Conditions
Conditional execution in assembly language is accomplished by several looping and branching instructions. These instructions can change the flow of control in a program.
Jump Instructions
Unconditional jump
This is performed by the JMP instruction. Conditional execution often involves a transfer of control to the address of an instruction that does not follow the currently executing instruction. Transfer of control may be forward, to execute a new set of instructions or backward, to re-execute the same steps.
Conditional jump
This is performed by a set of jump instructions j
Compare Instructions
The CMP instruction compares two operands. It is generally used in conditional execution. This instruction basically subtracts one operand from the other for comparing whether the operands are equal or not. It does not disturb the destination or source operands. It is used along with the conditional jump instruction for decision making.
CMP destination, source
CMP compares two numeric data fields. The destination operand could be either in register or in memory. The source operand could be a constant (immediate) data, register or memory.
Example
CMP DX, 00 ; Compare the DX value with zero
JE L7 ; If yes, then jump to label L7
.
.
L7: ...
CMP is often used for comparing whether a counter value has reached the number of times a loop needs to be run. Consider the following typical condition −
INC EDX
CMP EDX, 10 ; Compares whether the counter has reached 10
JLE LP1 ; If it is less than or equal to 10, then jump to LP1
Unconditional Jump
As mentioned earlier, this is performed by the JMP instruction. Conditional execution often involves a transfer of control to the address of an instruction that does not follow the currently executing instruction. Transfer of control may be forward, to execute a new set of instructions or backward, to re-execute the same steps.
The JMP instruction provides a label name where the flow of control is transferred immediately. The syntax of the JMP instruction is −
JMP label
Example
The following code snippet illustrates the JMP instruction −
MOV AX, 00 ; Initializing AX to 0
MOV BX, 00 ; Initializing BX to 0
MOV CX, 01 ; Initializing CX to 1
L20:
ADD AX, 01 ; Increment AX
ADD BX, AX ; Add AX to BX
SHL CX, 1 ; shift left CX, this in turn doubles the CX value
JMP L20 ; repeats the statements
Conditional Jump
If some specified condition is satisfied in conditional jump, the control flow is transferred to a target instruction. There are numerous conditional jump instructions depending upon the condition and data.
Following are the conditional jump instructions used on signed data used for arithmetic operations −
| Instruction | Description | Flags tested |
| JE/JZ | Jump Equal or Jump Zero | ZF |
| JNE/JNZ | Jump not Equal or Jump Not Zero | ZF |
| JG/JNLE | Jump Greater or Jump Not Less/Equal | OF, SF, ZF |
| JGE/JNL | Jump Greater/Equal or Jump Not Less | OF, SF |
| JL/JNGE | Jump Less or Jump Not Greater/Equal | OF, SF |
| JLE/JNG | Jump Less/Equal or Jump Not Greater | OF, SF, ZF |
Following are the conditional jump instructions used on unsigned data used for logical operations −
| Instruction | Description | Flags tested |
| JE/JZ | Jump Equal or Jump Zero | ZF |
| JNE/JNZ | Jump not Equal or Jump Not Zero | ZF |
| JG/JNLE | Jump Greater or Jump Not Less/Equal | CF, ZF |
| JGE/JNL | Jump Greater/Equal or Jump Not Less | CF |
| JL/JNGE | Jump Less or Jump Not Greater/Equal | CF |
| JLE/JNG | Jump Less/Equal or Jump Not Greater | AF, CF |
The following conditional jump instructions have special uses and check the value of flags −
| Instruction | Description | Flags tested |
| JXCZ | Jump if CX is Zero | none |
| JC | Jump If Carry | CF |
| JNC | Jump If No Carry | CF |
| JO | Jump If Overflow | OF |
| JNO | Jump If No Overflow | OF |
| JP/JPE | Jump Parity or Jump Parity Even | PF |
| JNP/JPO | Jump No Parity or Jump Parity Odd | PF |
| JS | Jump Sign (negative value) | SF |
| JNS | Jump No Sign (positive value) | SF |
Example
CMP AL, BL
JE EQUAL
CMP AL, BH
JE EQUAL
CMP AL, CL
JE EQUAL
NON_EQUAL: ...
EQUAL: ...
Example
section .text
global _start ;must be declared for using gcc
_start: ;tell linker entry point
mov ecx, [num1]
cmp ecx, [num2]
jg check_third_num
mov ecx, [num2]
check_third_num:
cmp ecx, [num3]
jg _exit
mov ecx, [num3]
_exit:
mov [largest], ecx
mov ecx,msg
mov edx, len
mov ebx,1 ;file descriptor (stdout)
mov eax,4 ;system call number (sys_write)
int 0x80 ;call kernel
mov ecx,largest
mov edx, 2
mov ebx,1 ;file descriptor (stdout)
mov eax,4 ;system call number (sys_write)
int 0x80 ;call kernel
mov eax, 1
int 80h
section .data
msg db "The largest digit is: ", 0xA,0xD
len equ $- msg
num1 dd '47'
num2 dd '22'
num3 dd '31'
segment .bss
largest resb 2