src/math/sigmoid-f32-avx2-rr1-p5-nr2fma.c - platform/external/XNNPACK - Git at Google

 // Copyright 2019 Google LLC
 //
 // This source code is licensed under the BSD-style license found in the
 // LICENSE file in the root directory of this source tree.

 #include <assert.h>
 #include <stddef.h>

 #include <immintrin.h>

 #include <xnnpack/math-stubs.h>


 void xnn_math_f32_sigmoid__avx2_rr1_p5_nr2fma(
     size_t n,
     const float* input,
     float* output)
 {
   assert(n % (8 * sizeof(float)) == 0);

   // Floating-point mask with only the sign bit set
   const __m256 vsign_mask = _mm256_set1_ps(-0.0f);
   // Large number such that ulp(magic bias) == 1 and magic bias === 127 mod 2**22.
   const __m256 vmagic_bias = _mm256_set1_ps(0x1.8000FEp23f);
   const __m256 vlog2e = _mm256_set1_ps(0x1.715476p0f);
   const __m256 vminus_ln2 = _mm256_set1_ps(-0x1.62E43p-1f);
   // Coefficient of polynomial approximation of
   // exp(t) ~ 1 + t * (c1 + t * (c2 + t * (c3 + t * (c4 + t * c5)))) on [-log(2)/2, log(2)/2]
   const __m256 vc5 = _mm256_set1_ps(0x1.0F9F9Cp-7f);
   const __m256 vc4 = _mm256_set1_ps(0x1.573A1Ap-5f);
   const __m256 vc3 = _mm256_set1_ps(0x1.555A80p-3f);
   const __m256 vc2 = _mm256_set1_ps(0x1.FFFDC6p-2f);
   const __m256 vc1 = _mm256_set1_ps(0x1.FFFFF6p-1f);
   const __m256 vone = _mm256_set1_ps(1.0f);
   // The smallest x for which sigmoidf(x) is normalized.
   // This number is also the smallest x for which expf(x) is normalized.
   const __m256 vdenorm_cutoff = _mm256_set1_ps(-0x1.5D589Ep+6f);

   for (; n != 0; n -= 8 * sizeof(float)) {
     const __m256 vx = _mm256_loadu_ps(input);

     // General structure of the algorithm:
     //
     //           / exp(x) / (1 + exp(x)) if x <= 0
     //   f[x] :=
     //           \ 1 - f[-x] if x >= 0
     //
     // First we compute f[z] := exp(z) / (1 + exp(z)) where z = -abs(x), then replace result with 1 - f[z] if x >= 0.
     const __m256 vz = _mm256_or_ps(vx, vsign_mask);

     // Compute reduced argument n := round(z / log(2)).
     // We do it by adding a large number (magic bias), which cause rounding of the result to integer, then subtracing
     // the large number back. The addition is combined with multiplication by log2e into a single FMA instruction. The
     // trick with adding large number is valid only within certain bounds (|z / log(2)| <= 2**22, i.e.
     // |z| <= 0x1.62E43p+21 = 2907270.0), but that is acceptable, because inputs x outside of [-87.336544, 17.328678]
     // (i.e. z outsize [87.336544, 0]) underflow or saturate sigmoidf(x). We fixup the result for such inputs at the
     // very end of the algorithm.
     __m256 vn = _mm256_fmadd_ps(vz, vlog2e, vmagic_bias);

     // Create a floating-point number s (scale) such that s == 2**n for inputs which don't cause underflow, i.e.
     // -87.33642 <= z <= 0.0, and -126 <= n <= 0 accordingly.
     const __m256 vs = _mm256_castsi256_ps(_mm256_slli_epi32(_mm256_castps_si256(vn), 23));

     // Subtract the large number back to get the final n := round(z / log(2)) as a floating-point number.
     vn = _mm256_sub_ps(vn, vmagic_bias);

     // Compute reduced argument t := z - n * log(2).
     __m256 vt = _mm256_fmadd_ps(vn, vminus_ln2, vz);

     // Compute degree-5 polynomial approximation for exp(t) on [-log(2)/2, log(2)/2].
     //   P(t) = 1 + t * (c1 + t * (c2 + t * (c3 + t * (c4 + t * c5)))) = 1 + t * p
     __m256 vp = _mm256_fmadd_ps(vc5, vt, vc4);
     vp = _mm256_fmadd_ps(vp, vt, vc3);
     vp = _mm256_fmadd_ps(vp, vt, vc2);
     vp = _mm256_fmadd_ps(vp, vt, vc1);

     // Reconstruct the exp(z) value:
     //   e = s * (1 + t * (c1 + t * (c2 + t * (c3 + t * (c4 + t * c5)))))
     //     = s + (t * s) * (c1 + t * (c2 + t * (c3 + t * (c4 + t * c5))))
     //     = s + (t * s) * p
     vt = _mm256_mul_ps(vt, vs);
     const __m256 ve = _mm256_fmadd_ps(vt, vp, vs);

     // Denominator of the sigmoid fraction: 1.0 + exp(z)
     const __m256 vd = _mm256_add_ps(ve, vone);

     // Use Newton-Raphson method (2 iterations) to compute reciprocal of denominator.
     // Note: 1 < d <= 2, because z >= 0.0 and 0 < exp(-z) <= 1.0.
     // Thus the reciprocal of the denominator never overflows.
     __m256 vr = _mm256_rcp_ps(vd);
     vr = _mm256_fmadd_ps(_mm256_fnmadd_ps(vr, vd, vone), vr, vr);
     vr = _mm256_fmadd_ps(_mm256_fnmadd_ps(vr, vd, vone), vr, vr);

     // Reconstruct sigmoid(z) = exp(z) / (1.0 + exp(z))
     __m256 vf = _mm256_mul_ps(ve, vr);

     // For inputs below denormal cutoff, replace output with +0.0f.
     // Note that for NaN inputs, comparison result is false, and outputs are left unchanged.
     vf = _mm256_andnot_ps(_mm256_cmp_ps(vz, vdenorm_cutoff, _CMP_LT_OS), vf);

     // Reconstruct sigmoid(x) = x < 0 ? sigmoid(z) : 1.0 - sigmoid(z)
     vf = _mm256_blendv_ps(_mm256_sub_ps(vone, vf), vf, vx);

     _mm256_storeu_ps(output, vf);

     input += 8;
     output += 8;
   }
 }
	// Copyright 2019 Google LLC
	//
	// This source code is licensed under the BSD-style license found in the
	// LICENSE file in the root directory of this source tree.

	#include <assert.h>
	#include <stddef.h>

	#include <immintrin.h>

	#include <xnnpack/math-stubs.h>


	void xnn_math_f32_sigmoid__avx2_rr1_p5_nr2fma(
	size_t n,
	const float* input,
	float* output)
	{
	assert(n % (8 * sizeof(float)) == 0);

	// Floating-point mask with only the sign bit set
	const __m256 vsign_mask = _mm256_set1_ps(-0.0f);
	// Large number such that ulp(magic bias) == 1 and magic bias === 127 mod 2**22.
	const __m256 vmagic_bias = _mm256_set1_ps(0x1.8000FEp23f);
	const __m256 vlog2e = _mm256_set1_ps(0x1.715476p0f);
	const __m256 vminus_ln2 = _mm256_set1_ps(-0x1.62E43p-1f);
	// Coefficient of polynomial approximation of
	// exp(t) ~ 1 + t * (c1 + t * (c2 + t * (c3 + t * (c4 + t * c5)))) on [-log(2)/2, log(2)/2]
	const __m256 vc5 = _mm256_set1_ps(0x1.0F9F9Cp-7f);
	const __m256 vc4 = _mm256_set1_ps(0x1.573A1Ap-5f);
	const __m256 vc3 = _mm256_set1_ps(0x1.555A80p-3f);
	const __m256 vc2 = _mm256_set1_ps(0x1.FFFDC6p-2f);
	const __m256 vc1 = _mm256_set1_ps(0x1.FFFFF6p-1f);
	const __m256 vone = _mm256_set1_ps(1.0f);
	// The smallest x for which sigmoidf(x) is normalized.
	// This number is also the smallest x for which expf(x) is normalized.
	const __m256 vdenorm_cutoff = _mm256_set1_ps(-0x1.5D589Ep+6f);

	for (; n != 0; n -= 8 * sizeof(float)) {
	const __m256 vx = _mm256_loadu_ps(input);

	// General structure of the algorithm:
	//
	// / exp(x) / (1 + exp(x)) if x <= 0
	// f[x] :=
	// \ 1 - f[-x] if x >= 0
	//
	// First we compute f[z] := exp(z) / (1 + exp(z)) where z = -abs(x), then replace result with 1 - f[z] if x >= 0.
	const __m256 vz = _mm256_or_ps(vx, vsign_mask);

	// Compute reduced argument n := round(z / log(2)).
	// We do it by adding a large number (magic bias), which cause rounding of the result to integer, then subtracing
	// the large number back. The addition is combined with multiplication by log2e into a single FMA instruction. The
	// trick with adding large number is valid only within certain bounds (\|z / log(2)\| <= 2**22, i.e.
	// \|z\| <= 0x1.62E43p+21 = 2907270.0), but that is acceptable, because inputs x outside of [-87.336544, 17.328678]
	// (i.e. z outsize [87.336544, 0]) underflow or saturate sigmoidf(x). We fixup the result for such inputs at the
	// very end of the algorithm.
	__m256 vn = _mm256_fmadd_ps(vz, vlog2e, vmagic_bias);

	// Create a floating-point number s (scale) such that s == 2**n for inputs which don't cause underflow, i.e.
	// -87.33642 <= z <= 0.0, and -126 <= n <= 0 accordingly.
	const __m256 vs = _mm256_castsi256_ps(_mm256_slli_epi32(_mm256_castps_si256(vn), 23));

	// Subtract the large number back to get the final n := round(z / log(2)) as a floating-point number.
	vn = _mm256_sub_ps(vn, vmagic_bias);

	// Compute reduced argument t := z - n * log(2).
	__m256 vt = _mm256_fmadd_ps(vn, vminus_ln2, vz);

	// Compute degree-5 polynomial approximation for exp(t) on [-log(2)/2, log(2)/2].
	// P(t) = 1 + t * (c1 + t * (c2 + t * (c3 + t * (c4 + t * c5)))) = 1 + t * p
	__m256 vp = _mm256_fmadd_ps(vc5, vt, vc4);
	vp = _mm256_fmadd_ps(vp, vt, vc3);
	vp = _mm256_fmadd_ps(vp, vt, vc2);
	vp = _mm256_fmadd_ps(vp, vt, vc1);

	// Reconstruct the exp(z) value:
	// e = s * (1 + t * (c1 + t * (c2 + t * (c3 + t * (c4 + t * c5)))))
	// = s + (t * s) * (c1 + t * (c2 + t * (c3 + t * (c4 + t * c5))))
	// = s + (t * s) * p
	vt = _mm256_mul_ps(vt, vs);
	const __m256 ve = _mm256_fmadd_ps(vt, vp, vs);

	// Denominator of the sigmoid fraction: 1.0 + exp(z)
	const __m256 vd = _mm256_add_ps(ve, vone);

	// Use Newton-Raphson method (2 iterations) to compute reciprocal of denominator.
	// Note: 1 < d <= 2, because z >= 0.0 and 0 < exp(-z) <= 1.0.
	// Thus the reciprocal of the denominator never overflows.
	__m256 vr = _mm256_rcp_ps(vd);
	vr = _mm256_fmadd_ps(_mm256_fnmadd_ps(vr, vd, vone), vr, vr);
	vr = _mm256_fmadd_ps(_mm256_fnmadd_ps(vr, vd, vone), vr, vr);

	// Reconstruct sigmoid(z) = exp(z) / (1.0 + exp(z))
	__m256 vf = _mm256_mul_ps(ve, vr);

	// For inputs below denormal cutoff, replace output with +0.0f.
	// Note that for NaN inputs, comparison result is false, and outputs are left unchanged.
	vf = _mm256_andnot_ps(_mm256_cmp_ps(vz, vdenorm_cutoff, _CMP_LT_OS), vf);

	// Reconstruct sigmoid(x) = x < 0 ? sigmoid(z) : 1.0 - sigmoid(z)
	vf = _mm256_blendv_ps(_mm256_sub_ps(vone, vf), vf, vx);

	_mm256_storeu_ps(output, vf);

	input += 8;
	output += 8;
	}
	}