_InterlockedXor Intrinsic Functions

 

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The latest version of this topic can be found at _InterlockedXor Intrinsic Functions.

Microsoft Specific**

Perform an atomic bitwise exclusive or (XOR) operation on a variable shared by multiple threads.

Syntax

long _InterlockedXor(  
   long volatile * Value,  
   long Mask  
);  
long _InterlockedXor_acq(  
   long volatile * Value,  
   long Mask  
);  
long _InterlockedXor_HLEAcquire(  
   long volatile * Value,  
   long Mask  
);  
long _InterlockedXor_HLERelease(  
   long volatile * Value,  
   long Mask  
);  
long _InterlockedXor_nf(  
   long volatile * Value,  
   long Mask  
);  
long _InterlockedXor_np(  
   long volatile * Value,  
   long Mask  
);  
long _InterlockedXor_rel(  
   long volatile * Value,  
   long Mask  
);  
char _InterlockedXor8(  
   char volatile * Value,  
   char Mask  
);  
char _InterlockedXor8_acq(  
   char volatile * Value,  
   char Mask  
);  
char _InterlockedXor8_nf(  
   char volatile * Value,  
   char Mask  
);  
char _InterlockedXor8_np(  
   char volatile * Value,  
   char Mask  
);  
char _InterlockedXor8_rel(  
   char volatile * Value,  
   char Mask  
);  
short _InterlockedXor16(  
   short volatile * Value,  
   short Mask  
);  
short _InterlockedXor16_acq(  
   short volatile * Value,  
   short Mask  
);  
short _InterlockedXor16_nf (  
   short volatile * Value,  
   short Mask  
);  
short _InterlockedXor16_np (  
   short volatile * Value,  
   short Mask  
);  
short _InterlockedXor16_rel(  
   short volatile * Value,  
   short Mask  
);  
__int64 _InterlockedXor64(  
   __int64 volatile * Value,  
   __int64 Mask  
);  
__int64 _InterlockedXor64_acq(  
   __int64 volatile * Value,  
   __int64 Mask  
);   
__int64 _InterlockedXor64_HLEAcquire(  
   __int64 volatile * Value,  
   __int64 Mask  
);  
__int64 _InterlockedXor64_HLERelease(  
   __int64 volatile * Value,  
   __int64 Mask  
);   
__int64 _InterlockedXor64_nf(  
   __int64 volatile * Value,  
   __int64 Mask  
);  
__int64 _InterlockedXor64_np(  
   __int64 volatile * Value,  
   __int64 Mask  
);  
__int64 _InterlockedXor64_rel(  
   __int64 volatile * Value,  
   __int64 Mask  
);  

Parameters

[in, out] Value
A pointer to the first operand, to be replaced by the result.

[in] Mask
The second operand.

Return Value

The original value of the first operand.

Requirements

Intrinsic Architecture Header
_InterlockedXor, _InterlockedXor8, _InterlockedXor16, _InterlockedXor64 x86, ARM, x64 <intrin.h>
_InterlockedXor_acq, _InterlockedXor_nf, _InterlockedXor_rel, _InterlockedXor8_acq, _InterlockedXor8_nf, _InterlockedXor8_rel, _InterlockedXor16_acq, _InterlockedXor16_nf, _InterlockedXor16_rel, _InterlockedXor64_acq, _InterlockedXor64_nf, _InterlockedXor64_rel, ARM <intrin.h>
_InterlockedXor_np, _InterlockedXor8_np, _InterlockedXor16_np, _InterlockedXor64_np x64 <intrin.h>
_InterlockedXor_HLEAcquire, _InterlockedXor_HLERelease, _InterlockedXor64_HLEAcquire, _InterlockedXor64_HLERelease x86, x64 <immintrin.h>

Remarks

The number in the name of each function specifies the bit size of the arguments.

On ARM platforms, use the intrinsics with _acq and _rel suffixes if you need acquire and release semantics, such as at the beginning and end of a critical section. The ARM intrinsics with an _nf ("no fence") suffix do not act as a memory barrier.

The intrinsics with an _np ("no prefetch") suffix prevent a possible prefetch operation from being inserted by the compiler.

On Intel platforms that support Hardware Lock Elision (HLE) instructions, the intrinsics with _HLEAcquire and _HLERelease suffixes include a hint to the processor that can accelerate performance by eliminating a lock write step in hardware. If these intrinsics are called on platforms that do not support HLE, the hint is ignored.

Example

// _InterLockedXor.cpp  
#include <stdio.h>  
#include <intrin.h>  
  
#pragma intrinsic(_InterlockedXor)  
  
int main()  
{  
        long data1 = 0xFF00FF00;  
        long data2 = 0x00FFFF00;  
        long retval;  
        retval = _InterlockedXor(&data1, data2);  
        printf_s("0x%x 0x%x 0x%x", data1, data2, retval);   
}  
0xffff0000 0xffff00 0xff00ff00  

END Microsoft Specific

See Also

Compiler Intrinsics
Conflicts with the x86 Compiler