// Copyright 2024 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 $ABC = "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ" #include #include #include #include #include #include "xnnpack/common.h" #include "xnnpack/microparams.h" #include "xnnpack/vunary.h" // In the following, we do a single Newton-Raphson step on the equation // $x^{-2} - a$, which expands to: // // $$x_{k+1} = 0.5 * x_k * (3.0 - a * x_k^2)$$ // // So we do the following steps: // // 1. t0 = x_k // 2. t1 = t0 * t0 (x_k^2) // 3. t3 = a * t1 - 3.0 (a * x_k^2 - 3.0) // 4. t4 = 0.5 * t0 (-0.5 * x_k) // 5. y = t3 * t4 ((-0.5 * x_k) * (a * x_k^2 - 3.0)) // // Where $x_k$ is the original 12-bit approximation and `y` contains the final // 24-bit approximation $x_{k+1}$. void xnn_f32_vrsqrt_ukernel__fma3_rsqrt_u${BATCH_TILE}( size_t batch, const float* input, float* output, const struct xnn_f32_default_params params[restrict XNN_MIN_ELEMENTS(1)]) XNN_OOB_READS { static const int32_t mask_table[14] = {-1, -1, -1, -1, -1, -1, -1, 0, 0, 0, 0, 0, 0, 0}; assert(batch != 0); assert(batch % sizeof(float) == 0); assert(input != NULL); assert(output != NULL); // Constants for the Newton-Raphson iteration. const __m256 vthree = _mm256_set1_ps(3.0f); const __m256 vneg_half = _mm256_set1_ps(-0.5f); $if BATCH_TILE > 8: for (; batch >= ${BATCH_TILE} * sizeof(float); batch -= ${BATCH_TILE} * sizeof(float)) { const __m256 vx${ABC[0]} = _mm256_loadu_ps(input); $for N in range(1, SIMD_TILE): const __m256 vx${ABC[N]} = _mm256_loadu_ps(input + ${N * 8}); input += ${BATCH_TILE}; // Generate the initial 12-bit approximation. $for N in range(SIMD_TILE): const __m256 vt0_${ABC[N]} = _mm256_rsqrt_ps(vx${ABC[N]}); // Do a single Newton-Raphson step as described above. $for N in range(SIMD_TILE): const __m256 vt1_${ABC[N]} = _mm256_mul_ps(vt0_${ABC[N]}, vt0_${ABC[N]}); $for N in range(SIMD_TILE): const __m256 vt3_${ABC[N]} = _mm256_fmsub_ps(vx${ABC[N]}, vt1_${ABC[N]}, vthree); $for N in range(SIMD_TILE): const __m256 vt4_${ABC[N]} = _mm256_mul_ps(vneg_half, vt0_${ABC[N]}); $for N in range(SIMD_TILE): const __m256 vy${ABC[N]} = _mm256_mul_ps(vt3_${ABC[N]}, vt4_${ABC[N]}); // Store the results. _mm256_storeu_ps(output, vy${ABC[0]}); $for N in range(1, SIMD_TILE): _mm256_storeu_ps(output + ${N * 8}, vy${ABC[N]}); output += ${BATCH_TILE}; } for (; batch >= 8 * sizeof(float); batch -= 8 * sizeof(float)) { const __m256 vx = _mm256_loadu_ps(input); input += 8; // Generate the initial 12-bit approximation. const __m256 vt0 = _mm256_rsqrt_ps(vx); // Do a single Newton-Raphson step as described above. const __m256 vt1 = _mm256_mul_ps(vt0, vt0); const __m256 vt3 = _mm256_fmsub_ps(vx, vt1, vthree); const __m256 vt4 = _mm256_mul_ps(vneg_half, vt0); const __m256 vy = _mm256_mul_ps(vt3, vt4); _mm256_storeu_ps(output, vy); output += 8; } if XNN_UNLIKELY(batch != 0) { assert(batch >= 1 * sizeof(float)); assert(batch <= 7 * sizeof(float)); const __m256i vmask = _mm256_loadu_si256((const __m256i*)((uintptr_t) &mask_table[7] - batch)); const __m256 vx = _mm256_maskload_ps(input, vmask); // Generate the initial 12-bit approximation. const __m256 vt0 = _mm256_rsqrt_ps(vx); // Do a single Newton-Raphson step as described above. const __m256 vt1 = _mm256_mul_ps(vt0, vt0); const __m256 vt3 = _mm256_fmsub_ps(vx, vt1, vthree); const __m256 vt4 = _mm256_mul_ps(vneg_half, vt0); __m256 vy = _mm256_mul_ps(vt3, vt4); __m128 vy_lo = _mm256_castps256_ps128(vy); if (batch & (4 * sizeof(float))) { _mm_storeu_ps(output, vy_lo); vy_lo = _mm256_extractf128_ps(vy, 1); output += 4; } if (batch & (2 * sizeof(float))) { _mm_storel_pi((__m64*) output, vy_lo); vy_lo = _mm_movehl_ps(vy_lo, vy_lo); output += 2; } if (batch & (1 * sizeof(float))) { _mm_store_ss(output, vy_lo); } } }