8086汇编指令快速参考

从emu8086软件的文档中看到的，觉得不错，所以拷贝出来了！

Complete 8086 instruction set  

---

Quick reference:

AAA  AAD  AAM  AAS  ADC  ADD  AND  CALL  CBW  CLC  CLD  CLI  CMC  CMP

CMPSB  CMPSW  CWD  DAA  DAS  DEC  DIV  HLT  IDIV  IMUL  IN  INC  INT  INTO  IRET  JA

JAE  JB  JBE  JC  JCXZ  JE  JG  JGE  JL  JLE  JMP  JNA  JNAE  JNB

JNBE  JNC  JNE  JNG  JNGE  JNL  JNLE  JNO  JNP  JNS  JNZ  JO  JP  JPE

JPO  JS  JZ  LAHF  LDS  LEA  LES  LODSB  LODSW  LOOP  LOOPE  LOOPNE  LOOPNZ  LOOPZ

MOV  MOVSB  MOVSW  MUL  NEG  NOP  NOT  OR  OUT  POP  POPA  POPF  PUSH  PUSHA  PUSHF  RCL

RCR  REP  REPE  REPNE  REPNZ  REPZ  RET  RETF  ROL  ROR  SAHF  SAL  SAR  SBB

SCASB  SCASW  SHL  SHR  STC  STD  STI  STOSB  STOSW  SUB  TEST  XCHG  XLATB  XOR

---

Operand types:

REG: AX, BX, CX, DX, AH, AL, BL, BH, CH, CL, DH, DL, DI, SI, BP, SP.

SREG: DS, ES, SS, and only as second operand: CS.

memory: [BX], [BX+SI+7], variable, etc...(see Memory Access).

immediate: 5, -24, 3Fh, 10001101b, etc...

---

Notes:

• When two operands are required for an instruction they are separated by comma. For example:
  
  REG, memory 
  
  
• When there are two operands, both operands must have the same size (except shift and rotate instructions). For example:
  
  AL, DL
  DX, AX
  m1 DB ?
  AL, m1
  m2 DW ?
  AX, m2 
  
  
• Some instructions allow several operand combinations. For example:
  
  memory, immediate
  REG, immediate
  
  memory, REG
  REG, SREG 
  
  
• Some examples contain macros, so it is advisable to use Shift + F8 hot key to Step Over (to make macro code execute at maximum speed set step delay to zero), otherwise emulator will step through each instruction of a macro. Here is an example that uses PRINTN macro:

   
     include 'emu8086.inc'
     ORG 100h
     MOV AL, 1
     MOV BL, 2
     PRINTN 'Hello World!'   ; macro.
     MOV CL, 3
     PRINTN 'Welcome!'       ; macro.
     RET

 

---

These marks are used to show the state of the flags:

1 - instruction sets this flag to 1.
0 - instruction sets this flag to 0.
r - flag value depends on result of the instruction.
? - flag value is undefined (maybe 1 or 0).

---

Some instructions generate exactly the same machine code, so disassembler may have a problem decoding to your original code. This is especially important for Conditional Jump instructions (see "Program Flow Control" in Tutorials for more information). 

---

Instructions in alphabetical order: 

Instruction

Operands

Description  

AAA

No operands

ASCII Adjust after Addition.
Corrects result in AH and AL after addition when working with BCD values. 

It works according to the following Algorithm: 

if low nibble of AL > 9 or AF = 1 then:

• AL = AL + 6
• AH = AH + 1
• AF = 1
• CF = 1

else

• AF = 0
• CF = 0

in both cases:
clear the high nibble of AL. 

Example:

MOV AX, 15   ; AH = 00, AL = 0Fh
AAA          ; AH = 01, AL = 05
RET

C	Z	S	O	P	A
r	?	?	?	?	r

 

AAD

No operands

ASCII Adjust before Division.
Prepares two BCD values for division. 

Algorithm: 

• AL = (AH * 10) + AL
• AH = 0

Example:

MOV AX, 0105h   ; AH = 01, AL = 05
AAD             ; AH = 00, AL = 0Fh (15)
RET

C	Z	S	O	P	A
?	r	r	?	r	?

 

AAM

No operands

ASCII Adjust after Multiplication.
Corrects the result of multiplication of two BCD values. 

Algorithm: 

• AH = AL / 10
• AL = remainder

Example:

MOV AL, 15   ; AL = 0Fh
AAM          ; AH = 01, AL = 05
RET

C	Z	S	O	P	A
?	r	r	?	r	?

 

AAS

No operands

ASCII Adjust after Subtraction.
Corrects result in AH and AL after subtraction when working with BCD values. 

Algorithm:

if low nibble of AL > 9 or AF = 1 then:

• AL = AL - 6
• AH = AH - 1
• AF = 1
• CF = 1

else

• AF = 0
• CF = 0

in both cases:
clear the high nibble of AL. 

Example:

MOV AX, 02FFh  ; AH = 02, AL = 0FFh
AAS            ; AH = 01, AL = 09
RET

C	Z	S	O	P	A
r	?	?	?	?	r

 

ADC

REG, memory
memory, REG
REG, REG
memory, immediate
REG, immediate

Add with Carry.


Algorithm:

operand1 = operand1 + operand2 + CF 

Example:

STC        ; set CF = 1
MOV AL, 5  ; AL = 5
ADC AL, 1  ; AL = 7
RET

C	Z	S	O	P	A
r	r	r	r	r	r

 

ADD

REG, memory
memory, REG
REG, REG
memory, immediate
REG, immediate

Add.


Algorithm:

operand1 = operand1 + operand2 

Example:

MOV AL, 5   ; AL = 5
ADD AL, -3  ; AL = 2
RET

C	Z	S	O	P	A
r	r	r	r	r	r

 

AND

REG, memory
memory, REG
REG, REG
memory, immediate
REG, immediate

Logical AND between all bits of two operands. Result is stored in operand1.

These rules apply:

1 AND 1 = 1
1 AND 0 = 0
0 AND 1 = 0
0 AND 0 = 0


Example:

MOV AL, 'a'        ; AL = 01100001b
AND AL, 11011111b  ; AL = 01000001b  ('A')
RET

C	Z	S	O	P
0	r	r	0	r

 

CALL

procedure name
label
4-byte address

Transfers control to procedure. Return address (IP) is pushed to stack. 4-byte address may be entered in this form: 1234h:5678h, first value is a segment second value is an offset. If it's a far call, then code segment is pushed to stack as well.


Example:

ORG 100h  ; for COM file.

CALL p1

ADD AX, 1

RET         ; return to OS.

p1 PROC     ; procedure declaration.
    MOV AX, 1234h
    RET     ; return to caller.
p1 ENDP

C	Z	S	O	P	A
unchanged

 

CBW

No operands

Convert byte into word. 

Algorithm: 

if high bit of AL = 1 then:

• AH = 255 (0FFh)

else

• AH = 0

Example:

MOV AX, 0   ; AH = 0, AL = 0
MOV AL, -5  ; AX = 000FBh (251)
CBW         ; AX = 0FFFBh (-5)
RET

C	Z	S	O	P	A
unchanged

 

CLC

No operands

Clear Carry flag. 

Algorithm: 

CF = 0 

C

0

 

CLD

No operands

Clear Direction flag. SI and DI will be incremented by chain instructions: CMPSB, CMPSW, LODSB, LODSW, MOVSB, MOVSW, STOSB, STOSW. 

Algorithm: 

DF = 0 

D

0

 

CLI

No operands

Clear Interrupt enable flag. This disables hardware interrupts. 

Algorithm: 

IF = 0 

I

0

 

CMC

No operands

Complement Carry flag. Inverts value of CF. 

Algorithm: 

if CF = 1 then CF = 0
if CF = 0 then CF = 1

C

r

 

CMP

REG, memory
memory, REG
REG, REG
memory, immediate
REG, immediate

Compare. 

Algorithm:

operand1 - operand2 

result is not stored anywhere, flags are set (OF, SF, ZF, AF, PF, CF) according to result. 

Example:

MOV AL, 5
MOV BL, 5
CMP AL, BL  ; AL = 5, ZF = 1 (so equal!)
RET

C	Z	S	O	P	A
r	r	r	r	r	r

 

CMPSB

No operands

Compare bytes: ES:[DI] from DS:[SI]. 

Algorithm: 

• DS:[SI] - ES:[DI]
• set flags according to result:
  OF, SF, ZF, AF, PF, CF
• if DF = 0 then
  • SI = SI + 1
  • DI = DI + 1
  else
  • SI = SI - 1
  • DI = DI - 1

Example:
open cmpsb.asm from c:emu8086examples 

C	Z	S	O	P	A
r	r	r	r	r	r

 

CMPSW

No operands

Compare words: ES:[DI] from DS:[SI]. 

Algorithm: 

• DS:[SI] - ES:[DI]
• set flags according to result:
  OF, SF, ZF, AF, PF, CF
• if DF = 0 then
  • SI = SI + 2
  • DI = DI + 2
  else
  • SI = SI - 2
  • DI = DI - 2

example:
open cmpsw.asm from c:emu8086examples 

C	Z	S	O	P	A
r	r	r	r	r	r

 

CWD

No operands

Convert Word to Double word. 

Algorithm: 

if high bit of AX = 1 then:

• DX = 65535 (0FFFFh)

else

• DX = 0

Example:

MOV DX, 0   ; DX = 0
MOV AX, 0   ; AX = 0
MOV AX, -5  ; DX AX = 00000h:0FFFBh
CWD         ; DX AX = 0FFFFh:0FFFBh
RET

C	Z	S	O	P	A
unchanged

 

DAA

No operands

Decimal adjust After Addition.
Corrects the result of addition of two packed BCD values. 

Algorithm: 

if low nibble of AL > 9 or AF = 1 then:

• AL = AL + 6
• AF = 1

if AL > 9Fh or CF = 1 then:

• AL = AL + 60h
• CF = 1

Example:

MOV AL, 0Fh  ; AL = 0Fh (15)
DAA          ; AL = 15h
RET

C	Z	S	O	P	A
r	r	r	r	r	r

 

DAS

No operands

Decimal adjust After Subtraction.
Corrects the result of subtraction of two packed BCD values. 

Algorithm: 

if low nibble of AL > 9 or AF = 1 then:

• AL = AL - 6
• AF = 1

if AL > 9Fh or CF = 1 then:

• AL = AL - 60h
• CF = 1

Example:

MOV AL, 0FFh  ; AL = 0FFh (-1)
DAS           ; AL = 99h, CF = 1
RET

C	Z	S	O	P	A
r	r	r	r	r	r

 

DEC

REG
memory

Decrement. 

Algorithm:

operand = operand - 1 


Example:

MOV AL, 255  ; AL = 0FFh (255 or -1)
DEC AL       ; AL = 0FEh (254 or -2)
RET

Z	S	O	P	A
r	r	r	r	r

CF - unchanged!  

DIV

REG
memory

Unsigned divide. 

Algorithm:

when operand is a byte:
AL = AX / operand
AH = remainder (modulus)

when operand is a word:
AX = (DX AX) / operand
DX = remainder (modulus)

Example:

MOV AX, 203   ; AX = 00CBh
MOV BL, 4
DIV BL        ; AL = 50 (32h), AH = 3
RET

C	Z	S	O	P	A
?	?	?	?	?	?

 

HLT

No operands

Halt the System.

Example:

MOV AX, 5
HLT

C	Z	S	O	P	A
unchanged

 

IDIV

REG
memory

Signed divide. 

Algorithm:

when operand is a byte:
AL = AX / operand
AH = remainder (modulus)

when operand is a word:
AX = (DX AX) / operand
DX = remainder (modulus)

Example:

MOV AX, -203 ; AX = 0FF35h
MOV BL, 4
IDIV BL      ; AL = -50 (0CEh), AH = -3 (0FDh)
RET

C	Z	S	O	P	A
?	?	?	?	?	?

 

IMUL

REG
memory

Signed multiply. 

Algorithm:

when operand is a byte:
AX = AL * operand.

when operand is a word:
(DX AX) = AX * operand.

Example:

MOV AL, -2
MOV BL, -4
IMUL BL      ; AX = 8
RET

C	Z	S	O	P	A
r	?	?	r	?	?

CF=OF=0 when result fits into operand of IMUL.  

IN

AL, im.byte
AL, DX
AX, im.byte
AX, DX

Input from port into AL or AX.
Second operand is a port number. If required to access port number over 255 - DX register should be used. 
Example:

IN AX, 4  ; get status of traffic lights.
IN AL, 7  ; get status of stepper-motor.

C	Z	S	O	P	A
unchanged

 

INC

REG
memory

Increment. 

Algorithm:

operand = operand + 1 

Example:

MOV AL, 4
INC AL       ; AL = 5
RET

Z	S	O	P	A
r	r	r	r	r

CF - unchanged!  

INT

immediate byte

Interrupt numbered by immediate byte (0..255). 

Algorithm:

Push to stack:
• flags register
• CS
• IP
• IF = 0
• Transfer control to interrupt procedure

Example:

MOV AH, 0Eh  ; teletype.
MOV AL, 'A'
INT 10h      ; BIOS interrupt.
RET

C	Z	S	O	P	A	I
unchanged						0

 

INTO

No operands

Interrupt 4 if Overflow flag is 1. 

Algorithm:

if OF = 1 then INT 4 

Example:

; -5 - 127 = -132 (not in -128..127)
; the result of SUB is wrong (124),
; so OF = 1 is set:
MOV AL, -5
SUB AL, 127   ; AL = 7Ch (124)
INTO          ; process error.
RET

 

IRET

No operands

Interrupt Return. 

Algorithm:

Pop from stack:
• IP
• CS
• flags register

C	Z	S	O	P	A
popped

 

JA

label

Short Jump if first operand is Above second operand (as set by CMP instruction). Unsigned. 

Algorithm:

if (CF = 0) and (ZF = 0) then jump

Example:

   include 'emu8086.inc'
   ORG 100h
   MOV AL, 250
   CMP AL, 5
   JA label1
   PRINT 'AL is not above 5'
   JMP exit
label1:
   PRINT 'AL is above 5'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

JAE

label

Short Jump if first operand is Above or Equal to second operand (as set by CMP instruction). Unsigned. 

Algorithm:

if CF = 0 then jump

Example:

   include 'emu8086.inc'
   ORG 100h
   MOV AL, 5
   CMP AL, 5
   JAE label1
   PRINT 'AL is not above or equal to 5'
   JMP exit
label1:
   PRINT 'AL is above or equal to 5'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

JB

label

Short Jump if first operand is Below second operand (as set by CMP instruction). Unsigned. 

Algorithm:

if CF = 1 then jump

Example:

   include 'emu8086.inc'
   ORG 100h
   MOV AL, 1
   CMP AL, 5
   JB  label1
   PRINT 'AL is not below 5'
   JMP exit
label1:
   PRINT 'AL is below 5'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

JBE

label

Short Jump if first operand is Below or Equal to second operand (as set by CMP instruction). Unsigned. 

Algorithm:

if CF = 1 or ZF = 1 then jump

Example:

   include 'emu8086.inc'
   ORG 100h
   MOV AL, 5
   CMP AL, 5
   JBE  label1
   PRINT 'AL is not below or equal to 5'
   JMP exit
label1:
   PRINT 'AL is below or equal to 5'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

JC

label

Short Jump if Carry flag is set to 1. 

Algorithm:

if CF = 1 then jump

Example:

   include 'emu8086.inc'
   ORG 100h
   MOV AL, 255
   ADD AL, 1
   JC  label1
   PRINT 'no carry.'
   JMP exit
label1:
   PRINT 'has carry.'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

JCXZ

label

Short Jump if CX register is 0. 

Algorithm:

if CX = 0 then jump

Example:

   include 'emu8086.inc'
   ORG 100h
   MOV CX, 0
   JCXZ label1
   PRINT 'CX is not zero.'
   JMP exit
label1:
   PRINT 'CX is zero.'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

JE

label

Short Jump if first operand is Equal to second operand (as set by CMP instruction). Signed/Unsigned. 

Algorithm:

if ZF = 1 then jump

Example:

   include 'emu8086.inc'
   ORG 100h
   MOV AL, 5
   CMP AL, 5
   JE  label1
   PRINT 'AL is not equal to 5.'
   JMP exit
label1:
   PRINT 'AL is equal to 5.'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

JG

label

Short Jump if first operand is Greater then second operand (as set by CMP instruction). Signed. 

Algorithm:

if (ZF = 0) and (SF = OF) then jump

Example:

   include 'emu8086.inc'
   ORG 100h
   MOV AL, 5
   CMP AL, -5
   JG  label1
   PRINT 'AL is not greater -5.'
   JMP exit
label1:
   PRINT 'AL is greater -5.'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

JGE

label

Short Jump if first operand is Greater or Equal to second operand (as set by CMP instruction). Signed. 

Algorithm:

if SF = OF then jump

Example:

   include 'emu8086.inc'
   ORG 100h
   MOV AL, 2
   CMP AL, -5
   JGE  label1
   PRINT 'AL < -5'
   JMP exit
label1:
   PRINT 'AL >= -5'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

JL

label

Short Jump if first operand is Less then second operand (as set by CMP instruction). Signed. 

Algorithm:

if SF <> OF then jump

Example:

   include 'emu8086.inc'
   ORG 100h
   MOV AL, -2
   CMP AL, 5
   JL  label1
   PRINT 'AL >= 5.'
   JMP exit
label1:
   PRINT 'AL < 5.'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

JLE

label

Short Jump if first operand is Less or Equal to second operand (as set by CMP instruction). Signed. 

Algorithm:

if SF <> OF or ZF = 1 then jump

Example:

   include 'emu8086.inc'
   ORG 100h
   MOV AL, -2
   CMP AL, 5
   JLE label1
   PRINT 'AL > 5.'
   JMP exit
label1:
   PRINT 'AL <= 5.'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

JMP

label
4-byte address

Unconditional Jump. Transfers control to another part of the program. 4-byte address may be entered in this form: 1234h:5678h, first value is a segment second value is an offset.


Algorithm:

always jump

Example:

   include 'emu8086.inc'
   ORG 100h
   MOV AL, 5
   JMP label1    ; jump over 2 lines!
   PRINT 'Not Jumped!'
   MOV AL, 0
label1:
   PRINT 'Got Here!'
   RET

C	Z	S	O	P	A
unchanged

 

JNA

label

Short Jump if first operand is Not Above second operand (as set by CMP instruction). Unsigned. 

Algorithm:

if CF = 1 or ZF = 1 then jump

Example:

   include 'emu8086.inc'

   ORG 100h
   MOV AL, 2
   CMP AL, 5
   JNA label1
   PRINT 'AL is above 5.'
   JMP exit
label1:
   PRINT 'AL is not above 5.'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

JNAE

label

Short Jump if first operand is Not Above and Not Equal to second operand (as set by CMP instruction). Unsigned. 

Algorithm:

if CF = 1 then jump

Example:

   include 'emu8086.inc'

   ORG 100h
   MOV AL, 2
   CMP AL, 5
   JNAE label1
   PRINT 'AL >= 5.'
   JMP exit
label1:
   PRINT 'AL < 5.'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

JNB

label

Short Jump if first operand is Not Below second operand (as set by CMP instruction). Unsigned. 

Algorithm:

if CF = 0 then jump

Example:

   include 'emu8086.inc'

   ORG 100h
   MOV AL, 7
   CMP AL, 5
   JNB label1
   PRINT 'AL < 5.'
   JMP exit
label1:
   PRINT 'AL >= 5.'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

JNBE

label

Short Jump if first operand is Not Below and Not Equal to second operand (as set by CMP instruction). Unsigned. 

Algorithm:

if (CF = 0) and (ZF = 0) then jump

Example:

   include 'emu8086.inc'

   ORG 100h
   MOV AL, 7
   CMP AL, 5
   JNBE label1
   PRINT 'AL <= 5.'
   JMP exit
label1:
   PRINT 'AL > 5.'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

JNC

label

Short Jump if Carry flag is set to 0. 

Algorithm:

if CF = 0 then jump

Example:

   include 'emu8086.inc'

   ORG 100h
   MOV AL, 2
   ADD AL, 3
   JNC  label1
   PRINT 'has carry.'
   JMP exit
label1:
   PRINT 'no carry.'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

JNE

label

Short Jump if first operand is Not Equal to second operand (as set by CMP instruction). Signed/Unsigned. 

Algorithm:

if ZF = 0 then jump

Example:

   include 'emu8086.inc'

   ORG 100h
   MOV AL, 2
   CMP AL, 3
   JNE  label1
   PRINT 'AL = 3.'
   JMP exit
label1:
   PRINT 'Al <> 3.'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

JNG

label

Short Jump if first operand is Not Greater then second operand (as set by CMP instruction). Signed. 

Algorithm:

if (ZF = 1) and (SF <> OF) then jump

Example:

   include 'emu8086.inc'

   ORG 100h
   MOV AL, 2
   CMP AL, 3
   JNG  label1
   PRINT 'AL > 3.'
   JMP exit
label1:
   PRINT 'Al <= 3.'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

JNGE

label

Short Jump if first operand is Not Greater and Not Equal to second operand (as set by CMP instruction). Signed. 

Algorithm:

if SF <> OF then jump

Example:

   include 'emu8086.inc'

   ORG 100h
   MOV AL, 2
   CMP AL, 3
   JNGE  label1
   PRINT 'AL >= 3.'
   JMP exit
label1:
   PRINT 'Al < 3.'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

JNL

label

Short Jump if first operand is Not Less then second operand (as set by CMP instruction). Signed. 

Algorithm:

if SF = OF then jump

Example:

   include 'emu8086.inc'

   ORG 100h
   MOV AL, 2
   CMP AL, -3
   JNL label1
   PRINT 'AL < -3.'
   JMP exit
label1:
   PRINT 'Al >= -3.'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

JNLE

label

Short Jump if first operand is Not Less and Not Equal to second operand (as set by CMP instruction). Signed. 

Algorithm:

if (SF = OF) and (ZF = 0) then jump

Example:

   include 'emu8086.inc'

   ORG 100h
   MOV AL, 2
   CMP AL, -3
   JNLE label1
   PRINT 'AL <= -3.'
   JMP exit
label1:
   PRINT 'Al > -3.'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

JNO

label

Short Jump if Not Overflow. 

Algorithm:

if OF = 0 then jump

Example:

; -5 - 2 = -7 (inside -128..127)
; the result of SUB is correct,
; so OF = 0:

include 'emu8086.inc'

ORG 100h
  MOV AL, -5
  SUB AL, 2   ; AL = 0F9h (-7)
JNO  label1
  PRINT 'overflow!'
JMP exit
label1:
  PRINT 'no overflow.'
exit:
  RET

C	Z	S	O	P	A
unchanged

 

JNP

label

Short Jump if No Parity (odd). Only 8 low bits of result are checked. Set by CMP, SUB, ADD, TEST, AND, OR, XOR instructions. 

Algorithm:

if PF = 0 then jump

Example:

   include 'emu8086.inc'

   ORG 100h
   MOV AL, 00000111b   ; AL = 7
   OR  AL, 0           ; just set flags.
   JNP label1
   PRINT 'parity even.'
   JMP exit
label1:
   PRINT 'parity odd.'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

JNS

label

Short Jump if Not Signed (if positive). Set by CMP, SUB, ADD, TEST, AND, OR, XOR instructions. 

Algorithm:

if SF = 0 then jump

Example:

   include 'emu8086.inc'

   ORG 100h
   MOV AL, 00000111b   ; AL = 7
   OR  AL, 0           ; just set flags.
   JNS label1
   PRINT 'signed.'
   JMP exit
label1:
   PRINT 'not signed.'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

JNZ

label

Short Jump if Not Zero (not equal). Set by CMP, SUB, ADD, TEST, AND, OR, XOR instructions. 

Algorithm:

if ZF = 0 then jump

Example:

   include 'emu8086.inc'

   ORG 100h
   MOV AL, 00000111b   ; AL = 7
   OR  AL, 0           ; just set flags.
   JNZ label1
   PRINT 'zero.'
   JMP exit
label1:
   PRINT 'not zero.'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

JO

label

Short Jump if Overflow. 

Algorithm:

if OF = 1 then jump

Example:

; -5 - 127 = -132 (not in -128..127)
; the result of SUB is wrong (124),
; so OF = 1 is set:

include 'emu8086.inc'

org 100h
  MOV AL, -5
  SUB AL, 127   ; AL = 7Ch (124)
JO  label1
  PRINT 'no overflow.'
JMP exit
label1:
  PRINT 'overflow!'
exit:
  RET

C	Z	S	O	P	A
unchanged

 

JP

label

Short Jump if Parity (even). Only 8 low bits of result are checked. Set by CMP, SUB, ADD, TEST, AND, OR, XOR instructions. 

Algorithm:

if PF = 1 then jump

Example:

   include 'emu8086.inc'

   ORG 100h
   MOV AL, 00000101b   ; AL = 5
   OR  AL, 0           ; just set flags.
   JP label1
   PRINT 'parity odd.'
   JMP exit
label1:
   PRINT 'parity even.'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

JPE

label

Short Jump if Parity Even. Only 8 low bits of result are checked. Set by CMP, SUB, ADD, TEST, AND, OR, XOR instructions. 

Algorithm:

if PF = 1 then jump

Example:

   include 'emu8086.inc'

   ORG 100h
   MOV AL, 00000101b   ; AL = 5
   OR  AL, 0           ; just set flags.
   JPE label1
   PRINT 'parity odd.'
   JMP exit
label1:
   PRINT 'parity even.'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

JPO

label

Short Jump if Parity Odd. Only 8 low bits of result are checked. Set by CMP, SUB, ADD, TEST, AND, OR, XOR instructions. 

Algorithm:

if PF = 0 then jump

Example:

   include 'emu8086.inc'

   ORG 100h
   MOV AL, 00000111b   ; AL = 7
   OR  AL, 0           ; just set flags.
   JPO label1
   PRINT 'parity even.'
   JMP exit
label1:
   PRINT 'parity odd.'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

JS

label

Short Jump if Signed (if negative). Set by CMP, SUB, ADD, TEST, AND, OR, XOR instructions. 

Algorithm:

if SF = 1 then jump

Example:

   include 'emu8086.inc'

   ORG 100h
   MOV AL, 10000000b   ; AL = -128
   OR  AL, 0           ; just set flags.
   JS label1
   PRINT 'not signed.'
   JMP exit
label1:
   PRINT 'signed.'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

JZ

label

Short Jump if Zero (equal). Set by CMP, SUB, ADD, TEST, AND, OR, XOR instructions. 

Algorithm:

if ZF = 1 then jump

Example:

   include 'emu8086.inc'

   ORG 100h
   MOV AL, 5
   CMP AL, 5
   JZ  label1
   PRINT 'AL is not equal to 5.'
   JMP exit
label1:
   PRINT 'AL is equal to 5.'
exit:
   RET

C	Z	S	O	P	A
unchanged

 

LAHF

No operands

Load AH from 8 low bits of Flags register. 

Algorithm:

AH = flags register

AH bit:   7    6   5    4   3    2   1    0
        [SF] [ZF] [0] [AF] [0] [PF] [1] [CF]

bits 1, 3, 5 are reserved. 

C	Z	S	O	P	A
unchanged

 

LDS

REG, memory

Load memory double word into word register and DS. 

Algorithm:

• REG = first word
• DS = second word

Example:

ORG 100h

LDS AX, m

RET

m  DW  1234h
   DW  5678h

END

AX is set to 1234h, DS is set to 5678h. 

C	Z	S	O	P	A
unchanged

 

LEA

REG, memory

Load Effective Address. 

Algorithm:

• REG = address of memory (offset)

Example:

MOV BX, 35h
MOV DI, 12h
LEA SI, [BX+DI]    ; SI = 35h + 12h = 47h 

Note: The integrated 8086 assembler automatically replaces LEA with a more efficient MOV where possible. For example:

org 100h
LEA AX, m       ; AX = offset of m
RET
m  dw  1234h
END

C	Z	S	O	P	A
unchanged

 

LES

REG, memory

Load memory double word into word register and ES. 

Algorithm:

• REG = first word
• ES = second word

Example:

ORG 100h

LES AX, m

RET

m  DW  1234h
   DW  5678h

END

AX is set to 1234h, ES is set to 5678h. 

C	Z	S	O	P	A
unchanged

 

LODSB

No operands

Load byte at DS:[SI] into AL. Update SI.

Algorithm: 

• AL = DS:[SI]
• if DF = 0 then
  • SI = SI + 1
  else
  • SI = SI - 1

Example:

ORG 100h

LEA SI, a1
MOV CX, 5
MOV AH, 0Eh

m: LODSB
INT 10h
LOOP m

RET

a1 DB 'H', 'e', 'l', 'l', 'o'

C	Z	S	O	P	A
unchanged

 

LODSW

No operands

Load word at DS:[SI] into AX. Update SI.

Algorithm: 

• AX = DS:[SI]
• if DF = 0 then
  • SI = SI + 2
  else
  • SI = SI - 2

Example:

ORG 100h

LEA SI, a1
MOV CX, 5

REP LODSW   ; finally there will be 555h in AX.

RET

a1 dw 111h, 222h, 333h, 444h, 555h

C	Z	S	O	P	A
unchanged

 

LOOP

label

Decrease CX, jump to label if CX not zero. 

Algorithm: 

• CX = CX - 1
• if CX <> 0 then
  • jump
  else
  • no jump, continue

Example:

   include 'emu8086.inc'

   ORG 100h
   MOV CX, 5
label1:
   PRINTN 'loop!'
   LOOP label1
   RET

C	Z	S	O	P	A
unchanged

 

LOOPE

label

Decrease CX, jump to label if CX not zero and Equal (ZF = 1). 

Algorithm: 

• CX = CX - 1
• if (CX <> 0) and (ZF = 1) then
  • jump
  else
  • no jump, continue

Example:

; Loop until result fits into AL alone,
; or 5 times. The result will be over 255
; on third loop (100+100+100),
; so loop will exit.

   include 'emu8086.inc'

   ORG 100h
   MOV AX, 0
   MOV CX, 5
label1:
   PUTC '*'
   ADD AX, 100
   CMP AH, 0
   LOOPE label1
   RET

C	Z	S	O	P	A
unchanged

 

LOOPNE

label

Decrease CX, jump to label if CX not zero and Not Equal (ZF = 0). 

Algorithm: 

• CX = CX - 1
• if (CX <> 0) and (ZF = 0) then
  • jump
  else
  • no jump, continue

Example:

; Loop until '7' is found,
; or 5 times.

   include 'emu8086.inc'

   ORG 100h
   MOV SI, 0
   MOV CX, 5
label1:
   PUTC '*'
   MOV AL, v1[SI]
   INC SI         ; next byte (SI=SI+1).
   CMP AL, 7
   LOOPNE label1
   RET
   v1 db 9, 8, 7, 6, 5

C	Z	S	O	P	A
unchanged

 

LOOPNZ

label

Decrease CX, jump to label if CX not zero and ZF = 0. 

Algorithm: 

• CX = CX - 1
• if (CX <> 0) and (ZF = 0) then
  • jump
  else
  • no jump, continue

Example:

; Loop until '7' is found,
; or 5 times.

   include 'emu8086.inc'

   ORG 100h
   MOV SI, 0
   MOV CX, 5
label1:
   PUTC '*'
   MOV AL, v1[SI]
   INC SI         ; next byte (SI=SI+1).
   CMP AL, 7
   LOOPNZ label1
   RET
   v1 db 9, 8, 7, 6, 5

C	Z	S	O	P	A
unchanged

 

LOOPZ

label

Decrease CX, jump to label if CX not zero and ZF = 1. 

Algorithm: 

• CX = CX - 1
• if (CX <> 0) and (ZF = 1) then
  • jump
  else
  • no jump, continue

Example:

; Loop until result fits into AL alone,
; or 5 times. The result will be over 255
; on third loop (100+100+100),
; so loop will exit.

   include 'emu8086.inc'

   ORG 100h
   MOV AX, 0
   MOV CX, 5
label1:
   PUTC '*'
   ADD AX, 100
   CMP AH, 0
   LOOPZ label1
   RET

C	Z	S	O	P	A
unchanged

 

MOV

REG, memory
memory, REG
REG, REG
memory, immediate
REG, immediate

SREG, memory
memory, SREG
REG, SREG
SREG, REG

Copy operand2 to operand1.

The MOV instruction cannot:

• set the value of the CS and IP registers.
• copy value of one segment register to another segment register (should copy to general register first).
• copy immediate value to segment register (should copy to general register first).

Algorithm:

operand1 = operand2

Example:

ORG 100h
MOV AX, 0B800h    ; set AX = B800h (VGA memory).
MOV DS, AX        ; copy value of AX to DS.
MOV CL, 'A'       ; CL = 41h (ASCII code).
MOV CH, 01011111b ; CL = color attribute.
MOV BX, 15Eh      ; BX = position on screen.
MOV [BX], CX      ; w.[0B800h:015Eh] = CX.
RET               ; returns to operating system.

C	Z	S	O	P	A
unchanged

 

MOVSB

No operands

Copy byte at DS:[SI] to ES:[DI]. Update SI and DI.

Algorithm: 

• ES:[DI] = DS:[SI]
• if DF = 0 then
  • SI = SI + 1
  • DI = DI + 1
  else
  • SI = SI - 1
  • DI = DI - 1

Example:

ORG 100h

CLD
LEA SI, a1
LEA DI, a2
MOV CX, 5
REP MOVSB

RET

a1 DB 1,2,3,4,5
a2 DB 5 DUP(0)

C	Z	S	O	P	A
unchanged

 

MOVSW

No operands

Copy word at DS:[SI] to ES:[DI]. Update SI and DI.

Algorithm: 

• ES:[DI] = DS:[SI]
• if DF = 0 then
  • SI = SI + 2
  • DI = DI + 2
  else
  • SI = SI - 2
  • DI = DI - 2

Example:

ORG 100h

CLD
LEA SI, a1
LEA DI, a2
MOV CX, 5
REP MOVSW

RET

a1 DW 1,2,3,4,5
a2 DW 5 DUP(0)

C	Z	S	O	P	A
unchanged

 

MUL

REG
memory

Unsigned multiply. 

Algorithm:

when operand is a byte:
AX = AL * operand.

when operand is a word:
(DX AX) = AX * operand.

Example:

MOV AL, 200   ; AL = 0C8h
MOV BL, 4
MUL BL        ; AX = 0320h (800)
RET

C	Z	S	O	P	A
r	?	?	r	?	?

CF=OF=0 when high section of the result is zero.  

NEG

REG
memory

Negate. Makes operand negative (two's complement). 

Algorithm:

• Invert all bits of the operand
• Add 1 to inverted operand

Example:

MOV AL, 5   ; AL = 05h
NEG AL      ; AL = 0FBh (-5)
NEG AL      ; AL = 05h (5)
RET

C	Z	S	O	P	A
r	r	r	r	r	r

 

NOP

No operands

No Operation.

Algorithm: 

• Do nothing

Example:

; do nothing, 3 times:
NOP
NOP
NOP
RET

C	Z	S	O	P	A
unchanged

 

NOT

REG
memory

Invert each bit of the operand.

Algorithm: 

• if bit is 1 turn it to 0.
• if bit is 0 turn it to 1.

Example:

MOV AL, 00011011b
NOT AL   ; AL = 11100100b
RET

C	Z	S	O	P	A
unchanged

 

OR

REG, memory
memory, REG
REG, REG
memory, immediate
REG, immediate

Logical OR between all bits of two operands. Result is stored in first operand.

These rules apply:

1 OR 1 = 1
1 OR 0 = 1
0 OR 1 = 1
0 OR 0 = 0


Example:

MOV AL, 'A'       ; AL = 01000001b
OR AL, 00100000b  ; AL = 01100001b  ('a')
RET

C	Z	S	O	P	A
0	r	r	0	r	?

 

OUT

im.byte, AL
im.byte, AX
DX, AL
DX, AX

Output from AL or AX to port.
First operand is a port number. If required to access port number over 255 - DX register should be used. 

Example:

MOV AX, 0FFFh ; Turn on all
OUT 4, AX     ; traffic lights.

MOV AL, 100b  ; Turn on the third
OUT 7, AL     ; magnet of the stepper-motor.

C	Z	S	O	P	A
unchanged

 

POP

REG
SREG
memory

Get 16 bit value from the stack. 

Algorithm:

• operand = SS:[SP] (top of the stack)
• SP = SP + 2

Example:

MOV AX, 1234h
PUSH AX
POP  DX     ; DX = 1234h
RET

C	Z	S	O	P	A
unchanged

 

POPA

No operands

Pop all general purpose registers DI, SI, BP, SP, BX, DX, CX, AX from the stack.
SP value is ignored, it is Popped but not set to SP register).

Note: this instruction works only on 80186 CPU and later! 

Algorithm:

• POP DI
• POP SI
• POP BP
• POP xx (SP value ignored)
• POP BX
• POP DX
• POP CX
• POP AX

C	Z	S	O	P	A
unchanged

 

POPF

No operands

Get flags register from the stack. 

Algorithm:

• flags = SS:[SP] (top of the stack)
• SP = SP + 2

C	Z	S	O	P	A
popped

 

PUSH

REG
SREG
memory
immediate

Store 16 bit value in the stack.

Note: PUSH immediate works only on 80186 CPU and later! 

Algorithm:

• SP = SP - 2
• SS:[SP] (top of the stack) = operand

Example:

MOV AX, 1234h
PUSH AX
POP  DX     ; DX = 1234h
RET

C	Z	S	O	P	A
unchanged

 

PUSHA

No operands

Push all general purpose registers AX, CX, DX, BX, SP, BP, SI, DI in the stack.
Original value of SP register (before PUSHA) is used.

Note: this instruction works only on 80186 CPU and later! 

Algorithm:

• PUSH AX
• PUSH CX
• PUSH DX
• PUSH BX
• PUSH SP
• PUSH BP
• PUSH SI
• PUSH DI

C	Z	S	O	P	A
unchanged

 

PUSHF

No operands

Store flags register in the stack. 

Algorithm:

• SP = SP - 2
• SS:[SP] (top of the stack) = flags

C	Z	S	O	P	A
unchanged

 

RCL

memory, immediate
REG, immediate

memory, CL
REG, CL

Rotate operand1 left through Carry Flag. The number of rotates is set by operand2. 
When immediate is greater then 1, assembler generates several RCL xx, 1 instructions because 8086 has machine code only for this instruction (the same principle works for all other shift/rotate instructions). 

Algorithm:

shift all bits left, the bit that goes off is set to CF and previous value of CF is inserted to the right-most position.

Example:

STC               ; set carry (CF=1).
MOV AL, 1Ch       ; AL = 00011100b
RCL AL, 1         ; AL = 00111001b,  CF=0.
RET

C	O
r	r

OF=0 if first operand keeps original sign.  

RCR

memory, immediate
REG, immediate

memory, CL
REG, CL

Rotate operand1 right through Carry Flag. The number of rotates is set by operand2. 

Algorithm:

shift all bits right, the bit that goes off is set to CF and previous value of CF is inserted to the left-most position.

Example:

STC               ; set carry (CF=1).
MOV AL, 1Ch       ; AL = 00011100b
RCR AL, 1         ; AL = 10001110b,  CF=0.
RET

C	O
r	r

OF=0 if first operand keeps original sign.  

REP

chain instruction

Repeat following MOVSB, MOVSW, LODSB, LODSW, STOSB, STOSW instructions CX times. 

Algorithm:

check_cx:

if CX <> 0 then

• do following chain instruction
• CX = CX - 1
• go back to check_cx

else

• exit from REP cycle

Z

r

 

REPE

chain instruction

Repeat following CMPSB, CMPSW, SCASB, SCASW instructions while ZF = 1 (result is Equal), maximum CX times. 

Algorithm:

check_cx:

if CX <> 0 then

• do following chain instruction
• CX = CX - 1
• if ZF = 1 then:
  • go back to check_cx
  else
  • exit from REPE cycle

else

• exit from REPE cycle

example:
open cmpsb.asm from c:emu8086examples 

Z

r

 

REPNE

chain instruction

Repeat following CMPSB, CMPSW, SCASB, SCASW instructions while ZF = 0 (result is Not Equal), maximum CX times. 

Algorithm:

check_cx:

if CX <> 0 then

• do following chain instruction
• CX = CX - 1
• if ZF = 0 then:
  • go back to check_cx
  else
  • exit from REPNE cycle

else

• exit from REPNE cycle

Z

r

 

REPNZ

chain instruction

Repeat following CMPSB, CMPSW, SCASB, SCASW instructions while ZF = 0 (result is Not Zero), maximum CX times. 

Algorithm:

check_cx:

if CX <> 0 then

• do following chain instruction
• CX = CX - 1
• if ZF = 0 then:
  • go back to check_cx
  else
  • exit from REPNZ cycle

else

• exit from REPNZ cycle

Z

r

 

REPZ

chain instruction

Repeat following CMPSB, CMPSW, SCASB, SCASW instructions while ZF = 1 (result is Zero), maximum CX times. 

Algorithm:

check_cx:

if CX <> 0 then

• do following chain instruction
• CX = CX - 1
• if ZF = 1 then:
  • go back to check_cx
  else
  • exit from REPZ cycle

else

• exit from REPZ cycle

Z

r

 

RET

No operands
or even immediate

Return from near procedure. 

Algorithm:

• Pop from stack:
  • IP
• if immediate operand is present: SP = SP + operand

Example:

ORG 100h  ; for COM file.

CALL p1

ADD AX, 1

RET         ; return to OS.

p1 PROC     ; procedure declaration.
    MOV AX, 1234h
    RET     ; return to caller.
p1 ENDP

C	Z	S	O	P	A
unchanged

 

RETF

No operands
or even immediate

Return from Far procedure. 

Algorithm:

• Pop from stack:
  • IP
  • CS
• if immediate operand is present: SP = SP + operand

C	Z	S	O	P	A
unchanged

 

ROL

memory, immediate
REG, immediate

memory, CL
REG, CL

Rotate operand1 left. The number of rotates is set by operand2. 

Algorithm:

shift all bits left, the bit that goes off is set to CF and the same bit is inserted to the right-most position.

Example:

MOV AL, 1Ch       ; AL = 00011100b
ROL AL, 1         ; AL = 00111000b,  CF=0.
RET

C	O
r	r

OF=0 if first operand keeps original sign.  

ROR

memory, immediate
REG, immediate

memory, CL
REG, CL

Rotate operand1 right. The number of rotates is set by operand2. 

Algorithm:

shift all bits right, the bit that goes off is set to CF and the same bit is inserted to the left-most position.

Example:

MOV AL, 1Ch       ; AL = 00011100b
ROR AL, 1         ; AL = 00001110b,  CF=0.
RET

C	O
r	r

OF=0 if first operand keeps original sign.  

SAHF

No operands

Store AH register into low 8 bits of Flags register. 

Algorithm:

flags register = AH

AH bit:   7    6   5    4   3    2   1    0
        [SF] [ZF] [0] [AF] [0] [PF] [1] [CF]

bits 1, 3, 5 are reserved. 

C	Z	S	O	P	A
r	r	r	r	r	r

 

SAL

memory, immediate
REG, immediate

memory, CL
REG, CL

Shift Arithmetic operand1 Left. The number of shifts is set by operand2. 

Algorithm:

• Shift all bits left, the bit that goes off is set to CF.
• Zero bit is inserted to the right-most position.

Example:

MOV AL, 0E0h      ; AL = 11100000b
SAL AL, 1         ; AL = 11000000b,  CF=1.
RET

C	O
r	r

OF=0 if first operand keeps original sign.  

SAR

memory, immediate
REG, immediate

memory, CL
REG, CL

Shift Arithmetic operand1 Right. The number of shifts is set by operand2. 

Algorithm:

• Shift all bits right, the bit that goes off is set to CF.
• The sign bit that is inserted to the left-most position has the same value as before shift.

Example:

MOV AL, 0E0h      ; AL = 11100000b
SAR AL, 1         ; AL = 11110000b,  CF=0.

MOV BL, 4Ch       ; BL = 01001100b
SAR BL, 1         ; BL = 00100110b,  CF=0.

RET

C	O
r	r

OF=0 if first operand keeps original sign.  

SBB

REG, memory
memory, REG
REG, REG
memory, immediate
REG, immediate

Subtract with Borrow. 

Algorithm:

operand1 = operand1 - operand2 - CF 

Example:

STC
MOV AL, 5
SBB AL, 3    ; AL = 5 - 3 - 1 = 1

RET

C	Z	S	O	P	A
r	r	r	r	r	r

 

SCASB

No operands

Compare bytes: AL from ES:[DI]. 

Algorithm: 

• AL - ES:[DI]
• set flags according to result:
  OF, SF, ZF, AF, PF, CF
• if DF = 0 then
  • DI = DI + 1
  else
  • DI = DI - 1

C	Z	S	O	P	A
r	r	r	r	r	r

 

SCASW

No operands

Compare words: AX from ES:[DI]. 

Algorithm: 

• AX - ES:[DI]
• set flags according to result:
  OF, SF, ZF, AF, PF, CF
• if DF = 0 then
  • DI = DI + 2
  else
  • DI = DI - 2

C	Z	S	O	P	A
r	r	r	r	r	r

 

SHL

memory, immediate
REG, immediate

memory, CL
REG, CL

Shift operand1 Left. The number of shifts is set by operand2. 

Algorithm:

• Shift all bits left, the bit that goes off is set to CF.
• Zero bit is inserted to the right-most position.

Example:

MOV AL, 11100000b
SHL AL, 1         ; AL = 11000000b,  CF=1.

RET

C	O
r	r

OF=0 if first operand keeps original sign.  

SHR

memory, immediate
REG, immediate

memory, CL
REG, CL

Shift operand1 Right. The number of shifts is set by operand2. 

Algorithm:

• Shift all bits right, the bit that goes off is set to CF.
• Zero bit is inserted to the left-most position.

Example:

MOV AL, 00000111b
SHR AL, 1         ; AL = 00000011b,  CF=1.

RET

C	O
r	r

OF=0 if first operand keeps original sign.  

STC

No operands

Set Carry flag. 

Algorithm: 

CF = 1 

C

1

 

STD

No operands

Set Direction flag. SI and DI will be decremented by chain instructions: CMPSB, CMPSW, LODSB, LODSW, MOVSB, MOVSW, STOSB, STOSW. 

Algorithm: 

DF = 1 

D

1

 

STI

No operands

Set Interrupt enable flag. This enables hardware interrupts. 

Algorithm: 

IF = 1 

I

1

 

STOSB

No operands

Store byte in AL into ES:[DI]. Update DI.

Algorithm: 

• ES:[DI] = AL
• if DF = 0 then
  • DI = DI + 1
  else
  • DI = DI - 1

Example:

ORG 100h

LEA DI, a1
MOV AL, 12h
MOV CX, 5

REP STOSB

RET

a1 DB 5 dup(0)

C	Z	S	O	P	A
unchanged

 

STOSW

No operands

Store word in AX into ES:[DI]. Update DI.

Algorithm: 

• ES:[DI] = AX
• if DF = 0 then
  • DI = DI + 2
  else
  • DI = DI - 2

Example:

ORG 100h

LEA DI, a1
MOV AX, 1234h
MOV CX, 5

REP STOSW

RET

a1 DW 5 dup(0)

C	Z	S	O	P	A
unchanged

 

SUB

REG, memory
memory, REG
REG, REG
memory, immediate
REG, immediate

Subtract. 

Algorithm:

operand1 = operand1 - operand2 

Example:

MOV AL, 5
SUB AL, 1         ; AL = 4

RET

C	Z	S	O	P	A
r	r	r	r	r	r

 

TEST

REG, memory
memory, REG
REG, REG
memory, immediate
REG, immediate

Logical AND between all bits of two operands for flags only. These flags are effected: ZF, SF, PF. Result is not stored anywhere.

These rules apply:

1 AND 1 = 1
1 AND 0 = 0
0 AND 1 = 0
0 AND 0 = 0


Example:

MOV AL, 00000101b
TEST AL, 1         ; ZF = 0.
TEST AL, 10b       ; ZF = 1.
RET

C	Z	S	O	P
0	r	r	0	r

 

XCHG

REG, memory
memory, REG
REG, REG

Exchange values of two operands. 

Algorithm:

operand1 < - > operand2 

Example:

MOV AL, 5
MOV AH, 2
XCHG AL, AH   ; AL = 2, AH = 5
XCHG AL, AH   ; AL = 5, AH = 2
RET

C	Z	S	O	P	A
unchanged

 

XLATB

No operands

Translate byte from table.
Copy value of memory byte at DS:[BX + unsigned AL] to AL register. 

Algorithm:

AL = DS:[BX + unsigned AL] 

Example:

ORG 100h
LEA BX, dat
MOV AL, 2
XLATB     ; AL = 33h

RET

dat DB 11h, 22h, 33h, 44h, 55h

C	Z	S	O	P	A
unchanged

 

XOR

REG, memory
memory, REG
REG, REG
memory, immediate
REG, immediate

Logical XOR (Exclusive OR) between all bits of two operands. Result is stored in first operand.

These rules apply:

1 XOR 1 = 0
1 XOR 0 = 1
0 XOR 1 = 1
0 XOR 0 = 0


Example:

MOV AL, 00000111b
XOR AL, 00000010b    ; AL = 00000101b
RET

C	Z	S	O	P	A
0	r	r	0	r	?

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