28

In C, why is signed int faster than unsigned int? True, I know that this has been asked and answered multiple times on this website (links below). However, most people said that there is no difference. I have written code and accidentally found a significant performance difference.

Why would the "unsigned" version of my code be slower than the "signed" version (even when testing the same number)? (I have a x86-64 Intel processor).

Similar links

Compile Command: gcc -Wall -Wextra -pedantic -O3 -Wl,-O3 -g0 -ggdb0 -s -fwhole-program -funroll-loops -pthread -pipe -ffunction-sections -fdata-sections -std=c11 -o ./test ./test.c && strip --strip-all --strip-unneeded --remove-section=.note --remove-section=.comment ./test


signed int version

NOTE: There is no difference if I explicitly declare signed int on all numbers.

int isprime(int num) {
    // Test if a signed int is prime
    int i;
    if (num % 2 == 0 || num % 3 == 0)
        return 0;
    else if (num % 5 == 0 || num % 7 == 0)
        return 0;
    else {
        for (i = 11; i < num; i += 2) {
            if (num % i == 0) {
                if (i != num)
                    return 0;
                else
                    return 1;
            }
        }
    }
    return 1;
}

unsigned int version

int isunsignedprime(unsigned int num) {
    // Test if an unsigned int is prime
    unsigned int i;
    if (num % (unsigned int)2 == (unsigned int)0 || num % (unsigned int)3 == (unsigned int)0)
        return 0;
    else if (num % (unsigned int)5 == (unsigned int)0 || num % (unsigned int)7 == (unsigned int)0)
        return 0;
    else {
        for (i = (unsigned int)11; i < num; i += (unsigned int)2) {
            if (num % i == (unsigned int)0) {
                if (i != num)
                    return 0;
                else
                    return 1;
            }
        }
    }
    return 1;
}

Test this in a file with the below code:

int main(void) {
    printf("%d\n", isprime(294967291));
    printf("%d\n", isprime(294367293));
    printf("%d\n", isprime(294967293));
    printf("%d\n", isprime(294967241)); // slow
    printf("%d\n", isprime(294967251));
    printf("%d\n", isprime(294965291));
    printf("%d\n", isprime(294966291));
    printf("%d\n", isprime(294963293));
    printf("%d\n", isprime(294927293));
    printf("%d\n", isprime(294961293));
    printf("%d\n", isprime(294917293));
    printf("%d\n", isprime(294167293));
    printf("%d\n", isprime(294267293));
    printf("%d\n", isprime(294367293)); // slow
    printf("%d\n", isprime(294467293));
    return 0;
}

Results (time ./test):

Signed - real 0m0.949s
Unsigned - real 0m1.174s
  • 4
    It may just be due to the overhead of all of the explicit casting. – Cᴏʀʏ Dec 8 '15 at 20:13
  • 12
    The first thing I'd do is compare the generated assembly code for both cases, and see if any additional instructions are being emitted in the unsigned case. – Tom Karzes Dec 8 '15 at 20:19
  • 14
    When writing benchmarks I strongly suggest to increase the measurement time to at least 30s and to run the task executing the benchmark with highest priority possible. Otherwise your measured 20% difference may be cause by a great deal by the OS. – Lukas Thomsen Dec 8 '15 at 20:22
  • 9
    @Cᴏʀʏ they're free casts anyway. They tell the compiler to change the type, but cost no code to implement. – harold Dec 8 '15 at 20:25
  • 5
    (unsigned int)3 can be more clearly written 3u – M.M Dec 8 '15 at 21:03
14

Your question is genuinely intriguing as the unsigned version consistently produces code that is 10 to 20% slower. Yet there are multiple problems in the code:

  • Both functions return 0 for 2, 3, 5 and 7, which is incorrect.
  • The test if (i != num) return 0; else return 1; is completely useless as the loop body is only run for i < num. Such a test would be useful for the small prime tests but special casing them is not really useful.
  • the casts in the unsigned version are redundant.
  • benchmarking code that produces textual output to the terminal is unreliable, you should use the clock() function to time CPU intensive functions without any intervening I/O.
  • the algorithm for prime testing is utterly inefficient as the loop runs num / 2 times instead of sqrt(num).

Let's simplify the code and run some precise benchmarks:

#include <stdio.h>
#include <time.h>

int isprime_slow(int num) {
    if (num % 2 == 0)
        return num == 2;
    for (int i = 3; i < num; i += 2) {
        if (num % i == 0)
            return 0;
    }
    return 1;
}

int unsigned_isprime_slow(unsigned int num) {
    if (num % 2 == 0)
        return num == 2;
    for (unsigned int i = 3; i < num; i += 2) {
        if (num % i == 0)
            return 0;
    }
    return 1;
}

int isprime_fast(int num) {
    if (num % 2 == 0)
        return num == 2;
    for (int i = 3; i * i <= num; i += 2) {
        if (num % i == 0)
            return 0;
    }
    return 1;
}

int unsigned_isprime_fast(unsigned int num) {
    if (num % 2 == 0)
        return num == 2;
    for (unsigned int i = 3; i * i <= num; i += 2) {
        if (num % i == 0)
            return 0;
    }
    return 1;
}

int main(void) {
    int a[] = {
        294967291, 0, 294367293, 0, 294967293, 0, 294967241, 1, 294967251, 0,
        294965291, 0, 294966291, 0, 294963293, 0, 294927293, 1, 294961293, 0,
        294917293, 0, 294167293, 0, 294267293, 0, 294367293, 0, 294467293, 0,
    };
    struct testcase { int (*fun)(); const char *name; int t; } test[] = {
        { isprime_slow, "isprime_slow", 0 },
        { unsigned_isprime_slow, "unsigned_isprime_slow", 0 },
        { isprime_fast, "isprime_fast", 0 },
        { unsigned_isprime_fast, "unsigned_isprime_fast", 0 },
    };

    for (int n = 0; n < 4; n++) {
        clock_t t = clock();
        for (int i = 0; i < 30; i += 2) {
            if (test[n].fun(a[i]) != a[i + 1]) {
                printf("%s(%d) != %d\n", test[n].name, a[i], a[i + 1]);
            }
        }
        test[n].t = clock() - t;
    }
    for (int n = 0; n < 4; n++) {
        printf("%21s: %4d.%03dms\n", test[n].name, test[n].t / 1000), test[n].t % 1000);
    }
    return 0;
}

The code compiled with clang -O2 on OS/X produces this output:

         isprime_slow:  788.004ms
unsigned_isprime_slow:  965.381ms
         isprime_fast:    0.065ms
unsigned_isprime_fast:    0.089ms

These timings are consistent with the OP's observed behavior on a different system, but show the dramatic improvement caused by the more efficient iteration test: 10000 times faster!

Regarding the question Why is the function slower with unsigned?, let's look at the generated code (gcc 7.2 -O2):

isprime_slow(int):
        ...
.L5:
        movl    %edi, %eax
        cltd
        idivl   %ecx
        testl   %edx, %edx
        je      .L1
.L4:
        addl    $2, %ecx
        cmpl    %esi, %ecx
        jne     .L5
.L6:
        movl    $1, %edx
.L1:
        movl    %edx, %eax
        ret

unsigned_isprime_slow(unsigned int):
        ...
.L19:
        xorl    %edx, %edx
        movl    %edi, %eax
        divl    %ecx
        testl   %edx, %edx
        je      .L22
.L18:
        addl    $2, %ecx
        cmpl    %esi, %ecx
        jne     .L19
.L20:
        movl    $1, %eax
        ret
       ...
.L22:
        xorl    %eax, %eax
        ret

The inner loops are very similar, same number of instructions, similar instructions. Here are however some potential explanations:

  • cltd extends the sign of the eax register into the edx register, which may be causing an instruction delay because eax is modified by the immediately preceeding instruction movl %edi, %eax. Yet this would make the signed version slower than the unsigned one, not faster.
  • the loops' initial instructions might be misaligned for the unsigned version, but it is unlikely as changing the order in the source code has no effect on the timings.
  • Although the register contents are identical for the signed and unsigned division opcodes, it is possible that the idivl instruction take fewer cycles than the divl instruction. Indeed the signed division operates on one less bit of precision than the unsigned division, but the difference seems quite large for this small change.
  • I suspect more effort was put into the silicon implementation of idivl because signed divisions are more common that unsigned divisions (as measured by years of coding statistics at Intel).
  • as commented by rcgldr, looking at instruction tables for Intel process, for Ivy Bridge, DIV 32 bit takes 10 micro ops, 19 to 27 cycles, IDIV 9 micro ops, 19 to 26 cycles. The benchmark times are consistent with these timings. The extra micro-op may be due to the longer operands in DIV (64/32 bits) as opposed to IDIV (63/31 bits).

This surprising result should teach us a few lessons:

  • optimizing is a difficult art, be humble and procrastinate.
  • correctness is often broken by optimizations.
  • choosing a better algorithm beats optimization by a long shot.
  • always benchmark code, do not trust your instincts.
  • Why not precompute sqrt(m) rounded down (float cast to unsigned int, say, once and use that as the upper limit in the iteration? That's faster than testing i * i <= m – Henno Brandsma Aug 31 '17 at 22:16
  • 1
    @HennoBrandsma: it may be faster or not faster, only benchmarking can tell... Multiplication is quite fast on modern CPUs. There is also a precision issue for large values of num. Last and not least, I was trying to have very simple functions so the assembly code would stay simple too. – chqrlie Aug 31 '17 at 22:22
  • This answer seems to have the most actual information, but it still doesn't clear things up for me. – Michael Burr Aug 31 '17 at 22:36
  • @MichaelBurr: I suspect more effort was put into the silicon implementation of idivl because signed divisions are more common that unsigned divisions (as measured by years of coding statistics at Intel), but I have no proof. – chqrlie Aug 31 '17 at 22:42
  • 2
    Looking at instruction tables for Intel process, for Ivy Bridge, DIV 32 bit takes 10 micro ops, 19 to 27 cycles, IDIV 9 micro ops, 19 to 26 cycles. On WIndows XP (my only 32 bit OS), Intel 3770K 3.5 ghz, Visual Studio, the fast times are 0.048 ms for int, 0.065 ms for unsigned int. – rcgldr Aug 31 '17 at 23:12
5

Because signed integer overflow is undefined, the compiler can make a lot of assumptions and optimizations on code involving signed integers. Unsigned integer overflow is defined to wrap around, so the compiler won't be able to optimize as much. See also http://blog.llvm.org/2011/05/what-every-c-programmer-should-know.html#signed_overflow and http://www.airs.com/blog/archives/120.

  • 2
    Your statements are correct, but looking at the code generated by x86 compilers, it does not seem to be a pertinent explanation. – chqrlie Aug 31 '17 at 22:48
  • Your statements looks right but it seems to be answering the reverse question. So wrong at last. – iBug Sep 1 '17 at 0:31
1

From Instruction specification on AMD/Intel we have (for K7):

Instruction Ops Latency Throughput
DIV r32/m32 32  24      23
IDIV r32    81  41      41
IDIV m32    89  41      41 

For i7, latency and throughput are the same for IDIVL and DIVL, a slight difference exists for the µops.

This may explain the difference as -O3 assembly codes only differ by signedness (DIVL vs IDIVL) on my machine.

  • 6
    Hold on, that's the wrong way around: this would make unsigned faster – harold Dec 8 '15 at 20:59
  • unsigned is faster for 64 bits arithmetic... – Jean-Baptiste Yunès Dec 8 '15 at 21:13
  • But this table says it should be faster for 32bit unsigned, which it wasn't (but of course OP probably doesn't have a K7 anymore) – harold Dec 8 '15 at 21:20
  • 1
    These may be worst case latency, for something like negative operands. Does your measured performance change when operands are negative? – Michael Dec 8 '15 at 22:14
  • the unsigned version uses div which will have to be faster – phuclv Nov 26 '16 at 17:19
0

Alternative wiki candidate test that may/may not show a significant time difference.

#include <stdio.h>
#include <time.h>

#define J 10
#define I 5

int main(void) {
  clock_t c1,c2,c3;
  for (int j=0; j<J; j++) {
    c1 = clock();
    for (int i=0; i<I; i++) {
      isprime(294967241);
      isprime(294367293);
    }
    c2 = clock();
    for (int i=0; i<I; i++) {
      isunsignedprime(294967241);
      isunsignedprime(294367293);
    }
    c3 = clock();
    printf("%d %d %d\n", (int)(c2-c1), (int)(c3-c2), (int)((c3-c2) - (c2-c1)));
    fflush(stdout);
  }
  return 0;
}

Sample output

2761 2746 -15
2777 2777 0
2761 2745 -16
2793 2808 15
2792 2730 -62
2746 2730 -16
2746 2730 -16
2776 2793 17
2823 2808 -15
2793 2823 30

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.