6

I'm making a small game engine for personal use. The target architecture is x86_64 preferably with SSE2.

The sine/cosine function is one of the core parts, and it's implemented as a precomputed table of 1024 cosine values for the input range [0, π / 2].

The scalar implementation is quite straightforward.

typedef unsigned uns;
typedef float flt;

enum {COS_TABLE_SIZE = 1 << 10};
extern flt COS_TABLE[COS_TABLE_SIZE];

flt f(uns i) {
    flt *t = COS_TABLE;
    uns z = COS_TABLE_SIZE;
    switch (i / z) {
    case 0:
        return +t[+(i - z * 0) + 0];
    case 1:
        return -t[-(i - z * 1) + z];
    case 2:
        return -t[+(i - z * 2) + 0];
    case 3:
        return +t[-(i - z * 3) + z];
    default:
        __builtin_unreachable();
    }
}

The code isn't tested yet, so there could be an error in math.

Modern compilers aren't sophisticated enough to generate good code for the naivest approach to vectorization.

typedef uns u32;
typedef u32 vec_u32 __attribute__((vector_size(16)));
typedef flt vec_flt __attribute__((vector_size(16)));

vec_flt fv(vec_u32 i) {
    vec_flt r;
    for (uns j = 0; j < 4; ++j) {
        r[j] = f(i[j]);
    }
    return r;
}

Both GCC and Clang produce horrible code for fv. So I decided to do the vectorization manually.

When you have a look below, the code above /*---*/ isn't related much to this question. The branching in the scalar version is converted to a branchless vectorized version. Please do comment if there is room for improvement in that part.

Anyway, this question is about the lines below /*---*/. The given problem is to create a vector from a vector of indices by doing table look-ups with those indices. In C, the upper part looks more complex, but in machine level the lower part is more expensive. Extracting each index value separately from a vector and then reconstructing a vector with the results doesn't seem to be a simple task.

What is an efficient way to deal with such problem? It is a personal project, and any kind of restructuring is always possible.

I prefer SSE2 for portability, but if there is a better solution available in later extensions, it would be good to know.

static uns uns_log2(uns x) {
    if (__builtin_constant_p(x)) {
        return 31 - __builtin_clz(x);
    }
    uns r = 0;
    __asm__ ("bsr\t%0, %1" : "+r"(r) : "r"(x));
    return r;
}

static u32 flt_reint_u32(flt x) {
    u32 r;
    memcpy(&r, &x, sizeof(x));
    return r;
}

static flt u32_reint_flt(u32 x) {
    flt r;
    memcpy(&r, &x, sizeof(x));
    return r;
}

static vec_u32 vec_u32_fill(u32 x) {
    return (vec_u32){x, x, x, x};
}

vec_flt fv2(vec_u32 i) {
    flt *t = COS_TABLE;
    uns z = COS_TABLE_SIZE;
    vec_u32 q = i >> uns_log2(z);
    i -= q << uns_log2(z);
    vec_u32 c = q == 1 | q == 3;
    i = i & ~c | z - i & c;
    vec_u32 s = vec_u32_fill(0x80000000);
    s &= ~(q == 0 | q == 3);
    
    /*---*/
    
    vec_flt r;
    for (uns j = 0; j < 4; ++j) {
        r[j] = u32_reint_flt(flt_reint_u32(t[i[j]]) ^ s[j]);
    }
    return r;
}

https://godbolt.org/z/aejc69q9Y

7
  • Have you looked at existing vectorized sin/cos library functions, like glibc's libmvec? (sourceware.org/glibc/wiki/libmvec) Looks like their SSE4 version uses a different strategy, though, with a polynomial approximation. And only falling back to calling scalar cosf for some inputs. Yours is I guess aiming to be faster and lower-precision? Apr 4, 2022 at 21:37
  • 2
    Without AVX2 for gather loads, you're definitely going to have to extract to scalar for table lookups. When you need all 4 elements, probably best to just store to tmp array and scalar reload it, instead of doing movd + 3x pextrd. Especially with SSE2! You might still do the first with movd, and the rest as reloads. The manual gather should be 4x movss + 3 shuffles, or possibly 2x movss + movhps pairs to save front-end bandwidth (but still costs a p5 uop in the back end micro-fused with it) and one shufps, if cache-line splits don't make 8-byte loads worse. (Page-align your table) Apr 4, 2022 at 21:40
  • XOR is slow, IF-ELSE is slow, get rid of these. Try to use register keyword for the the hot variables. Declare the hot variables as high as possible, best in function scope. Jump tables (goto) are faster than function calls. Try to write the hot stuff all within one singular function.
    – paladin
    Apr 5, 2022 at 2:30
  • 1
    As @PeterCordes said, doing a LUT without AVX2 is not possible in parallel. And you are likely much faster with a polynomial approximation. If you just need 10 bits of precision, 2--4 terms should be sufficient (you can also split the interval in two halves and calculate sine and cosine at the same time).
    – chtz
    Apr 5, 2022 at 8:16
  • @paladin The only thing I can partly agree with of your comment is that branching is (potentially) slow. But on what (modern) architecture is XOR slow, or which compiler needs the register keyword to decide what variables are hot? Also, compilers are pretty good at inlining, so no need to write big monolithic functions.
    – chtz
    Apr 5, 2022 at 8:20

1 Answer 1

2

Thanks for all the comments. This is my current solution.

Table look-up with vectors cannot be done efficiently without AVX2. Fortunately, for sine and cosine, Taylor series expansion apparently converges quite fast. With only 4 terms, the maximum absolute error is 0.0000068 and the average absolute error is 0.0000042.

The coefficients of the polynomial with a certain length can be optimized to minimize the error. The precomputed coefficients are from this website (https://publik-void.github.io/sin-cos-approximations/, Cos, abs. error minimized, degree 6)

This is the whole assembly output for cosine. The input should always be in the range [-π / 2, π / 2].

vec_flt_cos:
    andps   xmm0, XMMWORD PTR .LC0[rip]
    movaps  xmm1, XMMWORD PTR .LC2[rip]
    movaps  xmm3, XMMWORD PTR .LC1[rip]
    movaps  xmm2, XMMWORD PTR .LC3[rip]
    subps   xmm1, xmm0
    cmpltps xmm3, xmm0
    pxor    xmm1, xmm0
    pand    xmm1, xmm3
    pxor    xmm1, xmm0
    movdqa  xmm0, XMMWORD PTR .LC7[rip]
    mulps   xmm1, xmm1
    pand    xmm0, xmm3
    mulps   xmm2, xmm1
    addps   xmm2, XMMWORD PTR .LC4[rip]
    mulps   xmm2, xmm1
    addps   xmm2, XMMWORD PTR .LC5[rip]
    mulps   xmm1, xmm2
    addps   xmm1, XMMWORD PTR .LC6[rip]
    pxor    xmm0, xmm1
    ret

Below is the code for testing the accuracy, if you're interested.

#include <stdio.h>
#include <stdlib.h>
#include <stdint.h>
#include <string.h>
#include <time.h>
#include <math.h>

#define FLT_PI 3.14159265358979323846f
#define FLT_DPI 6.28318530717958647693f
#define FLT_HPI 1.57079632679489661923f

typedef unsigned uns;
typedef uint32_t u32;
typedef uint64_t u64;
typedef int32_t i32;
typedef float flt;
typedef double dbl;
typedef flt vec_flt __attribute__((vector_size(16)));
typedef u32 vec_u32 __attribute__((vector_size(16)));
typedef i32 vec_i32 __attribute__((vector_size(16)));

static vec_flt vec_flt_fill(flt x) {
    return (vec_flt){x, x, x, x};
}

static vec_flt vec_u32_reint_flt(vec_u32 x) {
    vec_flt r;
    memcpy(&r, &x, sizeof(x));
    return r;
}

static vec_u32 vec_flt_reint_u32(vec_flt x) {
    vec_u32 r;
    memcpy(&r, &x, sizeof(x));
    return r;
}

static vec_flt vec_flt_sq(vec_flt x) {
    return x * x;
}

static vec_flt vec_flt_abs(vec_flt x) {
    return vec_u32_reint_flt(vec_flt_reint_u32(x) & 0x7fffffff);
}

vec_flt vec_flt_cos(vec_flt x) {
    flt c[] = {
        0.999993295282167421664399661287022669f,
        -0.49991243971224581435251505760757806f,
        0.0414877480454292132253667471195955447f,
        -0.00127120948569655081466419067530634131f
    };
    x = vec_flt_abs(x);
    vec_u32 m = x > FLT_HPI;
    x = vec_flt_sq(
        vec_u32_reint_flt(
            m & vec_flt_reint_u32(FLT_PI - x) | ~m & vec_flt_reint_u32(x)
        )
    );
    return vec_u32_reint_flt(
        vec_flt_reint_u32(x * (x * (x * c[3] + c[2]) + c[1]) + c[0]) ^
        m & 0x80000000
    );
}

vec_flt vec_flt_sin(vec_flt x) {
    x -= FLT_HPI;
    return vec_flt_cos(
        x + vec_u32_reint_flt(
            x < -FLT_PI & vec_flt_reint_u32(vec_flt_fill(FLT_DPI))
        )
    );
}

enum {Z = 200000000};

static flt th(uns i) {
    return (flt)i * (FLT_DPI / (flt)(Z - 1)) - FLT_PI;
}

static void compute(vec_flt (*af)(vec_flt), vec_flt (*ef)(vec_flt), char *id) {
    static flt ap[Z], ex[Z];
    for (uns i = 0; i < Z; i += 4) {
        vec_flt x;
        for (uns j = 0; j < 4; ++j) {
            x[j] = th(i + j);
        }
        vec_flt r = af(x);
        memcpy(ap + i, &r, sizeof(r));
        r = ef(x);
        memcpy(ex + i, &r, sizeof(r));
    }
    dbl sum = 0.0;
    dbl max = 0.0;
    for (uns i = 0; i < Z; ++i) {
        dbl e = fabs((double)(ap[i] - ex[i]));
        sum += e;
        if (e > max) {
            max = e;
        }
    }
    printf("(%s) avg: %.12f max: %.12f\n", id, sum / (dbl)Z, max);
}

static vec_flt excos(vec_flt x) {
    return (vec_flt){
        (flt)cos((dbl)x[0]), (flt)cos((dbl)x[1]),
        (flt)cos((dbl)x[2]), (flt)cos((dbl)x[3])
    };
}

static vec_flt exsin(vec_flt x) {
    return (vec_flt){
        (flt)sin((dbl)x[0]), (flt)sin((dbl)x[1]),
        (flt)sin((dbl)x[2]), (flt)sin((dbl)x[3])
    };
}

int main() {
    compute(excos, vec_flt_cos, "vec_flt_cos");
    compute(exsin, vec_flt_sin, "vec_flt_sin");
    return 0;
}
5
  • Looks reasonable. Being able to skip range-reduction by requiring limited-range input helps a lot, I'd imagine. Apr 8, 2022 at 13:38
  • @PeterCordes Making an arbitrary input fit into the required range isn't that expensive (11 instructions, godbolt.org/z/EGbxdvs6f), but the main problem is that the error gets bigger as the initial input's absolute value gets bigger with the method I used. The error will remain if I subtract with a loop until it fits, but that's not efficient.
    – xiver77
    Apr 8, 2022 at 14:24
  • @PeterCordes BTW if you see the Godbolt link above, GCC uses comiss to branch while Clang chooses cmpss without a branch. The branching version won't make sense with the vectorized version, but in the given scalar code, which compiler is producing better code?
    – xiver77
    Apr 8, 2022 at 14:27
  • 1
    Yeah, range-reduction is a hard problem for accuracy. To really do it well, you'd need extended-precision or something, e.g. for the value of Pi. randomascii.wordpress.com/2014/10/09/… points out the problem for fsin as you approach sin(+Pi) ~= 0.0 Apr 8, 2022 at 14:30
  • branchless is great if the branch is unpredictable, otherwise branchy shortens the critical path and may run fewer total instructions. Clang's implementation is a good branchless strategy, making good use of cmpss / andps it looks like. Only briefly skimmed, though. Apr 8, 2022 at 14:33

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