Intel 8086 Users Manual

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September 1990 Order Number: 231455-005

8086

16-BIT HMOS MICROPROCESSOR

8086/8086-2/8086-1

YDirect Addressing Capability 1 MByte

of Memory

YArchitecture Designed for Powerful

Assembly Language and Efficient High

Level Languages

Y14 Word, by 16-Bit Register Set with

Symmetrical Operations

Y24 Operand Addressing Modes

YBit, Byte, Word, and Block Operations

Y8 and 16-Bit Signed and Unsigned

Arithmetic in Binary or Decimal

Including Multiply and Divide

YRange of Clock Rates:

5 MHz for 8086,

8 MHz for 8086-2,

10 MHz for 8086-1

YMULTIBUS System Compatible

Interface

YAvailable in EXPRESS

Ð Standard Temperature Range

Ð Extended Temperature Range

YAvailable in 40-Lead Cerdip and Plastic

Package

(See Packaging Spec. Order Ý231369)

The Intel 8086 high performance 16-bit CPU is available in three clock rates: 5, 8 and 10 MHz. The CPU is

implemented in N-Channel, depletion load, silicon gate technology (HMOS-III), and packaged in a 40-pin

CERDIP or plastic package. The 8086 operates in both single processor and multiple processor configurations

to achieve high performance levels.

231455–1

Figure 1. 8086 CPU Block Diagram

231455–2

40 Lead

Figure 2. 8086 Pin

Configuration

8086

Table 1. Pin Description

The following pin function descriptions are for 8086 systems in either minimum or maximum mode. The ‘‘Local

Bus’’ in these descriptions is the direct multiplexed bus interface connection to the 8086 (without regard to

additional bus buffers).

Symbol Pin No. Type Name and Function

AD15–AD02–16, 39 I/O ADDRESS DATA BUS: These lines constitute the time multiplexed

memory/IO address (T1), and data (T2,T

) bus. A0is

analogous to BHE for the lower byte of the data bus, pins D7–D0.Itis

LOW during T1when a byte is to be transferred on the lower portion

of the bus in memory or I/O operations. Eight-bit oriented devices tied

to the lower half would normally use A0to condition chip select

functions. (See BHE.) These lines are active HIGH and float to 3-state

OFF during interrupt acknowledge and local bus ‘‘hold acknowledge’’.

A19/S6, 35–38 O ADDRESS/STATUS: During T1these are the four most significant

address lines for memory operations. During I/O operations these

A18/S5,

lines are LOW. During memory and I/O operations, status information

A17/S4,is available on these lines during T2,T

. The status of the

A16/S3interrupt enable FLAG bit (S5) is updated at the beginning of each

CLK cycle. A17/S4and A16/S3are encoded as shown.

This information indicates which relocation register is presently being

used for data accessing.

These lines float to 3-state OFF during local bus ‘‘hold acknowledge.’’

A17/S4A16/S3Characteristics

0 (LOW) 0 Alternate Data

0 1 Stack

1 (HIGH) 0 Code or None

1 1 Data

S6is 0

(LOW)

BHE/S734 O BUS HIGH ENABLE/STATUS: During T1the bus high enable signal

(BHE) should be used to enable data onto the most significant half of

the data bus, pins D15–D8. Eight-bit oriented devices tied to the upper

half of the bus would normally use BHE to condition chip select

functions. BHE is LOW during T1for read, write, and interrupt

acknowledge cycles when a byte is to be transferred on the high

portion of the bus. The S7status information is available during T2,

T3, and T4. The signal is active LOW, and floats to 3-state OFF in

‘‘hold’’. It is LOW during T1for the first interrupt acknowledge cycle.

BHE A0Characteristics

0 0 Whole word

0 1 Upper byte from/to odd address

1 0 Lower byte from/to even address

1 1 None

RD 32 O READ: Read strobe indicates that the processor is performing a

memory or I/O read cycle, depending on the state of the S2pin. This

signal is used to read devices which reside on the 8086 local bus. RD

is active LOW during T2,T

3and TWof any read cycle, and is

guaranteed to remain HIGH in T2until the 8086 local bus has floated.

This signal floats to 3-state OFF in ‘‘hold acknowledge’’.

8086

Table 1. Pin Description (Continued)

Symbol Pin No. Type Name and Function

READY 22 I READY: is the acknowledgement from the addressed memory or I/O

device that it will complete the data transfer. The READY signal from

memory/IO is synchronized by the 8284A Clock Generator to form

READY. This signal is active HIGH. The 8086 READY input is not

synchronized. Correct operation is not guaranteed if the setup and hold

times are not met.

INTR 18 I INTERRUPT REQUEST: is a level triggered input which is sampled

during the last clock cycle of each instruction to determine if the

processor should enter into an interrupt acknowledge operation. A

subroutine is vectored to via an interrupt vector lookup table located in

system memory. It can be internally masked by software resetting the

interrupt enable bit. INTR is internally synchronized. This signal is

active HIGH.

TEST 23 I TEST: input is examined by the ‘‘Wait’’ instruction. If the TEST input is

LOW execution continues, otherwise the processor waits in an ‘‘Idle’’

state. This input is synchronized internally during each clock cycle on

the leading edge of CLK.

NMI 17 I NON-MASKABLE INTERRUPT: an edge triggered input which causes

a type 2 interrupt. A subroutine is vectored to via an interrupt vector

lookup table located in system memory. NMI is not maskable internally

by software. A transition from LOW to HIGH initiates the interrupt at the

end of the current instruction. This input is internally synchronized.

RESET 21 I RESET: causes the processor to immediately terminate its present

activity. The signal must be active HIGH for at least four clock cycles. It

restarts execution, as described in the Instruction Set description, when

RESET returns LOW. RESET is internally synchronized.

CLK 19 I CLOCK: provides the basic timing for the processor and bus controller.

It is asymmetric with a 33% duty cycle to provide optimized internal

timing.

VCC 40 VCC:a5V power supply pin.

GND 1, 20 GROUND

MN/MX 33 I MINIMUM/MAXIMUM: indicates what mode the processor is to

operate in. The two modes are discussed in the following sections.

The following pin function descriptions are for the 8086/8288 system in maximum mode (i.e., MN/MX

Only the pin functions which are unique to maximum mode are described; all other pin functions are as

described above.

S2,S

026–28 O STATUS: active during T4,T

, and T2and is returned to the passive state

(1, 1, 1) during T3or during TWwhen READY is HIGH. This status is used

by the 8288 Bus Controller to generate all memory and I/O access control

signals. Any change by S2,S

,orS

0during T4is used to indicate the

beginning of a bus cycle, and the return to the passive state in T3or TWis

used to indicate the end of a bus cycle.

8086

Table 1. Pin Description (Continued)

Symbol Pin No. Type Name and Function

S2,S

026– 28 O These signals float to 3-state OFF in ‘‘hold acknowledge’’. These status

lines are encoded as shown.

(Continued)

S2S1S0Characteristics

0 (LOW) 0 0 Interrupt Acknowledge

0 0 1 Read I/O Port

0 1 0 Write I/O Port

0 1 1 Halt

1 (HIGH) 0 0 Code Access

1 0 1 Read Memory

1 1 0 Write Memory

1 1 1 Passive

RQ/GT0, 30, 31 I/O REQUEST/GRANT: pins are used by other local bus masters to force

the processor to release the local bus at the end of the processor’s

RQ/GT1current bus cycle. Each pin is bidirectional with RQ/GT0having higher

priority than RQ/GT1.RQ/GT pins have internal pull-up resistors and

may be left unconnected. The request/grant sequence is as follows

(see Page 2-24):

1. A pulse of 1 CLK wide from another local bus master indicates a local

bus request (‘‘hold’’) to the 8086 (pulse 1).

2. During a T4or T1clock cycle, a pulse 1 CLK wide from the 8086 to

the requesting master (pulse 2), indicates that the 8086 has allowed the

local bus to float and that it will enter the ‘‘hold acknowledge’’ state at

the next CLK. The CPU’s bus interface unit is disconnected logically

from the local bus during ‘‘hold acknowledge’’.

3. A pulse 1 CLK wide from the requesting master indicates to the 8086

(pulse 3) that the ‘‘hold’’ request is about to end and that the 8086 can

reclaim the local bus at the next CLK.

Each master-master exchange of the local bus is a sequence of 3

pulses. There must be one dead CLK cycle after each bus exchange.

Pulses are active LOW.

If the request is made while the CPU is performing a memory cycle, it

will release the local bus during T4of the cycle when all the following

conditions are met:

1. Request occurs on or before T2.

2. Current cycle is not the low byte of a word (on an odd address).

3. Current cycle is not the first acknowledge of an interrupt acknowledge

sequence.

4. A locked instruction is not currently executing.

If the local bus is idle when the request is made the two possible events

will follow:

1. Local bus will be released during the next clock.

2. A memory cycle will start within 3 clocks. Now the four rules for a

currently active memory cycle apply with condition number 1 already

satisfied.

LOCK 29 O LOCK: output indicates that other system bus masters are not to gain

control of the system bus while LOCK is active LOW. The LOCK signal

is activated by the ‘‘LOCK’’ prefix instruction and remains active until the

completion of the next instruction. This signal is active LOW, and floats

to 3-state OFF in ‘‘hold acknowledge’’.

8086

Table 1. Pin Description (Continued)

Symbol Pin No. Type Name and Function

QS1,QS

024, 25 O QUEUE STATUS: The queue status is valid during the CLK cycle after

which the queue operation is performed.

QS1and QS0provide status to allow external tracking of the internal

8086 instruction queue.

QS1QS0Characteristics

0 (LOW) 0 No Operation

0 1 First Byte of Op Code from Queue

1 (HIGH) 0 Empty the Queue

1 1 Subsequent Byte from Queue

The following pin function descriptions are for the 8086 in minimum mode (i.e., MN/MX

). Only the pin

functions which are unique to minimum mode are described; all other pin functions are as described above.

M/IO 28 O STATUS LINE: logically equivalent to S2in the maximum mode. It is used to

distinguish a memory access from an I/O access. M/IO becomes valid in

the T4preceding a bus cycle and remains valid until the final T4of the cycle

(M eHIGH, IO eLOW). M/IO floats to 3-state OFF in local bus ‘‘hold

acknowledge’’.

WR 29 O WRITE: indicates that the processor is performing a write memory or write

I/O cycle, depending on the state of the M/IO signal. WR is active for T2,T

and TWof any write cycle. It is active LOW, and floats to 3-state OFF in

local bus ‘‘hold acknowledge’’.

INTA 24 O INTA: is used as a read strobe for interrupt acknowledge cycles. It is active

LOW during T2,T

3and TWof each interrupt acknowledge cycle.

ALE 25 O ADDRESS LATCH ENABLE: provided by the processor to latch the

address into the 8282/8283 address latch. It is a HIGH pulse active during

T1of any bus cycle. Note that ALE is never floated.

DT/R 27 O DATA TRANSMIT/RECEIVE: needed in minimum system that desires to

use an 8286/8287 data bus transceiver. It is used to control the direction of

data flow through the transceiver. Logically DT/R is equivalent to S1in the

maximum mode, and its timing is the same as for M/IO.(TeHIGH, R e

LOW.) This signal floats to 3-state OFF in local bus ‘‘hold acknowledge’’.

DEN 26 O DATA ENABLE: provided as an output enable for the 8286/8287 in a

minimum system which uses the transceiver. DEN is active LOW during

each memory and I/O access and for INTA cycles. For a read or INTA cycle

it is active from the middle of T2until the middle of T4, while for a write cycle

it is active from the beginning of T2until the middle of T4. DEN floats to 3-

state OFF in local bus ‘‘hold acknowledge’’.

HOLD, 31, 30 I/O HOLD: indicates that another master is requesting a local bus ‘‘hold.’’ To be

acknowledged, HOLD must be active HIGH. The processor receiving the

HLDA

‘‘hold’’ request will issue HLDA (HIGH) as an acknowledgement in the

middle of a T4or Ticlock cycle. Simultaneous with the issuance of HLDA

the processor will float the local bus and control lines. After HOLD is

detected as being LOW, the processor will LOWer the HLDA, and when the

processor needs to run another cycle, it will again drive the local bus and

control lines. Hold acknowledge (HLDA) and HOLD have internal pull-up

resistors.

The same rules as for RQ/GT apply regarding when the local bus will be

released.

HOLD is not an asynchronous input. External synchronization should be

provided if the system cannot otherwise guarantee the setup time.

8086

FUNCTIONAL DESCRIPTION

General Operation

The internal functions of the 8086 processor are

partitioned logically into two processing units. The

first is the Bus Interface Unit (BIU) and the second is

the Execution Unit (EU) as shown in the block dia-

gram of Figure 1.

These units can interact directly but for the most

part perform as separate asynchronous operational

processors. The bus interface unit provides the func-

tions related to instruction fetching and queuing, op-

erand fetch and store, and address relocation. This

unit also provides the basic bus control. The overlap

of instruction pre-fetching provided by this unit

serves to increase processor performance through

improved bus bandwidth utilization. Up to 6 bytes of

the instruction stream can be queued while waiting

for decoding and execution.

The instruction stream queuing mechanism allows

the BIU to keep the memory utilized very efficiently.

Whenever there is space for at least 2 bytes in the

queue, the BIU will attempt a word fetch memory

cycle. This greatly reduces ‘‘dead time’’ on the

memory bus. The queue acts as a First-In-First-Out

(FIFO) buffer, from which the EU extracts instruction

bytes as required. If the queue is empty (following a

branch instruction, for example), the first byte into

the queue immediately becomes available to the EU.

The execution unit receives pre-fetched instructions

from the BIU queue and provides un-relocated oper-

and addresses to the BIU. Memory operands are

passed through the BIU for processing by the EU,

which passes results to the BIU for storage. See the

Instruction Set description for further register set

and architectural descriptions.

MEMORY ORGANIZATION

The processor provides a 20-bit address to memory

which locates the byte being referenced. The memo-

ry is organized as a linear array of up to 1 million

bytes, addressed as 00000(H) to FFFFF(H). The

memory is logically divided into code, data, extra

data, and stack segments of up to 64K bytes each,

with each segment falling on 16-byte boundaries.

(See Figure 3a.)

All memory references are made relative to base ad-

dresses contained in high speed segment registers.

The segment types were chosen based on the ad-

dressing needs of programs. The segment register

to be selected is automatically chosen according to

the rules of the following table. All information in one

segment type share the same logical attributes (e.g.

code or data). By structuring memory into relocat-

able areas of similar characteristics and by automati-

cally selecting segment registers, programs are

shorter, faster, and more structured.

Word (16-bit) operands can be located on even or

odd address boundaries and are thus not con-

strained to even boundaries as is the case in many

16-bit computers. For address and data operands,

the least significant byte of the word is stored in the

lower valued address location and the most signifi-

cant byte in the next higher address location. The

BIU automatically performs the proper number of

memory accesses, one if the word operand is on an

even byte boundary and two if it is on an odd byte

boundary. Except for the performance penalty, this

double access is transparent to the software. This

performance penalty does not occur for instruction

fetches, only word operands.

Physically, the memory is organized as a high bank

(D15–D8) and a low bank (D7–D0) of 512K 8-bit

bytes addressed in parallel by the processor’s ad-

dress lines A19–A1. Byte data with even addresses

is transferred on the D7–D0bus lines while odd ad-

dressed byte data (A0HIGH) is transferred on the

D15–D8bus lines. The processor provides two en-

able signals, BHE and A0, to selectively allow read-

ing from or writing into either an odd byte location,

even byte location, or both. The instruction stream is

fetched from memory as words and is addressed

internally by the processor to the byte level as nec-

essary.

Memory Segment Register Segment

Reference Need Used Selection Rule

Instructions CODE (CS) Automatic with all instruction prefetch.

Stack STACK (SS) All stack pushes and pops. Memory references relative to BP

base register except data references.

Local Data DATA (DS) Data references when: relative to stack, destination of string

operation, or explicitly overridden.

External (Global) Data EXTRA (ES) Destination of string operations: explicitly selected using a

segment override.

8086

231455–3

Figure 3a. Memory Organization

In referencing word data the BIU requires one or two

memory cycles depending on whether or not the

starting byte of the word is on an even or odd ad-

dress, respectively. Consequently, in referencing

word operands performance can be optimized by lo-

cating data on even address boundaries. This is an

especially useful technique for using the stack, since

odd address references to the stack may adversely

affect the context switching time for interrupt pro-

cessing or task multiplexing.

231455–4

Figure 3b. Reserved Memory Locations

Certain locations in memory are reserved for specific

CPU operations (see Figure 3b). Locations from

address FFFF0H through FFFFFH are reserved for

operations including a jump to the initial program

loading routine. Following RESET, the CPU will al-

ways begin execution at location FFFF0H where the

jump must be. Locations 00000H through 003FFH

are reserved for interrupt operations. Each of the

256 possible interrupt types has its service routine

pointed to by a 4-byte pointer element consisting of

a 16-bit segment address and a 16-bit offset ad-

dress. The pointer elements are assumed to have

been stored at the respective places in reserved

memory prior to occurrence of interrupts.

MINIMUM AND MAXIMUM MODES

The requirements for supporting minimum and maxi-

mum 8086 systems are sufficiently different that

they cannot be done efficiently with 40 uniquely de-

fined pins. Consequently, the 8086 is equipped with

a strap pin (MN/MX) which defines the system con-

figuration. The definition of a certain subset of the

pins changes dependent on the condition of the

strap pin. When MN/MX pin is strapped to GND, the

8086 treats pins 24 through 31 in maximum mode.

An 8288 bus controller interprets status information

coded into S0,S

2to generate bus timing and

control signals compatible with the MULTIBUS ar-

chitecture. When the MN/MX pin is strapped to VCC,

the 8086 generates bus control signals itself on pins

24 through 31, as shown in parentheses in Figure 2.

Examples of minimum mode and maximum mode

systems are shown in Figure 4.

BUS OPERATION

The 8086 has a combined address and data bus

commonly referred to as a time multiplexed bus.

This technique provides the most efficient use of

pins on the processor while permitting the use of a

standard 40-lead package. This ‘‘local bus’’ can be

buffered directly and used throughout the system

with address latching provided on memory and I/O

modules. In addition, the bus can also be demulti-

plexed at the processor with a single set of address

latches if a standard non-multiplexed bus is desired

for the system.

Each processor bus cycle consists of at least four

CLK cycles. These are referred to as T1,T

3and

T4(see Figure 5). The address is emitted from the

processor during T1and data transfer occurs on the

bus during T3and T4.T

2is used primarily for chang-

ing the direction of the bus during read operations. In

the event that a ‘‘NOT READY’’ indication is given

by the addressed device, ‘‘Wait’’ states (TW) are in-

serted between T3and T4. Each inserted ‘‘Wait’’

state is of the same duration as a CLK cycle. Periods

8086

231455–5

Figure 4a. Minimum Mode 8086 Typical Configuration

231455–6

Figure 4b. Maximum Mode 8086 Typical Configuration

8086

can occur between 8086 bus cycles. These are re-

ferred to as ‘‘Idle’’ states (Ti) or inactive CLK cycles.

The processor uses these cycles for internal house-

keeping.

During T1of any bus cycle the ALE (Address Latch

Enable) signal is emitted (by either the processor or

the 8288 bus controller, depending on the MN/MX

strap). At the trailing edge of this pulse, a valid ad-

dress and certain status information for the cycle

may be latched.

Status bits S0,S

, and S2are used, in maximum

mode, by the bus controller to identify the type of

bus transaction according to the following table:

S2S1S0Characteristics

0 (LOW) 0 0 Interrupt Acknowledge

0 0 1 Read I/O

0 1 0 Write I/O

0 1 1 Halt

1 (HIGH) 0 0 Instruction Fetch

1 0 1 Read Data from Memory

1 1 0 Write Data to Memory

1 1 1 Passive (no bus cycle)

231455–8

Figure 5. Basic System Timing

8086

Status bits S3through S7are multiplexed with high-

order address bits and the BHE signal, and are

therefore valid during T2through T4.S

3and S4indi-

cate which segment register (see Instruction Set de-

scription) was used for this bus cycle in forming the

address, according to the following table:

S4S3Characteristics

0 (LOW) 0 Alternate Data (extra segment)

0 1 Stack

1 (HIGH) 0 Code or None

1 1 Data

S5is a reflection of the PSW interrupt enable bit.

S6e0 and S7is a spare status bit.

I/O ADDRESSING

In the 8086, I/O operations can address up to a

maximum of 64K I/O byte registers or 32K I/O word

registers. The I/O address appears in the same for-

mat as the memory address on bus lines A15 –A0.

The address lines A19–A16 are zero in I/O opera-

tions. The variable I/O instructions which use regis-

ter DX as a pointer have full address capability while

the direct I/O instructions directly address one or

two of the 256 I/O byte locations in page 0 of the

I/O address space.

I/O ports are addressed in the same manner as

memory locations. Even addressed bytes are trans-

ferred on the D7–D0bus lines and odd addressed

bytes on D15–D8. Care must be taken to assure that

each register within an 8-bit peripheral located on

the lower portion of the bus be addressed as even.

External Interface

PROCESSOR RESET AND INITIALIZATION

Processor initialization or start up is accomplished

with activation (HIGH) of the RESET pin. The 8086

RESET is required to be HIGH for greater than 4

CLK cycles. The 8086 will terminate operations on

the high-going edge of RESET and will remain dor-

mant as long as RESET is HIGH. The low-going

transition of RESET triggers an internal reset se-

quence for approximately 10 CLK cycles. After this

interval the 8086 operates normally beginning with

the instruction in absolute location FFFF0H (see Fig-

ure 3b). The details of this operation are specified in

the Instruction Set description of the MCS-86 Family

User’s Manual. The RESET input is internally syn-

chronized to the processor clock. At initialization the

HIGH-to-LOW transition of RESET must occur no

sooner than 50 ms after power-up, to allow complete

initialization of the 8086.

NMI asserted prior to the 2nd clock after the end of

RESET will not be honored. If NMI is asserted after

that point and during the internal reset sequence,

the processor may execute one instruction before

responding to the interrupt. A hold request active

immediately after RESET will be honored before the

first instruction fetch.

All 3-state outputs float to 3-state OFF during

RESET. Status is active in the idle state for the first

clock after RESET becomes active and then floats

to 3-state OFF. ALE and HLDA are driven low.

INTERRUPT OPERATIONS

Interrupt operations fall into two classes; software or

hardware initiated. The software initiated interrupts

and software aspects of hardware interrupts are

specified in the Instruction Set description. Hard-

ware interrupts can be classified as non-maskable or

maskable.

Interrupts result in a transfer of control to a new pro-

gram location. A 256-element table containing ad-

dress pointers to the interrupt service program loca-

tions resides in absolute locations 0 through 3FFH

(see Figure 3b), which are reserved for this purpose.

Each element in the table is 4 bytes in size and

corresponds to an interrupt ‘‘type’’. An interrupting

device supplies an 8-bit type number, during the in-

terrupt acknowledge sequence, which is used to

‘‘vector’’ through the appropriate element to the new

interrupt service program location.

NON-MASKABLE INTERRUPT (NMI)

The processor provides a single non-maskable inter-

rupt pin (NMI) which has higher priority than the

maskable interrupt request pin (INTR). A typical use

would be to activate a power failure routine. The

NMI is edge-triggered on a LOW-to-HIGH transition.

The activation of this pin causes a type 2 interrupt.

(See Instruction Set description.)

NMI is required to have a duration in the HIGH state

of greater than two CLK cycles, but is not required to

be synchronized to the clock. Any high-going tran-

sition of NMI is latched on-chip and will be serviced

at the end of the current instruction or between

whole moves of a block-type instruction. Worst case

response to NMI would be for multiply, divide, and

variable shift instructions. There is no specification

on the occurrence of the low-going edge; it may oc-

cur before, during, or after the servicing of NMI. An-

other high-going edge triggers another response if it

occurs after the start of the NMI procedure. The sig-

nal must be free of logical spikes in general and be

free of bounces on the low-going edge to avoid trig-

gering extraneous responses.

8086

MASKABLE INTERRUPT (INTR)

The 8086 provides a single interrupt request input

(INTR) which can be masked internally by software

with the resetting of the interrupt enable FLAG

status bit. The interrupt request signal is level trig-

gered. It is internally synchronized during each clock

cycle on the high-going edge of CLK. To be re-

sponded to, INTR must be present (HIGH) during

the clock period preceding the end of the current

instruction or the end of a whole move for a block-

type instruction. During the interrupt response se-

quence further interrupts are disabled. The enable

bit is reset as part of the response to any interrupt

(INTR, NMI, software interrupt or single-step), al-

though the FLAGS register which is automatically

pushed onto the stack reflects the state of the proc-

essor prior to the interrupt. Until the old FLAGS reg-

ister is restored the enable bit will be zero unless

specifically set by an instruction.

During the response sequence (Figure 6) the proc-

essor executes two successive (back-to-back) inter-

rupt acknowledge cycles. The 8086 emits the LOCK

signal from T2of the first bus cycle until T2of the

second. A local bus ‘‘hold’’ request will not be hon-

ored until the end of the second bus cycle. In the

second bus cycle a byte is fetched from the external

interrupt system (e.g., 8259A PIC) which identifies

the source (type) of the interrupt. This byte is multi-

plied by four and used as a pointer into the interrupt

vector lookup table. An INTR signal left HIGH will be

continually responded to within the limitations of the

enable bit and sample period. The INTERRUPT RE-

TURN instruction includes a FLAGS pop which re-

turns the status of the original interrupt enable bit

when it restores the FLAGS.

HALT

When a software ‘‘HALT’’ instruction is executed the

processor indicates that it is entering the ‘‘HALT’’

state in one of two ways depending upon which

mode is strapped. In minimum mode, the processor

issues one ALE with no qualifying bus control sig-

nals. In maximum mode, the processor issues ap-

propriate HALT status on S2,S

, and S0; and the

8288 bus controller issues one ALE. The 8086 will

not leave the ‘‘HALT’’ state when a local bus ‘‘hold’’

is entered while in ‘‘HALT’’. In this case, the proces-

sor reissues the HALT indicator. An interrupt request

or RESET will force the 8086 out of the ‘‘HALT’’

state.

READ/MODIFY/WRITE (SEMAPHORE)

OPERATIONS VIA LOCK

The LOCK status information is provided by the

processor when directly consecutive bus cycles are

required during the execution of an instruc-

tion. This provides the processor with the capability

of performing read/modify/write operations on

memory (via the Exchange Register With Memory

instruction, for example) without the possibility of an-

other system bus master receiving intervening mem-

ory cycles. This is useful in multi-processor system

configurations to accomplish ‘‘test and set lock’’ op-

erations. The LOCK signal is activated (forced LOW)

in the clock cycle following the one in which the soft-

ware ‘‘LOCK’’ prefix instruction is decoded by the

EU. It is deactivated at the end of the last bus cycle

of the instruction following the ‘‘LOCK’’ prefix in-

struction. While LOCK is active a request on a RQ/

GT pin will be recorded and then honored at the end

of the LOCK.

231455–9

Figure 6. Interrupt Acknowledge Sequence

8086

EXTERNAL SYNCHRONIZATION VIA TEST

As an alternative to the interrupts and general I/O

capabilities, the 8086 provides a single software-

testable input known as the TEST signal. At any time

the program may execute a WAIT instruction. If at

that time the TEST signal is inactive (HIGH), pro-

gram execution becomes suspended while the proc-

essor waits for TEST to become active. It must

remain active for at least 5 CLK cycles. The WAIT

instruction is re-executed repeatedly until that time.

This activity does not consume bus cycles. The

processor remains in an idle state while waiting. All

8086 drivers go to 3-state OFF if bus ‘‘Hold’’ is en-

tered. If interrupts are enabled, they may occur while

the processor is waiting. When this occurs the proc-

essor fetches the WAIT instruction one extra time,

processes the interrupt, and then re-fetches and re-

executes the WAIT instruction upon returning from

the interrupt.

Basic System Timing

Typical system configurations for the processor op-

erating in minimum mode and in maximum mode are

shown in Figures 4a and 4b, respectively. In mini-

mum mode, the MN/MX pin is strapped to VCC and

the processor emits bus control signals in a manner

similar to the 8085. In maximum mode, the MN/MX

pin is strapped to VSS and the processor emits cod-

ed status information which the 8288 bus controller

uses to generate MULTIBUS compatible bus control

signals. Figure 5 illustrates the signal timing relation-

ships.

231455–10

Figure 7. 8086 Register Model

SYSTEM TIMINGÐMINIMUM SYSTEM

The read cycle begins in T1with the assertion of the

Address Latch Enable (ALE) signal. The trailing (low-

going) edge of this signal is used to latch the ad-

dress information, which is valid on the local bus at

this time, into the address latch. The BHE and A0

signals address the low, high, or both bytes. From T1

to T4the M/IO signal indicates a memory or I/O

operation. At T2the address is removed from the

local bus and the bus goes to a high impedance

state. The read control signal is also asserted at T2.

The read (RD) signal causes the addressed device

to enable its data bus drivers to the local bus. Some

time later valid data will be available on the bus and

the addressed device will drive the READY line

HIGH. When the processor returns the read signal to

a HIGH level, the addressed device will again 3-

state its bus drivers. If a transceiver is required to

buffer the 8086 local bus, signals DT/R and DEN

are provided by the 8086.

A write cycle also begins with the assertion of ALE

and the emission of the address. The M/IO signal is

again asserted to indicate a memory or I/O write

operation. In the T2immediately following the ad-

dress emission the processor emits the data to be

written into the addressed location. This data re-

mains valid until the middle of T4. During T2,T

, and

TWthe processor asserts the write control signal.

The write (WR) signal becomes active at the begin-

ning of T2as opposed to the read which is delayed

somewhat into T2to provide time for the bus to float.

The BHE and A0signals are used to select the prop-

er byte(s) of the memory/IO word to be read or writ-

ten according to the following table:

BHE A0 Characteristics

0 0 Whole word

0 1 Upper byte from/to

odd address

1 0 Lower byte from/to

even address

1 1 None

I/O ports are addressed in the same manner as

memory location. Even addressed bytes are trans-

ferred on the D7–D0bus lines and odd addressed

bytes on D15–D8.

The basic difference between the interrupt acknowl-

edge cycle and a read cycle is that the interrupt ac-

knowledge signal (INTA) is asserted in place of the

read (RD) signal and the address bus is floated.

(See Figure 6.) In the second of two successive

INTA cycles, a byte of information is read from bus

8086

lines D7–D0as supplied by the inerrupt system logic

(i.e., 8259A Priority Interrupt Controller). This byte

identifies the source (type) of the interrupt. It is multi-

plied by four and used as a pointer into an interrupt

vector lookup table, as described earlier.

BUS TIMINGÐMEDIUM SIZE SYSTEMS

For medium size systems the MN/MX pin is con-

nected to VSS and the 8288 Bus Controller is added

to the system as well as a latch for latching the sys-

tem address, and a transceiver to allow for bus load-

ing greater than the 8086 is capable of handling.

Signals ALE, DEN, and DT/R are generated by the

8288 instead of the processor in this configuration

although their timing remains relatively the same.

The 8086 status outputs (S2,S

, and S0) provide

type-of-cycle information and become 8288 inputs.

This bus cycle information specifies read (code,

data, or I/O), write (data or I/O), interrupt

acknowledge, or software halt. The 8288 thus issues

control signals specifying memory read or write, I/O

read or write, or interrupt acknowledge. The 8288

provides two types of write strobes, normal and ad-

vanced, to be applied as required. The normal write

strobes have data valid at the leading edge of write.

The advanced write strobes have the same timing

as read strobes, and hence data isn’t valid at the

leading edge of write. The transceiver receives the

usual DIR and G inputs from the 8288’s DT/R and

DEN.

The pointer into the interrupt vector table, which is

passed during the second INTA cycle, can derive

from an 8259A located on either the local bus or the

system bus. If the master 8259A Priority Interrupt

Controller is positioned on the local bus, a TTL gate

is required to disable the transceiver when reading

from the master 8259A during the interrupt acknowl-

edge sequence and software ‘‘poll’’.

8086

ABSOLUTE MAXIMUM RATINGS*

Ambient Temperature Under Bias ÀÀÀÀÀÀ0§Cto70

Storage Temperature ÀÀÀÀÀÀÀÀÀÀb65§Ctoa

150§C

Voltage on Any Pin with

Respect to GroundÀÀÀÀÀÀÀÀÀÀÀÀÀÀb1.0V to a7V

Power DissipationÀÀÀÀÀÀÀÀÀÀÀÀÀÀÀÀÀÀÀÀÀÀÀÀÀÀ2.5W

NOTICE: This is a production data sheet. The specifi-

cations are subject to change without notice.

WARNING: Stressing the device beyond the ‘‘Absolute

Maximum Ratings’’ may cause permanent damage.

These are stress ratings only. Operation beyond the

‘‘Operating Conditions’’ is not recommended and ex-

tended exposure beyond the ‘‘Operating Conditions’’

may affect device reliability.

D.C. CHARACTERISTICS (8086: TAe0§Cto70

C, VCC e5V g10%)

(8086-1: TAe0§Cto70

C, VCC e5V g5%)

(8086-2: TAe0§Cto70

C, VCC e5V g5%)

Symbol Parameter Min Max Units Test Conditions

VIL Input Low Voltage b0.5 a0.8 V (Note 1)

VIH Input High Voltage 2.0 VCC a0.5 V (Notes 1, 2)

VOL Output Low Voltage 0.45 V IOL e2.5 mA

VOH Output High Voltage 2.4 V IOH eb400 mA

ICC Power Supply Current: 8086 340

8086-1 360 mA TAe25§C

8086-2 350

ILI Input Leakage Current g10 mA0V

IN sVCC (Note 3)

ILO Output Leakage Current g10 mA 0.45V sVOUT sVCC

VCL Clock Input Low Voltage b0.5 a0.6 V

VCH Clock Input High Voltage 3.9 VCC a1.0 V

CIN Capacitance of Input Buffer 15 pF fc e1 MHz

(All input except

AD0–AD15,RQ/GT)

CIO Capacitance of I/O Buffer 15 pF fc e1 MHz

(AD0–AD15,RQ/GT)

NOTES:

1. VIL tested with MN/MX Pin e0V. VIH tested with MN/MX Pin e5V. MN/MX Pin is a Strap Pin.

2. Not applicable to RQ/GT0 and RQ/GT1 (Pins 30 and 31).

3. HOLD and HLDA ILI min e30 mA, max e500 mA.

8086

A.C. CHARACTERISTICS (8086: TAe0§Cto70

C, VCC e5V g10%)

(8086-1: TAe0§Cto70

C, VCC e5V g5%)

(8086-2: TAe0§Cto70

C, VCC e5V g5%)

MINIMUM COMPLEXITY SYSTEM TIMING REQUIREMENTS

Symbol Parameter 8086 8086-1 8086-2 Units Test Conditions

Min Max Min Max Min Max

TCLCL CLK Cycle Period 200 500 100 500 125 500 ns

TCLCH CLK Low Time 118 53 68 ns

TCHCL CLK High Time 69 39 44 ns

TCH1CH2 CLK Rise Time 10 10 10 ns From 1.0V to 3.5V

TCL2CL1 CLK Fall Time 10 10 10 ns From 3.5V to 1.0V

TDVCL Data in Setup Time 30 5 20 ns

TCLDX Data in Hold Time 10 10 10 ns

TR1VCL RDY Setup Time 35 35 35 ns

into 8284A (See

Notes 1, 2)

TCLR1X RDY Hold Time 0 0 0 ns

into 8284A (See

Notes 1, 2)

TRYHCH READY Setup 118 53 68 ns

Time into 8086

TCHRYX READY Hold Time 30 20 20 ns

into 8086

TRYLCL READY Inactive to b8b10 b8ns

CLK (See Note 3)

THVCH HOLD Setup Time 35 20 20 ns

TINVCH INTR, NMI, TEST 30 15 15 ns

Setup Time (See

Note 2)

TILIH Input Rise Time 20 20 20 ns From 0.8V to 2.0V

(Except CLK)

TIHIL Input Fall Time 12 12 12 ns From 2.0V to 0.8V

(Except CLK)

8086

A.C. CHARACTERISTICS (Continued)

TIMING RESPONSES

Symbol Parameter 8086 8086-1 8086-2 Units Test

Min Max Min Max Min Max Conditions

TCLAV Address Valid Delay 10 110 10 50 10 60 ns

TCLAX Address Hold Time 10 10 10 ns

TCLAZ Address Float TCLAX 80 10 40 TCLAX 50 ns

Delay

TLHLL ALE Width TCLCH-20 TCLCH-10 TCLCH-10 ns

TCLLH ALE Active Delay 80 40 50 ns

TCHLL ALE Inactive Delay 85 45 55 ns

TLLAX Address Hold Time TCHCL-10 TCHCL-10 TCHCL-10 ns

TCLDV Data Valid Delay 10 110 10 50 10 60 ns *CLe20–100 pF

for all 8086

TCHDX Data Hold Time 10 10 10 ns Outputs (In

addition to 8086

TWHDX Data Hold Time TCLCH-30 TCLCH-25 TCLCH-30 ns

selfload)

After WR

TCVCTV Control Active 10 110 10 50 10 70 ns

Delay 1

TCHCTV Control Active 10 110 10 45 10 60 ns

Delay 2

TCVCTX Control Inactive 10 110 10 50 10 70 ns

Delay

TAZRL Address Float to 0 0 0 ns

READ Active

TCLRL RD Active Delay 10 165 10 70 10 100 ns

TCLRH RD Inactive Delay 10 150 10 60 10 80 ns

TRHAV RD Inactive to Next TCLCL-45 TCLCL-35 TCLCL-40 ns

Address Active

TCLHAV HLDA Valid Delay 10 160 10 60 10 100 ns

TRLRH RD Width 2TCLCL-75 2TCLCL-40 2TCLCL-50 ns

TWLWH WR Width 2TCLCL-60 2TCLCL-35 2TCLCL-40 ns

TAVAL Address Valid to TCLCH-60 TCLCH-35 TCLCH-40 ns

ALE Low

TOLOH Output Rise Time 20 20 20 ns From 0.8V to 2.0V

TOHOL Output Fall Time 12 12 12 ns From 2.0V to 0.8V

NOTES:

1. Signal at 8284A shown for reference only.

2. Setup requirement for asynchronous signal only to guarantee recognition at next CLK.

3. Applies only to T2 state. (8 ns into T3).

8086

A.C. TESTING INPUT, OUTPUT WAVEFORM

231455-11

A.C. Testing: Inputs are driven at 2.4V for a Logic ‘‘1’’ and 0.45V

for a Logic ‘‘0’’. Timing measurements are made at 1.5V for both

a Logic ‘‘1’’ and ‘‘0’’.

A.C. TESTING LOAD CIRCUIT

231455–12

CLIncludes Jig Capacitance

WAVEFORMS

MINIMUM MODE

231455–13

8086

WAVEFORMS (Continued)

MINIMUM MODE (Continued)

231455–14

SOFTWARE HALTÐ

RD, WR, INTA eVOH

DT/R eINDETERMINATE

NOTES:

1. All signals switch between VOH and VOL unless otherwise specified.

2. RDY is sampled near the end of T2,T

Wto determine if TWmachines states are to be inserted.

3. Two INTA cycles run back-to-back. The 8086 LOCAL ADDR/DATA BUS is floating during both INTA cycles. Control

signals shown for second INTA cycle.

4. Signals at 8284A are shown for reference only.

5. All timing measurements are made at 1.5V unless otherwise noted.

8086

A.C. CHARACTERISTICS

MAX MODE SYSTEM (USING 8288 BUS CONTROLLER)

TIMING REQUIREMENTS

Symbol Parameter 8086 8086-1 8086-2 Units Test

Min Max Min Max Min Max Conditions

TCLCL CLK Cycle Period 200 500 100 500 125 500 ns

TCLCH CLK Low Time 118 53 68 ns

TCHCL CLK High Time 69 39 44 ns

TCH1CH2 CLK Rise Time 10 10 10 ns From 1.0V to 3.5V

TCL2CL1 CLK Fall Time 10 10 10 ns From 3.5V to 1.0V

TDVCL Data in Setup Time 30 5 20 ns

TCLDX Data in Hold Time 10 10 10 ns

TR1VCL RDY Setup Time 35 35 35 ns

into 8284A

(Notes 1, 2)

TCLR1X RDY Hold Time 0 0 0 ns

into 8284A

(Notes 1, 2)

TRYHCH READY Setup 118 53 68 ns

Time into 8086

TCHRYX READY Hold Time 30 20 20 ns

into 8086

TRYLCL READY Inactive to b8b10 b8ns

CLK (Note 4)

TINVCH Setup Time for 30 15 15 ns

Recognition (INTR,

NMI, TEST)

(Note 2)

TGVCH RQ/GT Setup Time 30 15 15 ns

(Note 5)

TCHGX RQ Hold Time into 40 20 30 ns

8086

TILIH Input Rise Time 20 20 20 ns From 0.8V to 2.0V

(Except CLK)

TIHIL Input Fall Time 12 12 12 ns From 2.0V to 0.8V

(Except CLK)

8086

A.C. CHARACTERISTICS (Continued)

TIMING RESPONSES

Symbol Parameter 8086 8086-1 8086-2 Units Test

Min Max Min Max Min Max Conditions

TCLML Command Active 10 35 10 35 10 35 ns

Delay (See Note 1)

TCLMH Command Inactive 10 35 10 35 10 35 ns

Delay (See Note 1)

TRYHSH READY Active to 110 45 65 ns

Status Passive (See

Note 3)

TCHSV Status Active Delay 10 110 10 45 10 60 ns

TCLSH Status Inactive 10 130 10 55 10 70 ns

Delay

TCLAV Address Valid Delay 10 110 10 50 10 60 ns

TCLAX Address Hold Time 10 10 10 ns

TCLAZ Address Float Delay TCLAX 80 10 40 TCLAX 50 ns

TSVLH Status Valid to ALE 15 15 15 ns

High (See Note 1)

TSVMCH Status Valid to 15 15 15 ns

MCE High (See

Note 1)

TCLLH CLK Low to ALE 15 15 15 ns CLe20–100 pF

for all 8086

Valid (See Note 1)

Outputs (In

TCLMCH CLK Low to MCE 15 15 15 ns addition to 8086

High (See Note 1) self-load)

TCHLL ALE Inactive Delay 15 15 15 ns

(See Note 1)

TCLMCL MCE Inactive Delay 15 15 15 ns

(See Note 1)

TCLDV Data Valid Delay 10 110 10 50 10 60 ns

TCHDX Data Hold Time 10 10 10 ns

TCVNV Control Active 5 45 5 45 5 45 ns

Delay (See Note 1)

TCVNX Control Inactive 10 45 10 45 10 45 ns

Delay (See Note 1)

TAZRL Address Float to 0 0 0 ns

READ Active

TCLRL RD Active Delay 10 165 10 70 10 100 ns

TCLRH RD Inactive Delay 10 150 10 60 10 80 ns

8086

A.C. CHARACTERISTICS (Continued)

TIMING RESPONSES (Continued)

Symbol Parameter 8086 8086-1 8086-2 Units Test

Min Max Min Max Min Max Conditions

TRHAV RD Inactive to Next TCLCL-45 TCLCL-35 TCLCL-40 ns

Address Active

TCHDTL Direction Control 50 50 50 ns CLe20 –100 pF

for all 8086

Active Delay

Outputs (In

(Note 1) addition to 8086

TCHDTH Direction Control 30 30 30 ns self-load)

Inactive Delay

(Note 1)

TCLGL GT Active Delay 0 85 0 38 0 50 ns

TCLGH GT Inactive Delay 0 85 0 45 0 50 ns

TRLRH RD Width 2TCLCL-75 2TCLCL-40 2TCLCL-50 ns

TOLOH Output Rise Time 20 20 20 ns From 0.8V to 2.0V

TOHOL Output Fall Time 12 12 12 ns From 2.0V to 0.8V

NOTES:

1. Signal at 8284A or 8288 shown for reference only.

2. Setup requirement for asynchronous signal only to guarantee recognition at next CLK.

3. Applies only to T3 and wait states.

4. Applies only to T2 state (8 ns into T3).

8086

WAVEFORMS

MAXIMUM MODE

231455–15

8086

WAVEFORMS (Continued)

MAXIMUM MODE (Continued)

231455–16

NOTES:

1. All signals switch between VOH and VOL unless otherwise specified.

2. RDY is sampled near the end of T2,T

Wto determine if TWmachines states are to be inserted.

3. Cascade address is valid between first and second INTA cycle.

4. Two INTA cycles run back-to-back. The 8086 LOCAL ADDR/DATA BUS is floating during both INTA cycles. Control for

pointer address is shown for second INTA cycle.

5. Signals at 8284A or 8288 are shown for reference only.

6. The issuance of the 8288 command and control signals (MRDC, MWTC, AMWC, IORC, IOWC, AIOWC, INTA and DEN)

lags the active high 8288 CEN.

7. All timing measurements are made at 1.5V unless otherwise noted.

8. Status inactive in state just prior to T4.

8086

WAVEFORMS (Continued)

ASYNCHRONOUS SIGNAL RECOGNITION

231455–17

NOTE:

1. Setup requirements for asynchronous signals only to guarantee recognition at next CLK.

BUS LOCK SIGNAL TIMING (MAXIMUM MODE

ONLY)

231455–18

RESET TIMING

231455–19

REQUEST/GRANT SEQUENCE TIMING (MAXIMUM MODE ONLY)

231455–20

NOTE:

The coprocessor may not drive the buses outside the region shown without risking contention.

8086

WAVEFORMS (Continued)

HOLD/HOLD ACKNOWLEDGE TIMING (MINIMUM MODE ONLY)

231455–21

8086

Table 2. Instruction Set Summary

Mnemonic and Instruction Code

Description

DATA TRANSFER

MOV eMove: 76543210 76543210 76543210 76543210

Immediate to Register/Memory 1100011w mod000r/m data data if w e1

Immediate to Register 1011wreg data data if w e1

Memory to Accumulator 1010000w addr-low addr-high

Accumulator to Memory 1010001w addr-low addr-high

Segment Register to Register/Memory 10001100 mod0regr/m

PUSH ePush:

Segment Register 000reg110

POP ePop:

Segment Register 000reg111

XCHG eExchange:

IN eInput from:

Fixed Port 1110010w port

Variable Port 1110110w

OUT eOutput to:

Fixed Port 1110011w port

Variable Port 1110111w

XLAT eTranslate Byte to AL 11010111

LEA eLoad EA to Register 10001101 modregr/m

LDS eLoad Pointer to DS 11000101 modregr/m

LES eLoad Pointer to ES 11000100 modregr/m

LAHF eLoad AH with Flags 10011111

SAHF eStore AH into Flags 10011110

PUSHF ePush Flags 10011100

POPF ePop Flags 10011101

8086

Table 2. Instruction Set Summary (Continued)

Mnemonic and Instruction Code

Description

ARITHMETIC 76543210 76543210 76543210 76543210

ADD eAdd:

Reg./Memory with Register to Either 000000dw modregr/m

Immediate to Register/Memory 100000sw mod000r/m data data if s: w e01

Immediate to Accumulator 0000010w data data if w e1

ADC eAdd with Carry:

Reg./Memory with Register to Either 000100dw modregr/m

Immediate to Register/Memory 100000sw mod010r/m data data if s: w e01

Immediate to Accumulator 0001010w data data if w e1

INC eIncrement:

AAA eASCII Adjust for Add 00110111

BAA eDecimal Adjust for Add 00100111

SUB eSubtract:

Reg./Memory and Register to Either 001010dw modregr/m

Immediate from Register/Memory 100000sw mod101r/m data data if s w e01

Immediate from Accumulator 0010110w data data if w e1

SSB eSubtract with Borrow

Reg./Memory and Register to Either 000110dw modregr/m

Immediate from Register/Memory 100000sw mod011r/m data data if s w e01

Immediate from Accumulator 000111w data data if w e1

DEC eDecrement:

NEG eChange sign 1111011w mod011 r/m

CMP eCompare:

Immediate with Register/Memory 100000sw mod111r/m data data if s w e01

Immediate with Accumulator 0011110w data data if w e1

AAS eASCII Adjust for Subtract 00111111

DAS eDecimal Adjust for Subtract 00101111

MUL eMultiply (Unsigned) 1111011w mod100r/m

IMUL eInteger Multiply (Signed) 1111011w mod101r/m

AAM eASCII Adjust for Multiply 11010100 00001010

DIV eDivide (Unsigned) 1111011w mod110r/m

IDIV eInteger Divide (Signed) 1111011w mod111r/m

AAD eASCII Adjust for Divide 11010101 00001010

CBW eConvert Byte to Word 10011000

CWD eConvert Word to Double Word 10011001

8086

Table 2. Instruction Set Summary (Continued)

Mnemonic and Instruction Code

Description

LOGIC 76543210 76543210 76543210 76543210

NOT eInvert 1111011w mod010r/m

SHL/SAL eShift Logical/Arithmetic Left 110100vw mod100r/m

SHR eShift Logical Right 110100vw mod101r/m

SAR eShift Arithmetic Right 110100vw mod111r/m

ROL eRotate Left 110100vw mod000r/m

ROR eRotate Right 110100vw mod001r/m

RCL eRotate Through Carry Flag Left 110100vw mod010r/m

RCR eRotate Through Carry Right 110100vw mod011r/m

AND eAnd:

Reg./Memory and Register to Either 001000dw modregr/m

Immediate to Register/Memory 1000000w mod100r/m data data if w e1

Immediate to Accumulator 0010010w data data if w e1

TEST eAnd Function to Flags, No Result:

Immediate Data and Register/Memory 1111011w mod000r/m data data if w e1

Immediate Data and Accumulator 1010100w data data if w e1

OR eOr:

Reg./Memory and Register to Either 000010dw modregr/m

Immediate to Register/Memory 1000000w mod001r/m data data if w e1

Immediate to Accumulator 0000110w data data if w e1

XOR eExclusive or:

Reg./Memory and Register to Either 001100dw modregr/m

Immediate to Register/Memory 1000000w mod110r/m data data if w e1

Immediate to Accumulator 0011010w data data if w e1

STRING MANIPULATION

REP eRepeat 1111001z

MOVS eMove Byte/Word 1010010w

CMPS eCompare Byte/Word 1010011w

SCAS eScan Byte/Word 1010111w

LODS eLoad Byte/Wd to AL/AX 1010110w

STOS eStor Byte/Wd from AL/A 1010101w

CONTROL TRANSFER

CALL eCall:

Direct within Segment 11101000 disp-low disp-high

Indirect within Segment 11111111 mod010r/m

Direct Intersegment 10011010 offset-low offset-high

seg-low seg-high

Indirect Intersegment 11111111 mod011r/m

8086

Table 2. Instruction Set Summary (Continued)

Mnemonic and Instruction Code

Description

JMP eUnconditional Jump: 76543210 76543210 76543210

Direct within Segment 11101001 disp-low disp-high

Direct within Segment-Short 11101011 disp

Indirect within Segment 11111111 mod100r/m

Direct Intersegment 11101010 offset-low offset-high

seg-low seg-high

Indirect Intersegment 11111111 mod101r/m

RET eReturn from CALL:

Within Segment 11000011

Within Seg Adding Immed to SP 11000010 data-low data-high

Intersegment 11001011

Intersegment Adding Immediate to SP 11001010 data-low data-high

JE/JZ eJump on Equal/Zero 01110100 disp

JL/JNGE eJump on Less/Not Greater 01111100 disp

or Equal

JLE/JNG eJump on Less or Equal/ 01111110 disp

Not Greater

JB/JNAE eJump on Below/Not Above 01110010 disp

or Equal

JBE/JNA eJump on Below or Equal/ 01110110 disp

Not Above

JP/JPE eJump on Parity/Parity Even 01111010 disp

JO eJump on Overflow 01110000 disp

JS eJump on Sign 01111000 disp

JNE/JNZ eJump on Not Equal/Not Zero 01110101 disp

JNL/JGE eJump on Not Less/Greater 01111101 disp

or Equal

JNLE/JG eJump on Not Less or Equal/ 01111111 disp

Greater

JNB/JAE eJump on Not Below/Above 01110011 disp

or Equal

JNBE/JA eJump on Not Below or 01110111 disp

Equal/Above

JNP/JPO eJump on Not Par/Par Odd 01111011 disp

JNO eJump on Not Overflow 01110001 disp

JNS eJump on Not Sign 01111001 disp

LOOP eLoop CX Times 11100010 disp

LOOPZ/LOOPE eLoop While Zero/Equal 11100001 disp

LOOPNZ/LOOPNE eLoop While Not 11100000 disp

Zero/Equal

JCXZ eJump on CX Zero 11100011 disp

INT eInterrupt

Type Specified 11001101 type

Type 3 11001100

INTO eInterrupt on Overflow 11001110

IRET eInterrupt Return 11001111

8086

Table 2. Instruction Set Summary (Continued)

Mnemonic and Instruction Code

Description

76543210 76543210

PROCESSOR CONTROL

CLC eClear Carry 11111000

CMC eComplement Carry 11110101

STC eSet Carry 11111001

CLD eClear Direction 11111100

STD eSet Direction 11111101

CLI eClear Interrupt 11111010

STI eSet Interrupt 11111011

HLT eHalt 11110100

WAIT eWait 10011011

ESC eEscape (to External Device) 11011xxx modxxxr/m

LOCK eBus Lock Prefix 11110000

NOTES:

AL e8-bit accumulator

AX e16-bit accumulator

CX eCount register

DS eData segment

ES eExtra segment

Above/below refers to unsigned value

Greater emore positive;

Less eless positive (more negative) signed values

if d e1 then ‘‘to’’ reg; if d e0 then ‘‘from’’ reg

if w e1 then word instruction; if w e0 then byte instruc-

tion

if mod e11 then r/m is treated as a REG field

if mod e00 then DISP e0*, disp-low and disp-high are

absent

if mod e01 then DISP edisp-low sign-extended to

16 bits, disp-high is absent

if mod e10 then DISP edisp-high; disp-low

if r/m e000 then EA e(BX) a(SI) aDISP

if r/m e001 then EA e(BX) a(DI) aDISP

if r/m e010 then EA e(BP) a(SI) aDISP

if r/m e011 then EA e(BP) a(DI) aDISP

if r/m e100 then EA e(SI) aDISP

if r/m e101 then EA e(DI) aDISP

if r/m e110 then EA e(BP) aDISP*

if r/m e111 then EA e(BX) aDISP

DISP follows 2nd byte of instruction (before data if re-

quired)

*except if mod e00 and r/m e110 then EA edisp-high;

disp-low.

ifswe01 then 16 bits of immediate data form the oper-

and

ifswe11 then an immediate data byte is sign extended

to form the 16-bit operand

if v e0 then ‘‘count’’ e1; if v e1 then ‘‘count’’ in (CL)

xedon’t care

z is used for string primitives for comparison with ZF FLAG

SEGMENT OVERRIDE PREFIX

001reg110

REG is assigned according to the following table:

16-Bit (w e1) 8-Bit (w e0) Segment

000 AX 000 AL 00 ES

001 CX 001 CL 01 CS

010 DX 010 DL 10 SS

011 BX 011 BL 11 DS

100 SP 100 AH

101 BP 101 CH

110 SI 110 DH

111 DI 111 BH

Instructions which reference the flag register file as a 16-bit

object use the symbol FLAGS to represent the file:

FLAGS eX:X:X:X:(OF):(DF):(IF):(TF):(SF):(ZF):X:(AF):X:(PF):X:(CF)

DATA SHEET REVISION REVIEW

The following list represents key differences between this and the -004 data sheet. Please review this summa-

ry carefully.

1. The Intel 8086 implementation technology (HMOS) has been changed to (HMOS-III).

2. Delete all ‘‘changes from 1985 Handbook Specification’’ sentences.

Intel 8086 Users Manual

8086-1 to the manual a4abd15f-84d6-4711-88b1-60204e5d1e35

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