2

I want to add two 32-bit unsigned integers in CUDA PTX and I also want to take care of the carry propagation. I am using the code below to do that, but the result is not as expected.
Acording to the documentation, the add.cc.u32 d, a, b performs integer addition and writes the carry-out value into the condition code register, that is CC.CF.
On the other hand, addc.cc.u32 d, a, b performs integer addition with carry-in and writes the carry-out value into the condition code register. The semantics of this instruction would be
d = a + b + CC.CF. I also tryed addc.u32 d, a, b with no difference.

#include <stdio.h>
#include <stdlib.h>
#include <cuda_runtime_api.h>
#include "device_launch_parameters.h"
#include <cuda.h>

typedef unsigned int u32;
#define TRY_CUDA_CALL(x) \
do \
  { \
    cudaError_t err; \
    err = x; \
    if(err != cudaSuccess) \
  { \
    printf("Error %08X: %s at %s in line %d\n", err, cudaGetErrorString(err), __FILE__, __LINE__); \
    exit(err); \
  } \
} while(0)


__device__ u32
__uaddo(u32 a, u32 b) {
    u32 res;
    asm("add.cc.u32 %0, %1, %2; /* inline */ \n\t" 
        : "=r" (res) : "r" (a) , "r" (b));
    return res;
}

__device__ u32
__uaddc(u32 a, u32 b) {
    u32 res;
    asm("addc.cc.u32 %0, %1, %2; /* inline */ \n\t" 
        : "=r" (res) : "r" (a) , "r" (b));
    return res;
}

__global__ void testing(u32* s)
{
    u32 a, b;

    a = 0xffffffff;
    b = 0x2;
    
    s[0] = __uaddo(a,b);
    s[0] = __uaddc(0,0);

}

int main()
{
    u32 *s_dev;
    u32 *s;
    s = (u32*)malloc(sizeof(u32));
    TRY_CUDA_CALL(cudaMalloc((void**)&s_dev, sizeof(u32)));
    testing<<<1,1>>>(s_dev);
    TRY_CUDA_CALL( cudaMemcpy(s, s_dev, sizeof(u32), cudaMemcpyDeviceToHost) );
    
    printf("s = %d;\n",s[0]);
    
    
    return 1;
}

As far as I know, you get a carry if the result doesn't fit in the variable, which happens here and an overflow if the sign bit is corrupted, but I'm working with unsigned values.
The code above tries to add 0xFFFFFFFF to 0x2 and of course the result won't fit on 32-bit, so why I don't get a 1 after __uaddc(0,0) call?

EDIT

Nvidia Geforce GT 520mx
Windows 7 Ultimate, 64-bit
Visual Studio 2012
CUDA 7.0

  • See this answer for a worked example of how to use carry-propagation in PTX for multi-word arithmetic. – njuffa Mar 26 '16 at 17:34
  • I used add_uint128 from your answer and the carry propagation was working, but what is wrong with my aproach? The succesion add.cc.u32 and addc.cc.u32 is the same as I can see. – Dani Grosu Mar 26 '16 at 18:27
  • The succesion is the same, but I'm using different calls. I think the register CC.CF should not change. – Dani Grosu Mar 26 '16 at 18:34
  • Flags are ephemeral. Unless you re-use the carry flag in the same asm statement, there is no guarantee that it will still be available in a subsequent asm statement. If you must use multiple asm statements, you will need to "export" the carry flag setting into a C variable, and "import" it into the following asm statement. – njuffa Mar 26 '16 at 19:31
  • You are saying it is possible that another process or thread to change the flag before I use the carry-in instruction? It seems right then. – Dani Grosu Mar 26 '16 at 20:28
2

The only data dependencies affecting an asm() statement are those that are explicitly expressed by the variable bindings. Note that you can bind register operands, but not the condition codes. Since in this code the result of __uaddo(a, b) is immediately being overwritten, the compiler determines that it does not contribute to the observable results, is therefore "dead code" and can be eliminated. This is easily checked by examining the generated machine code (SASS) for a release build with cuobjdump --dump-sass.

If we had slightly different code that does not allow the compiler to eliminate the code for __uaddo() outright, there would still be the issue that the compiler can schedule any instructions it likes between the code generated for __uaddo() and __uaddc(), and such instructions could destroy any setting of the carry flag due to __uaddo().

As a consequence, if one plans to use the carry flag for multi-word arithmetic, both carry-generating and carry-consuming instructions must occur in the same asm() statement. A worked example can be found in this answer that shows how to add 128-bit operands. Alternatively, if two separate asm() statements must be used, one could export the carry flag setting from the earlier one into a C variable, then import it into the subsequent asm() statement from there. I can't think of many situations where this would be practical, as the performance advantage of using the carry flag is likely lost.

| improve this answer | |
  • Would adding the volatile keyword to the asm statements help? The docs say "To ensure that the asm is not deleted or moved, you should use the volatile keyword". – Frepa Jul 29 '16 at 13:51
  • 1
    As far as I am aware, the volatile keyword, when used with an asm() statement just controls what happens with the code inside that asm() statement, it does not control what happens in between two separate asm() statements. Therefore the use of volatile cannot ensure the survival of a carry flag setting between two separate asm() statements. – njuffa Jul 29 '16 at 19:12
0

So, as @njuffa already said, other instructions from other source code can modify the CC.CF register between the two calls and there is no guarantee for getting the expected value of the register.
As a possible solution the __add32 function can be used:

__device__ uint2 __add32 (u32 a, u32 b)
{
    uint2 res;
    asm ("add.cc.u32      %0, %2, %3;\n\t"
         "addc.u32        %1, 0, 0;\n\t"
         : "=r"(res.x), "=r"(res.y)
         : "r"(a), "r"(b));
    return res;
}

The res.y will have the possible carry and res.x the result of addition.

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