// Copyright (c) Facebook, Inc. and its affiliates. // All rights reserved. // // 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. #pragma once #include #include #include #include #include #include #include #include #include #include #include #include class MaxPoolMicrokernelTester { public: inline MaxPoolMicrokernelTester& output_pixels(size_t output_pixels) { assert(output_pixels != 0); this->output_pixels_ = output_pixels; return *this; } inline size_t output_pixels() const { return this->output_pixels_; } inline MaxPoolMicrokernelTester& step(size_t step) { assert(step != 0); this->step_ = step; return *this; } inline size_t step() const { return this->step_; } inline MaxPoolMicrokernelTester& input_offset(size_t input_offset) { assert(input_offset != 0); this->input_offset_ = input_offset; return *this; } inline size_t input_offset() const { return this->input_offset_; } inline MaxPoolMicrokernelTester& pooling_elements(size_t pooling_elements) { assert(pooling_elements != 0); this->pooling_elements_ = pooling_elements; return *this; } inline size_t pooling_elements() const { return this->pooling_elements_; } inline size_t packed_pooling_elements() const { if (pooling_elements() <= primary_pooling_tile()) { return primary_pooling_tile(); } else { return (pooling_elements() - primary_pooling_tile()) % incremental_pooling_tile() == 0 ? pooling_elements() : ((pooling_elements() - primary_pooling_tile()) / incremental_pooling_tile() + 1) * incremental_pooling_tile() + primary_pooling_tile(); } } inline MaxPoolMicrokernelTester& pooling_tile(size_t primary_tile, size_t incremental_tile) { assert(primary_tile != 0); this->primary_pooling_tile_ = primary_tile; this->incremental_pooling_tile_ = incremental_tile; return *this; } inline MaxPoolMicrokernelTester& primary_pooling_tile(size_t primary_pooling_tile) { assert(primary_pooling_tile != 0); this->primary_pooling_tile_ = primary_pooling_tile; return *this; } inline size_t primary_pooling_tile() const { return this->primary_pooling_tile_; } inline MaxPoolMicrokernelTester& incremental_pooling_tile(size_t incremental_pooling_tile) { assert(incremental_pooling_tile != 0); this->incremental_pooling_tile_ = incremental_pooling_tile; return *this; } inline size_t incremental_pooling_tile() const { return this->incremental_pooling_tile_; } inline MaxPoolMicrokernelTester& channels(size_t channels) { assert(channels != 0); this->channels_ = channels; return *this; } inline size_t channels() const { return this->channels_; } inline MaxPoolMicrokernelTester& output_stride(size_t output_stride) { assert(output_stride != 0); this->output_stride_ = output_stride; return *this; } inline size_t output_stride() const { if (this->output_stride_ == 0) { return channels(); } else { assert(this->output_stride_ >= channels()); return this->output_stride_; } } inline MaxPoolMicrokernelTester& qmin(int16_t qmin) { this->qmin_ = qmin; return *this; } inline int16_t qmin() const { return this->qmin_; } inline MaxPoolMicrokernelTester& qmax(int16_t qmax) { this->qmax_ = qmax; return *this; } inline int16_t qmax() const { return this->qmax_; } inline MaxPoolMicrokernelTester& iterations(size_t iterations) { this->iterations_ = iterations; return *this; } inline size_t iterations() const { return this->iterations_; } void Test(xnn_s8_maxpool_ukernel_function maxpool, xnn_init_s8_minmax_params_fn init_params) const { ASSERT_GE(qmin(), std::numeric_limits::min()); ASSERT_LE(qmax(), std::numeric_limits::max()); ASSERT_LT(qmin(), qmax()); std::random_device random_device; auto rng = std::mt19937(random_device()); std::uniform_int_distribution i8dist( std::numeric_limits::min(), std::numeric_limits::max()); std::vector indirect_input((output_pixels() - 1) * step() + packed_pooling_elements()); std::vector input(XNN_EXTRA_BYTES / sizeof(int8_t) + indirect_input.size() * channels()); std::vector output(XNN_EXTRA_BYTES / sizeof(int8_t) + (output_pixels() - 1) * output_stride() + channels()); std::vector output_ref(output_pixels() * channels()); for (size_t iteration = 0; iteration < iterations(); iteration++) { do { std::generate(input.begin(), input.end(), [&]() { return i8dist(rng); }); } while (input.size() > 1 && *std::max_element(input.cbegin(), input.cend()) == *std::min_element(input.cbegin(), input.cend())); std::fill(output.begin(), output.end(), INT8_C(0xA5)); for (size_t i = 0; i < (output_pixels() - 1) * step() + pooling_elements(); i++) { indirect_input[i] = input.data() + i * channels() - input_offset(); } std::shuffle(indirect_input.begin(), indirect_input.begin() + (output_pixels() - 1) * step() + pooling_elements(), rng); // Prepare parameters. xnn_s8_minmax_params params; init_params(¶ms, static_cast(qmin()), static_cast(qmax())); // Compute reference results. for (size_t x = 0; x < output_pixels(); x++) { for (size_t c = 0; c < channels(); c++) { int8_t max_value = std::numeric_limits::min(); for (size_t p = 0; p < pooling_elements(); p++) { max_value = std::max(max_value, indirect_input[x * step() + p][c + input_offset()]); } max_value = std::min(max_value, static_cast(qmax())); max_value = std::max(max_value, static_cast(qmin())); output_ref[x * channels() + c] = max_value; } } // Call optimized micro-kernel. maxpool(output_pixels(), pooling_elements(), channels(), indirect_input.data(), input_offset() * sizeof(int8_t), output.data(), (step() - packed_pooling_elements()) * sizeof(void*), (output_stride() - channels()) * sizeof(int8_t), ¶ms); // Verify results. for (size_t x = 0; x < output_pixels(); x++) { for (size_t c = 0; c < channels(); c++) { ASSERT_GE(int16_t(output[x * output_stride() + c]), qmin()) << "at pixel " << x << " / " << output_pixels() << ", channel " << c << " / " << channels() << ", pooling elements = " << pooling_elements() << ", step = " << step() << ", input offset = " << input_offset(); ASSERT_LE(int16_t(output[x * output_stride() + c]), qmax()) << "at pixel " << x << " / " << output_pixels() << ", channel " << c << " / " << channels() << ", pooling elements = " << pooling_elements() << ", step = " << step() << ", input offset = " << input_offset(); ASSERT_EQ(int32_t(output_ref[x * channels() + c]), int32_t(output[x * output_stride() + c])) << "at pixel " << x << " / " << output_pixels() << ", channel " << c << " / " << channels() << ", pooling elements = " << pooling_elements() << ", step = " << step() << ", input offset = " << input_offset(); } } } } void Test(xnn_u8_maxpool_ukernel_function maxpool, xnn_init_u8_minmax_params_fn init_params) const { ASSERT_GE(qmin(), std::numeric_limits::min()); ASSERT_LE(qmax(), std::numeric_limits::max()); ASSERT_LT(qmin(), qmax()); std::random_device random_device; auto rng = std::mt19937(random_device()); std::uniform_int_distribution u8dist( std::numeric_limits::min(), std::numeric_limits::max()); std::vector indirect_input((output_pixels() - 1) * step() + packed_pooling_elements()); std::vector input(XNN_EXTRA_BYTES / sizeof(uint8_t) + indirect_input.size() * channels()); std::vector output(XNN_EXTRA_BYTES / sizeof(uint8_t) + (output_pixels() - 1) * output_stride() + channels()); std::vector output_ref(output_pixels() * channels()); for (size_t iteration = 0; iteration < iterations(); iteration++) { do { std::generate(input.begin(), input.end(), [&]() { return u8dist(rng); }); } while (input.size() > 1 && *std::max_element(input.cbegin(), input.cend()) == *std::min_element(input.cbegin(), input.cend())); std::fill(output.begin(), output.end(), UINT8_C(0xA5)); for (size_t i = 0; i < (output_pixels() - 1) * step() + pooling_elements(); i++) { indirect_input[i] = input.data() + i * channels() - input_offset(); } std::shuffle(indirect_input.begin(), indirect_input.begin() + (output_pixels() - 1) * step() + pooling_elements(), rng); // Prepare parameters. xnn_u8_minmax_params params; init_params(¶ms, static_cast(qmin()), static_cast(qmax())); // Compute reference results. for (size_t x = 0; x < output_pixels(); x++) { for (size_t c = 0; c < channels(); c++) { uint8_t max_value = 0; for (size_t p = 0; p < pooling_elements(); p++) { max_value = std::max(max_value, indirect_input[x * step() + p][c + input_offset()]); } max_value = std::min(max_value, static_cast(qmax())); max_value = std::max(max_value, static_cast(qmin())); output_ref[x * channels() + c] = max_value; } } // Call optimized micro-kernel. maxpool(output_pixels(), pooling_elements(), channels(), indirect_input.data(), input_offset() * sizeof(uint8_t), output.data(), (step() - packed_pooling_elements()) * sizeof(void*), (output_stride() - channels()) * sizeof(uint8_t), ¶ms); // Verify results. for (size_t x = 0; x < output_pixels(); x++) { for (size_t c = 0; c < channels(); c++) { ASSERT_GE(int16_t(output[x * output_stride() + c]), qmin()) << "at pixel " << x << " / " << output_pixels() << ", channel " << c << " / " << channels() << ", pooling elements = " << pooling_elements() << ", step = " << step() << ", input offset = " << input_offset(); ASSERT_LE(int16_t(output[x * output_stride() + c]), qmax()) << "at pixel " << x << " / " << output_pixels() << ", channel " << c << " / " << channels() << ", pooling elements = " << pooling_elements() << ", step = " << step() << ", input offset = " << input_offset(); ASSERT_EQ(int32_t(output_ref[x * channels() + c]), int32_t(output[x * output_stride() + c])) << "at pixel " << x << " / " << output_pixels() << ", channel " << c << " / " << channels() << ", pooling elements = " << pooling_elements() << ", step = " << step() << ", input offset = " << input_offset(); } } } } void Test(xnn_f16_maxpool_ukernel_function maxpool, xnn_init_f16_minmax_params_fn init_params) const { ASSERT_LT(qmin(), qmax()); std::random_device random_device; auto rng = std::mt19937(random_device()); std::uniform_real_distribution f32dist(-1.0f, 1.0f); std::vector indirect_input((output_pixels() - 1) * step() + packed_pooling_elements()); std::vector input(XNN_EXTRA_BYTES / sizeof(uint16_t) + ((output_pixels() - 1) * step() + pooling_elements()) * channels()); std::vector output(XNN_EXTRA_BYTES / sizeof(uint16_t) + (output_pixels() - 1) * output_stride() + channels()); std::vector output_ref(output_pixels() * channels()); for (size_t iteration = 0; iteration < iterations(); iteration++) { std::generate(input.begin(), input.end(), [&]() { return fp16_ieee_from_fp32_value(f32dist(rng)); }); std::fill(output.begin(), output.end(), UINT16_C(0x7E00) /* NaN */); for (size_t i = 0; i < (output_pixels() - 1) * step() + pooling_elements(); i++) { indirect_input[i] = input.data() + i * channels() - input_offset(); } std::shuffle(indirect_input.begin(), indirect_input.begin() + (output_pixels() - 1) * step() + pooling_elements(), rng); // Compute reference results, without clamping. for (size_t x = 0; x < output_pixels(); x++) { for (size_t c = 0; c < channels(); c++) { float max_value = -std::numeric_limits::infinity(); for (size_t p = 0; p < pooling_elements(); p++) { max_value = std::max(max_value, fp16_ieee_to_fp32_value(indirect_input[x * step() + p][c + input_offset()])); } output_ref[x * channels() + c] = max_value; } } // Compute clamping parameters. const float accumulated_min = *std::min_element(output_ref.cbegin(), output_ref.cend()); const float accumulated_max = *std::max_element(output_ref.cbegin(), output_ref.cend()); const float accumulated_range = accumulated_max - accumulated_min; float output_min = accumulated_min + accumulated_range * (static_cast(qmin() - std::numeric_limits::min()) / static_cast(std::numeric_limits::max() - std::numeric_limits::min())); if (qmin() == std::numeric_limits::min()) { output_min = -std::numeric_limits::infinity(); } float output_max = accumulated_max - accumulated_range * (static_cast(std::numeric_limits::max() - qmax()) / static_cast(std::numeric_limits::max() - std::numeric_limits::min())); if (qmax() == std::numeric_limits::max()) { output_max = +std::numeric_limits::infinity(); } output_min = fp16_ieee_to_fp32_value(fp16_ieee_from_fp32_value(output_min)); output_max = fp16_ieee_to_fp32_value(fp16_ieee_from_fp32_value(output_max)); // Prepare parameters. xnn_f16_minmax_params params; init_params(¶ms, fp16_ieee_from_fp32_value(output_min), fp16_ieee_from_fp32_value(output_max)); // Clamp reference results. for (float& output_value : output_ref) { output_value = std::max(std::min(output_value, output_max), output_min); } // Call optimized micro-kernel. maxpool(output_pixels(), pooling_elements(), channels(), reinterpret_cast(indirect_input.data()), input_offset() * sizeof(uint16_t), output.data(), (step() - packed_pooling_elements()) * sizeof(void*), (output_stride() - channels()) * sizeof(uint16_t), ¶ms); // Verify results. for (size_t x = 0; x < output_pixels(); x++) { for (size_t c = 0; c < channels(); c++) { ASSERT_GE(fp16_ieee_to_fp32_value(output[x * output_stride() + c]), output_min) << "at pixel " << x << " / " << output_pixels() << ", channel " << c << " / " << channels() << ", pooling elements = " << pooling_elements() << ", step = " << step() << ", input offset = " << input_offset(); ASSERT_LE(fp16_ieee_to_fp32_value(output[x * output_stride() + c]), output_max) << "at pixel " << x << " / " << output_pixels() << ", channel " << c << " / " << channels() << ", pooling elements = " << pooling_elements() << ", step = " << step() << ", input offset = " << input_offset(); ASSERT_EQ(fp16_ieee_to_fp32_value(output[x * output_stride() + c]), output_ref[x * channels() + c]) << "at pixel " << x << " / " << output_pixels() << ", channel " << c << " / " << channels() << ", pooling elements = " << pooling_elements() << ", step = " << step() << ", input offset = " << input_offset(); } } } } void Test(xnn_f32_maxpool_ukernel_function maxpool, xnn_init_f32_minmax_params_fn init_params) const { ASSERT_LT(qmin(), qmax()); std::random_device random_device; auto rng = std::mt19937(random_device()); std::uniform_real_distribution f32dist(-1.0f, 1.0f); std::vector indirect_input((output_pixels() - 1) * step() + packed_pooling_elements()); std::vector input(XNN_EXTRA_BYTES / sizeof(float) + ((output_pixels() - 1) * step() + pooling_elements()) * channels()); std::vector output(XNN_EXTRA_BYTES / sizeof(float) + (output_pixels() - 1) * output_stride() + channels()); std::vector output_ref(output_pixels() * channels()); for (size_t iteration = 0; iteration < iterations(); iteration++) { std::generate(input.begin(), input.end(), [&]() { return f32dist(rng); }); std::fill(output.begin(), output.end(), nanf("")); for (size_t i = 0; i < (output_pixels() - 1) * step() + pooling_elements(); i++) { indirect_input[i] = input.data() + i * channels() - input_offset(); } std::shuffle(indirect_input.begin(), indirect_input.begin() + (output_pixels() - 1) * step() + pooling_elements(), rng); // Compute reference results, without clamping. for (size_t x = 0; x < output_pixels(); x++) { for (size_t c = 0; c < channels(); c++) { float max_value = -std::numeric_limits::infinity(); for (size_t p = 0; p < pooling_elements(); p++) { max_value = std::max(max_value, indirect_input[x * step() + p][c + input_offset()]); } output_ref[x * channels() + c] = max_value; } } // Compute clamping parameters. const float accumulated_min = *std::min_element(output_ref.cbegin(), output_ref.cend()); const float accumulated_max = *std::max_element(output_ref.cbegin(), output_ref.cend()); const float accumulated_range = accumulated_max - accumulated_min; float output_min = accumulated_min + accumulated_range * (static_cast(qmin() - std::numeric_limits::min()) / static_cast(std::numeric_limits::max() - std::numeric_limits::min())); if (qmin() == std::numeric_limits::min()) { output_min = -std::numeric_limits::infinity(); } float output_max = accumulated_max - accumulated_range * (static_cast(std::numeric_limits::max() - qmax()) / static_cast(std::numeric_limits::max() - std::numeric_limits::min())); if (qmax() == std::numeric_limits::max()) { output_max = +std::numeric_limits::infinity(); } // Prepare parameters. xnn_f32_minmax_params params; init_params(¶ms, output_min, output_max); // Clamp reference results. for (float& output_value : output_ref) { output_value = std::max(std::min(output_value, output_max), output_min); } // Call optimized micro-kernel. maxpool(output_pixels(), pooling_elements(), channels(), indirect_input.data(), input_offset() * sizeof(float), output.data(), (step() - packed_pooling_elements()) * sizeof(void*), (output_stride() - channels()) * sizeof(float), ¶ms); // Verify results. for (size_t x = 0; x < output_pixels(); x++) { for (size_t c = 0; c < channels(); c++) { ASSERT_GE(output[x * output_stride() + c], output_min) << "at pixel " << x << " / " << output_pixels() << ", channel " << c << " / " << channels() << ", pooling elements = " << pooling_elements() << ", step = " << step() << ", input offset = " << input_offset(); ASSERT_LE(output[x * output_stride() + c], output_max) << "at pixel " << x << " / " << output_pixels() << ", channel " << c << " / " << channels() << ", pooling elements = " << pooling_elements() << ", step = " << step() << ", input offset = " << input_offset(); ASSERT_EQ(output_ref[x * channels() + c], output[x * output_stride() + c]) << "at pixel " << x << " / " << output_pixels() << ", channel " << c << " / " << channels() << ", pooling elements = " << pooling_elements() << ", step = " << step() << ", input offset = " << input_offset(); } } } } private: size_t output_pixels_{1}; size_t pooling_elements_{1}; size_t channels_{1}; size_t input_offset_{0}; size_t step_{1}; size_t primary_pooling_tile_{1}; size_t incremental_pooling_tile_{1}; size_t output_stride_{0}; int16_t qmin_{std::numeric_limits::min()}; int16_t qmax_{std::numeric_limits::max()}; size_t iterations_{3}; };