X86 Assembly/Logic

Logical instructions

The instructions on this page deal with bit-wise logical instructions. For more information about bit-wise logic, see Digital Circuits/Logic Operations.

All logical instructions presented in this section are executed in the, as the name already suggests, the arithmetic logic unit.

binary operations

These instructions require two operands.

logical `and`

and mask, destination	GAS Syntax
and destination, mask	Intel Syntax

operation

and performs a bit-wise and of the two operands, and stores the result in destination.

side effects

See below.

example

movl $0x1, %edx ; edx ≔ 1
movl $0x0, %ecx ; ecx ≔ 0
andl %edx, %ecx ; ecx ≔ edx ∧ ecx
; here ecx would be 0 because 1 ∧ 0 ⇔ 0

application

An and can be used to calculate the intersection of two “sets”, or a value representing a “mask”. Some programming language require that Boolean values are stored exactly as either 1 or 0. An and rax, 1 will ensure only the LSB is set, or not set.
If partial register addressing is not available in the desired size, an and can be used for a ${\text{destination}}\!\!\!\!\mod {\text{mask}}$ operation, that is the remainder of integer division. For that, mask has to contain the value $2^{n}-1$ (i. e. all lower bits set until a certain threshold), where $2^{n}$ equals your desired divisor.

logical `or`

or addend, destination	GAS Syntax
or destination, addend	Intel Syntax

operation

The or instruction performs a bit-wise or of the two operands, and stores the result in destination.

side effects

See below.

example

movl $0x1, %edx ; edx ≔ 1
movl $0x0, %ecx ; ecx ≔ 0
orl  %edx, %ecx ; ecx ≔ edx ∨ ecx
; here ecx would be 1 because 1 ∨ 0 ⇔ 1

application

An or can be used to calculate the union of two “sets”, or a value representing a “mask”.

logical `xor`

xor flip, destination	GAS Syntax
xor destination, flip	Intel Syntax

operation

Performs a bit-wise xor of the two operands, and stores the result in destination.

side effects

See below.

example

movl $0x1, %edx ; edx ≔ 1
movl $0x0, %ecx ; ecx ≔ 0
xorl %edx, %ecx ; ecx ≔ edx ⊕ ecx
; here ecx would be 1 because 1 ⊕ 0 ⇔ 1

application

xor rax, rax (or any GPR twice) will clear all bits. It is a specially recognized word. However, since xor affects flags it might introduce bogus dependencies.

common remarks

side effects for `and`, `or`, and `xor`

OF ≔ 0
CF ≔ 0
SF becomes the value of the most significant bit of the calculated result
ZF ≔ result = 0
PF is set according to the result

unary operations

logical `not`

not argument

operation

Performs a bit-wise inversion of argument.

side-effects

None.

example

movl $0x1, %edx ; edx ≔ 1
notl %edx ; edx ≔ ¬edx
; here edx would be 0xFFFFFFFE because a bitwise NOT 0x00000001 = 0xFFFFFFFE

application

not is frequently used to get a register with all bits set.

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Logical instructions

binary operations

logical and

operation

side effects

example

application

logical or

operation

side effects

example

application

logical xor

operation

side effects

example

application

common remarks

side effects for and, or, and xor

unary operations

logical not

operation

side-effects

example

application

logical `and`

logical `or`

logical `xor`

side effects for `and`, `or`, and `xor`

logical `not`