// 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. $assert BATCH_TILE % 8 == 0 $assert BATCH_TILE >= 8 $SIMD_TILE = BATCH_TILE // 8 #include #include #include "xnnpack/intrinsics-polyfill.h" #include "xnnpack/raddstoreexpminusmax.h" $ISA = "avx2" if AVX == 2 else "avx256skx" void xnn_f32_raddstoreexpminusmax_ukernel__${ISA}_rr2_p5_u${BATCH_TILE}${"" if ACCUMULATORS == 1 else "_acc%d" % ACCUMULATORS}( size_t batch, const float* input, const float* max, float* output, float* sum, const void* params) { assert(batch != 0); assert(batch % sizeof(float) == 0); assert(input != NULL); assert(max != NULL); assert(output != NULL); assert(sum != NULL); $if AVX != 10: static const int32_t mask_table[16] = {-1, -1, -1, -1, -1, -1, -1, -1, 0, 0, 0, 0, 0, 0, 0, 0}; const __m256 vlog2e = _mm256_set1_ps(0x1.715476p+0f); const __m256 vmagic_bias = _mm256_set1_ps(0x1.8000FEp23f); const __m256 vminus_ln2_hi = _mm256_set1_ps(-0x1.62E400p-1f); const __m256 vminus_ln2_lo = _mm256_set1_ps(-0x1.7F7D1Cp-20f); 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 vdenorm_cutoff = _mm256_set1_ps(-0x1.5D589Ep6f); XNN_FORCE_REALIZATION(vlog2e); XNN_FORCE_REALIZATION(vmagic_bias); XNN_FORCE_REALIZATION(vminus_ln2_hi); XNN_FORCE_REALIZATION(vminus_ln2_lo); XNN_FORCE_REALIZATION(vc5); XNN_FORCE_REALIZATION(vc4); XNN_FORCE_REALIZATION(vc3); XNN_FORCE_REALIZATION(vc2); XNN_FORCE_REALIZATION(vc1); XNN_FORCE_REALIZATION(vdenorm_cutoff); const __m256 vi_max = _mm256_broadcast_ss(max); $if AVX == 10: const __m256 vzero = _mm256_setzero_ps(); $for K in range(ACCUMULATORS): __m256 vacc${K} = _mm256_setzero_ps(); for (; batch >= ${BATCH_TILE} * sizeof(float); batch -= ${BATCH_TILE} * sizeof(float)) { // Load ${BATCH_TILE} (${SIMD_TILE}x8) inputs at a time. const __m256 vi0 = _mm256_loadu_ps(input); $for N in range(1, SIMD_TILE): const __m256 vi${N} = _mm256_loadu_ps(input + ${N * 8}); input += ${BATCH_TILE}; // Subtract maximum input x := i - i_max. This implies x <= 0. $for N in range(SIMD_TILE): const __m256 vx${N} = _mm256_sub_ps(vi${N}, vi_max); // Compute reduced argument batch := round(x / log(2)). $for N in range(SIMD_TILE): __m256 vn${N} = _mm256_fmadd_ps(vx${N}, vlog2e, vmagic_bias); // Create a floating-point number s (scale) such that s == 2**batch for inputs which don't cause underflow, i.e. // -87.33642 <= x <= 0.0, and -126 <= batch <= 0 accordingly. $for N in range(SIMD_TILE): const __m256 vs${N} = _mm256_castsi256_ps(_mm256_slli_epi32(_mm256_castps_si256(vn${N}), 23)); // Subtract the large number back to get final batch := round(x / log(2)). $for N in range(SIMD_TILE): vn${N} = _mm256_sub_ps(vn${N}, vmagic_bias); // Compute reduced argument t := x - batch * log(2). // Use Cody-Waite range reduction method (note two constants to represent log(2)) to improve accuracy. $for N in range(SIMD_TILE): __m256 vt${N} = _mm256_fmadd_ps(vn${N}, vminus_ln2_hi, vx${N}); $for N in range(SIMD_TILE): vt${N} = _mm256_fmadd_ps(vn${N}, vminus_ln2_lo, vt${N}); // Compute degree-5 polynomial approximation for exp(t) on [-log(2)/2, log(2)/2]. $for N in range(SIMD_TILE): __m256 vp${N} = _mm256_fmadd_ps(vc5, vt${N}, vc4); $for N in range(SIMD_TILE): vp${N} = _mm256_fmadd_ps(vp${N}, vt${N}, vc3); $for N in range(SIMD_TILE): vp${N} = _mm256_fmadd_ps(vp${N}, vt${N}, vc2); $for N in range(SIMD_TILE): vp${N} = _mm256_fmadd_ps(vp${N}, vt${N}, vc1); // Reconstruct the final f value: // f = 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 $for N in range(SIMD_TILE): vt${N} = _mm256_mul_ps(vt${N}, vs${N}); $for N in range(SIMD_TILE): __m256 vf${N} = _mm256_fmadd_ps(vt${N}, vp${N}, vs${N}); // For inputs below zero cutoff, replace output with +0.0f. // Note that for NaN inputs, comparison result is false, and outputs are left unchanged. $for N in range(SIMD_TILE): $if AVX == 10: vf${N} = _mm256_mask_blend_ps(_mm256_cmp_ps_mask(vx${N}, vdenorm_cutoff, _CMP_LT_OS), vf${N}, vzero); $else: vf${N} = _mm256_andnot_ps(_mm256_cmp_ps(vx${N}, vdenorm_cutoff, _CMP_LT_OS), vf${N}); // Store ${BATCH_TILE} (${SIMD_TILE}x8) outputs at a time. _mm256_storeu_ps(output, vf0); $for N in range(1, SIMD_TILE): _mm256_storeu_ps(output + ${N * 8}, vf${N}); output += ${BATCH_TILE}; // Accumulate computed exponents. $for N in range(SIMD_TILE): vacc${N % ACCUMULATORS} = _mm256_add_ps(vacc${N % ACCUMULATORS}, vf${N}); } $if ACCUMULATORS > 1: // Add up all accumulators to vacc0 $ACC_SLICE = 1 $while ACC_SLICE < ACCUMULATORS: $for A in range(0, ACCUMULATORS, ACC_SLICE * 2): $if A + ACC_SLICE < ACCUMULATORS: vacc${A} = _mm256_add_ps(vacc${A}, vacc${A + ACC_SLICE}); $ACC_SLICE *= 2 __m256 vacc = vacc0; for (; batch >= 8 * sizeof(float); batch -= 8 * sizeof(float)) { // Load 8 inputs at a time. const __m256 vi = _mm256_loadu_ps(input); input += 8; // Subtract maximum input x := i - i_max. This implies x <= 0. const __m256 vx = _mm256_sub_ps(vi, vi_max); // Compute reduced argument batch := round(x / log(2)). __m256 vn = _mm256_fmadd_ps(vx, vlog2e, vmagic_bias); // Create a floating-point number s (scale) such that s == 2**batch for inputs which don't cause underflow, i.e. // -87.33642 <= x <= 0.0, and -126 <= batch <= 0 accordingly. const __m256 vs = _mm256_castsi256_ps(_mm256_slli_epi32(_mm256_castps_si256(vn), 23)); // Subtract the large number back to get final batch := round(x / log(2)). vn = _mm256_sub_ps(vn, vmagic_bias); // Compute reduced argument t := x - batch * log(2). // Use Cody-Waite range reduction method (note two constants to represent log(2)) to improve accuracy. __m256 vt = _mm256_fmadd_ps(vn, vminus_ln2_hi, vx); vt = _mm256_fmadd_ps(vn, vminus_ln2_lo, vt); // Compute degree-5 polynomial approximation for exp(t) on [-log(2)/2, log(2)/2]. __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 final f value: // f = 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); __m256 vf = _mm256_fmadd_ps(vt, vp, vs); // For inputs below zero cutoff, replace output with +0.0f. // Note that for NaN inputs, comparison result is false, and outputs are left unchanged. $if AVX == 10: vf = _mm256_mask_blend_ps(_mm256_cmp_ps_mask(vx, vdenorm_cutoff, _CMP_LT_OS), vf, vzero); $else: vf = _mm256_andnot_ps(_mm256_cmp_ps(vx, vdenorm_cutoff, _CMP_LT_OS), vf); // Store 8 outputs at a time. _mm256_storeu_ps(output, vf); output += 8; // Accumulate computed exponents. vacc = _mm256_add_ps(vacc, vf); } if (batch != 0) { assert(batch >= 1 * sizeof(float)); assert(batch <= 7 * sizeof(float)); $if AVX == 10: // Prepare mask for valid 32-bit batch (depends on batch). batch >>= XNN_LOG2_SIZEOF_FLOAT; const __mmask8 vmask = _cvtu32_mask8((uint32_t) ((UINT32_C(1) << batch) - UINT32_C(1))); // Load 8 inputs at a time. const __m256 vi = _mm256_maskz_loadu_ps(vmask, input); $else: const __m256i vmask = _mm256_loadu_si256((const __m256i*) ((uintptr_t) &mask_table[8] - batch)); const __m256 vi = _mm256_maskload_ps(input, vmask); // Subtract maximum input x := i - i_max. This implies x <= 0. const __m256 vx = _mm256_sub_ps(vi, vi_max); // Compute reduced argument batch := round(x / log(2)). __m256 vn = _mm256_fmadd_ps(vx, vlog2e, vmagic_bias); // Create a floating-point number s (scale) such that s == 2**batch for inputs which don't cause underflow, i.e. // -87.33642 <= x <= 0.0, and -126 <= batch <= 0 accordingly. const __m256 vs = _mm256_castsi256_ps(_mm256_slli_epi32(_mm256_castps_si256(vn), 23)); // Subtract the large number back to get final batch := round(x / log(2)). vn = _mm256_sub_ps(vn, vmagic_bias); // Compute reduced argument t := x - batch * log(2). // Use Cody-Waite range reduction method (note two constants to represent log(2)) to improve accuracy. __m256 vt = _mm256_fmadd_ps(vn, vminus_ln2_hi, vx); vt = _mm256_fmadd_ps(vn, vminus_ln2_lo, vt); // Compute degree-5 polynomial approximation for exp(t) on [-log(2)/2, log(2)/2]. __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 final f value: // f = 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); __m256 vf = _mm256_fmadd_ps(vt, vp, vs); // For inputs below zero cutoff, replace output with +0.0f. // Note that for NaN inputs, comparison result is false, and outputs are left unchanged. $if AVX == 10: vf = _mm256_mask_blend_ps(_mm256_cmp_ps_mask(vx, vdenorm_cutoff, _CMP_LT_OS), vf, vzero); $else: vf = _mm256_andnot_ps(_mm256_cmp_ps(vx, vdenorm_cutoff, _CMP_LT_OS), vf); $if AVX == 10: // For inputs below zero cutoff, replace output with +0.0f. // Note that for NaN inputs, comparison result is false, and outputs are left unchanged. vf = _mm256_mask_blend_ps(_mm256_cmp_ps_mask(vx, vdenorm_cutoff, _CMP_LT_OS), vf, vzero); _mm256_mask_storeu_ps(output, vmask, vf); vacc = _mm256_mask_add_ps(vacc, vmask, vacc, vf); $else: __m128 vf_lo = _mm256_castps256_ps128(vf); if (batch & (4 * sizeof(float))) { _mm_storeu_ps(output, vf_lo); vf_lo = _mm256_extractf128_ps(vf, 1); output += 4; } if (batch & (2 * sizeof(float))) { _mm_storel_pi((__m64*) output, vf_lo); vf_lo = _mm_movehl_ps(vf_lo, vf_lo); output += 2; } if (batch & (1 * sizeof(float))) { _mm_store_ss(output, vf_lo); } vacc = _mm256_add_ps(vacc, _mm256_and_ps(vf, _mm256_castsi256_ps(vmask))); } __m128 vacc_lo = _mm_add_ps(_mm256_castps256_ps128(vacc), _mm256_extractf128_ps(vacc, 1)); vacc_lo = _mm_add_ps(vacc_lo, _mm_movehl_ps(vacc_lo, vacc_lo)); vacc_lo = _mm_add_ss(vacc_lo, _mm_movehdup_ps(vacc_lo)); _mm_store_ss(sum, vacc_lo); }