/* * Copyright (c) 2017-2019 ARM Limited. * * SPDX-License-Identifier: MIT * * Permission is hereby granted, free of charge, to any person obtaining a copy * of this software and associated documentation files (the "Software"), to * deal in the Software without restriction, including without limitation the * rights to use, copy, modify, merge, publish, distribute, sublicense, and/or * sell copies of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in all * copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE * SOFTWARE. */ #include "arm_compute/core/NEON/kernels/NEReductionOperationKernel.h" #include "arm_compute/core/CPP/Validate.h" #include "arm_compute/core/Coordinates.h" #include "arm_compute/core/Helpers.h" #include "arm_compute/core/IAccessWindow.h" #include "arm_compute/core/ITensor.h" #include "arm_compute/core/NEON/INEKernel.h" #include "arm_compute/core/NEON/NEMath.h" #include "arm_compute/core/TensorInfo.h" #include "arm_compute/core/Validate.h" #include "arm_compute/core/utils/misc/ShapeCalculator.h" #include "arm_compute/core/NEON/wrapper/wrapper.h" #include namespace arm_compute { namespace { template uint32x4x4_t calculate_index(uint32_t idx, T a, T b, uint32x4x4_t c, ReductionOperation op, int axis) { uint32x4_t mask{ 0 }; if(op == ReductionOperation::ARG_IDX_MIN) { mask = wrapper::vcgt(b, a); } else { mask = wrapper::vclt(b, a); } uint32x4_t vec_idx = { idx, idx + 1, idx + 2, idx + 3 }; if(axis != 0) { vec_idx = wrapper::vdup_n(idx, wrapper::traits::vector_128_tag{}); } uint32x4x4_t res = { { wrapper::vbsl(mask, vec_idx, c.val[0]), 0, 0, 0 } }; return res; } template <> uint32x4x4_t calculate_index(uint32_t idx, uint8x16_t a, uint8x16_t b, uint32x4x4_t c, ReductionOperation op, int axis) { uint32x4x4_t mask{ { 0 } }; uint8x16_t mask_u8{ 0 }; if(op == ReductionOperation::ARG_IDX_MIN) { mask_u8 = wrapper::vcgt(b, a); } else { mask_u8 = wrapper::vclt(b, a); } auto wide_u16_1 = wrapper::vorr(vshll_n_u8(wrapper::vgetlow(mask_u8), 8), wrapper::vmovl(wrapper::vgetlow(mask_u8))); auto wide_u16_2 = wrapper::vorr(vshll_n_u8(wrapper::vgethigh(mask_u8), 8), wrapper::vmovl(wrapper::vgethigh(mask_u8))); mask.val[0] = wrapper::vorr(vshll_n_u16(wrapper::vgetlow(wide_u16_1), 16), wrapper::vmovl(wrapper::vgetlow(wide_u16_1))); mask.val[1] = wrapper::vorr(vshll_n_u16(wrapper::vgethigh(wide_u16_1), 16), wrapper::vmovl(wrapper::vgethigh(wide_u16_1))); mask.val[2] = wrapper::vorr(vshll_n_u16(wrapper::vgetlow(wide_u16_2), 16), wrapper::vmovl(wrapper::vgetlow(wide_u16_2))); mask.val[3] = wrapper::vorr(vshll_n_u16(wrapper::vgethigh(wide_u16_2), 16), wrapper::vmovl(wrapper::vgethigh(wide_u16_2))); uint32x4x4_t vec_idx = { { { idx + 0, idx + 1, idx + 2, idx + 3 }, { idx + 4, idx + 5, idx + 6, idx + 7 }, { idx + 8, idx + 9, idx + 10, idx + 11 }, { idx + 12, idx + 13, idx + 14, idx + 15 } } }; if(axis != 0) { vec_idx.val[0] = wrapper::vdup_n(idx, wrapper::traits::vector_128_tag{}); vec_idx.val[1] = wrapper::vdup_n(idx, wrapper::traits::vector_128_tag{}); vec_idx.val[2] = wrapper::vdup_n(idx, wrapper::traits::vector_128_tag{}); vec_idx.val[3] = wrapper::vdup_n(idx, wrapper::traits::vector_128_tag{}); } uint32x4x4_t res = { { vbslq_u32(mask.val[0], vec_idx.val[0], c.val[0]), vbslq_u32(mask.val[1], vec_idx.val[1], c.val[1]), vbslq_u32(mask.val[2], vec_idx.val[2], c.val[2]), vbslq_u32(mask.val[3], vec_idx.val[3], c.val[3]) } }; return res; } // Helper function to calculate the minimum value of the input vector. All the elements in the output vector contain the min value. float32x2_t calculate_min(float32x4_t in) { auto pmin = wrapper::vpmin(wrapper::vgethigh(in), wrapper::vgetlow(in)); return wrapper::vpmin(pmin, pmin); } // Helper function to calculate the maximum value of the input vector. All the elements in the output vector contain the max value. float32x2_t calculate_max(float32x4_t in) { auto pmax = wrapper::vpmax(wrapper::vgethigh(in), wrapper::vgetlow(in)); return wrapper::vpmax(pmax, pmax); } // Helper function to calculate the minimum value of the input vector. All the elements in the output vector contain the min value. int32x2_t calculate_min(int32x4_t in) { auto pmin = wrapper::vpmin(wrapper::vgethigh(in), wrapper::vgetlow(in)); return wrapper::vpmin(pmin, pmin); } // Helper function to calculate the maximum value of the input vector. All the elements in the output vector contain the max value. int32x2_t calculate_max(int32x4_t in) { auto pmax = wrapper::vpmax(wrapper::vgethigh(in), wrapper::vgetlow(in)); return wrapper::vpmax(pmax, pmax); } template uint32_t calculate_vector_index(uint32x4x4_t vec_res_idx, T vec_res_value, ReductionOperation op) { uint32x4_t res_idx_mask{ 0 }; uint32x4_t mask_ones = vdupq_n_u32(0xFFFFFFFF); if(op == ReductionOperation::ARG_IDX_MIN) { auto pmin = calculate_min(vec_res_value); auto mask = wrapper::vceq(vec_res_value, wrapper::vcombine(pmin, pmin)); res_idx_mask = wrapper::vand(vec_res_idx.val[0], mask); } else { auto pmax = calculate_max(vec_res_value); auto mask = wrapper::vceq(vec_res_value, wrapper::vcombine(pmax, pmax)); res_idx_mask = wrapper::vand(vec_res_idx.val[0], mask); } res_idx_mask = wrapper::vadd(res_idx_mask, mask_ones); auto pmin = wrapper::vpmin(wrapper::vgethigh(res_idx_mask), wrapper::vgetlow(res_idx_mask)); pmin = wrapper::vpmin(pmin, pmin); uint32_t res = wrapper::vgetlane(pmin, 0); return (res - 0xFFFFFFFF); } // Helper function to calculate the minimum value of the input vector. All the elements in the output vector contain the min value. inline uint8x8_t calculate_min(uint8x16_t in) { auto pmin = wrapper::vpmin(wrapper::vgethigh(in), wrapper::vgetlow(in)); pmin = wrapper::vpmin(pmin, pmin); pmin = wrapper::vpmin(pmin, pmin); return wrapper::vpmin(pmin, pmin); } // Helper function to calculate the maximum value of the input vector. All the elements in the output vector contain the max value. inline uint8x8_t calculate_max(uint8x16_t in) { auto pmax = wrapper::vpmax(wrapper::vgethigh(in), wrapper::vgetlow(in)); pmax = wrapper::vpmax(pmax, pmax); pmax = wrapper::vpmax(pmax, pmax); return wrapper::vpmax(pmax, pmax); } template <> uint32_t calculate_vector_index(uint32x4x4_t vec_res_idx, uint8x16_t vec_res_value, ReductionOperation op) { uint32x4x4_t res_idx_mask{ { 0 } }; uint32x4_t mask_ones = vdupq_n_u32(0xFFFFFFFF); uint8x16_t mask_u8{ 0 }; if(op == ReductionOperation::ARG_IDX_MIN) { auto pmin = calculate_min(vec_res_value); mask_u8 = wrapper::vceq(vec_res_value, wrapper::vcombine(pmin, pmin)); } else { auto pmax = calculate_max(vec_res_value); mask_u8 = wrapper::vceq(vec_res_value, wrapper::vcombine(pmax, pmax)); } // Widen vectors auto wide_u16_1 = wrapper::vorr(vshll_n_u8(wrapper::vgetlow(mask_u8), 8), wrapper::vmovl(wrapper::vgetlow(mask_u8))); auto wide_u16_2 = wrapper::vorr(vshll_n_u8(wrapper::vgethigh(mask_u8), 8), wrapper::vmovl(wrapper::vgethigh(mask_u8))); auto wide_u32_1 = wrapper::vorr(vshll_n_u16(wrapper::vgetlow(wide_u16_1), 16), wrapper::vmovl(wrapper::vgetlow(wide_u16_1))); auto wide_u32_2 = wrapper::vorr(vshll_n_u16(wrapper::vgethigh(wide_u16_1), 16), wrapper::vmovl(wrapper::vgethigh(wide_u16_1))); auto wide_u32_3 = wrapper::vorr(vshll_n_u16(wrapper::vgetlow(wide_u16_2), 16), wrapper::vmovl(wrapper::vgetlow(wide_u16_2))); auto wide_u32_4 = wrapper::vorr(vshll_n_u16(wrapper::vgethigh(wide_u16_2), 16), wrapper::vmovl(wrapper::vgethigh(wide_u16_2))); res_idx_mask.val[0] = wrapper::vand(vec_res_idx.val[0], wide_u32_1); res_idx_mask.val[1] = wrapper::vand(vec_res_idx.val[1], wide_u32_2); res_idx_mask.val[2] = wrapper::vand(vec_res_idx.val[2], wide_u32_3); res_idx_mask.val[3] = wrapper::vand(vec_res_idx.val[3], wide_u32_4); res_idx_mask.val[0] = wrapper::vadd(res_idx_mask.val[0], mask_ones); res_idx_mask.val[1] = wrapper::vadd(res_idx_mask.val[1], mask_ones); res_idx_mask.val[2] = wrapper::vadd(res_idx_mask.val[2], mask_ones); res_idx_mask.val[3] = wrapper::vadd(res_idx_mask.val[3], mask_ones); uint32_t res = 0xFFFFFFFF; int iter = 0; do { auto pmin = wrapper::vpmin(wrapper::vgethigh(res_idx_mask.val[iter]), wrapper::vgetlow(res_idx_mask.val[iter])); pmin = wrapper::vpmin(pmin, pmin); res = std::min(wrapper::vgetlane(pmin, 0), res); iter++; } while(iter < 4); return (res - 0xFFFFFFFF); } #ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC template <> uint32x4x4_t calculate_index(uint32_t idx, float16x8_t a, float16x8_t b, uint32x4x4_t c, ReductionOperation op, int axis) { uint32x4x2_t mask{ 0 }; uint16x8_t mask_u16{ 0 }; if(op == ReductionOperation::ARG_IDX_MIN) { mask_u16 = wrapper::vcgt(b, a); } else { mask_u16 = wrapper::vclt(b, a); } mask.val[0] = wrapper::vmovl(wrapper::vgetlow(mask_u16)); mask.val[1] = wrapper::vmovl(wrapper::vgethigh(mask_u16)); uint32x4x2_t vec_idx = { { { idx + 0, idx + 1, idx + 2, idx + 3 }, { idx + 4, idx + 5, idx + 6, idx + 7 } } }; if(axis != 0) { vec_idx.val[0] = wrapper::vdup_n(idx, wrapper::traits::vector_128_tag{}); vec_idx.val[1] = wrapper::vdup_n(idx, wrapper::traits::vector_128_tag{}); } uint32x4x4_t res = { wrapper::vbsl(mask.val[0], vec_idx.val[0], c.val[0]), wrapper::vbsl(mask.val[1], vec_idx.val[1], c.val[1]), 0, 0 }; return res; } // Helper function to calculate the minimum value of the input vector. All the elements in the output vector contain the min value. inline float16x4_t calculate_min(float16x8_t in) { auto pmin = wrapper::vpmin(wrapper::vgethigh(in), wrapper::vgetlow(in)); pmin = wrapper::vpmin(pmin, pmin); return wrapper::vpmin(pmin, pmin); } // Helper function to calculate the maximum value of the input vector. All the elements in the output vector contain the max value. inline float16x4_t calculate_max(float16x8_t in) { auto pmax = wrapper::vpmax(wrapper::vgethigh(in), wrapper::vgetlow(in)); pmax = wrapper::vpmax(pmax, pmax); return wrapper::vpmax(pmax, pmax); } template <> uint32_t calculate_vector_index(uint32x4x4_t vec_res_idx, float16x8_t vec_res_value, ReductionOperation op) { uint32x4x2_t res_idx_mask{ 0 }; uint32x4_t mask_ones = vdupq_n_u32(0xFFFFFFFF); uint16x8_t mask_u16; if(op == ReductionOperation::ARG_IDX_MIN) { auto pmin = calculate_min(vec_res_value); mask_u16 = wrapper::vceq(vec_res_value, wrapper::vcombine(pmin, pmin)); } else { auto pmax = calculate_max(vec_res_value); mask_u16 = wrapper::vceq(vec_res_value, wrapper::vcombine(pmax, pmax)); } // Widen vectors auto wide_u32_1 = wrapper::vorr(vshll_n_u16(wrapper::vgetlow(mask_u16), 8), wrapper::vmovl(wrapper::vgetlow(mask_u16))); auto wide_u32_2 = wrapper::vorr(vshll_n_u16(wrapper::vgethigh(mask_u16), 8), wrapper::vmovl(wrapper::vgethigh(mask_u16))); res_idx_mask.val[0] = wrapper::vand(vec_res_idx.val[0], wide_u32_1); res_idx_mask.val[1] = wrapper::vand(vec_res_idx.val[1], wide_u32_2); res_idx_mask.val[0] = wrapper::vadd(res_idx_mask.val[0], mask_ones); res_idx_mask.val[1] = wrapper::vadd(res_idx_mask.val[1], mask_ones); uint32_t res = 0xFFFFFFFF; int iter = 0; do { auto pmin = wrapper::vpmin(wrapper::vgethigh(res_idx_mask.val[iter]), wrapper::vgetlow(res_idx_mask.val[iter])); pmin = wrapper::vpmin(pmin, pmin); res = std::min(wrapper::vgetlane(pmin, 0), res); iter++; } while(iter < 2); return (res - 0xFFFFFFFF); } #endif // __ARM_FEATURE_FP16_VECTOR_ARITHMETIC template class Reducer { public: static void reduceX(const Window &window, const ITensor *input, ITensor *output, F f, const ReductionOperation op) { // Set out window Window out_window(window); out_window.set(Window::DimX, Window::Dimension(0, 0, 0)); // Get first input and output slices Window in_slice = window.first_slice_window_1D(); Window out_slice = out_window.first_slice_window_1D(); do { Iterator in(input, in_slice); Iterator out(output, out_slice); f(in, out, in_slice, out_slice, *input->info(), op); } while(window.slide_window_slice_1D(in_slice) && out_window.slide_window_slice_1D(out_slice)); } static void reduceY(const Window &window, const ITensor *input, ITensor *output, F f, const ReductionOperation op) { // Set in window Window in_window(window); Window out_window(window); in_window.set(Window::DimY, Window::Dimension(0, 1, 1)); out_window.set(Window::DimY, Window::Dimension(0, output->info()->dimension(1), output->info()->dimension(1))); // Get first input and output slices Window in_slice = in_window.first_slice_window_2D(); Window out_slice = out_window.first_slice_window_2D(); do { Iterator in(input, in_slice); Iterator out(output, out_slice); f(in, out, in_slice, out_slice, *input->info(), 1, op); } while(in_window.slide_window_slice_2D(in_slice) && out_window.slide_window_slice_2D(out_slice)); } static void reduceZ(const Window &window, const ITensor *input, ITensor *output, F f, const ReductionOperation op) { // Set in window Window in_window(window); Window out_window(window); in_window.set(Window::DimZ, Window::Dimension(0, 1, 1)); out_window.set(Window::DimZ, Window::Dimension(0, output->info()->dimension(2), output->info()->dimension(2))); // Get first input and output slices Window in_slice = in_window.first_slice_window_3D(); Window out_slice = out_window.first_slice_window_3D(); do { Iterator in(input, in_slice); Iterator out(output, out_slice); f(in, out, in_slice, out_slice, *input->info(), 2, op); } while(in_window.slide_window_slice_3D(in_slice) && out_window.slide_window_slice_3D(out_slice)); } static void reduceW(const Window &window, const ITensor *input, ITensor *output, F f, const ReductionOperation op) { // Set in/out window Window in_window(window); Window out_window(window); in_window.set(3, Window::Dimension(0, 1, 1)); out_window.set(3, Window::Dimension(0, 1, 1)); // Get first input and output slices Window in_slice = in_window.first_slice_window_4D(); Window out_slice = out_window.first_slice_window_4D(); do { Iterator in(input, in_slice); Iterator out(output, out_slice); f(in, out, in_slice, out_slice, *input->info(), 3, op); } while(in_window.slide_window_slice_4D(in_slice) && out_window.slide_window_slice_4D(out_slice)); } }; template struct RedOpX { /** NEON vector tag type. */ using ExactTagType = typename wrapper::traits::neon_vector::tag_type; inline void operator()(Iterator &input, Iterator &output, Window &in_slice, Window &out_slice, const TensorInfo &in_info, const ReductionOperation op) { ARM_COMPUTE_UNUSED(out_slice); auto init_res_value = static_cast(0.f); switch(op) { case ReductionOperation::ARG_IDX_MAX: case ReductionOperation::ARG_IDX_MIN: case ReductionOperation::MIN: case ReductionOperation::MAX: { init_res_value = *reinterpret_cast(input.ptr()); break; } case ReductionOperation::PROD: { init_res_value = static_cast(1.f); break; } default: break; } auto vec_res_value = wrapper::vdup_n(init_res_value, ExactTagType{}); uint32x4x4_t vec_res_idx{ { 0 } }; execute_window_loop(in_slice, [&](const Coordinates & id) { const auto in_ptr = reinterpret_cast(input.ptr()); const auto vec_elements = wrapper::vloadq(in_ptr); switch(op) { case ReductionOperation::SUM_SQUARE: vec_res_value = wrapper::vadd(wrapper::vmul(vec_elements, vec_elements), vec_res_value); break; case ReductionOperation::MEAN_SUM: case ReductionOperation::SUM: vec_res_value = wrapper::vadd(vec_elements, vec_res_value); break; case ReductionOperation::PROD: vec_res_value = wrapper::vmul(vec_elements, vec_res_value); break; case ReductionOperation::ARG_IDX_MIN: { auto temp_vec_res_value = wrapper::vmin(vec_elements, vec_res_value); vec_res_idx = calculate_index(id.x(), temp_vec_res_value, vec_res_value, vec_res_idx, op, 0); vec_res_value = temp_vec_res_value; break; } case ReductionOperation::ARG_IDX_MAX: { auto temp_vec_res_value = wrapper::vmax(vec_elements, vec_res_value); vec_res_idx = calculate_index(id.x(), temp_vec_res_value, vec_res_value, vec_res_idx, op, 0); vec_res_value = temp_vec_res_value; break; } case ReductionOperation::MIN: { vec_res_value = wrapper::vmin(vec_elements, vec_res_value); break; } case ReductionOperation::MAX: { vec_res_value = wrapper::vmax(vec_elements, vec_res_value); break; } default: ARM_COMPUTE_ERROR("Not supported"); } }, input); switch(op) { case ReductionOperation::SUM: case ReductionOperation::SUM_SQUARE: case ReductionOperation::MEAN_SUM: { auto carry_res = wrapper::vpadd(wrapper::vgethigh(vec_res_value), wrapper::vgetlow(vec_res_value)); for(int i = 0; i < S / 4; ++i) { carry_res = wrapper::vpadd(carry_res, carry_res); } auto res = wrapper::vgetlane(carry_res, 0); if(op == ReductionOperation::MEAN_SUM) { res /= in_info.dimension(0); } *(reinterpret_cast(output.ptr())) = res; break; } case ReductionOperation::PROD: { auto carry_res = wrapper::vmul(wrapper::vgethigh(vec_res_value), wrapper::vgetlow(vec_res_value)); T res = 1; for(int i = 0; i < S / 2; ++i) { res *= wrapper::vgetlane(carry_res, i); } *(reinterpret_cast(output.ptr())) = res; break; } case ReductionOperation::ARG_IDX_MIN: case ReductionOperation::ARG_IDX_MAX: { auto res = calculate_vector_index(vec_res_idx, vec_res_value, op); *(reinterpret_cast(output.ptr())) = res; break; } case ReductionOperation::MIN: { *(reinterpret_cast(output.ptr())) = wrapper::vgetlane(calculate_min(vec_res_value), 0); break; } case ReductionOperation::MAX: { *(reinterpret_cast(output.ptr())) = wrapper::vgetlane(calculate_max(vec_res_value), 0); break; } default: ARM_COMPUTE_ERROR("Not supported"); } } }; struct RedOpX_qasymm8 { inline void operator()(Iterator &input, Iterator &output, Window &in_slice, Window &out_slice, const TensorInfo &in_info, const ReductionOperation op) { ARM_COMPUTE_UNUSED(out_slice); const UniformQuantizationInfo iq_info = in_info.quantization_info().uniform(); auto vec_res_value1 = vdupq_n_u32(static_cast(0.f)); auto vec_res_value2 = vdupq_n_u32(static_cast(0.f)); auto vec_res_value3 = vdupq_n_u32(static_cast(0.f)); auto vec_res_value4 = vdupq_n_u32(static_cast(0.f)); auto vec_res_value1_f = vdupq_n_f32(static_cast(1.f)); auto vec_res_value2_f = vdupq_n_f32(static_cast(1.f)); auto vec_res_value3_f = vdupq_n_f32(static_cast(1.f)); auto vec_res_value4_f = vdupq_n_f32(static_cast(1.f)); uint8x16_t vec_res_value = { 0 }; if(op == ReductionOperation::ARG_IDX_MAX || op == ReductionOperation::ARG_IDX_MIN || op == ReductionOperation::MIN || op == ReductionOperation::MAX) { vec_res_value = wrapper::vdup_n(*input.ptr(), wrapper::traits::vector_128_tag{}); } uint32x4x4_t vec_res_idx{ { 0 } }; execute_window_loop(in_slice, [&](const Coordinates & id) { const auto vec_elements = wrapper::vloadq(input.ptr()); switch(op) { case ReductionOperation::SUM: case ReductionOperation::MEAN_SUM: { const auto temp16x8t_1 = wrapper::vmovl(wrapper::vgetlow(vec_elements)); const auto temp16x8t_2 = wrapper::vmovl(wrapper::vgethigh(vec_elements)); const auto temp32x4t_1 = wrapper::vmovl(wrapper::vgetlow(temp16x8t_1)); const auto temp32x4t_2 = wrapper::vmovl(wrapper::vgethigh(temp16x8t_1)); const auto temp32x4t_3 = wrapper::vmovl(wrapper::vgetlow(temp16x8t_2)); const auto temp32x4t_4 = wrapper::vmovl(wrapper::vgethigh(temp16x8t_2)); vec_res_value1 = wrapper::vadd(temp32x4t_1, vec_res_value1); vec_res_value2 = wrapper::vadd(temp32x4t_2, vec_res_value2); vec_res_value3 = wrapper::vadd(temp32x4t_3, vec_res_value3); vec_res_value4 = wrapper::vadd(temp32x4t_4, vec_res_value4); break; } case ReductionOperation::PROD: { const auto offset32x4f_4 = vdupq_n_f32(iq_info.offset); const auto scale32x4f_4 = vdupq_n_f32(iq_info.scale); const auto temp16x8t_1 = vmovl_u8(vget_low_u8(vec_elements)); const auto temp16x8t_2 = vmovl_u8(vget_high_u8(vec_elements)); const auto temp32x4t_1 = vmovl_u16(vget_low_u16(temp16x8t_1)); const auto temp32x4t_2 = vmovl_u16(vget_high_u16(temp16x8t_1)); const auto temp32x4t_3 = vmovl_u16(vget_low_u16(temp16x8t_2)); const auto temp32x4t_4 = vmovl_u16(vget_high_u16(temp16x8t_2)); auto temp32x4f_1 = vcvtq_f32_u32(temp32x4t_1); auto temp32x4f_2 = vcvtq_f32_u32(temp32x4t_2); auto temp32x4f_3 = vcvtq_f32_u32(temp32x4t_3); auto temp32x4f_4 = vcvtq_f32_u32(temp32x4t_4); //de-quantize vec_elements temp32x4f_1 = vmulq_f32(vsubq_f32(temp32x4f_1, offset32x4f_4), scale32x4f_4); temp32x4f_2 = vmulq_f32(vsubq_f32(temp32x4f_2, offset32x4f_4), scale32x4f_4); temp32x4f_3 = vmulq_f32(vsubq_f32(temp32x4f_3, offset32x4f_4), scale32x4f_4); temp32x4f_4 = vmulq_f32(vsubq_f32(temp32x4f_4, offset32x4f_4), scale32x4f_4); vec_res_value1_f = vmulq_f32(temp32x4f_1, vec_res_value1_f); vec_res_value2_f = vmulq_f32(temp32x4f_2, vec_res_value2_f); vec_res_value3_f = vmulq_f32(temp32x4f_3, vec_res_value3_f); vec_res_value4_f = vmulq_f32(temp32x4f_4, vec_res_value4_f); break; } case ReductionOperation::ARG_IDX_MIN: { auto temp_vec_res_value = wrapper::vmin(vec_elements, vec_res_value); vec_res_idx = calculate_index(id.x(), temp_vec_res_value, vec_res_value, vec_res_idx, op, 0); vec_res_value = temp_vec_res_value; break; } case ReductionOperation::ARG_IDX_MAX: { auto temp_vec_res_value = wrapper::vmax(vec_elements, vec_res_value); vec_res_idx = calculate_index(id.x(), temp_vec_res_value, vec_res_value, vec_res_idx, op, 0); vec_res_value = temp_vec_res_value; break; } case ReductionOperation::MIN: { vec_res_value = wrapper::vmin(vec_elements, vec_res_value); break; } case ReductionOperation::MAX: { vec_res_value = wrapper::vmax(vec_elements, vec_res_value); break; } default: ARM_COMPUTE_ERROR("Not supported"); } }, input); switch(op) { case ReductionOperation::ARG_IDX_MIN: case ReductionOperation::ARG_IDX_MAX: { auto res = calculate_vector_index(vec_res_idx, vec_res_value, op); *(reinterpret_cast(output.ptr())) = res; break; } case ReductionOperation::MIN: { *(output.ptr()) = static_cast(wrapper::vgetlane(calculate_min(vec_res_value), 0)); break; } case ReductionOperation::MAX: { *(output.ptr()) = static_cast(wrapper::vgetlane(calculate_max(vec_res_value), 0)); break; } case ReductionOperation::PROD: { auto carry_res = wrapper::vmul(vec_res_value1_f, vec_res_value2_f); carry_res = wrapper::vmul(carry_res, vec_res_value3_f); carry_res = wrapper::vmul(carry_res, vec_res_value4_f); float res = wrapper::vgetlane(carry_res, 0); res *= wrapper::vgetlane(carry_res, 1); res *= wrapper::vgetlane(carry_res, 2); res *= wrapper::vgetlane(carry_res, 3); //re-quantize result res = quantize_qasymm8(res, iq_info); *(output.ptr()) = static_cast(res); break; } default: { auto carry_res = wrapper::vadd(vec_res_value1, vec_res_value2); carry_res = wrapper::vadd(carry_res, vec_res_value3); carry_res = wrapper::vadd(carry_res, vec_res_value4); auto carry_paddition = wrapper::vpadd(wrapper::vgethigh(carry_res), wrapper::vgetlow(carry_res)); carry_paddition = wrapper::vpadd(carry_paddition, carry_paddition); auto res = wrapper::vgetlane(carry_paddition, 0); if(op == ReductionOperation::MEAN_SUM) { res /= in_info.dimension(0); } *(output.ptr()) = static_cast(res); } } } }; template struct RedOpYZW { /** NEON vector tag type. */ using ExactTagType = typename wrapper::traits::neon_vector::tag_type; using neon_vector = typename wrapper::traits::neon_vector::type; inline void operator()(Iterator &input, Iterator &output, Window &in_slice, Window &out_slice, const TensorInfo &in_info, int axis, const ReductionOperation op) { ARM_COMPUTE_UNUSED(out_slice); execute_window_loop(in_slice, [&](const Coordinates &) { neon_vector vec_res_value = { 0 }; switch(op) { case ReductionOperation::ARG_IDX_MAX: case ReductionOperation::ARG_IDX_MIN: case ReductionOperation::MIN: case ReductionOperation::MAX: { vec_res_value = wrapper::vloadq(reinterpret_cast(input.ptr())); break; } case ReductionOperation::PROD: { vec_res_value = wrapper::vdup_n(static_cast(1.f), ExactTagType{}); break; } default: { vec_res_value = wrapper::vdup_n(static_cast(0.f), ExactTagType{}); break; } } uint32x4x4_t vec_res_idx{ { 0 } }; for(unsigned int dim = 0; dim < in_info.dimension(axis); ++dim) { T *in_ptr; switch(axis) { case 1: in_ptr = reinterpret_cast(input.ptr() + in_info.offset_element_in_bytes(Coordinates(0, dim))); break; case 2: in_ptr = reinterpret_cast(input.ptr() + in_info.offset_element_in_bytes(Coordinates(0, 0, dim))); break; case 3: in_ptr = reinterpret_cast(input.ptr() + in_info.offset_element_in_bytes(Coordinates(0, 0, 0, dim))); break; default: ARM_COMPUTE_ERROR("Not supported"); } const auto vec_elements = wrapper::vloadq(in_ptr); switch(op) { case ReductionOperation::SUM: case ReductionOperation::MEAN_SUM: vec_res_value = wrapper::vadd(vec_elements, vec_res_value); break; case ReductionOperation::SUM_SQUARE: vec_res_value = wrapper::vadd(wrapper::vmul(vec_elements, vec_elements), vec_res_value); break; case ReductionOperation::PROD: vec_res_value = wrapper::vmul(vec_elements, vec_res_value); break; case ReductionOperation::ARG_IDX_MIN: { auto temp_vec_res_value = wrapper::vmin(vec_elements, vec_res_value); vec_res_idx = calculate_index(dim, temp_vec_res_value, vec_res_value, vec_res_idx, op, axis); vec_res_value = temp_vec_res_value; break; } case ReductionOperation::ARG_IDX_MAX: { auto temp_vec_res_value = wrapper::vmax(vec_elements, vec_res_value); vec_res_idx = calculate_index(dim, temp_vec_res_value, vec_res_value, vec_res_idx, op, axis); vec_res_value = temp_vec_res_value; break; } case ReductionOperation::MIN: { vec_res_value = wrapper::vmin(vec_elements, vec_res_value); break; } case ReductionOperation::MAX: { vec_res_value = wrapper::vmax(vec_elements, vec_res_value); break; } default: ARM_COMPUTE_ERROR("Not supported"); } } if(op == ReductionOperation::MEAN_SUM) { auto vec_width_inv = wrapper::vinv(wrapper::vdup_n(static_cast(in_info.dimension(axis)), ExactTagType{})); vec_res_value = wrapper::vmul(vec_res_value, vec_width_inv); } if(op == ReductionOperation::ARG_IDX_MIN || op == ReductionOperation::ARG_IDX_MAX) { wrapper::vstore(reinterpret_cast(output.ptr()), vec_res_idx.val[0]); #ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC if(std::is_same::value) { wrapper::vstore(reinterpret_cast(output.ptr()) + 4, vec_res_idx.val[1]); } #endif // __ARM_FEATURE_FP16_VECTOR_ARITHMETIC } else { wrapper::vstore(reinterpret_cast(output.ptr()), vec_res_value); } }, input, output); } }; template struct RedOpYZW_complex { /** NEON vector tag type. */ using ExactTagType = typename wrapper::traits::neon_vector::tag_type; using neon_vector = typename wrapper::traits::neon_vector::type; inline void operator()(Iterator &input, Iterator &output, Window &in_slice, Window &out_slice, const TensorInfo &in_info, int, const ReductionOperation) { ARM_COMPUTE_UNUSED(out_slice); ARM_COMPUTE_ERROR_ON(axis != 2); const size_t stride_z = in_info.strides_in_bytes()[axis]; execute_window_loop(in_slice, [&](const Coordinates &) { neon_vector vec_res_value_0 = { 0 }; neon_vector vec_res_value_1 = { 0 }; vec_res_value_0 = wrapper::vdup_n(static_cast(0.f), ExactTagType{}); vec_res_value_1 = wrapper::vdup_n(static_cast(0.f), ExactTagType{}); for(unsigned int dim = 0; dim < in_info.dimension(axis); ++dim) { T *in_ptr_0; T *in_ptr_1; switch(axis) { case 2: in_ptr_0 = reinterpret_cast(input.ptr() + stride_z * dim); in_ptr_1 = reinterpret_cast(input.ptr() + 16 + stride_z * dim); break; default: ARM_COMPUTE_ERROR("Not supported"); } const auto vec_elements_0 = wrapper::vloadq(in_ptr_0); const auto vec_elements_1 = wrapper::vloadq(in_ptr_1); switch(op) { case ReductionOperation::SUM: vec_res_value_0 = wrapper::vadd(vec_elements_0, vec_res_value_0); vec_res_value_1 = wrapper::vadd(vec_elements_1, vec_res_value_1); break; default: ARM_COMPUTE_ERROR("Not supported"); } } wrapper::vstore(reinterpret_cast(output.ptr()), vec_res_value_0); wrapper::vstore(reinterpret_cast(output.ptr() + 16), vec_res_value_1); }, input, output); } }; struct RedOpYZW_qasymm8 { inline void operator()(Iterator &input, Iterator &output, Window &in_slice, Window &out_slice, const TensorInfo &in_info, int axis, const ReductionOperation op) { ARM_COMPUTE_UNUSED(out_slice); const UniformQuantizationInfo iq_info = in_info.quantization_info().uniform(); execute_window_loop(in_slice, [&](const Coordinates &) { uint32x4x4_t vec_res_idx{ { 0 } }; auto vec_res_value1 = vdupq_n_u32(0); auto vec_res_value2 = vdupq_n_u32(0); auto vec_res_value3 = vdupq_n_u32(0); auto vec_res_value4 = vdupq_n_u32(0); auto vec_res_value1_f = vdupq_n_f32(1); auto vec_res_value2_f = vdupq_n_f32(1); auto vec_res_value3_f = vdupq_n_f32(1); auto vec_res_value4_f = vdupq_n_f32(1); auto vec_res_value = wrapper::vloadq(input.ptr()); for(unsigned int index_dim = 0; index_dim < in_info.dimension(axis); ++index_dim) { uint8_t *in_ptr; switch(axis) { case 1: in_ptr = input.ptr() + in_info.offset_element_in_bytes(Coordinates(0, index_dim)); break; case 2: in_ptr = input.ptr() + in_info.offset_element_in_bytes(Coordinates(0, 0, index_dim)); break; case 3: in_ptr = input.ptr() + in_info.offset_element_in_bytes(Coordinates(0, 0, 0, index_dim)); break; default: ARM_COMPUTE_ERROR("Not supported"); } const auto vec_elements = wrapper::vloadq(in_ptr); switch(op) { case ReductionOperation::SUM: case ReductionOperation::MEAN_SUM: { const auto temp16x8t_1 = wrapper::vmovl(wrapper::vgetlow(vec_elements)); const auto temp16x8t_2 = wrapper::vmovl(wrapper::vgethigh(vec_elements)); const auto temp32x4t_1 = wrapper::vmovl(wrapper::vgetlow(temp16x8t_1)); const auto temp32x4t_2 = wrapper::vmovl(wrapper::vgethigh(temp16x8t_1)); const auto temp32x4t_3 = wrapper::vmovl(wrapper::vgetlow(temp16x8t_2)); const auto temp32x4t_4 = wrapper::vmovl(wrapper::vgethigh(temp16x8t_2)); vec_res_value1 = wrapper::vadd(temp32x4t_1, vec_res_value1); vec_res_value2 = wrapper::vadd(temp32x4t_2, vec_res_value2); vec_res_value3 = wrapper::vadd(temp32x4t_3, vec_res_value3); vec_res_value4 = wrapper::vadd(temp32x4t_4, vec_res_value4); break; } case ReductionOperation::PROD: { const auto offset32x4f_4 = vdupq_n_f32(iq_info.offset); const auto scale32x4f_4 = vdupq_n_f32(iq_info.scale); const auto temp16x8t_1 = vmovl_u8(vget_low_u8(vec_elements)); const auto temp16x8t_2 = vmovl_u8(vget_high_u8(vec_elements)); const auto temp32x4t_1 = vmovl_u16(vget_low_u16(temp16x8t_1)); const auto temp32x4t_2 = vmovl_u16(vget_high_u16(temp16x8t_1)); const auto temp32x4t_3 = vmovl_u16(vget_low_u16(temp16x8t_2)); const auto temp32x4t_4 = vmovl_u16(vget_high_u16(temp16x8t_2)); auto temp32x4f_1 = vcvtq_f32_u32(temp32x4t_1); auto temp32x4f_2 = vcvtq_f32_u32(temp32x4t_2); auto temp32x4f_3 = vcvtq_f32_u32(temp32x4t_3); auto temp32x4f_4 = vcvtq_f32_u32(temp32x4t_4); //de-quantize vec_elements temp32x4f_1 = vmulq_f32(vsubq_f32(temp32x4f_1, offset32x4f_4), scale32x4f_4); temp32x4f_2 = vmulq_f32(vsubq_f32(temp32x4f_2, offset32x4f_4), scale32x4f_4); temp32x4f_3 = vmulq_f32(vsubq_f32(temp32x4f_3, offset32x4f_4), scale32x4f_4); temp32x4f_4 = vmulq_f32(vsubq_f32(temp32x4f_4, offset32x4f_4), scale32x4f_4); vec_res_value1_f = vmulq_f32(temp32x4f_1, vec_res_value1_f); vec_res_value2_f = vmulq_f32(temp32x4f_2, vec_res_value2_f); vec_res_value3_f = vmulq_f32(temp32x4f_3, vec_res_value3_f); vec_res_value4_f = vmulq_f32(temp32x4f_4, vec_res_value4_f); break; } case ReductionOperation::ARG_IDX_MIN: { auto temp_vec_res_value = wrapper::vmin(vec_elements, vec_res_value); vec_res_idx = calculate_index(index_dim, temp_vec_res_value, vec_res_value, vec_res_idx, op, axis); vec_res_value = temp_vec_res_value; break; } case ReductionOperation::ARG_IDX_MAX: { auto temp_vec_res_value = wrapper::vmax(vec_elements, vec_res_value); vec_res_idx = calculate_index(index_dim, temp_vec_res_value, vec_res_value, vec_res_idx, op, axis); vec_res_value = temp_vec_res_value; break; } case ReductionOperation::MIN: { vec_res_value = wrapper::vmin(vec_elements, vec_res_value); break; } case ReductionOperation::MAX: { vec_res_value = wrapper::vmax(vec_elements, vec_res_value); break; } default: ARM_COMPUTE_ERROR("Not supported"); } } if(op == ReductionOperation::MEAN_SUM) { const auto vec_width_inv = wrapper::vinv(vdupq_n_f32(in_info.dimension(axis))); vec_res_value1_f = wrapper::vmul(vcvtq_f32_u32(vec_res_value1), vec_width_inv); vec_res_value2_f = wrapper::vmul(vcvtq_f32_u32(vec_res_value2), vec_width_inv); vec_res_value3_f = wrapper::vmul(vcvtq_f32_u32(vec_res_value3), vec_width_inv); vec_res_value4_f = wrapper::vmul(vcvtq_f32_u32(vec_res_value4), vec_width_inv); vec_res_value1 = vcvtq_u32_f32(vec_res_value1_f); vec_res_value2 = vcvtq_u32_f32(vec_res_value2_f); vec_res_value3 = vcvtq_u32_f32(vec_res_value3_f); vec_res_value4 = vcvtq_u32_f32(vec_res_value4_f); } else if(op == ReductionOperation::PROD) { const auto offset32x4f_4 = vdupq_n_f32(iq_info.offset); const auto iscale32x4f_4 = vinvq_f32(vdupq_n_f32(iq_info.scale)); //re-quantize vec_res_value1_f = vaddq_f32(vmulq_f32(vec_res_value1_f, iscale32x4f_4), offset32x4f_4); vec_res_value2_f = vaddq_f32(vmulq_f32(vec_res_value2_f, iscale32x4f_4), offset32x4f_4); vec_res_value3_f = vaddq_f32(vmulq_f32(vec_res_value3_f, iscale32x4f_4), offset32x4f_4); vec_res_value4_f = vaddq_f32(vmulq_f32(vec_res_value4_f, iscale32x4f_4), offset32x4f_4); vec_res_value1 = vcvtq_u32_f32(vec_res_value1_f); vec_res_value2 = vcvtq_u32_f32(vec_res_value2_f); vec_res_value3 = vcvtq_u32_f32(vec_res_value3_f); vec_res_value4 = vcvtq_u32_f32(vec_res_value4_f); } if(op == ReductionOperation::ARG_IDX_MIN || op == ReductionOperation::ARG_IDX_MAX) { wrapper::vstore(reinterpret_cast(output.ptr()), vec_res_idx.val[0]); wrapper::vstore(reinterpret_cast(output.ptr()) + 4, vec_res_idx.val[1]); wrapper::vstore(reinterpret_cast(output.ptr()) + 8, vec_res_idx.val[2]); wrapper::vstore(reinterpret_cast(output.ptr()) + 12, vec_res_idx.val[3]); } else if(op == ReductionOperation::ARG_IDX_MIN) { wrapper::vstore(output.ptr(), vec_res_value); } else { const auto temp16x8t_1 = vcombine_u16(wrapper::vqmovn(vec_res_value1), wrapper::vqmovn(vec_res_value2)); const auto temp16x8t_2 = vcombine_u16(wrapper::vqmovn(vec_res_value3), wrapper::vqmovn(vec_res_value4)); auto res = vcombine_u8(wrapper::vqmovn(temp16x8t_1), wrapper::vqmovn(temp16x8t_2)); wrapper::vstore(output.ptr(), res); } }, input, output); } }; void reduce_op(const Window &window, const ITensor *input, ITensor *output, unsigned int axis, const ReductionOperation op) { const bool is_complex = (input->info()->num_channels() == 2); if(is_complex) { switch(axis) { case 2: switch(input->info()->data_type()) { case DataType::F32: switch(op) { case ReductionOperation::SUM: return Reducer>::reduceZ(window, input, output, RedOpYZW_complex(), op); default: ARM_COMPUTE_ERROR("Not supported"); } default: ARM_COMPUTE_ERROR("Not supported"); } default: ARM_COMPUTE_ERROR("Not supported"); } } switch(axis) { case 0: switch(input->info()->data_type()) { case DataType::QASYMM8: return Reducer::reduceX(window, input, output, RedOpX_qasymm8(), op); #ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC case DataType::F16: return Reducer>::reduceX(window, input, output, RedOpX(), op); #endif // __ARM_FEATURE_FP16_VECTOR_ARITHMETIC case DataType::F32: return Reducer>::reduceX(window, input, output, RedOpX(), op); case DataType::S32: return Reducer>::reduceX(window, input, output, RedOpX(), op); default: ARM_COMPUTE_ERROR("Not supported"); } case 1: switch(input->info()->data_type()) { case DataType::QASYMM8: return Reducer::reduceY(window, input, output, RedOpYZW_qasymm8(), op); #ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC case DataType::F16: return Reducer>::reduceY(window, input, output, RedOpYZW(), op); #endif // __ARM_FEATURE_FP16_VECTOR_ARITHMETIC case DataType::F32: return Reducer>::reduceY(window, input, output, RedOpYZW(), op); case DataType::S32: return Reducer>::reduceY(window, input, output, RedOpYZW(), op); default: ARM_COMPUTE_ERROR("Not supported"); } case 2: switch(input->info()->data_type()) { case DataType::QASYMM8: return Reducer::reduceZ(window, input, output, RedOpYZW_qasymm8(), op); #ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC case DataType::F16: return Reducer>::reduceZ(window, input, output, RedOpYZW(), op); #endif // __ARM_FEATURE_FP16_VECTOR_ARITHMETIC case DataType::F32: return Reducer>::reduceZ(window, input, output, RedOpYZW(), op); case DataType::S32: return Reducer>::reduceZ(window, input, output, RedOpYZW(), op); default: ARM_COMPUTE_ERROR("Not supported"); } case 3: switch(input->info()->data_type()) { case DataType::QASYMM8: return Reducer::reduceW(window, input, output, RedOpYZW_qasymm8(), op); #ifdef __ARM_FEATURE_FP16_VECTOR_ARITHMETIC case DataType::F16: return Reducer>::reduceW(window, input, output, RedOpYZW(), op); #endif // __ARM_FEATURE_FP16_VECTOR_ARITHMETIC case DataType::F32: return Reducer>::reduceW(window, input, output, RedOpYZW(), op); case DataType::S32: return Reducer>::reduceW(window, input, output, RedOpYZW(), op); default: ARM_COMPUTE_ERROR("Not supported"); } default: ARM_COMPUTE_ERROR("Unsupported reduction axis"); } } Status validate_arguments(const ITensorInfo *input, const ITensorInfo *output, unsigned int axis, ReductionOperation op) { ARM_COMPUTE_UNUSED(op); ARM_COMPUTE_RETURN_ERROR_ON_NULLPTR(input, output); ARM_COMPUTE_RETURN_ERROR_ON_CPU_F16_UNSUPPORTED(input); if(input->num_channels() == 1) { ARM_COMPUTE_RETURN_ERROR_ON_DATA_TYPE_CHANNEL_NOT_IN(input, 1, DataType::QASYMM8, DataType::S32, DataType::F16, DataType::F32); } else { ARM_COMPUTE_RETURN_ERROR_ON_DATA_TYPE_CHANNEL_NOT_IN(input, 2, DataType::F32); ARM_COMPUTE_RETURN_ERROR_ON(op != ReductionOperation::SUM); ARM_COMPUTE_RETURN_ERROR_ON(axis != 2); } ARM_COMPUTE_RETURN_ERROR_ON_MSG(axis >= TensorShape::num_max_dimensions, "Reduction axis greater than max number of dimensions"); ARM_COMPUTE_RETURN_ERROR_ON_MSG(axis > 3, "Unsupported reduction axis"); if(output->total_size() != 0) { bool is_arg_min_max = (op == ReductionOperation::ARG_IDX_MAX || op == ReductionOperation::ARG_IDX_MIN); if(!is_arg_min_max) { ARM_COMPUTE_RETURN_ERROR_ON_MISMATCHING_DATA_TYPES(input, output); ARM_COMPUTE_RETURN_ERROR_ON_MISMATCHING_QUANTIZATION_INFO(input, output); ARM_COMPUTE_RETURN_ERROR_ON(input->num_channels() != output->num_channels()); } else { ARM_COMPUTE_RETURN_ERROR_ON_DATA_TYPE_CHANNEL_NOT_IN(output, 1, DataType::U32); } const TensorShape output_shape = arm_compute::misc::shape_calculator::compute_reduced_shape(input->tensor_shape(), axis); const TensorInfo tensor_info_reshaped = input->clone()->set_tensor_shape(output_shape); ARM_COMPUTE_RETURN_ERROR_ON_MISMATCHING_SHAPES(output, &tensor_info_reshaped); } return Status{}; } std::tuple validate_and_configure_window(ITensorInfo *input, ITensorInfo *output, unsigned int axis, ReductionOperation op) { // Calculate output shape and set if empty const TensorShape output_shape = arm_compute::misc::shape_calculator::compute_reduced_shape(input->tensor_shape(), axis); // Output auto initialization if not yet initialized const bool is_arg_min_max = (op == ReductionOperation::ARG_IDX_MIN || op == ReductionOperation::ARG_IDX_MAX); DataType output_data_type = is_arg_min_max ? DataType::U32 : input->data_type(); auto_init_if_empty(*output, input->clone()->set_tensor_shape(output_shape).set_data_type(output_data_type).reset_padding().set_is_resizable(true)); unsigned int num_elems_processed_per_iteration = 16 / data_size_from_type(input->data_type()); // Configure kernel window Window win = calculate_max_window(*input, Steps(num_elems_processed_per_iteration)); AccessWindowHorizontal input_access(input, 0, num_elems_processed_per_iteration); AccessWindowHorizontal output_access(output, 0, num_elems_processed_per_iteration); bool window_changed = update_window_and_padding(win, input_access, output_access); output_access.set_valid_region(win, ValidRegion(Coordinates(), output->tensor_shape())); Status err = (window_changed) ? ARM_COMPUTE_CREATE_ERROR(ErrorCode::RUNTIME_ERROR, "Insufficient Padding!") : Status{}; return std::make_tuple(err, win); } } // namespace NEReductionOperationKernel::NEReductionOperationKernel() : _input(nullptr), _output(nullptr), _reduction_axis(0), _op(ReductionOperation::SUM_SQUARE), _border_size() { } BorderSize NEReductionOperationKernel::border_size() const { return _border_size; } void NEReductionOperationKernel::configure(const ITensor *input, ITensor *output, unsigned int axis, ReductionOperation op) { ARM_COMPUTE_ERROR_ON_NULLPTR(input, output); ARM_COMPUTE_ERROR_THROW_ON(validate_arguments(input->info(), output->info(), axis, op)); unsigned int num_elems_processed_per_iteration = 16 / data_size_from_type(input->info()->data_type()); _input = input; _output = output; _border_size = (axis == 0) ? BorderSize(0, num_elems_processed_per_iteration - (input->info()->dimension(0) % num_elems_processed_per_iteration), 0, 0) : BorderSize(); _op = op; _reduction_axis = axis; // Configure kernel window auto win_config = validate_and_configure_window(_input->info(), _output->info(), axis, op); ARM_COMPUTE_ERROR_THROW_ON(std::get<0>(win_config)); INEKernel::configure(std::get<1>(win_config)); } Status NEReductionOperationKernel::validate(const ITensorInfo *input, const ITensorInfo *output, unsigned int axis, ReductionOperation op) { ARM_COMPUTE_RETURN_ON_ERROR(validate_arguments(input, output, axis, op)); ARM_COMPUTE_RETURN_ON_ERROR(std::get<0>(validate_and_configure_window(input->clone().get(), output->clone().get(), axis, op))); return Status{}; } void NEReductionOperationKernel::run(const Window &window, const ThreadInfo &info) { ARM_COMPUTE_UNUSED(info); ARM_COMPUTE_ERROR_ON_UNCONFIGURED_KERNEL(this); ARM_COMPUTE_ERROR_ON_INVALID_SUBWINDOW(INEKernel::window(), window); reduce_op(window, _input, _output, _reduction_axis, _op); } } // namespace arm_compute