
NOTES:
24. IBHL should be measured after lowering VIN to GND and then raising to 1.0V on the following pins: 36-51, 66, 67.
25. IBHH should be measured after raising VIN to VCC and then lowering to 3.0V on the following pins: 4-6, 36-51, 66-68.
26. ICCSB tested with the clock stopped in phase two of the processor clock cycle. VIN = VCC or GND, VCC = VCC (Max), outputs unloaded.
27. ICCOP measured at 10MHz for the 80C286-10, 12.5MHz for the 80C286-12, 16MHz for the 80C286-16, 20MHz for the 80C286-20, and
25MHz for the 80C286-25. VIN = 2.4V or 0.4V, VCC = VCC (Max), outputs unloaded.
28. ISH should be measured after raising VIN to VCC and then lowering to GND on pins 53 and 54.
41
80C286
AC Electrical Specifications VCC = +5V ±10%, TA = 0oC to +70oC (C80C286-12), TA = -40oC to +85oC (I80C286-10, -12)
VCC = +5V ±5%, TA = 0oC to +70oC (C80C286-16), TA = -40oC to +85oC (I80C286-16) AC Timings
are Referenced to 0.8V and 2.0V Points of the Signals as Illustrated in Data Sheet Waveforms,
Unless Otherwise Specified
10MHz
SYMBOL
PARAMETER
12.5MHz
16MHz
MIN
MAX
MIN
MAX
MIN
MAX
UNIT
TEST
CONDITION
TIMING REQUIREMENTS
1
System Clock (CLK) Period
50
-
40
-
31
-
ns
2
System Clock (CLK) LOW Time
12
-
11
-
7
-
ns
At 1.0V
3
System Clock (CLK) HIGH Time
16
-
13
-
11
-
ns
At 3.6V
17
System Clock (CLK) RISE Time
-
8
-
8
-
5
ns
1.0V to 3.6V
18
System Clock (CLK) FALL Time
-
8
-
8
-
5
ns
3.6V to 1.0V
4
Asynchronous Inputs SETUP Time
20
-
15
-
5
-
ns
(Note 29)
5
Asynchronous Inputs HOLD Time
20
-
15
-
5
-
ns
(Note 29)
6
RESET SETUP Time
19
-
10
-
10
-
ns
7
RESET HOLD Time
0
-
0
-
0
-
ns
8
Read Data SETUP Time
8
-
5
-
5
-
ns
9
Read Data HOLD Time
4
-
4
-
3
-
ns
10
READY SETUP Time
26
-
20
-
12
-
ns
11
READY HOLD Time
25
-
20
-
5
-
ns
20
Input RISE/FALL Times
-
10
-
8
-
6
ns
0.8V to 2.0V
TIMING RESPONSES
12A
Status/PEACK Active Delay
1
22
1
21
1
18
ns
1, (Notes 31, 35)
12B
Status/PEACK Inactive Delay
1
30
1
24
1
20
ns
1, (Notes 31, 34)
13
Address Valid Delay
1
35
1
32
1
27
ns
1, (Notes 30, 31)
14
Write Data Valid Delay
0
40
0
31
0
28
ns
1, (Notes 30, 31)
15
Address/Status/Data Float Delay
0
47
0
32
0
29
ns
2, (Note 33)
16
HLDA Valid Delay
0
47
0
25
0
25
ns
1, (Notes 31, 36)
19
Address Valid to Status SETUP Time
27
-
22
-
16
-
ns
1, (Notes 31, 32)
NOTES:
29. Asynchronous inputs are INTR, NMl, HOLD, PEREQ, ERROR, and BUSY. This specification is given only for testing purposes, to assure
recognition at a specific CLK edge.
30. Delay from 1.0V on the CLK to 0.8V or 2.0V.
31. Output load: CL = 100pF.
32. Delay measured from address either reaching 0.8V or 2.0V (valid) to status going active reaching 0.8V or status going inactive reaching
2.0V.
33. Delay from 1.0V on the CLK to Float (no current drive) condition.
34. Delay from 1.0V on the CLK to 0.8V for min. (HOLD time) and to 2.0V for max. (inactive delay).
35. Delay from 1.0V on the CLK to 2.0V for min. (HOLD time) and to 0.8V for max. (active delay).
36. Delay from 1.0V on the CLK to 2.0V.
AC Test Conditions
TEST CONDITION
IL (CONSTANT CURRENT SOURCE)
CL
1
|2.0mA|
100pF
2
-6mA (VOH to Float)
8mA (VOL to Float)
100pF
42
80C286
AC Electrical Specifications VCC = +5V ±5%, TA = 0oC to +70oC (C80C286-20, -25), TA = -40oC to +85oC (l80C286-20)
AC Timings are Referenced to the 1.5V Point of the Signals as Illustrated in Data Sheet Waveforms,
Unless Otherwise Specified
20MHz
SYMBOL
PARAMETER
25MHz
MIN
MAX
MIN
MAX
UNIT
TEST CONDITION
TIMING REQUIREMENTS
1
System Clock (CLK) Period
25
-
20
-
ns
2
System Clock (CLK) LOW Time
6
-
5
-
ns
At 1.0V
3
System Clock (CLK) HIGH Time
9
-
7
-
ns
At 3.6V
17
System Clock (CLK) RISE Time
-
4
-
4
ns
1.0V to 3.6V
18
System Clock (CLK) FALL Time
-
4
-
4
ns
3.6V to 1.0V
4
Asynchronous Inputs SETUP Time
4
-
4
-
ns
(Note 37)
5
Asynchronous Inputs HOLD Time
4
-
4
-
ns
(Note 37)
6
RESET SETUP Time
10
-
10
-
ns
7
RESET HOLD Time
0
-
0
-
ns
8
Read Data SETUP Time
3
-
3
-
ns
9
Read Data HOLD Time
2
-
2
-
ns
10
READY SETUP Time
10
-
9
-
ns
11
READY HOLD Time
3
-
3
-
ns
20
Input RISE/FALL Times
-
6
-
6
ns
0.8V to 2.0V
TIMING RESPONSES
12A
Status/PEACK Active Delay
1
15
1
12
ns
1, (Notes 39, 42)
12B
Status/PEACK Inactive Delay
1
16
1
13
ns
1, (Notes 39, 42)
13
Address Valid Delay
1
23
1
20
ns
1, (Notes 38, 39)
14
Write Data Valid Delay
0
27
0
24
ns
1, (Notes 38, 39)
15
Address/Status/Data Float Delay
0
25
0
24
ns
2, (Note 41)
16
HLDA Valid Delay
0
20
0
19
ns
1, (Notes 38, 39)
19
Address Valid to Status SETUP Time
9
-
12
-
ns
1, (Notes 39, 40)
NOTES:
37. Asynchronous inputs are INTR, NMl, HOLD, PEREQ, ERROR, and BUSY. This specification is given only for testing purposes, to assure
recognition at a specific CLK edge.
38. Delay from 1.0V on the CLK to 1.5V.
39. Output load: CL = 100pF.
40. Delay measured from address reaching 1.5V to status reaching 1.5V.
41. Delay from 1.0V on the CLK to Float (no current drive) condition.
42. Delay from 1.0V on the CLK to 1.5V.
AC Test Conditions
TEST CONDITION
IL (CONSTANT CURRENT SOURCE)
CL
1
|2.0mA|
100pF
2
-6mA (VOH to Float)
8mA (VOL to Float)
100pF
43
80C286
AC Specifications
(Continued)
C80C86-12, -16
I80C286-10, -12, -16
AC DRIVE AND MEASURE POINTS - CLK INPUT
4.0V
3.6V
3.6V
CLK INPUT
1.0V
1.0V
0.45V
4.0V
3.6V
3.6V
CLK INPUT
1.0V
1.0V
0.45V
tSETUP
tHOLD
2.4V
OTHER
DEVICE
INPUT
2.0V
2.0V
0.8V
0.8V
0.4V
tDELAY (MAX)
tDELAY (MAX)
2.0V
DEVICE
OUTPUT
0.8V
NOTE: For AC testing, input rise and fall times are driven at 1ns per volt.
FIGURE 32.
44
80C286
AC Specifications
(Continued)
C80C286-20, -25
I80C286-20
AC DRIVE AND MEASURE POINTS - CLK INPUT
4.0V
3.6V
3.6V
CLK INPUT
1.0V
1.0V
0.45V
4.0V
3.6V
3.6V
CLK INPUT
1.0V
1.0V
0.45V
tSETUP
tHOLD
2.4V
OTHER
DEVICE
INPUT
2.0V
2.0V
0.8V
0.8V
0.4V
tDELAY
DEVICE
OUTPUT
1.5V
NOTE: Typical Output Rise/Fall Time is 6ns. For AC testing, input rise and fall times are driven at 1ns per volt.
FIGURE 33.
45
80C286
AC Electrical Specifications 82C284 and 82C288 Timing Specifications are given for reference only and no guarantee is implied.
82C284 Timing
10MHz
SYMBOL
PARAMETER
12.5MHz
16MHz
MIN
MAX
MIN
MAX
MIN
MAX
UNIT
TEST
CONDITION
TIMING REQUIREMENTS
11
SRDY/SRDYEN Setup Time
15
-
15
-
10
-
ns
12
SRDY/SRDYEN Hold Time
2
-
2
-
1
-
ns
13
ARDY/ARDYEN Setup Time
5
-
5
-
3
-
ns
(Note 43)
14
ARDY/ARDYEN Hold Time
30
-
25
-
20
-
ns
(Note 43)
0
20
0
16
0
15
ns
CL = 75pF,
IOL = 5mA,
IOH = 1mA
TIMING RESPONSES
19
PCLK Delay
NOTE:
43. These times are given for testing purposes to ensure a predetermined action.
82C288 Timing
10MHz
SYMBOL
PARAMETER
12.5MHz
16MHz
MIN
MAX
MIN
MAX
MIN
MAX
UNIT
TEST
CONDITION
TIMING REQUIREMENTS
12
CMDLY Setup Time
15
-
15
-
10
-
ns
13
CMDLY Hold Time
1
-
1
-
0
-
ns
TIMING RESPONSES
16
ALE Active Delay
1
16
1
16
1
12
ns
17
ALE Inactive Delay
-
19
-
19
-
15
ns
19
DT/R Read Active Delay
-
23
-
23
-
18
ns
CL = 150pF
20
DEN Read Active Delay
-
21
-
21
-
16
ns
IOL = 16mA Max
21
DEN Read Inactive Delay
3
23
3
21
5
14
ns
IOL = 1mA Max
22
DT/R Read Inactive Delay
5
24
5
18
5
14
ns
23
DEN Write Active Delay
-
23
-
23
-
17
ns
24
DEN Write Inactive Delay
3
23
3
23
3
15
ns
29
Command Active Delay from CLK
3
21
3
21
3
15
ns
CL = 300pF
30
Command Inactive Delay from CLK
3
20
3
20
3
15
ns
IOL = 32mA Max
NOTE:
44. These times are given for testing purposes to ensure a predetermined action.
46
80C286
Waveforms
BUS
CYCLE TYPE
TI
3
VOH
READ CYCLE
WRITE CYCLE
ILLUSTRATED WITH ZERO
ILLUSTRATED WITH ONE
WAIT STATES
WAIT STATE
TS
TC
TS
TC
1
φ2
φ2
φ1
φ2
φ1
φ2
φ1
READ
(TS OR TS)
TC
φ2
φ1
φ2
φ1
CLK
VOL
2
12B
12A
S1 • S0
19
19
13
80C286
13
A23 - A0
M/IO, COD,
INTA
VALID ADDRESS
13
13
VALID CONTROL
VALID CONTROL
BHE, LOCK
VALID IF TS
VALID ADDRESS
9
14
8
15
VALID WRITE DATA
D15 - D0
VALID READ DATA
11
11
10
10
READY
12
11
SRDY + SRDYEN
82C284
19
14
13
ARDY + ARDYEN
19
19
16
17
20
PLCK
ALE
13
12
13
12
13
12
CMDLY
82C288
29
MWTC
(SEE NOTE 1)
30
29
30
MRDC
19
DT/R
22
20
21
23
DEN
FIGURE 34. MAJOR CYCLE TIMING
NOTE: The modified timing is due to the CMDLY signal being active.
47
24
80C286
Waveforms
(Continued)
VCH
BUS CYCLE TYPE
VCH
TX
φ1
φ2
19
TX
φ1
φ1
φ2
CLK
CLK
VCL
φ2
VCL
19
PCLK
(SEE NOTE 47)
(SEE NOTE 47)
7
6
RESET
5
4
VCH
INTR, NMI
HOLD, PEREQ
(SEE NOTE 45)
TX
φ2
φ1
φ1
CLK
4
5
VCL
ERROR, BUSY
(SEE NOTE 46)
(SEE NOTE 47)
7
6
RESET
FIGURE 36. 80C286 RESET INPUT TIMING AND SUBSEQUENT
PROCESSOR CYCLE PHASE
NOTE:
FIGURE 35. 80C286 ASYNCHRONOUS INPUT SIGNAL TIMING
NOTES:
45. PCLK indicates which processor cycle phase will occur on the
next CLK, PCLK may not indicate the correct phase until the first
cycle is performed.
47. When RESET meets the setup time shown, the next CLK will
start or repeat φ1 of a processor cycle.
46. These inputs are asynchronous. The setup and hold times
shown assure recognition for testing purposes.
48
80C286
Waveforms
(Continued)
BUS
CYCLE TYPE
VCH
TS OR TI
TH
φ2
φ1
φ1
φ2
φ1
TI
φ2
φ1
TH
φ2
CLK
VCL
HLDA
16
16
(SEE NOTE 51)
12A (SEE NOTE 50)
15
S1 • S0
IF TS
12B
80C286
(SEE NOTE 50)
15
CLK
BHE, LOCK
A23 - A0,
M/IO,
COD/INTA
IF NPX TRANSFER
(SEE NOTE 48)
15
13
(SEE NOTE 52)
VALID
(SEE NOTE 49)
14
D15 - D0
15
(SEE NOTE 53)
80C284
VALID IF WRITE
PCLK
FIGURE 37. EXITING AND ENTERING HOLD
NOTES:
48. These signals may not be driven by the 80C286 during the time shown. The worst case in terms of latest float time is shown.
49. The data bus will be driven as shown if the cycle before TI in the diagram was a write TC.
50. The 80C286 puts its status pins in a high impedance logic one state during TH.
51. For HOLD request set up to HLDA, refer to Figure 29.
52. BHE and LOCK are driven at this time but will not become valid until TS.
53. The data bus will remain in a high impedance state if a read cycle is performed.
49
80C286
Waveforms
(Continued)
BUS
CYCLE TYPE
VCH
TI
φ2
φ1
TS
φ2
1
TC
φ2
TS
φ1
φ2
φ1
TC
φ2
φ1
TI
CLK
VCL
I/O READ IF PROC. EXT. TO MEMORY
MEMORY READ IF MEMORY TO PROC. EXT.
MEMORY WRITE IF PROC. EXT. TO MEMORY
I/O WRITE IF MEMORY TO PROC. EXT.
S1 • S0
MEMORY ADDRESS IF PROC. EXT. TO MEMORY TRANSFER I/O PORT
ADDRESS 00FA(H) IF MEMORY TO PROC. EXT. TRANSFER
A23 - A0
M/IO,
COD INTA
12A
PEACK
I/O PORT ADDRESS 00FA(H) IF PROC. EXT. TO MEMORY TRANSFER
MEMORY ADDRESS IF MEMORY TO PROC. EXT. TRANSFER
12B
(SEE NOTE 54)
(SEE NOTE 55)
4
5
PEREQ
ASSUMING WORD-ALIGNED MEMORY OPERAND. IF ODD ALIGNED, 80C286 TRANSFERS TO/FROM MEMORY BYTE-AT-A-TIME WITH TWO MEMORY
CYCLES.
FIGURE 38. 80C286 PEREQ/PEACK TIMING FOR ONE TRANSFER ONLY
NOTES:
54. PEACK always goes active during the first bus operation of a processor extension data operand transfer sequence. The first bus operation will be either a memory read at operand address or I/O read at port address 00FA(H).
55. To prevent a second processor extension data operand transfer, the worst case maximum time (Shown above) is
3 x 1 - 12AMAX - 4 MIN. The actual configuration dependent, maximum time is: 3 x 1 - 12AMAX - 4 MIN + N x 2 x 1 . N is the
number of extra TC states added to either the first or second bus operation of the processor extension data operand transfer sequence.
BUS
CYCLE TYPE
VCH
TX
φ2
φ2
φ1
19
(SEE NOTE 56)
φ1
TX
φ2
φ1
TX
φ2
φ1
TI
φ2
CLK
VCL
RESET
S1 • S0
PEACK
A23 - A0
BHE
7
AT LEAST
16 CLK PERIODS
6
(SEE NOTE 57)
12B
UNKNOWN
13
UNKNOWN
13
M/IO
COD/INTA
UNKNOWN
13
LOCK
UNKNOWN
15
(SEE NOTE 58)
DATA
16
HLDA
UNKNOWN
FIGURE 39. INITIAL 80C286 PIN STATE DURING RESET
NOTES:
56. Setup time for RESET ↑ may be violated with the consideration that φ1 of the processor clock may begin one system CLK period later.
57. Setup and hold times for RESET ↓ must be met for proper operation, but RESET ↓ may occur during φ1 or φ2.
58. The data bus is only guaranteed to be in a high impedance state at the time shown.
50
80C286
Waveforms
(Continued)
BYTE 1
BYTE 3
BYTE 4
BYTE 5
BYTE 6
LOW DISP/DATA
HIGH DISP/DATA
LOW DATA
HIGH DATA
BYTE 2
7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
OPCODE
d w MOD
REG
R/M
REGISTER OPERAND REGISTERS TO USE IN OFFSET CALCULATION
REGISTER OPERAND/EXTENSION OF OPCODE
REGISTER MODE/MEMORY MODE WITH DISPLACEMENT LENGTH
WORD/BYTE OPERATION
DIRECTION IS TO REGISTER DIRECTION IS FROM REGISTER
OPERATION (INSTRUCTION) CODE
FIGURE 40A. SHORT OPCODE FORMAT EXAMPLE
BYTE 1
BYTE 2
BYTE 3
BYTE 4
BYTE 5
LOW DISP
HIGH DISP
7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0 7 6 5 4 3 2 1 0
LONG OPCODE
MOD
REG
R/M
FIGURE 40B. LONG OPCODE FORMAT EXAMPLE
FIGURE 40. 80C286 INSTRUCTION FORMAT EXAMPLES
80C286 Instruction Set Summary
Instruction Timing Notes
The instruction clock counts listed below establish the maximum execution rate of the 80C286. With no delays in bus
cycles, the actual clock count of an 80C286 program will
average 5% more than the calculated clock count, due to
instruction sequences which execute faster than they can be
fetched from memory.
Above/below refers to unsigned value.
To calculate elapsed times for instruction sequences, multiply the sum of all instruction clock counts, as listed in the
table below, by the processor clock period. An 12.5MHz processor clock has a clock period of 80 nanoseconds and
requires an 80C286 system clock (CLK input) of 25MHz.
if w = 1, then word instruction; if w = 0, then byte instruction
Instruction Clock Count Assumptions
x don’t care
Greater refers to more positive signed values.
Less refers to less positive (more negative) signed values
if d = 1, then “to” register; if d = 0 then “from” register
if s = 0, then 16-bit immediate data form the operand
if s = 1, then an immediate data byte is sign-extended to
form the 16-bit operand
z used for string primitives for comparison with ZF FLAG
1. The instruction has been perfected, decoded and is
ready for execution. Control transfer instruction clock
counts include all time required to fetch, decode, and
prepare the next instruction for execution.
If two clock counts are given, the smaller refers to a register
operand and the larger refers to a memory operand
2. Bus cycles do not require wait states.
* = add one clock if offset calculation requires summing 3
elements
3. There are no processor extension data transfer or local
bus HOLD requests.
n = number of times repeated
m = number of bytes of code in next instruction
4. No exceptions occur during instruction execution.
Level (L) - Lexical nesting level of the procedure
Instruction Set Summary Notes
The following comments describe possible exceptions, side
effects and allowed usage for instructions in both operating
modes of the 80C286.
Addressing displacements selected by the MOD field are not
shown. If necessary they appear after the instruction fields
shown.
51
80C286
Real Address Mode Only
1. This is a protected mode instruction. Attempted execution in real address mode will result in an undefined
opcode exception (6).
segment not-present violation occurs, a stack exception
(12) occurs.
11. All segment descriptor accesses in the GDT or LDT made
by this instruction will automatically assert LOCK to maintain descriptor integrity in multiprocessor systems.
2. A segment overrun exception (13) will occur if a word
operand references at offset FFFF(H) is attempted.
12. JMP, CALL, INT, RET, IRET instructions referring to
another code segment will cause a general protection
exception (13) if any privilege rule is violated.
3. This instruction may be executed in real address mode to
initialize the CPU for protected mode.
4. The IOPL and NT fields will remain 0.
13. A general protection exception (13) occurs if CPL ≠ 0.
5. Processor extension segment overrun interrupt (9) will
occur if the operand exceeds the segment limit.
14. A general protection exception (13) occurs if CPL > IOPL.
15. The IF field of the flag word is not updated if CPL > IOPL.
The IOPL field is updated only if CPL = 0.
Either Mode
6. An exception may occur, depending on the value of the
operand.
16. Any violation of privilege rules as applied to the selector
operand does not cause a protection exception; rather,
the instruction does not return a result and the zero flag
is cleared.
7. LOCK is automatically asserted regardless of the presence or absence of the LOCK instruction prefix.
8. LOCK does not remain active between all operand
transfers.
17. If the starting address of the memory operand violates a
segment limit, or an invalid access is attempted, a general protection exception (13) will occur before the ESC
instruction is executed. A stack segment overrun exception (12) will occur if the stack limit is violated by the
operand’s starting address. If a segment limit is violated
during an attempted data transfer then a processor
extension segment overrun exception (9) occurs.
Protected Virtual Address Mode Only
9. A general protection exception (13) will occur if the memory operand cannot be used due to either a segment limit
or access rights violation. If a stack segment limit is violated, a stack segment overrun exception (12) occurs.
18. The destination of an INT, JMP, CALL, RET or IRET
instruction must be in the defined limit of a code segment
or a general protection exception (13) will occur.
10. For segment load operations, the CPL, RPL and DPL
must agree with privilege rules to avoid an exception.
The segment must be present to avoid a not-present
exception (11). If the SS register is the destination and a
80C286 Instruction Set Summary
FUNCTION
FORMAT
CLOCK COUNT
COMMENTS
REAL
ADDRES
S
MODE
REAL
ADDRES
S
MODE
PROTECTED
VIRTUAL
ADDRESS
MODE
PROTECTED
VIRTUAL
ADDRESS
MODE
DATA TRANSFER
MOV = Move
Register to Register/Mem- 1000100w mod
ory
r/m
reg
2, 3
2, 3
(Note 59) (Note 59)
2
9
Register/Memory to Regis- 1000101w mod
ter
r/m
reg
2, 5
2, 5
(Note 59) (Note 59)
2
9
2, 3
2, 3
(Note 59) (Note 59)
2
9
2
9
Immediate to Register/Mem- 1100011w mod 000 data
ory
r/m
data if
w=1
Immediate to Register
1011w reg data
data if w =
1
2
2
Memory to Accumulator
1010000w addr-low
addr-high
5
5
52
80C286
80C286 Instruction Set Summary (Continued)
FUNCTION
Accumulator to Memory
FORMAT
1010001w addr-low
addr-high
CLOCK COUNT
COMMENTS
REAL
ADDRES
S
MODE
PROTECTED
VIRTUAL
ADDRESS
MODE
REAL
ADDRES
S
MODE
PROTECTED
VIRTUAL
ADDRESS
MODE
3
3
2
9
Register/Memory to Seg- 10001110 mod 0 reg
ment Register
r/m
2, 5
17, 19
(Note 59) (Note 59)
2
9, 10, 11
Segment Register to Regis- 10001100 mod 0 reg
ter/Memory
r/m
2, 3
2, 3
(Note 59) (Note 59)
2
9
5
5
(Note 59) (Note 59)
2
9
PUSH = Push
Memory
11111111 mod
r/m
110
Register
01010 reg
3
3
2
9
Segment Register
000
110
3
3
2
9
Immediate
011010s0 data
3
3
2
9
PUSHA = Push All
01100000
17
17
2
9
5
5
(Note 59) (Note 59)
2
9
5
5
2
9
5
20
2
9, 10, 11
19
19
2
9
2, 7
7, 9
reg
data if s =
0
POP = Pop
Memory
10001111 mod
r/m
Register
01011 reg
Segment Register
000
111
POPA = Pop All
01100001
000
reg (reg ≠ 01)
XCHG = Exchange
Register/Memory with Reg- 1000011w mod
ister
r/m
Register with Accumulator
reg
3, 5
3, 5
(Note 59) (Note 59)
10010 reg
3
3
Fixed Port
1110010w port
5
5
14
Variable Port
1110110w
5
5
14
Fixed Port
1110011w port
3
3
14
Variable Port
1110111w
3
3
14
XLAT = Translate Byte to 11010111
AL
5
5
9
IN = Input From
OUT = Output To
53
80C286
80C286 Instruction Set Summary (Continued)
FUNCTION
FORMAT
CLOCK COUNT
COMMENTS
REAL
ADDRES
S
MODE
REAL
ADDRES
S
MODE
PROTECTED
VIRTUAL
ADDRESS
MODE
PROTECTED
VIRTUAL
ADDRESS
MODE
LEA = Load EA to Register 10001101 mod
r/m
reg
3
3
(Note 59) (Note 59)
LDS = Load Pointer to DS
11000101 mod
r/m
reg (mod ≠ 11)
7
21
(Note 59) (Note 59)
2
9, 10, 11
LES = Load Pointer to ES
11000100 mod
r/m
reg (mod ≠ 1)
7
21
(Note 59) (Note 59)
2
9, 10, 11
LAHF Load AH with Flags
10011111
2
2
SAHF = Store AH into Flags 10011110
2
2
PUSHF = Push Flags
10011100
3
3
2
9
POPF = Pop Flags
10011101
5
5
2, 4
9, 15
2, 7
2, 7
(Note 59) (Note 59)
2
9
3, 7
3, 7
(Note 59) (Note 59)
2
9
2, 7
2, 7
(Note 59) (Note 59)
2
9
3, 7
3, 7
(Note 59) (Note 59)
2
9
2
9
2
9
ARlTHMETlC
ADD = Add
Reg/Memory with Register 000000dw mod
to
r/m
Either
reg
Immediate
ter/Memory
000 data
to
Regis- 100000sw mod
r/m
Immediate to Accumulator
0000010w data
data if
sw = 01
data if w =
1
3
3
ADC = Add with Carry
Reg/Memory with Register 000100dw mod
to
r/m
Either
reg
Immediate
ter/Memory
010 data
to
Regis- 100000sw mod
r/m
Immediate to Accumulator
0001010w data
data if
sw = 01
data if w =
1
3
3
INC = Increment
Register/Memory
1111111w mod
r/m
Register
01000 reg
000
2, 7
2, 7
(Note 59) (Note 59)
2
2
SUB = Subtract
Reg/Memory and Register 001010dw mod
to
r/m
Either
reg
2, 7
2, 7
(Note 59) (Note 59)
54
80C286
80C286 Instruction Set Summary (Continued)
FUNCTION
Immediate
ter/Memory
FORMAT
from
Regis- 100000sw mod
r/m
101 data
Immediate from Accumula- 0010110w data
tor
data if
sw = 01
data if w =
1
CLOCK COUNT
COMMENTS
REAL
ADDRES
S
MODE
REAL
ADDRES
S
MODE
PROTECTED
VIRTUAL
ADDRESS
MODE
2
9
2, 7
2, 7
(Note 59) (Note 59)
2
9
3, 7
3, 7
(Note 59) (Note 59)
2
9
2
9
PROTECTED
VIRTUAL
ADDRESS
MODE
3, 7
3, 7
(Note 59) (Note 59)
3
3
SBB = Subtract with Borrow
Reg/Memory and Register 000110dw mod
to
r/m
Either
reg
Immediate
ter/Memory
011 data
from
Regis- 100000sw mod
r/m
Immediate from Accumula- 0001110w data
tor
data if
sw = 01
data if w =
1
3
3
DEC = Decrement
Register/Memory
1111111w mod
r/m
Register
01001 reg
001
2, 7
2, 7
(Note 59) (Note 59)
2
2
CMP = Compare
Register/Memory with Reg- 0011101w mod
ister
r/m
reg
2, 6
2, 6
(Note 59) (Note 59)
2
9
Register
with
ter/Memory
Regis- 0011100w mod
r/m
reg
2, 7
2, 7
(Note 59) (Note 59)
2
9
Immediate
ter/Memory
Regis- 100000sw mod
r/m
111 data
3, 6
3, 6
(Note 59) (Note 59)
2
9
2
7
with
Immediate with Accumula- 0011110w data
tor
data if
sw = 01
3
3
2
7
(Note 59)
AAA = ASCII Adjust for Add 00110111
3
3
DAA = Decimal Adjust for 00100111
Add
3
3
AAS = ASCII Adjust for 00111111
Subtract
3
3
DAS = Decimal Adlust for 00101111
Subtract
3
3
NEG = Change Sign
1111011w mod
r/m
MUL = Multiply (Unsigned) 1111011w mod
r/m
data if w =
1
011
100
55
80C286
80C286 Instruction Set Summary (Continued)
FUNCTION
FORMAT
CLOCK COUNT
COMMENTS
REAL
ADDRES
S
MODE
PROTECTED
VIRTUAL
ADDRESS
MODE
REAL
ADDRES
S
MODE
PROTECTED
VIRTUAL
ADDRESS
MODE
Register - Byte
13
13
Register - Word
21
21
Memory - Byte
16
16
(Note 59) (Note 59)
2
9
Memory - Word
24
24
(Note 59) (Note 59)
2
9
IMUL = Integer Multiply
(Signed)
1111011w mod
r/m
101
Register - Byte
13
13
Register - Word
21
21
Memory - Byte
16
16
(Note 59) (Note 59)
2
9
Memory - Word
24
24
(Note 59) (Note 59)
2
9
data if s = 21, 24
21, 24
0
(Note 59) (Note 59)
2
9
IMUL = Interger Immediate 011010s1 mod
Multiply (Signed)
r/m
reg data
DIV = Divide (Unsigned)
110
1111011w mod
r/m
Register - Byte
14
14
6
6
Register - Word
22
22
6
6
Memory - Byte
17
17
(Note 59) (Note 59)
2, 6
6, 9
Memory - Word
25
25
(Note 59) (Note 59)
2, 6
6, 9
Register - Byte
17
17
6
6
Register - Word
25
25
6
6
Memory - Byte
20
20
(Note 59) (Note 59)
2, 6
6, 9
Memory - Word
28
28
(Note 59) (Note 59)
2, 6
6, 9
AAM = ASCII Adjust for 11010100 00001010
Multiply
16
IDIV =
(Signed)
Integer
Divide 1111011w mod
r/m
111
56
16
80C286
80C286 Instruction Set Summary (Continued)
FUNCTION
FORMAT
CLOCK COUNT
COMMENTS
REAL
ADDRES
S
MODE
PROTECTED
VIRTUAL
ADDRESS
MODE
REAL
ADDRES
S
MODE
PROTECTED
VIRTUAL
ADDRESS
MODE
AAD = ASCII Adjust for 11010101 00001010
Divide
14
14
CBW = Convert Byte to 10011000
Word
2
2
CWD = Convert Word to 10011001
Double Word
2
2
LOGIC
Shift/Rotate Instructions
Register/Memory by 1
1101000w mod
r/m
TTT
2, 7
2, 7
(Note 59) (Note 59)
2
9
Register/Memory by CL
1101001w mod
r/m
TTT
5+n, 8+n 5+n, 8+n
(Note 59) (Note 59)
2
9
TTT count
5+n, 8+n 5+n, 8+n
(Note 59) (Note 59)
2
9
2, 7
2, 7
(Note 59) (Note 59)
2
9
data if w = 3, 7
3, 7
1
(Note 59) (Note 59)
2
9
2
9
Register/Memory by Count 1100000
mod
r/m
TTT
Instruction
000
ROL
001
ROR
010
RCL
011
RCR
100
SHL/SAL
101
SHR
111
SAR
AND = And
Reg/Memory and Register 001000dw mod
to
r/m
Either
reg
Immediate
ter/Memory
100 data
to
Regis- 1000000w mod
r/m
Immediate to Accumulator
0010010w data
data if w =
1
3
3
TEST = And Function to Flags, No Result
Register/Memory and Reg- 1000010w mod
ister
r/m
reg
2, 6
2, 6
(Note 59) (Note 59)
57
80C286
80C286 Instruction Set Summary (Continued)
FUNCTION
FORMAT
CLOCK COUNT
COMMENTS
REAL
ADDRES
S
MODE
REAL
ADDRES
S
MODE
PROTECTED
VIRTUAL
ADDRESS
MODE
2
9
2, 7
2, 7
(Note 59) (Note 59)
2
9
data if w = 3, 7
3, 7
1
(Note 59) (Note 59)
2
9
2, 7
2, 7
(Note 59) (Note 59)
2
9
data if w = 3, 7
3, 7
1
(Note 59) (Note 59)
2
9
2, 7
2, 7
(Note 59) (Note 59)
2
9
1010010w
5
5
2
9
Compare 1010011w
8
8
2
9
1010111w
7
7
2
9
LODS = Load Byte/Word to 1010110w
AL/AX
5
5
2
9
STOS = Store Byte/Word 1010101w
from AL/A
3
3
2
9
INS = Input Byte/Word from 0110110w
DX Port
5
5
2
9, 14
OUTS = Output Byte/Word 0110111w
to
DX Port
5
5
2
9, 14
Immediate Data and Regis- 1111011w mod
ter/Memory
r/m
000 data
Immediate Data and Accu- 1010100w data
mulator
PROTECTED
VIRTUAL
ADDRESS
MODE
data if w = 3, 6
3, 6
1
(Note 59) (Note 59)
data if w =
1
3
3
OR = Or
Reg/Memory and Register 000010dw mod
to
r/m
Either
reg
Immediate
ter/Memory
001 data
to
Regis- 1000000w mod
r/m
Immediate to Accumulator
0000110w data
data if w =
1
3
3
XOR = Exclusive or
Reg/Memory and Register 001100dw mod
to
r/m
Either
reg
Immediate
ter/Memory
reg data
to
Regis- 1000000w mod
r/m
Immediate to Accumulator
NOT = Invert
ter/Memory
0011010w data
Regis- 1111011w mod
r/m
data if w =
1
010
3
3
STRING MANIPULATION
MOVS = Move Byte/Word
CMPS
=
Byte/Word
SCAS = Scan Byte/Word
58
59
1111001z 1010111w
11110011 1010110w
11110011 1010101w
11110011 0110110w
11110011 0110111w
SCAS = Scan String
LODS = Load String
STOS = Store String
INS = Input String
OUTS = Output String
010
disp-high
7+m
5 + 4n
5 + 4n
4 + 3n
5 + 4n
5 + 8n
5 + 9n
5 + 4n
82 + m
Via Call Gate to Different
Privilege
Level,
No
Parameters
26 + m
41 + m
13 + m
7 + m,
7 + m,
11 + m
11 + m
(Note 59) (Note 59)
7+m
5 + 4n
5 + 4n
4 + 3n
5 + 4n
5 + 8n
5 + 9n
5 + 4n
2
2, 8
2
2
2
2, 8
2, 8
2, 8
2, 8
2
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8, 11, 12, 18
8, 11, 12, 18
11, 12,18
8, 9, 18
18
9, 14
9, 14
8, 9
8, 9
8, 9
8, 9
9
PROTECTED
VIRTUAL
ADDRESS
MODE
REAL
ADDRES
S
MODE
REAL
ADDRES
S
MODE
PROTECTED
VIRTUAL
ADDRESS
MODE
COMMENTS
CLOCK COUNT
Via Call Gate to Same
Privilege Level
Segment Selector
10011010 Segment Offset
Indirect 11111111 mod
r/m
Protected Mode Only
(Direct Intersegment)
Direct Intersegment
Register/Memory
Within Segment
Direct Within Segment
CALL = Call
11101000 disp-low
1111001z 1010011w
CMPS = Compare String
CONTROL TRANSFER
11110011 1010010w
FORMAT
MOVS = Move String
Repeated by Count in CX
FUNCTION
80C286 Instruction Set Summary (Continued)
80C286
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Intersil products are sold by description only. Intersil Corporation reserves the right to make changes in circuit design, software and/or specifications at any time without
notice. Accordingly, the reader is cautioned to verify that data sheets are current before placing orders. Information furnished by Intersil is believed to be accurate and
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80C286
80C286 Instruction Set Summary (Continued)
FUNCTION
FORMAT
CLOCK COUNT
COMMENTS
REAL
ADDRES
S
MODE
REAL
ADDRES
S
MODE
PROTECTED
VIRTUAL
ADDRESS
MODE
PROTECTED
VIRTUAL
ADDRESS
MODE
Via Call Gate to Different
Privilege Level, X Parameters
86 + 4x + m
8, 11, 12, 18
Via TSS
177 + m
8, 11, 12, 18
Via Task Gate
182 + m
8, 11, 12, 18
Indirect Intersegment
11111111 mod
r/m
011 mod ≠ 11
16 + m
29 + m
(Note 59) (Note 59)
2
8, 9, 11, 12,
18
Protected Mode Only (Indirect Intersegment)
Via Call Gate to Same
Privilege Level
44 + m
(Note 59)
8, 9, 11, 12,
18
Via Call Gate to Different
Privilege
Level,
No
Parameters
83 + m
(Note 59)
8, 9, 11, 12,
18
Via Call Gate to Different
Privilege Level, X Parameters
90 + 4x + m
(Note 59)
8, 9, 11, 12,
18
Via TSS
180 + m
(Note 59)
8, 9, 11, 12,
18
185 + m
(Note 59)
8, 9, 11, 12,
18
7+m
7+m
18
7+m
7+m
18
Protected Mode Only (Indirect Intersegment) (Continued)
Via Task Gate
JMP = Unconditional Jump
Short/Long
11101011 disp-low
Direct Within Segment
11101001 disp-low
Register/Memory Indirect
Within Segment
11111111 mod
r/m
Direct Intersegment
11101010 Segment Offset
disp-high
100
7 + m,
7 + m,
11 + m
11 + m
(Note 59) (Note 59)
9, 18
23 + m
11, 12, 18
Via Call Gate to Same
Privilege Level
38 + m
8, 11,12,18
Via TSS
175 + m
8, 11,12,18
Via Task Gate
180 + m
8, 11,12,18
Protected Mode Only
(Direct Intersegment)
Indirect Intersegment
11 + m
2
Segment Selector
11111111 mod
r/m
101 mod ≠ 11
Protected Mode Only (Indirect Intersegment)
60
15 + m
26 + m
(Note 59) (Note 59)
2
8, 9, 11, 12,
18
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