13

I'm looking for an approximation of the exponent function operating on SSE element. Namely - __m128 exp( __m128 x ).

I have an implementation which is quick but seems to be very low in accuracy:

static inline __m128 FastExpSse(__m128 x)
{
    __m128 a = _mm_set1_ps(12102203.2f); // (1 << 23) / ln(2)
    __m128i b = _mm_set1_epi32(127 * (1 << 23) - 486411);
    __m128  m87 = _mm_set1_ps(-87);
    // fast exponential function, x should be in [-87, 87]
    __m128 mask = _mm_cmpge_ps(x, m87);

    __m128i tmp = _mm_add_epi32(_mm_cvtps_epi32(_mm_mul_ps(a, x)), b);
    return _mm_and_ps(_mm_castsi128_ps(tmp), mask);
}

Could anybody have an implementation with better accuracy yet as fast (Or faster)?

I'd be happy if it i written in C Style.

Thank You.

  • 1
    What is the accuracy of your current implementation (maximum relative error)? And what accuracy are you targeting for an improved version? – njuffa Oct 30 '17 at 22:55
  • It is really bad (I'd even suspect there is an error, if someone could spot it). So probably anything which makes sense will beat it. Something below 1% would be great! – Royi Oct 30 '17 at 22:56
  • See: sse_mathfun and this answer (relates to log2 but most of the suggestions also include an exp function). – Paul R Oct 31 '17 at 7:41
  • @PaulR, How different it is from njuffa's solution? – Royi Oct 31 '17 at 9:16
  • @Royi: there are several different options in the linked answer, but in general they are probably somewhat more accurate and somewhat slower. So it depends on whereabouts on the accuracy-versus-performance curve you want to be. – Paul R Oct 31 '17 at 9:23
13

The C code below is a translation into SSE intrinsics of an algorithm I used in a previous answer to a similar question.

The basic idea is to transform the computation of the standard exponential function into computation of a power of 2: expf (x) = exp2f (x / logf (2.0f)) = exp2f (x * 1.44269504). We split t = x * 1.44269504 into an integer i and a fraction f, such that t = i + f and 0 <= f <= 1. We can now compute 2f with a polynomial approximation, then scale the result by 2i by adding i to the exponent field of the single-precision floating-point result.

One problem that exists with an SSE implementation is that we want to compute i = floorf (t), but there is no fast way to compute the floor() function. However, we observe that for positive numbers, floor(x) == trunc(x), and that for negative numbers, floor(x) == trunc(x) - 1, except when x is a negative integer. However, since the core approximation can handle an f value of 1.0f, using the approximation for negative arguments is harmless. SSE provides an instruction to convert single-precision floating point operands to integers with truncation, so this solution is efficient.

Peter Cordes points out that SSE4.1 supports a fast floor function _mm_floor_ps(), so a variant using SSE4.1 is also shown below. Not all toolchains automatically predefine the macro __SSE4_1__ when SSE 4.1 code generation is enabled, but gcc does.

Compiler Explorer (Godbolt) shows that gcc 7.2 compiles the code below into sixteen instructions for plain SSE and twelve instructions for SSE 4.1.

#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <math.h>
#include <emmintrin.h>
#ifdef __SSE4_1__
#include <smmintrin.h>
#endif

/* max. rel. error = 1.72863156e-3 on [-87.33654, 88.72283] */
__m128 fast_exp_sse (__m128 x)
{
    __m128 t, f, e, p, r;
    __m128i i, j;
    __m128 l2e = _mm_set1_ps (1.442695041f);  /* log2(e) */
    __m128 c0  = _mm_set1_ps (0.3371894346f);
    __m128 c1  = _mm_set1_ps (0.657636276f);
    __m128 c2  = _mm_set1_ps (1.00172476f);

    /* exp(x) = 2^i * 2^f; i = floor (log2(e) * x), 0 <= f <= 1 */   
    t = _mm_mul_ps (x, l2e);             /* t = log2(e) * x */
#ifdef __SSE4_1__
    e = _mm_floor_ps (t);                /* floor(t) */
    i = _mm_cvtps_epi32 (e);             /* (int)floor(t) */
#else /* __SSE4_1__*/
    i = _mm_cvttps_epi32 (t);            /* i = (int)t */
    j = _mm_srli_epi32 (_mm_castps_si128 (x), 31); /* signbit(t) */
    i = _mm_sub_epi32 (i, j);            /* (int)t - signbit(t) */
    e = _mm_cvtepi32_ps (i);             /* floor(t) ~= (int)t - signbit(t) */
#endif /* __SSE4_1__*/
    f = _mm_sub_ps (t, e);               /* f = t - floor(t) */
    p = c0;                              /* c0 */
    p = _mm_mul_ps (p, f);               /* c0 * f */
    p = _mm_add_ps (p, c1);              /* c0 * f + c1 */
    p = _mm_mul_ps (p, f);               /* (c0 * f + c1) * f */
    p = _mm_add_ps (p, c2);              /* p = (c0 * f + c1) * f + c2 ~= 2^f */
    j = _mm_slli_epi32 (i, 23);          /* i << 23 */
    r = _mm_castsi128_ps (_mm_add_epi32 (j, _mm_castps_si128 (p))); /* r = p * 2^i*/
    return r;
}

int main (void)
{
    union {
        float f[4];
        unsigned int i[4];
    } arg, res;
    double relerr, maxrelerr = 0.0;
    int i, j;
    __m128 x, y;

    float start[2] = {-0.0f, 0.0f};
    float finish[2] = {-87.33654f, 88.72283f};

    for (i = 0; i < 2; i++) {

        arg.f[0] = start[i];
        arg.i[1] = arg.i[0] + 1;
        arg.i[2] = arg.i[0] + 2;
        arg.i[3] = arg.i[0] + 3;
        do {
            memcpy (&x, &arg, sizeof(x));
            y = fast_exp_sse (x);
            memcpy (&res, &y, sizeof(y));
            for (j = 0; j < 4; j++) {
                double ref = exp ((double)arg.f[j]);
                relerr = fabs ((res.f[j] - ref) / ref);
                if (relerr > maxrelerr) {
                    printf ("arg=% 15.8e  res=%15.8e  ref=%15.8e  err=%15.8e\n", 
                            arg.f[j], res.f[j], ref, relerr);
                    maxrelerr = relerr;
                }
            }   
            arg.i[0] += 4;
            arg.i[1] += 4;
            arg.i[2] += 4;
            arg.i[3] += 4;
        } while (fabsf (arg.f[3]) < fabsf (finish[i]));
    }
    printf ("maximum relative errror = %15.8e\n", maxrelerr);
    return EXIT_SUCCESS;
}

An alternative design for fast_sse_exp() extracts the integer portion of the adjusted argument x / log(2) in round-to-nearest mode, using the well-known technique of adding the "magic" conversion constant 1.5 * 223 to force rounding in the correct bit position, then subtracting out the same number again. This requires that the SSE rounding mode in effect during the addition is "round to nearest or even", which is the default. wim pointed out in comments that some compilers may optimize out the addition and subtraction of the conversion constant cvt as redundant when aggressive optimization is used, interfering with the functionality of this code sequence, so it is recommended to inspect the machine code generated. The approximation interval for computation of 2f is now centered around zero, since -0.5 <= f <= 0.5, requiring a different core approximation.

/* max. rel. error <= 1.72860465e-3 on [-87.33654, 88.72283] */
__m128 fast_exp_sse (__m128 x)
{
    __m128 t, f, p, r;
    __m128i i, j;

    const __m128 l2e = _mm_set1_ps (1.442695041f); /* log2(e) */
    const __m128 cvt = _mm_set1_ps (12582912.0f);  /* 1.5 * (1 << 23) */
    const __m128 c0 =  _mm_set1_ps (0.238428936f);
    const __m128 c1 =  _mm_set1_ps (0.703448006f);
    const __m128 c2 =  _mm_set1_ps (1.000443142f);

    /* exp(x) = 2^i * 2^f; i = rint (log2(e) * x), -0.5 <= f <= 0.5 */
    t = _mm_mul_ps (x, l2e);             /* t = log2(e) * x */
    r = _mm_sub_ps (_mm_add_ps (t, cvt), cvt); /* r = rint (t) */
    f = _mm_sub_ps (t, r);               /* f = t - rint (t) */
    i = _mm_cvtps_epi32 (t);             /* i = (int)t */
    p = c0;                              /* c0 */
    p = _mm_mul_ps (p, f);               /* c0 * f */
    p = _mm_add_ps (p, c1);              /* c0 * f + c1 */
    p = _mm_mul_ps (p, f);               /* (c0 * f + c1) * f */
    p = _mm_add_ps (p, c2);              /* p = (c0 * f + c1) * f + c2 ~= exp2(f) */
    j = _mm_slli_epi32 (i, 23);          /* i << 23 */
    r = _mm_castsi128_ps (_mm_add_epi32 (j, _mm_castps_si128 (p))); /* r = p * 2^i*/
    return r;
}

The algorithm for the code in the question appears to be taken from the work of Nicol N. Schraudolph, which cleverly exploits the semi-logarithmic nature of IEEE-754 binary floating-point formats:

N. N. Schraudolph. "A fast, compact approximation of the exponential function." Neural Computation, 11(4), May 1999, pp.853-862.

After removal of the argument clamping code, it reduces to just three SSE instructions. The "magical" correction constant 486411 is not optimal for minimizing maximum relative error over the entire input domain. Based on simple binary search, the value 298765 seems to be superior, reducing maximum relative error for FastExpSse() to 3.56e-2 vs. maximum relative error of 1.73e-3 for fast_exp_sse().

/* max. rel. error = 3.55959567e-2 on [-87.33654, 88.72283] */
__m128 FastExpSse (__m128 x)
{
    __m128 a = _mm_set1_ps (12102203.0f); /* (1 << 23) / log(2) */
    __m128i b = _mm_set1_epi32 (127 * (1 << 23) - 298765);
    __m128i t = _mm_add_epi32 (_mm_cvtps_epi32 (_mm_mul_ps (a, x)), b);
    return _mm_castsi128_ps (t);
}

Schraudolph's algorithm basically uses the linear approximation 2f ~= 1.0 + f for f in [0,1], and its accuracy could be improved by adding a quadratic term. The clever part of Schraudolph's approach is computing 2i * 2f without explicitly separating the integer portion i = floor(x * 1.44269504) from the fraction. I see no way to extend that trick to a quadratic approximation, but one can certainly combine the floor() computation from Schraudolph with the quadratic approximation used above:

/* max. rel. error <= 1.72886892e-3 on [-87.33654, 88.72283] */
__m128 fast_exp_sse (__m128 x)
{
    __m128 f, p, r;
    __m128i t, j;
    const __m128 a = _mm_set1_ps (12102203.0f); /* (1 << 23) / log(2) */
    const __m128i m = _mm_set1_epi32 (0xff800000); /* mask for integer bits */
    const __m128 ttm23 = _mm_set1_ps (1.1920929e-7f); /* exp2(-23) */
    const __m128 c0 = _mm_set1_ps (0.3371894346f);
    const __m128 c1 = _mm_set1_ps (0.657636276f);
    const __m128 c2 = _mm_set1_ps (1.00172476f);

    t = _mm_cvtps_epi32 (_mm_mul_ps (a, x));
    j = _mm_and_si128 (t, m);            /* j = (int)(floor (x/log(2))) << 23 */
    t = _mm_sub_epi32 (t, j);
    f = _mm_mul_ps (ttm23, _mm_cvtepi32_ps (t)); /* f = (x/log(2)) - floor (x/log(2)) */
    p = c0;                              /* c0 */
    p = _mm_mul_ps (p, f);               /* c0 * f */
    p = _mm_add_ps (p, c1);              /* c0 * f + c1 */
    p = _mm_mul_ps (p, f);               /* (c0 * f + c1) * f */
    p = _mm_add_ps (p, c2);              /* p = (c0 * f + c1) * f + c2 ~= 2^f */
    r = _mm_castsi128_ps (_mm_add_epi32 (j, _mm_castps_si128 (p))); /* r = p * 2^i*/
    return r;
}
  • 1
    @Royi Note that I posted my test framework along with fast_exp_sse() iself, so you should be able to verify my accuracy claim and test your existing function as well, for a side-by-side comparison. – njuffa Oct 30 '17 at 23:27
  • For code-style, I'd highly recommend _mm_set1_ps() for the constant vectors in the first code block as well. Initializing a __m128 with a braced initializer is not even guaranteed to be portable, but I think it does work on gcc/clang and I assume MSVC. But repeating each constant 4 times in the source is not nice. – Peter Cordes Nov 1 '17 at 11:20
  • 1
    SSE4.1 roundps provides a fast _mm_floor_ps (), so you could #ifdef __SSE4_1__ that part to use a more efficient floor when it's enable at compile time. (MSVC doesn't define that macro, so you need other checks there...) – Peter Cordes Nov 1 '17 at 11:26
  • 1
    @PeterCordes, could you post your code which is optimized for SSE4? Thank You. – Royi Nov 1 '17 at 12:42
  • 1
    @PeterCordes Note that my code requires floor(t) both as an integer i (to be added to the exponent field later) and a floating-point number e (for the computation of the "fraction" f). So that would give us: e = _mm_floor_ps (t); i = _mm_cvtps_epi32 (e);. – njuffa Nov 1 '17 at 15:44
5

A good increase in accuracy in my algorithm (implementation FastExpSse in the answer above) can be obtained at the cost of an integer subtraction and floating-point division by using FastExpSse(x/2)/FastExpSse(-x/2) instead of FastExpSse(x). The trick here is to set the shift parameter (298765 above) to zero so that the piecewise linear approximations in the numerator and denominator line up to give you substantial error cancellation. Roll it into a single function:

__m128 BetterFastExpSse (__m128 x)
{
  const __m128 a = _mm_set1_ps ((1 << 22) / float(M_LN2));  // to get exp(x/2)
  const __m128i b = _mm_set1_epi32 (127 * (1 << 23));       // NB: zero shift!
  __m128i r = _mm_cvtps_epi32 (_mm_mul_ps (a, x));
  __m128i s = _mm_add_epi32 (b, r);
  __m128i t = _mm_sub_epi32 (b, r);
  return _mm_div_ps (_mm_castsi128_ps (s), _mm_castsi128_ps (t));
}

(I'm not a hardware guy - how bad a performance killer is the division here?)

If you need exp(x) just to get y = tanh(x) (e.g. for neural networks), use FastExpSse with zero shift as follows:

a = FastExpSse(x);
b = FastExpSse(-x);
y = (a - b)/(a + b);

to get the same type of error cancellation benefit. The logistic function works similarly, using FastExpSse(x/2)/(FastExpSse(x/2) + FastExpSse(-x/2)) with zero shift. (This is just to show the principle - you obviously don't want to evaluate FastExpSse multiple times here, but roll it into a single function along the lines of BetterFastExpSse above.)

I did develop a series of higher-order approximations from this, ever more accurate but also slower. Unpublished but happy to collaborate if anyone wants to give them a spin.

And finally, for some fun: use in reverse gear to get FastLogSse. Chaining that with FastExpSse gives you both operator and error cancellation, and out pops a blazingly fast power function...

  • One division mixed in with a lot of multiplies is the best case. divps has worse latency than a multiply, but starting a division doesn't block the multiply / FMA units, so if you're doing multiple exp() calls on independent data, it's going to be about as cheap as another multiply. (And thus much better than using on large polynomial or double-precision or w/e.) The main cost here is from evaluating the same polynomial twice, not the division at the end, on modern x86. – Peter Cordes May 16 '18 at 22:04
  • auto is not the same in C and the question isn't tagged c++... – technosaurus May 17 '18 at 0:25
  • @technosaurus I've removed auto. This is generic code, I wasn't meaning to imply any particular language. – Nic Schraudolph May 17 '18 at 17:23
  • 1
    @Peter no need to evaluate a polynomial twice - since the argument is merely negated, it's just an extra integer subtraction. I've expanded the code snippet to clarify. Good news about the division! – Nic Schraudolph May 17 '18 at 18:41
  • Oh, I hadn't realized how simple the rest of the code was. This probably will bottleneck on divps throughput on most CPUs, especially a 256-bit AVX version, if you're doing just this over an array. But to feed another calculation it might still be fine. @njuffa's 2nd version fast_exp_ssewith relative error 1.72886892e-3 might be faster, especially on Haswell (where FMA is available for very fast polylnomials, but divps isn't as fast as Skylake). – Peter Cordes May 17 '18 at 19:31
3

Going back through my notes from way back then, I did explore ways to improve the accuracy without using division. I used the same reinterpret-as-float trick but applied a polynomial correction to the mantissa which was essentially calculated in 16-bit fixed-point arithmetic (the only way to do it fast back then).

The cubic resp. quartic versions give you 4 resp. 5 significant digits of accuracy. There was no point increasing the order beyond that, as the noise of the low-precision arithmetic then starts to drown out the error of the polynomial approximation. Here are the plain C versions:

#include <stdint.h>

float fastExp3(register float x)  // cubic spline approximation
{
    union { float f; int32_t i; } reinterpreter;

    reinterpreter.i = (int32_t)(12102203.0f*x) + 127*(1 << 23);
    int32_t m = (reinterpreter.i >> 7) & 0xFFFF;  // copy mantissa
    // empirical values for small maximum relative error (8.34e-5):
    reinterpreter.i +=
         ((((((((1277*m) >> 14) + 14825)*m) >> 14) - 79749)*m) >> 11) - 626;
    return reinterpreter.f;
}

float fastExp4(register float x)  // quartic spline approximation
{
    union { float f; int32_t i; } reinterpreter;

    reinterpreter.i = (int32_t)(12102203.0f*x) + 127*(1 << 23);
    int32_t m = (reinterpreter.i >> 7) & 0xFFFF;  // copy mantissa
    // empirical values for small maximum relative error (1.21e-5):
    reinterpreter.i += (((((((((((3537*m) >> 16)
        + 13668)*m) >> 18) + 15817)*m) >> 14) - 80470)*m) >> 11);
    return reinterpreter.f;
}

The quartic one obeys (fastExp4(0f) == 1f), which can be important for fixed-point iteration algorithms.

How efficient are these integer multiply-shift-add sequences in SSE? On architectures where float arithmetic is just as fast, one could use that instead, reducing the arithmetic noise. This would essentially yield cubic and quartic extensions of @njuffa's answer above.

  • 1
    Hi, Could you write it in SSE / AVX code? – Royi May 19 '18 at 13:34
  • M_LN2 is a double, so the resulting asm has to convert float to double. With (float)((1 << 23)/M_LN2), gcc7.3 auto-vectorizes these pretty reasonably in a loop (godbolt.org/g/vEWofG), with SSE4.1 or AVX2 (vcvttps2dq packed FP->int conversion, vpmulld packed 32-bit multiply / vpsrad packed arithmetic right shift), but clang doesn't autovectorize at all; it still converts to scalar. So you'd need to manually vectorize for this to be good with clang, I guess. – Peter Cordes May 19 '18 at 19:34
  • I haven't looked at the speed vs. precision tradeoff or this vs. others, but vpmulld has one per 2 clock throughput on Haswell (1/4 the throughput of FP mul or FMA). It's still 2 uops on Skylake, but SKL can run it on p0 / p1 for a throughput of one per clock. But it takes up more execution resources. This might be good on Nehalem or maybe Sandybridge where 128-bit pmulld is 1 uop, and FP division is more expensive. Static analysis of these with IACA (What is IACA and how do I use it?) would be interesting and not difficult – Peter Cordes May 19 '18 at 19:38
  • 2
    After replacing (1 << 23)/M_LN2 with 12102203.0f, an exhaustive test of all IEEE-754 binary32 floating-point numbers in [-87.33654, 88.72283] shows: max. rel. error fastExp3() = 8.34e-5; max. rel. error fastExp4() = 1.21e-5 – njuffa May 22 '18 at 16:53
  • 1
    @njuffa I suspect the higher errors you find are due to the inaccurate constant - can you try the exact value 12102203.161561f? I've edited my answer to use that, in order to avoid the problems with (1 << 23)/M_LN2 that you and @Peter describe. Cheers – Nic Schraudolph May 23 '18 at 12:41
1

There is a paper about creating fast versions of these equations (tanh, cosh, artanh, sinh, etc):

http://ijeais.org/wp-content/uploads/2018/07/IJAER180702.pdf "Creating a Compiler Optimized Inlineable Implementation of Intel Svml Simd Intrinsics"

their tanh equation 6, on page 9 is very similar to @NicSchraudolph answer

  • 2
    Normally link-only answers aren't welcome on SO. This arguably belongs as a comment, but I'm not going to flag it because it's potentially useful enough. – Peter Cordes Jun 23 at 14:53

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