test/vbinaryc-microkernel-tester.h - platform/external/XNNPACK - Gitiles

 // 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 <gtest/gtest.h>

 #include <algorithm>
 #include <cassert>
 #include <cstddef>
 #include <cstdlib>
 #include <functional>
 #include <random>
 #include <vector>

 #include <fp16.h>

 #include <xnnpack.h>
 #include <xnnpack/params-init.h>
 #include <xnnpack/params.h>


 class VBinaryCMicrokernelTester {
  public:
   enum class OpType {
     AddC,
     DivC,
     RDivC,
     MaxC,
     MinC,
     MulC,
     SqrDiffC,
     SubC,
     RSubC,
   };

   inline VBinaryCMicrokernelTester& batch_size(size_t batch_size) {
     assert(batch_size != 0);
     this->batch_size_ = batch_size;
     return *this;
   }

   inline size_t batch_size() const {
     return this->batch_size_;
   }

   inline VBinaryCMicrokernelTester& inplace(bool inplace) {
     this->inplace_ = inplace;
     return *this;
   }

   inline bool inplace() const {
     return this->inplace_;
   }

   inline VBinaryCMicrokernelTester& qmin(uint8_t qmin) {
     this->qmin_ = qmin;
     return *this;
   }

   inline uint8_t qmin() const {
     return this->qmin_;
   }

   inline VBinaryCMicrokernelTester& qmax(uint8_t qmax) {
     this->qmax_ = qmax;
     return *this;
   }

   inline uint8_t qmax() const {
     return this->qmax_;
   }

   inline VBinaryCMicrokernelTester& iterations(size_t iterations) {
     this->iterations_ = iterations;
     return *this;
   }

   inline size_t iterations() const {
     return this->iterations_;
   }

   void Test(xnn_f16_vbinary_ukernel_function vbinaryc, OpType op_type) const {
     std::random_device random_device;
     auto rng = std::mt19937(random_device());
     auto f32rng = std::bind(std::uniform_real_distribution<float>(0.01f, 1.0f), rng);
     auto f16rng = std::bind(fp16_ieee_from_fp32_value, f32rng);

     std::vector<uint16_t> a(batch_size() + XNN_EXTRA_BYTES / sizeof(uint16_t));
     const uint16_t b = f16rng();
     std::vector<uint16_t> y(batch_size() + (inplace() ? XNN_EXTRA_BYTES / sizeof(uint16_t) : 0));
     std::vector<float> y_ref(batch_size());
     for (size_t iteration = 0; iteration < iterations(); iteration++) {
       std::generate(a.begin(), a.end(), std::ref(f16rng));
       if (inplace()) {
         std::generate(y.begin(), y.end(), std::ref(f16rng));
       } else {
         std::fill(y.begin(), y.end(), UINT16_C(0x7E00) /* NaN */);
       }
       const uint16_t* a_data = inplace() ? y.data() : a.data();

       // Compute reference results.
       for (size_t i = 0; i < batch_size(); i++) {
         switch (op_type) {
           case OpType::AddC:
             y_ref[i] = fp16_ieee_to_fp32_value(a_data[i]) + fp16_ieee_to_fp32_value(b);
             break;
           case OpType::DivC:
             y_ref[i] = fp16_ieee_to_fp32_value(a_data[i]) / fp16_ieee_to_fp32_value(b);
             break;
           case OpType::RDivC:
             y_ref[i] = fp16_ieee_to_fp32_value(b) / fp16_ieee_to_fp32_value(a_data[i]);
             break;
           case OpType::MaxC:
             y_ref[i] = std::max<float>(fp16_ieee_to_fp32_value(a_data[i]), fp16_ieee_to_fp32_value(b));
             break;
           case OpType::MinC:
             y_ref[i] = std::min<float>(fp16_ieee_to_fp32_value(a_data[i]), fp16_ieee_to_fp32_value(b));
             break;
           case OpType::MulC:
             y_ref[i] = fp16_ieee_to_fp32_value(a_data[i]) * fp16_ieee_to_fp32_value(b);
             break;
           case OpType::SqrDiffC:
           {
             const float diff = fp16_ieee_to_fp32_value(a_data[i]) - fp16_ieee_to_fp32_value(b);
             y_ref[i] = diff * diff;
             break;
           }
           case OpType::SubC:
             y_ref[i] = fp16_ieee_to_fp32_value(a_data[i]) - fp16_ieee_to_fp32_value(b);
             break;
           case OpType::RSubC:
             y_ref[i] = fp16_ieee_to_fp32_value(b) - fp16_ieee_to_fp32_value(a_data[i]);
             break;
         }
       }
       // Call optimized micro-kernel.
       vbinaryc(batch_size() * sizeof(uint16_t), a_data, &b, y.data(), nullptr);

       // Verify results.
       for (size_t i = 0; i < batch_size(); i++) {
         ASSERT_NEAR(fp16_ieee_to_fp32_value(y[i]), y_ref[i], std::max(1.0e-4f, std::abs(y_ref[i]) * 1.0e-2f))
           << "at " << i << " / " << batch_size();
       }
     }
   }

   void Test(xnn_f16_vbinary_minmax_ukernel_function vbinaryc_minmax, OpType op_type, xnn_init_f16_minmax_params_fn init_params) const {
     std::random_device random_device;
     auto rng = std::mt19937(random_device());
     auto f32rng = std::bind(std::uniform_real_distribution<float>(1.0e-3f, 1.0f), rng);
     auto f16rng = std::bind(fp16_ieee_from_fp32_value, f32rng);

     std::vector<uint16_t> a(batch_size() + XNN_EXTRA_BYTES / sizeof(uint16_t));
     const uint16_t b = f16rng();
     std::vector<uint16_t> y(batch_size() + (inplace() ? XNN_EXTRA_BYTES / sizeof(uint16_t) : 0));
     std::vector<float> y_ref(batch_size());
     for (size_t iteration = 0; iteration < iterations(); iteration++) {
       std::generate(a.begin(), a.end(), std::ref(f16rng));
       if (inplace()) {
         std::generate(y.begin(), y.end(), std::ref(f16rng));
       } else {
         std::fill(y.begin(), y.end(), UINT16_C(0x7E00) /* NaN */);
       }
       const uint16_t* a_data = inplace() ? y.data() : a.data();

       // Compute reference results.
       for (size_t i = 0; i < batch_size(); i++) {
         switch (op_type) {
           case OpType::AddC:
             y_ref[i] = fp16_ieee_to_fp32_value(a_data[i]) + fp16_ieee_to_fp32_value(b);
             break;
           case OpType::DivC:
             y_ref[i] = fp16_ieee_to_fp32_value(a_data[i]) / fp16_ieee_to_fp32_value(b);
             break;
           case OpType::RDivC:
             y_ref[i] = fp16_ieee_to_fp32_value(b) / fp16_ieee_to_fp32_value(a_data[i]);
             break;
           case OpType::MaxC:
             y_ref[i] = std::max<float>(fp16_ieee_to_fp32_value(a_data[i]), fp16_ieee_to_fp32_value(b));
             break;
           case OpType::MinC:
             y_ref[i] = std::min<float>(fp16_ieee_to_fp32_value(a_data[i]), fp16_ieee_to_fp32_value(b));
             break;
           case OpType::MulC:
             y_ref[i] = fp16_ieee_to_fp32_value(a_data[i]) * fp16_ieee_to_fp32_value(b);
             break;
           case OpType::SqrDiffC:
           {
             const float diff = fp16_ieee_to_fp32_value(a_data[i]) - fp16_ieee_to_fp32_value(b);
             y_ref[i] = diff * diff;
             break;
           }
           case OpType::SubC:
             y_ref[i] = fp16_ieee_to_fp32_value(a_data[i]) - fp16_ieee_to_fp32_value(b);
             break;
           case OpType::RSubC:
             y_ref[i] = fp16_ieee_to_fp32_value(b) - fp16_ieee_to_fp32_value(a_data[i]);
             break;
         }
       }
       const float accumulated_min = *std::min_element(y_ref.cbegin(), y_ref.cend());
       const float accumulated_max = *std::max_element(y_ref.cbegin(), y_ref.cend());
       const float accumulated_range = accumulated_max - accumulated_min;
       const float y_max = fp16_ieee_to_fp32_value(fp16_ieee_from_fp32_value(accumulated_range > 0.0f ?
         (accumulated_max - accumulated_range / 255.0f * float(255 - qmax())) :
         +std::numeric_limits<float>::infinity()));
       const float y_min = fp16_ieee_to_fp32_value(fp16_ieee_from_fp32_value(accumulated_range > 0.0f ?
         (accumulated_min + accumulated_range / 255.0f * float(qmin())) :
         -std::numeric_limits<float>::infinity()));
       for (size_t i = 0; i < batch_size(); i++) {
         y_ref[i] = std::max<float>(std::min<float>(y_ref[i], y_max), y_min);
       }

       // Prepare parameters.
       xnn_f16_minmax_params params;
       init_params(&params,
         fp16_ieee_from_fp32_value(y_min), fp16_ieee_from_fp32_value(y_max));

       // Call optimized micro-kernel.
       vbinaryc_minmax(batch_size() * sizeof(uint16_t), a_data, &b, y.data(), &params);

       // Verify results.
       for (size_t i = 0; i < batch_size(); i++) {
         ASSERT_NEAR(fp16_ieee_to_fp32_value(y[i]), y_ref[i], std::max(1.0e-4f, std::abs(y_ref[i]) * 1.0e-2f))
           << "at " << i << " / " << batch_size();
       }
     }
   }

   void Test(xnn_f32_vbinary_ukernel_function vbinaryc, OpType op_type, xnn_init_f32_default_params_fn init_params = nullptr) const {
     std::random_device random_device;
     auto rng = std::mt19937(random_device());
     auto f32rng = std::bind(std::uniform_real_distribution<float>(0.0f, 1.0f), rng);

     std::vector<float> a(batch_size() + XNN_EXTRA_BYTES / sizeof(float));
     const float b = f32rng();
     std::vector<float> y(batch_size() + (inplace() ? XNN_EXTRA_BYTES / sizeof(float) : 0));
     std::vector<float> y_ref(batch_size());
     for (size_t iteration = 0; iteration < iterations(); iteration++) {
       std::generate(a.begin(), a.end(), std::ref(f32rng));
       if (inplace()) {
         std::generate(y.begin(), y.end(), std::ref(f32rng));
       } else {
         std::fill(y.begin(), y.end(), nanf(""));
       }
       const float* a_data = inplace() ? y.data() : a.data();

       // Compute reference results.
       for (size_t i = 0; i < batch_size(); i++) {
         switch (op_type) {
           case OpType::AddC:
             y_ref[i] = a_data[i] + b;
             break;
           case OpType::DivC:
             y_ref[i] = a_data[i] / b;
             break;
           case OpType::RDivC:
             y_ref[i] = b / a_data[i];
             break;
           case OpType::MaxC:
             y_ref[i] = std::max<float>(a_data[i], b);
             break;
           case OpType::MinC:
             y_ref[i] = std::min<float>(a_data[i], b);
             break;
           case OpType::MulC:
             y_ref[i] = a_data[i] * b;
             break;
           case OpType::SqrDiffC:
           {
             const float diff = a_data[i] - b;
             y_ref[i] = diff * diff;
             break;
           }
           case OpType::SubC:
             y_ref[i] = a_data[i] - b;
             break;
           case OpType::RSubC:
             y_ref[i] = b - a_data[i];
             break;
         }
       }

       // Prepare parameters.
       xnn_f32_default_params params;
       if (init_params) {
         init_params(&params);
       }

       // Call optimized micro-kernel.
       vbinaryc(batch_size() * sizeof(float), a_data, &b, y.data(), init_params != nullptr ? &params : nullptr);

       // Verify results.
       for (size_t i = 0; i < batch_size(); i++) {
         ASSERT_NEAR(y[i], y_ref[i], std::abs(y_ref[i]) * 1.0e-6f)
           << "at " << i << " / " << batch_size();
       }
     }
   }

   void Test(xnn_f32_vbinary_relu_ukernel_function vbinaryc_relu, OpType op_type) const {
     std::random_device random_device;
     auto rng = std::mt19937(random_device());
     auto f32rng = std::bind(std::uniform_real_distribution<float>(-1.0f, 1.0f), rng);

     std::vector<float> a(batch_size() + XNN_EXTRA_BYTES / sizeof(float));
     const float b = f32rng();
     std::vector<float> y(batch_size() + (inplace() ? XNN_EXTRA_BYTES / sizeof(float) : 0));
     std::vector<float> y_ref(batch_size());
     for (size_t iteration = 0; iteration < iterations(); iteration++) {
       std::generate(a.begin(), a.end(), std::ref(f32rng));
       if (inplace()) {
         std::generate(y.begin(), y.end(), std::ref(f32rng));
       } else {
         std::fill(y.begin(), y.end(), nanf(""));
       }
       const float* a_data = inplace() ? y.data() : a.data();

       // Compute reference results.
       for (size_t i = 0; i < batch_size(); i++) {
         switch (op_type) {
           case OpType::AddC:
             y_ref[i] = a_data[i] + b;
             break;
           case OpType::DivC:
             y_ref[i] = a_data[i] / b;
             break;
           case OpType::RDivC:
             y_ref[i] = b / a_data[i];
             break;
           case OpType::MaxC:
             y_ref[i] = std::max<float>(a_data[i], b);
             break;
           case OpType::MinC:
             y_ref[i] = std::min<float>(a_data[i], b);
             break;
           case OpType::MulC:
             y_ref[i] = a_data[i] * b;
             break;
           case OpType::SqrDiffC:
           {
             const float diff = a_data[i] - b;
             y_ref[i] = diff * diff;
             break;
           }
           case OpType::SubC:
             y_ref[i] = a_data[i] - b;
             break;
           case OpType::RSubC:
             y_ref[i] = b - a_data[i];
             break;
         }
       }
       for (size_t i = 0; i < batch_size(); i++) {
         y_ref[i] = std::max(y_ref[i], 0.0f);
       }

       // Call optimized micro-kernel.
       vbinaryc_relu(batch_size() * sizeof(float), a_data, &b, y.data(), nullptr);

       // Verify results.
       for (size_t i = 0; i < batch_size(); i++) {
         ASSERT_GE(y[i], 0.0f)
           << "at " << i << " / " << batch_size();
         ASSERT_NEAR(y[i], y_ref[i], std::abs(y_ref[i]) * 1.0e-6f)
           << "at " << i << " / " << batch_size();
       }
     }
   }

   void Test(xnn_f32_vbinary_minmax_ukernel_function vbinaryc_minmax, OpType op_type, xnn_init_f32_minmax_params_fn init_params) const {
     std::random_device random_device;
     auto rng = std::mt19937(random_device());
     auto f32rng = std::bind(std::uniform_real_distribution<float>(0.0f, 1.0f), rng);

     std::vector<float> a(batch_size() + XNN_EXTRA_BYTES / sizeof(float));
     const float b = f32rng();
     std::vector<float> y(batch_size() + (inplace() ? XNN_EXTRA_BYTES / sizeof(float) : 0));
     std::vector<float> y_ref(batch_size());
     for (size_t iteration = 0; iteration < iterations(); iteration++) {
       std::generate(a.begin(), a.end(), std::ref(f32rng));
       if (inplace()) {
         std::generate(y.begin(), y.end(), std::ref(f32rng));
       } else {
         std::fill(y.begin(), y.end(), nanf(""));
       }
       const float* a_data = inplace() ? y.data() : a.data();

       // Compute reference results.
       for (size_t i = 0; i < batch_size(); i++) {
         switch (op_type) {
           case OpType::AddC:
             y_ref[i] = a_data[i] + b;
             break;
           case OpType::DivC:
             y_ref[i] = a_data[i] / b;
             break;
           case OpType::RDivC:
             y_ref[i] = b / a_data[i];
             break;
           case OpType::MaxC:
             y_ref[i] = std::max<float>(a_data[i], b);
             break;
           case OpType::MinC:
             y_ref[i] = std::min<float>(a_data[i], b);
             break;
           case OpType::MulC:
             y_ref[i] = a_data[i] * b;
             break;
           case OpType::SqrDiffC:
           {
             const float diff = a_data[i] - b;
             y_ref[i] = diff * diff;
             break;
           }
           case OpType::SubC:
             y_ref[i] = a_data[i] - b;
             break;
           case OpType::RSubC:
             y_ref[i] = b - a_data[i];
             break;
         }
       }
       const float accumulated_min = *std::min_element(y_ref.cbegin(), y_ref.cend());
       const float accumulated_max = *std::max_element(y_ref.cbegin(), y_ref.cend());
       const float accumulated_range = accumulated_max - accumulated_min;
       const float y_max = accumulated_range > 0.0f ?
         (accumulated_max - accumulated_range / 255.0f * float(255 - qmax())) :
         +std::numeric_limits<float>::infinity();
       const float y_min = accumulated_range > 0.0f ?
         (accumulated_min + accumulated_range / 255.0f * float(qmin())) :
         -std::numeric_limits<float>::infinity();
       for (size_t i = 0; i < batch_size(); i++) {
         y_ref[i] = std::max<float>(std::min<float>(y_ref[i], y_max), y_min);
       }

       // Prepare parameters.
       xnn_f32_minmax_params params;
       init_params(&params, y_min, y_max);

       // Call optimized micro-kernel.
       vbinaryc_minmax(batch_size() * sizeof(float), a_data, &b, y.data(), &params);

       // Verify results.
       for (size_t i = 0; i < batch_size(); i++) {
         ASSERT_NEAR(y[i], y_ref[i], std::abs(y_ref[i]) * 1.0e-6f)
           << "at " << i << " / " << batch_size();
       }
     }
   }

  private:
   size_t batch_size_{1};
   bool inplace_{false};
   uint8_t qmin_{0};
   uint8_t qmax_{255};
   size_t iterations_{15};
 };
	// 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 <gtest/gtest.h>

	#include <algorithm>
	#include <cassert>
	#include <cstddef>
	#include <cstdlib>
	#include <functional>
	#include <random>
	#include <vector>

	#include <fp16.h>

	#include <xnnpack.h>
	#include <xnnpack/params-init.h>
	#include <xnnpack/params.h>


	class VBinaryCMicrokernelTester {
	public:
	enum class OpType {
	AddC,
	DivC,
	RDivC,
	MaxC,
	MinC,
	MulC,
	SqrDiffC,
	SubC,
	RSubC,
	};

	inline VBinaryCMicrokernelTester& batch_size(size_t batch_size) {
	assert(batch_size != 0);
	this->batch_size_ = batch_size;
	return *this;
	}

	inline size_t batch_size() const {
	return this->batch_size_;
	}

	inline VBinaryCMicrokernelTester& inplace(bool inplace) {
	this->inplace_ = inplace;
	return *this;
	}

	inline bool inplace() const {
	return this->inplace_;
	}

	inline VBinaryCMicrokernelTester& qmin(uint8_t qmin) {
	this->qmin_ = qmin;
	return *this;
	}

	inline uint8_t qmin() const {
	return this->qmin_;
	}

	inline VBinaryCMicrokernelTester& qmax(uint8_t qmax) {
	this->qmax_ = qmax;
	return *this;
	}

	inline uint8_t qmax() const {
	return this->qmax_;
	}

	inline VBinaryCMicrokernelTester& iterations(size_t iterations) {
	this->iterations_ = iterations;
	return *this;
	}

	inline size_t iterations() const {
	return this->iterations_;
	}

	void Test(xnn_f16_vbinary_ukernel_function vbinaryc, OpType op_type) const {
	std::random_device random_device;
	auto rng = std::mt19937(random_device());
	auto f32rng = std::bind(std::uniform_real_distribution<float>(0.01f, 1.0f), rng);
	auto f16rng = std::bind(fp16_ieee_from_fp32_value, f32rng);

	std::vector<uint16_t> a(batch_size() + XNN_EXTRA_BYTES / sizeof(uint16_t));
	const uint16_t b = f16rng();
	std::vector<uint16_t> y(batch_size() + (inplace() ? XNN_EXTRA_BYTES / sizeof(uint16_t) : 0));
	std::vector<float> y_ref(batch_size());
	for (size_t iteration = 0; iteration < iterations(); iteration++) {
	std::generate(a.begin(), a.end(), std::ref(f16rng));
	if (inplace()) {
	std::generate(y.begin(), y.end(), std::ref(f16rng));
	} else {
	std::fill(y.begin(), y.end(), UINT16_C(0x7E00) /* NaN */);
	}
	const uint16_t* a_data = inplace() ? y.data() : a.data();

	// Compute reference results.
	for (size_t i = 0; i < batch_size(); i++) {
	switch (op_type) {
	case OpType::AddC:
	y_ref[i] = fp16_ieee_to_fp32_value(a_data[i]) + fp16_ieee_to_fp32_value(b);
	break;
	case OpType::DivC:
	y_ref[i] = fp16_ieee_to_fp32_value(a_data[i]) / fp16_ieee_to_fp32_value(b);
	break;
	case OpType::RDivC:
	y_ref[i] = fp16_ieee_to_fp32_value(b) / fp16_ieee_to_fp32_value(a_data[i]);
	break;
	case OpType::MaxC:
	y_ref[i] = std::max<float>(fp16_ieee_to_fp32_value(a_data[i]), fp16_ieee_to_fp32_value(b));
	break;
	case OpType::MinC:
	y_ref[i] = std::min<float>(fp16_ieee_to_fp32_value(a_data[i]), fp16_ieee_to_fp32_value(b));
	break;
	case OpType::MulC:
	y_ref[i] = fp16_ieee_to_fp32_value(a_data[i]) * fp16_ieee_to_fp32_value(b);
	break;
	case OpType::SqrDiffC:
	{
	const float diff = fp16_ieee_to_fp32_value(a_data[i]) - fp16_ieee_to_fp32_value(b);
	y_ref[i] = diff * diff;
	break;
	}
	case OpType::SubC:
	y_ref[i] = fp16_ieee_to_fp32_value(a_data[i]) - fp16_ieee_to_fp32_value(b);
	break;
	case OpType::RSubC:
	y_ref[i] = fp16_ieee_to_fp32_value(b) - fp16_ieee_to_fp32_value(a_data[i]);
	break;
	}
	}
	// Call optimized micro-kernel.
	vbinaryc(batch_size() * sizeof(uint16_t), a_data, &b, y.data(), nullptr);

	// Verify results.
	for (size_t i = 0; i < batch_size(); i++) {
	ASSERT_NEAR(fp16_ieee_to_fp32_value(y[i]), y_ref[i], std::max(1.0e-4f, std::abs(y_ref[i]) * 1.0e-2f))
	<< "at " << i << " / " << batch_size();
	}
	}
	}

	void Test(xnn_f16_vbinary_minmax_ukernel_function vbinaryc_minmax, OpType op_type, xnn_init_f16_minmax_params_fn init_params) const {
	std::random_device random_device;
	auto rng = std::mt19937(random_device());
	auto f32rng = std::bind(std::uniform_real_distribution<float>(1.0e-3f, 1.0f), rng);
	auto f16rng = std::bind(fp16_ieee_from_fp32_value, f32rng);

	std::vector<uint16_t> a(batch_size() + XNN_EXTRA_BYTES / sizeof(uint16_t));
	const uint16_t b = f16rng();
	std::vector<uint16_t> y(batch_size() + (inplace() ? XNN_EXTRA_BYTES / sizeof(uint16_t) : 0));
	std::vector<float> y_ref(batch_size());
	for (size_t iteration = 0; iteration < iterations(); iteration++) {
	std::generate(a.begin(), a.end(), std::ref(f16rng));
	if (inplace()) {
	std::generate(y.begin(), y.end(), std::ref(f16rng));
	} else {
	std::fill(y.begin(), y.end(), UINT16_C(0x7E00) /* NaN */);
	}
	const uint16_t* a_data = inplace() ? y.data() : a.data();

	// Compute reference results.
	for (size_t i = 0; i < batch_size(); i++) {
	switch (op_type) {
	case OpType::AddC:
	y_ref[i] = fp16_ieee_to_fp32_value(a_data[i]) + fp16_ieee_to_fp32_value(b);
	break;
	case OpType::DivC:
	y_ref[i] = fp16_ieee_to_fp32_value(a_data[i]) / fp16_ieee_to_fp32_value(b);
	break;
	case OpType::RDivC:
	y_ref[i] = fp16_ieee_to_fp32_value(b) / fp16_ieee_to_fp32_value(a_data[i]);
	break;
	case OpType::MaxC:
	y_ref[i] = std::max<float>(fp16_ieee_to_fp32_value(a_data[i]), fp16_ieee_to_fp32_value(b));
	break;
	case OpType::MinC:
	y_ref[i] = std::min<float>(fp16_ieee_to_fp32_value(a_data[i]), fp16_ieee_to_fp32_value(b));
	break;
	case OpType::MulC:
	y_ref[i] = fp16_ieee_to_fp32_value(a_data[i]) * fp16_ieee_to_fp32_value(b);
	break;
	case OpType::SqrDiffC:
	{
	const float diff = fp16_ieee_to_fp32_value(a_data[i]) - fp16_ieee_to_fp32_value(b);
	y_ref[i] = diff * diff;
	break;
	}
	case OpType::SubC:
	y_ref[i] = fp16_ieee_to_fp32_value(a_data[i]) - fp16_ieee_to_fp32_value(b);
	break;
	case OpType::RSubC:
	y_ref[i] = fp16_ieee_to_fp32_value(b) - fp16_ieee_to_fp32_value(a_data[i]);
	break;
	}
	}
	const float accumulated_min = *std::min_element(y_ref.cbegin(), y_ref.cend());
	const float accumulated_max = *std::max_element(y_ref.cbegin(), y_ref.cend());
	const float accumulated_range = accumulated_max - accumulated_min;
	const float y_max = fp16_ieee_to_fp32_value(fp16_ieee_from_fp32_value(accumulated_range > 0.0f ?
	(accumulated_max - accumulated_range / 255.0f * float(255 - qmax())) :
	+std::numeric_limits<float>::infinity()));
	const float y_min = fp16_ieee_to_fp32_value(fp16_ieee_from_fp32_value(accumulated_range > 0.0f ?
	(accumulated_min + accumulated_range / 255.0f * float(qmin())) :
	-std::numeric_limits<float>::infinity()));
	for (size_t i = 0; i < batch_size(); i++) {
	y_ref[i] = std::max<float>(std::min<float>(y_ref[i], y_max), y_min);
	}

	// Prepare parameters.
	xnn_f16_minmax_params params;
	init_params(&params,
	fp16_ieee_from_fp32_value(y_min), fp16_ieee_from_fp32_value(y_max));

	// Call optimized micro-kernel.
	vbinaryc_minmax(batch_size() * sizeof(uint16_t), a_data, &b, y.data(), &params);

	// Verify results.
	for (size_t i = 0; i < batch_size(); i++) {
	ASSERT_NEAR(fp16_ieee_to_fp32_value(y[i]), y_ref[i], std::max(1.0e-4f, std::abs(y_ref[i]) * 1.0e-2f))
	<< "at " << i << " / " << batch_size();
	}
	}
	}

	void Test(xnn_f32_vbinary_ukernel_function vbinaryc, OpType op_type, xnn_init_f32_default_params_fn init_params = nullptr) const {
	std::random_device random_device;
	auto rng = std::mt19937(random_device());
	auto f32rng = std::bind(std::uniform_real_distribution<float>(0.0f, 1.0f), rng);

	std::vector<float> a(batch_size() + XNN_EXTRA_BYTES / sizeof(float));
	const float b = f32rng();
	std::vector<float> y(batch_size() + (inplace() ? XNN_EXTRA_BYTES / sizeof(float) : 0));
	std::vector<float> y_ref(batch_size());
	for (size_t iteration = 0; iteration < iterations(); iteration++) {
	std::generate(a.begin(), a.end(), std::ref(f32rng));
	if (inplace()) {
	std::generate(y.begin(), y.end(), std::ref(f32rng));
	} else {
	std::fill(y.begin(), y.end(), nanf(""));
	}
	const float* a_data = inplace() ? y.data() : a.data();

	// Compute reference results.
	for (size_t i = 0; i < batch_size(); i++) {
	switch (op_type) {
	case OpType::AddC:
	y_ref[i] = a_data[i] + b;
	break;
	case OpType::DivC:
	y_ref[i] = a_data[i] / b;
	break;
	case OpType::RDivC:
	y_ref[i] = b / a_data[i];
	break;
	case OpType::MaxC:
	y_ref[i] = std::max<float>(a_data[i], b);
	break;
	case OpType::MinC:
	y_ref[i] = std::min<float>(a_data[i], b);
	break;
	case OpType::MulC:
	y_ref[i] = a_data[i] * b;
	break;
	case OpType::SqrDiffC:
	{
	const float diff = a_data[i] - b;
	y_ref[i] = diff * diff;
	break;
	}
	case OpType::SubC:
	y_ref[i] = a_data[i] - b;
	break;
	case OpType::RSubC:
	y_ref[i] = b - a_data[i];
	break;
	}
	}

	// Prepare parameters.
	xnn_f32_default_params params;
	if (init_params) {
	init_params(&params);
	}

	// Call optimized micro-kernel.
	vbinaryc(batch_size() * sizeof(float), a_data, &b, y.data(), init_params != nullptr ? &params : nullptr);

	// Verify results.
	for (size_t i = 0; i < batch_size(); i++) {
	ASSERT_NEAR(y[i], y_ref[i], std::abs(y_ref[i]) * 1.0e-6f)
	<< "at " << i << " / " << batch_size();
	}
	}
	}

	void Test(xnn_f32_vbinary_relu_ukernel_function vbinaryc_relu, OpType op_type) const {
	std::random_device random_device;
	auto rng = std::mt19937(random_device());
	auto f32rng = std::bind(std::uniform_real_distribution<float>(-1.0f, 1.0f), rng);

	std::vector<float> a(batch_size() + XNN_EXTRA_BYTES / sizeof(float));
	const float b = f32rng();
	std::vector<float> y(batch_size() + (inplace() ? XNN_EXTRA_BYTES / sizeof(float) : 0));
	std::vector<float> y_ref(batch_size());
	for (size_t iteration = 0; iteration < iterations(); iteration++) {
	std::generate(a.begin(), a.end(), std::ref(f32rng));
	if (inplace()) {
	std::generate(y.begin(), y.end(), std::ref(f32rng));
	} else {
	std::fill(y.begin(), y.end(), nanf(""));
	}
	const float* a_data = inplace() ? y.data() : a.data();

	// Compute reference results.
	for (size_t i = 0; i < batch_size(); i++) {
	switch (op_type) {
	case OpType::AddC:
	y_ref[i] = a_data[i] + b;
	break;
	case OpType::DivC:
	y_ref[i] = a_data[i] / b;
	break;
	case OpType::RDivC:
	y_ref[i] = b / a_data[i];
	break;
	case OpType::MaxC:
	y_ref[i] = std::max<float>(a_data[i], b);
	break;
	case OpType::MinC:
	y_ref[i] = std::min<float>(a_data[i], b);
	break;
	case OpType::MulC:
	y_ref[i] = a_data[i] * b;
	break;
	case OpType::SqrDiffC:
	{
	const float diff = a_data[i] - b;
	y_ref[i] = diff * diff;
	break;
	}
	case OpType::SubC:
	y_ref[i] = a_data[i] - b;
	break;
	case OpType::RSubC:
	y_ref[i] = b - a_data[i];
	break;
	}
	}
	for (size_t i = 0; i < batch_size(); i++) {
	y_ref[i] = std::max(y_ref[i], 0.0f);
	}

	// Call optimized micro-kernel.
	vbinaryc_relu(batch_size() * sizeof(float), a_data, &b, y.data(), nullptr);

	// Verify results.
	for (size_t i = 0; i < batch_size(); i++) {
	ASSERT_GE(y[i], 0.0f)
	<< "at " << i << " / " << batch_size();
	ASSERT_NEAR(y[i], y_ref[i], std::abs(y_ref[i]) * 1.0e-6f)
	<< "at " << i << " / " << batch_size();
	}
	}
	}

	void Test(xnn_f32_vbinary_minmax_ukernel_function vbinaryc_minmax, OpType op_type, xnn_init_f32_minmax_params_fn init_params) const {
	std::random_device random_device;
	auto rng = std::mt19937(random_device());
	auto f32rng = std::bind(std::uniform_real_distribution<float>(0.0f, 1.0f), rng);

	std::vector<float> a(batch_size() + XNN_EXTRA_BYTES / sizeof(float));
	const float b = f32rng();
	std::vector<float> y(batch_size() + (inplace() ? XNN_EXTRA_BYTES / sizeof(float) : 0));
	std::vector<float> y_ref(batch_size());
	for (size_t iteration = 0; iteration < iterations(); iteration++) {
	std::generate(a.begin(), a.end(), std::ref(f32rng));
	if (inplace()) {
	std::generate(y.begin(), y.end(), std::ref(f32rng));
	} else {
	std::fill(y.begin(), y.end(), nanf(""));
	}
	const float* a_data = inplace() ? y.data() : a.data();

	// Compute reference results.
	for (size_t i = 0; i < batch_size(); i++) {
	switch (op_type) {
	case OpType::AddC:
	y_ref[i] = a_data[i] + b;
	break;
	case OpType::DivC:
	y_ref[i] = a_data[i] / b;
	break;
	case OpType::RDivC:
	y_ref[i] = b / a_data[i];
	break;
	case OpType::MaxC:
	y_ref[i] = std::max<float>(a_data[i], b);
	break;
	case OpType::MinC:
	y_ref[i] = std::min<float>(a_data[i], b);
	break;
	case OpType::MulC:
	y_ref[i] = a_data[i] * b;
	break;
	case OpType::SqrDiffC:
	{
	const float diff = a_data[i] - b;
	y_ref[i] = diff * diff;
	break;
	}
	case OpType::SubC:
	y_ref[i] = a_data[i] - b;
	break;
	case OpType::RSubC:
	y_ref[i] = b - a_data[i];
	break;
	}
	}
	const float accumulated_min = *std::min_element(y_ref.cbegin(), y_ref.cend());
	const float accumulated_max = *std::max_element(y_ref.cbegin(), y_ref.cend());
	const float accumulated_range = accumulated_max - accumulated_min;
	const float y_max = accumulated_range > 0.0f ?
	(accumulated_max - accumulated_range / 255.0f * float(255 - qmax())) :
	+std::numeric_limits<float>::infinity();
	const float y_min = accumulated_range > 0.0f ?
	(accumulated_min + accumulated_range / 255.0f * float(qmin())) :
	-std::numeric_limits<float>::infinity();
	for (size_t i = 0; i < batch_size(); i++) {
	y_ref[i] = std::max<float>(std::min<float>(y_ref[i], y_max), y_min);
	}

	// Prepare parameters.
	xnn_f32_minmax_params params;
	init_params(&params, y_min, y_max);

	// Call optimized micro-kernel.
	vbinaryc_minmax(batch_size() * sizeof(float), a_data, &b, y.data(), &params);

	// Verify results.
	for (size_t i = 0; i < batch_size(); i++) {
	ASSERT_NEAR(y[i], y_ref[i], std::abs(y_ref[i]) * 1.0e-6f)
	<< "at " << i << " / " << batch_size();
	}
	}
	}

	private:
	size_t batch_size_{1};
	bool inplace_{false};
	uint8_t qmin_{0};
	uint8_t qmax_{255};
	size_t iterations_{15};
	};