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I have a C program which does some extensive swapping operations on a large array. It has a modulo operation in its tight loop. In fact there is an integer in the range [-N|N[ with N a power of 2 and it should be wrapped to [0,N[.

Example with N=4: -4 => 0, -3 => 1, -2 => 2, -1 => 3, 0 => 0, ..., 3 => 3

At first I tried the version 1 below but was surprised that version 2 is actually notably faster even though it has a conditional expression.

Can you explain why version 2 is faster than version 1 for this special case?

Version 1:

#define N (1<<(3*5))

inline int modBitAnd(int x)
    return (x & (N-1));

Runtime: 17.1 seconds (for the whole program)

Version 2:

inline int modNeg1(int x)
    return (x < 0 ? x + N : x);

Runtime: 14.6 seconds (for the whole program)

Program is compiled on GCC 4.8.2. with -std=c99 -O3.


Here is the main loop in my program:

int en(uint16_t* p, uint16_t i, uint16_t v)
    uint16_t n1 = p[modNeg1((int)i - 1)];
    uint16_t n2 = p[modBitAnd((int)i + 1)];
    uint16_t n3 = p[modNeg1((int)i - C_WIDTH)];
    uint16_t n4 = p[modBitAnd((int)i + C_WIDTH)];
    return d(n1,v) + d(n2,v) + d(n3,v) + d(n4,v);

void arrange(uint16_t* p)
    for(size_t i=0; i<10000000; i++) {
        uint16_t ia = random(); // random integer [0|2^15[
        uint16_t va = p[ia];
        uint16_t ib = random(); // random integer [0|2^15[
        uint16_t vb = p[ib];
        if(en(p,ia,vb) + en(p,ib,va) < en(p,ia,va) + en(p,ib,vb)) {
            p[ia] = vb;
            p[ib] = va;

int d(uint16_t a, uint16_t b) is a distance function e.g. abs((int)a-(int)b).

This is how p is initialized:

uint16_t* p = malloc(sizeof(uint16_t)*N);
for(unsigned i=0; i<N; i++) *p++ = i;

First I used modBitAnd everywhere, but found out that the modNeg1 is acutally faster for the two cases where it can be used.

share|improve this question
Have you tried looking at the assembly code produced by the compiler? – Medinoc Jul 16 '14 at 10:13
the 2nd version doesn't work correctly unless you pass to it a remainder result because there's no modulo happens in it – Lưu Vĩnh Phúc Jul 16 '14 at 10:20
Which platform (32 or 64 bits)? Also, please post a complete code example or a disassembly listing. – anatolyg Jul 16 '14 at 10:48
@LưuVĩnhPhúc: I think it works fine. Please read the specifications carefully. – Danvil Jul 16 '14 at 11:41
I note that random() should generate the same sequence each time the program is run... unless you have arranged otherwise. Clearly it is important to run the two versions with the same sequence. If you want ia to be set to 0..32767 I suggest masking the result of random()... as it stands ia is set to 0..65535... which modBitAnd() will gloss over, but modNeg1() will not ! It's not clear to me why uint16_t va = p[ia]; doesn't crash and burn... unless the area pointed to by p is larger than it apparently needs to be from the code fragments shown. – user3793679 Jul 16 '14 at 13:13

First take a few stackshots to find out where the time is actually going. Your mod functions will grab some fraction of the samples, but you've also got two calls to random, plus a fair amount of array indexing. Also, it looks like you've got four calls to en with some arguments that are the same, so maybe your modularity is leading to repeat calls to the mod functions.

share|improve this answer
Thank you for your comment. There is definitely a lot of time spent elsewhere. But what I observed is by choosing modNeg1 instead of modBitAnd at the two locations in function en the program runs 20% faster. That is what I am wondering about. – Danvil Jul 16 '14 at 13:57
@Danvil: I generally do mod with unsigned integers or pure bit masks to get around issues with negative numbers. Regardless, 20% is not a huge speedup, and you can probably do better than that. – Mike Dunlavey Jul 16 '14 at 14:02

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