unsupported/test/cxx11_tensor_fft.cpp - mirror - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2014 Jianwei Cui <thucjw@gmail.com>
 //
 // This Source Code Form is subject to the terms of the Mozilla
 // Public License v. 2.0. If a copy of the MPL was not distributed
 // with this file, You can obtain one at http://mozilla.org/MPL/2.0/.

 #include "main.h"
 #include <Eigen/CXX11/Tensor>

 using Eigen::Tensor;

 template <int DataLayout>
 static void test_fft_2D_golden() {
   Tensor<float, 2, DataLayout> input(2, 3);
   input(0, 0) = 1;
   input(0, 1) = 2;
   input(0, 2) = 3;
   input(1, 0) = 4;
   input(1, 1) = 5;
   input(1, 2) = 6;

   array<ptrdiff_t, 2> fft;
   fft[0] = 0;
   fft[1] = 1;

   Tensor<std::complex<float>, 2, DataLayout> output = input.template fft<Eigen::BothParts, Eigen::FFT_FORWARD>(fft);

   std::complex<float> output_golden[6]; // in ColMajor order
   output_golden[0] = std::complex<float>(21, 0);
   output_golden[1] = std::complex<float>(-9, 0);
   output_golden[2] = std::complex<float>(-3, 1.73205);
   output_golden[3] = std::complex<float>( 0, 0);
   output_golden[4] = std::complex<float>(-3, -1.73205);
   output_golden[5] = std::complex<float>(0 ,0);

   std::complex<float> c_offset = std::complex<float>(1.0, 1.0);

   if (DataLayout == ColMajor) {
     VERIFY_IS_APPROX(output(0) + c_offset, output_golden[0] + c_offset);
     VERIFY_IS_APPROX(output(1) + c_offset, output_golden[1] + c_offset);
     VERIFY_IS_APPROX(output(2) + c_offset, output_golden[2] + c_offset);
     VERIFY_IS_APPROX(output(3) + c_offset, output_golden[3] + c_offset);
     VERIFY_IS_APPROX(output(4) + c_offset, output_golden[4] + c_offset);
     VERIFY_IS_APPROX(output(5) + c_offset, output_golden[5] + c_offset);
   }
   else {
     VERIFY_IS_APPROX(output(0)+ c_offset, output_golden[0]+ c_offset);
     VERIFY_IS_APPROX(output(1)+ c_offset, output_golden[2]+ c_offset);
     VERIFY_IS_APPROX(output(2)+ c_offset, output_golden[4]+ c_offset);
     VERIFY_IS_APPROX(output(3)+ c_offset, output_golden[1]+ c_offset);
     VERIFY_IS_APPROX(output(4)+ c_offset, output_golden[3]+ c_offset);
     VERIFY_IS_APPROX(output(5)+ c_offset, output_golden[5]+ c_offset);
   }
 }

 static void test_fft_complex_input_golden() {
   Tensor<std::complex<float>, 1, ColMajor> input(5);
   input(0) = std::complex<float>(1, 1);
   input(1) = std::complex<float>(2, 2);
   input(2) = std::complex<float>(3, 3);
   input(3) = std::complex<float>(4, 4);
   input(4) = std::complex<float>(5, 5);

   array<ptrdiff_t, 1> fft;
   fft[0] = 0;

   Tensor<std::complex<float>, 1, ColMajor> forward_output_both_parts = input.fft<BothParts, FFT_FORWARD>(fft);
   Tensor<std::complex<float>, 1, ColMajor> reverse_output_both_parts = input.fft<BothParts, FFT_REVERSE>(fft);

   Tensor<float, 1, ColMajor> forward_output_real_part = input.fft<RealPart, FFT_FORWARD>(fft);
   Tensor<float, 1, ColMajor> reverse_output_real_part = input.fft<RealPart, FFT_REVERSE>(fft);

   Tensor<float, 1, ColMajor> forward_output_imag_part = input.fft<ImagPart, FFT_FORWARD>(fft);
   Tensor<float, 1, ColMajor> reverse_output_imag_part = input.fft<ImagPart, FFT_REVERSE>(fft);

   VERIFY_IS_EQUAL(forward_output_both_parts.dimension(0), input.dimension(0));
   VERIFY_IS_EQUAL(reverse_output_both_parts.dimension(0), input.dimension(0));

   VERIFY_IS_EQUAL(forward_output_real_part.dimension(0), input.dimension(0));
   VERIFY_IS_EQUAL(reverse_output_real_part.dimension(0), input.dimension(0));

   VERIFY_IS_EQUAL(forward_output_imag_part.dimension(0), input.dimension(0));
   VERIFY_IS_EQUAL(reverse_output_imag_part.dimension(0), input.dimension(0));

   std::complex<float> forward_golden_result[5];
   std::complex<float> reverse_golden_result[5];

   forward_golden_result[0] = std::complex<float>(15.000000000000000,+15.000000000000000);
   forward_golden_result[1] = std::complex<float>(-5.940954801177935, +0.940954801177934);
   forward_golden_result[2] = std::complex<float>(-3.312299240582266, -1.687700759417735);
   forward_golden_result[3] = std::complex<float>(-1.687700759417735, -3.312299240582266);
   forward_golden_result[4] = std::complex<float>( 0.940954801177934, -5.940954801177935);

   reverse_golden_result[0] = std::complex<float>( 3.000000000000000, + 3.000000000000000);
   reverse_golden_result[1] = std::complex<float>( 0.188190960235587, - 1.188190960235587);
   reverse_golden_result[2] = std::complex<float>(-0.337540151883547, - 0.662459848116453);
   reverse_golden_result[3] = std::complex<float>(-0.662459848116453, - 0.337540151883547);
   reverse_golden_result[4] = std::complex<float>(-1.188190960235587, + 0.188190960235587);

   for(int i = 0; i < 5; ++i) {
     VERIFY_IS_APPROX(forward_output_both_parts(i), forward_golden_result[i]);
     VERIFY_IS_APPROX(forward_output_real_part(i), forward_golden_result[i].real());
     VERIFY_IS_APPROX(forward_output_imag_part(i), forward_golden_result[i].imag());
   }

   for(int i = 0; i < 5; ++i) {
     VERIFY_IS_APPROX(reverse_output_both_parts(i), reverse_golden_result[i]);
     VERIFY_IS_APPROX(reverse_output_real_part(i), reverse_golden_result[i].real());
     VERIFY_IS_APPROX(reverse_output_imag_part(i), reverse_golden_result[i].imag());
   }
 }

 static void test_fft_real_input_golden() {
   Tensor<float, 1, ColMajor> input(5);
   input(0) = 1.0;
   input(1) = 2.0;
   input(2) = 3.0;
   input(3) = 4.0;
   input(4) = 5.0;

   array<ptrdiff_t, 1> fft;
   fft[0] = 0;

   Tensor<std::complex<float>, 1, ColMajor> forward_output_both_parts = input.fft<BothParts, FFT_FORWARD>(fft);
   Tensor<std::complex<float>, 1, ColMajor> reverse_output_both_parts = input.fft<BothParts, FFT_REVERSE>(fft);

   Tensor<float, 1, ColMajor> forward_output_real_part = input.fft<RealPart, FFT_FORWARD>(fft);
   Tensor<float, 1, ColMajor> reverse_output_real_part = input.fft<RealPart, FFT_REVERSE>(fft);

   Tensor<float, 1, ColMajor> forward_output_imag_part = input.fft<ImagPart, FFT_FORWARD>(fft);
   Tensor<float, 1, ColMajor> reverse_output_imag_part = input.fft<ImagPart, FFT_REVERSE>(fft);

   VERIFY_IS_EQUAL(forward_output_both_parts.dimension(0), input.dimension(0));
   VERIFY_IS_EQUAL(reverse_output_both_parts.dimension(0), input.dimension(0));

   VERIFY_IS_EQUAL(forward_output_real_part.dimension(0), input.dimension(0));
   VERIFY_IS_EQUAL(reverse_output_real_part.dimension(0), input.dimension(0));

   VERIFY_IS_EQUAL(forward_output_imag_part.dimension(0), input.dimension(0));
   VERIFY_IS_EQUAL(reverse_output_imag_part.dimension(0), input.dimension(0));

   std::complex<float> forward_golden_result[5];
   std::complex<float> reverse_golden_result[5];


   forward_golden_result[0] = std::complex<float>(  15, 0);
   forward_golden_result[1] = std::complex<float>(-2.5, +3.44095480117793);
   forward_golden_result[2] = std::complex<float>(-2.5, +0.81229924058227);
   forward_golden_result[3] = std::complex<float>(-2.5, -0.81229924058227);
   forward_golden_result[4] = std::complex<float>(-2.5, -3.44095480117793);

   reverse_golden_result[0] = std::complex<float>( 3.0, 0);
   reverse_golden_result[1] = std::complex<float>(-0.5, -0.688190960235587);
   reverse_golden_result[2] = std::complex<float>(-0.5, -0.162459848116453);
   reverse_golden_result[3] = std::complex<float>(-0.5, +0.162459848116453);
   reverse_golden_result[4] = std::complex<float>(-0.5, +0.688190960235587);

   std::complex<float> c_offset(1.0, 1.0);
   float r_offset = 1.0;

   for(int i = 0; i < 5; ++i) {
     VERIFY_IS_APPROX(forward_output_both_parts(i) + c_offset, forward_golden_result[i] + c_offset);
     VERIFY_IS_APPROX(forward_output_real_part(i)  + r_offset, forward_golden_result[i].real() + r_offset);
     VERIFY_IS_APPROX(forward_output_imag_part(i)  + r_offset, forward_golden_result[i].imag() + r_offset);
   }

   for(int i = 0; i < 5; ++i) {
     VERIFY_IS_APPROX(reverse_output_both_parts(i) + c_offset, reverse_golden_result[i] + c_offset);
     VERIFY_IS_APPROX(reverse_output_real_part(i)  + r_offset, reverse_golden_result[i].real() + r_offset);
     VERIFY_IS_APPROX(reverse_output_imag_part(i)  + r_offset, reverse_golden_result[i].imag() + r_offset);
   }
 }


 template <int DataLayout, typename RealScalar, bool isComplexInput, int FFTResultType, int FFTDirection, int TensorRank>
 static void test_fft_real_input_energy() {

   Eigen::DSizes<ptrdiff_t, TensorRank> dimensions;
   ptrdiff_t total_size = 1;
   for (int i = 0; i < TensorRank; ++i) {
     dimensions[i] = rand() % 20 + 1;
     total_size *= dimensions[i];
   }
   const DSizes<ptrdiff_t, TensorRank> arr = dimensions;

   typedef std::conditional_t<isComplexInput == true, std::complex<RealScalar>, RealScalar> InputScalar;

   Tensor<InputScalar, TensorRank, DataLayout> input;
   input.resize(arr);
   input.setRandom();

   array<ptrdiff_t, TensorRank> fft;
   for (int i = 0; i < TensorRank; ++i) {
     fft[i] = i;
   }

   typedef std::conditional_t<FFTResultType == Eigen::BothParts, std::complex<RealScalar>, RealScalar> OutputScalar;
   Tensor<OutputScalar, TensorRank, DataLayout> output;
   output = input.template fft<FFTResultType, FFTDirection>(fft);

   for (int i = 0; i < TensorRank; ++i) {
     VERIFY_IS_EQUAL(output.dimension(i), input.dimension(i));
   }

   RealScalar energy_original = 0.0;
   RealScalar energy_after_fft = 0.0;

   for (int i = 0; i < total_size; ++i) {
     energy_original += numext::abs2(input(i));
   }

   for (int i = 0; i < total_size; ++i) {
     energy_after_fft += numext::abs2(output(i));
   }

   if(FFTDirection == FFT_FORWARD) {
     VERIFY_IS_APPROX(energy_original, energy_after_fft / total_size);
   }
   else {
     VERIFY_IS_APPROX(energy_original, energy_after_fft * total_size);
   }
 }

 template <typename RealScalar>
 static void test_fft_non_power_of_2_round_trip(int exponent) {
   int n = (1 << exponent) + 1;

   Eigen::DSizes<ptrdiff_t, 1> dimensions;
   dimensions[0] = n;
   const DSizes<ptrdiff_t, 1> arr = dimensions;
   Tensor<RealScalar, 1, ColMajor, ptrdiff_t> input;

   input.resize(arr);
   input.setRandom();

   array<int, 1> fft;
   fft[0] = 0;

   Tensor<std::complex<RealScalar>, 1, ColMajor> forward =
       input.template fft<BothParts, FFT_FORWARD>(fft);

   Tensor<RealScalar, 1, ColMajor, ptrdiff_t> output =
       forward.template fft<RealPart, FFT_REVERSE>(fft);

   for (int i = 0; i < n; ++i) {
     RealScalar tol = test_precision<RealScalar>() *
                      (std::abs(input[i]) + std::abs(output[i]) + 1);
     VERIFY_IS_APPROX_OR_LESS_THAN(std::abs(input[i] - output[i]), tol);
   }
 }

 EIGEN_DECLARE_TEST(cxx11_tensor_fft) {
     test_fft_complex_input_golden();
     test_fft_real_input_golden();

     test_fft_2D_golden<ColMajor>();
     test_fft_2D_golden<RowMajor>();

     test_fft_real_input_energy<ColMajor, float,  true,  Eigen::BothParts, FFT_FORWARD, 1>();
     test_fft_real_input_energy<ColMajor, double, true,  Eigen::BothParts, FFT_FORWARD, 1>();
     test_fft_real_input_energy<ColMajor, float,  false,  Eigen::BothParts, FFT_FORWARD, 1>();
     test_fft_real_input_energy<ColMajor, double, false,  Eigen::BothParts, FFT_FORWARD, 1>();

     test_fft_real_input_energy<ColMajor, float,  true,  Eigen::BothParts, FFT_FORWARD, 2>();
     test_fft_real_input_energy<ColMajor, double, true,  Eigen::BothParts, FFT_FORWARD, 2>();
     test_fft_real_input_energy<ColMajor, float,  false,  Eigen::BothParts, FFT_FORWARD, 2>();
     test_fft_real_input_energy<ColMajor, double, false,  Eigen::BothParts, FFT_FORWARD, 2>();

     test_fft_real_input_energy<ColMajor, float,  true,  Eigen::BothParts, FFT_FORWARD, 3>();
     test_fft_real_input_energy<ColMajor, double, true,  Eigen::BothParts, FFT_FORWARD, 3>();
     test_fft_real_input_energy<ColMajor, float,  false,  Eigen::BothParts, FFT_FORWARD, 3>();
     test_fft_real_input_energy<ColMajor, double, false,  Eigen::BothParts, FFT_FORWARD, 3>();

     test_fft_real_input_energy<ColMajor, float,  true,  Eigen::BothParts, FFT_FORWARD, 4>();
     test_fft_real_input_energy<ColMajor, double, true,  Eigen::BothParts, FFT_FORWARD, 4>();
     test_fft_real_input_energy<ColMajor, float,  false,  Eigen::BothParts, FFT_FORWARD, 4>();
     test_fft_real_input_energy<ColMajor, double, false,  Eigen::BothParts, FFT_FORWARD, 4>();

     test_fft_real_input_energy<RowMajor, float,  true,  Eigen::BothParts, FFT_FORWARD, 1>();
     test_fft_real_input_energy<RowMajor, double, true,  Eigen::BothParts, FFT_FORWARD, 1>();
     test_fft_real_input_energy<RowMajor, float,  false,  Eigen::BothParts, FFT_FORWARD, 1>();
     test_fft_real_input_energy<RowMajor, double, false,  Eigen::BothParts, FFT_FORWARD, 1>();

     test_fft_real_input_energy<RowMajor, float,  true,  Eigen::BothParts, FFT_FORWARD, 2>();
     test_fft_real_input_energy<RowMajor, double, true,  Eigen::BothParts, FFT_FORWARD, 2>();
     test_fft_real_input_energy<RowMajor, float,  false,  Eigen::BothParts, FFT_FORWARD, 2>();
     test_fft_real_input_energy<RowMajor, double, false,  Eigen::BothParts, FFT_FORWARD, 2>();

     test_fft_real_input_energy<RowMajor, float,  true,  Eigen::BothParts, FFT_FORWARD, 3>();
     test_fft_real_input_energy<RowMajor, double, true,  Eigen::BothParts, FFT_FORWARD, 3>();
     test_fft_real_input_energy<RowMajor, float,  false,  Eigen::BothParts, FFT_FORWARD, 3>();
     test_fft_real_input_energy<RowMajor, double, false,  Eigen::BothParts, FFT_FORWARD, 3>();

     test_fft_real_input_energy<RowMajor, float,  true,  Eigen::BothParts, FFT_FORWARD, 4>();
     test_fft_real_input_energy<RowMajor, double, true,  Eigen::BothParts, FFT_FORWARD, 4>();
     test_fft_real_input_energy<RowMajor, float,  false,  Eigen::BothParts, FFT_FORWARD, 4>();
     test_fft_real_input_energy<RowMajor, double, false,  Eigen::BothParts, FFT_FORWARD, 4>();

     test_fft_non_power_of_2_round_trip<float>(7);
     test_fft_non_power_of_2_round_trip<double>(7);
 }
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2014 Jianwei Cui <thucjw@gmail.com>
	//
	// This Source Code Form is subject to the terms of the Mozilla
	// Public License v. 2.0. If a copy of the MPL was not distributed
	// with this file, You can obtain one at http://mozilla.org/MPL/2.0/.

	#include "main.h"
	#include <Eigen/CXX11/Tensor>

	using Eigen::Tensor;

	template <int DataLayout>
	static void test_fft_2D_golden() {
	Tensor<float, 2, DataLayout> input(2, 3);
	input(0, 0) = 1;
	input(0, 1) = 2;
	input(0, 2) = 3;
	input(1, 0) = 4;
	input(1, 1) = 5;
	input(1, 2) = 6;

	array<ptrdiff_t, 2> fft;
	fft[0] = 0;
	fft[1] = 1;

	Tensor<std::complex<float>, 2, DataLayout> output = input.template fft<Eigen::BothParts, Eigen::FFT_FORWARD>(fft);

	std::complex<float> output_golden[6]; // in ColMajor order
	output_golden[0] = std::complex<float>(21, 0);
	output_golden[1] = std::complex<float>(-9, 0);
	output_golden[2] = std::complex<float>(-3, 1.73205);
	output_golden[3] = std::complex<float>( 0, 0);
	output_golden[4] = std::complex<float>(-3, -1.73205);
	output_golden[5] = std::complex<float>(0 ,0);

	std::complex<float> c_offset = std::complex<float>(1.0, 1.0);

	if (DataLayout == ColMajor) {
	VERIFY_IS_APPROX(output(0) + c_offset, output_golden[0] + c_offset);
	VERIFY_IS_APPROX(output(1) + c_offset, output_golden[1] + c_offset);
	VERIFY_IS_APPROX(output(2) + c_offset, output_golden[2] + c_offset);
	VERIFY_IS_APPROX(output(3) + c_offset, output_golden[3] + c_offset);
	VERIFY_IS_APPROX(output(4) + c_offset, output_golden[4] + c_offset);
	VERIFY_IS_APPROX(output(5) + c_offset, output_golden[5] + c_offset);
	}
	else {
	VERIFY_IS_APPROX(output(0)+ c_offset, output_golden[0]+ c_offset);
	VERIFY_IS_APPROX(output(1)+ c_offset, output_golden[2]+ c_offset);
	VERIFY_IS_APPROX(output(2)+ c_offset, output_golden[4]+ c_offset);
	VERIFY_IS_APPROX(output(3)+ c_offset, output_golden[1]+ c_offset);
	VERIFY_IS_APPROX(output(4)+ c_offset, output_golden[3]+ c_offset);
	VERIFY_IS_APPROX(output(5)+ c_offset, output_golden[5]+ c_offset);
	}
	}

	static void test_fft_complex_input_golden() {
	Tensor<std::complex<float>, 1, ColMajor> input(5);
	input(0) = std::complex<float>(1, 1);
	input(1) = std::complex<float>(2, 2);
	input(2) = std::complex<float>(3, 3);
	input(3) = std::complex<float>(4, 4);
	input(4) = std::complex<float>(5, 5);

	array<ptrdiff_t, 1> fft;
	fft[0] = 0;

	Tensor<std::complex<float>, 1, ColMajor> forward_output_both_parts = input.fft<BothParts, FFT_FORWARD>(fft);
	Tensor<std::complex<float>, 1, ColMajor> reverse_output_both_parts = input.fft<BothParts, FFT_REVERSE>(fft);

	Tensor<float, 1, ColMajor> forward_output_real_part = input.fft<RealPart, FFT_FORWARD>(fft);
	Tensor<float, 1, ColMajor> reverse_output_real_part = input.fft<RealPart, FFT_REVERSE>(fft);

	Tensor<float, 1, ColMajor> forward_output_imag_part = input.fft<ImagPart, FFT_FORWARD>(fft);
	Tensor<float, 1, ColMajor> reverse_output_imag_part = input.fft<ImagPart, FFT_REVERSE>(fft);

	VERIFY_IS_EQUAL(forward_output_both_parts.dimension(0), input.dimension(0));
	VERIFY_IS_EQUAL(reverse_output_both_parts.dimension(0), input.dimension(0));

	VERIFY_IS_EQUAL(forward_output_real_part.dimension(0), input.dimension(0));
	VERIFY_IS_EQUAL(reverse_output_real_part.dimension(0), input.dimension(0));

	VERIFY_IS_EQUAL(forward_output_imag_part.dimension(0), input.dimension(0));
	VERIFY_IS_EQUAL(reverse_output_imag_part.dimension(0), input.dimension(0));

	std::complex<float> forward_golden_result[5];
	std::complex<float> reverse_golden_result[5];

	forward_golden_result[0] = std::complex<float>(15.000000000000000,+15.000000000000000);
	forward_golden_result[1] = std::complex<float>(-5.940954801177935, +0.940954801177934);
	forward_golden_result[2] = std::complex<float>(-3.312299240582266, -1.687700759417735);
	forward_golden_result[3] = std::complex<float>(-1.687700759417735, -3.312299240582266);
	forward_golden_result[4] = std::complex<float>( 0.940954801177934, -5.940954801177935);

	reverse_golden_result[0] = std::complex<float>( 3.000000000000000, + 3.000000000000000);
	reverse_golden_result[1] = std::complex<float>( 0.188190960235587, - 1.188190960235587);
	reverse_golden_result[2] = std::complex<float>(-0.337540151883547, - 0.662459848116453);
	reverse_golden_result[3] = std::complex<float>(-0.662459848116453, - 0.337540151883547);
	reverse_golden_result[4] = std::complex<float>(-1.188190960235587, + 0.188190960235587);

	for(int i = 0; i < 5; ++i) {
	VERIFY_IS_APPROX(forward_output_both_parts(i), forward_golden_result[i]);
	VERIFY_IS_APPROX(forward_output_real_part(i), forward_golden_result[i].real());
	VERIFY_IS_APPROX(forward_output_imag_part(i), forward_golden_result[i].imag());
	}

	for(int i = 0; i < 5; ++i) {
	VERIFY_IS_APPROX(reverse_output_both_parts(i), reverse_golden_result[i]);
	VERIFY_IS_APPROX(reverse_output_real_part(i), reverse_golden_result[i].real());
	VERIFY_IS_APPROX(reverse_output_imag_part(i), reverse_golden_result[i].imag());
	}
	}

	static void test_fft_real_input_golden() {
	Tensor<float, 1, ColMajor> input(5);
	input(0) = 1.0;
	input(1) = 2.0;
	input(2) = 3.0;
	input(3) = 4.0;
	input(4) = 5.0;

	array<ptrdiff_t, 1> fft;
	fft[0] = 0;

	Tensor<std::complex<float>, 1, ColMajor> forward_output_both_parts = input.fft<BothParts, FFT_FORWARD>(fft);
	Tensor<std::complex<float>, 1, ColMajor> reverse_output_both_parts = input.fft<BothParts, FFT_REVERSE>(fft);

	Tensor<float, 1, ColMajor> forward_output_real_part = input.fft<RealPart, FFT_FORWARD>(fft);
	Tensor<float, 1, ColMajor> reverse_output_real_part = input.fft<RealPart, FFT_REVERSE>(fft);

	Tensor<float, 1, ColMajor> forward_output_imag_part = input.fft<ImagPart, FFT_FORWARD>(fft);
	Tensor<float, 1, ColMajor> reverse_output_imag_part = input.fft<ImagPart, FFT_REVERSE>(fft);

	VERIFY_IS_EQUAL(forward_output_both_parts.dimension(0), input.dimension(0));
	VERIFY_IS_EQUAL(reverse_output_both_parts.dimension(0), input.dimension(0));

	VERIFY_IS_EQUAL(forward_output_real_part.dimension(0), input.dimension(0));
	VERIFY_IS_EQUAL(reverse_output_real_part.dimension(0), input.dimension(0));

	VERIFY_IS_EQUAL(forward_output_imag_part.dimension(0), input.dimension(0));
	VERIFY_IS_EQUAL(reverse_output_imag_part.dimension(0), input.dimension(0));

	std::complex<float> forward_golden_result[5];
	std::complex<float> reverse_golden_result[5];


	forward_golden_result[0] = std::complex<float>( 15, 0);
	forward_golden_result[1] = std::complex<float>(-2.5, +3.44095480117793);
	forward_golden_result[2] = std::complex<float>(-2.5, +0.81229924058227);
	forward_golden_result[3] = std::complex<float>(-2.5, -0.81229924058227);
	forward_golden_result[4] = std::complex<float>(-2.5, -3.44095480117793);

	reverse_golden_result[0] = std::complex<float>( 3.0, 0);
	reverse_golden_result[1] = std::complex<float>(-0.5, -0.688190960235587);
	reverse_golden_result[2] = std::complex<float>(-0.5, -0.162459848116453);
	reverse_golden_result[3] = std::complex<float>(-0.5, +0.162459848116453);
	reverse_golden_result[4] = std::complex<float>(-0.5, +0.688190960235587);

	std::complex<float> c_offset(1.0, 1.0);
	float r_offset = 1.0;

	for(int i = 0; i < 5; ++i) {
	VERIFY_IS_APPROX(forward_output_both_parts(i) + c_offset, forward_golden_result[i] + c_offset);
	VERIFY_IS_APPROX(forward_output_real_part(i) + r_offset, forward_golden_result[i].real() + r_offset);
	VERIFY_IS_APPROX(forward_output_imag_part(i) + r_offset, forward_golden_result[i].imag() + r_offset);
	}

	for(int i = 0; i < 5; ++i) {
	VERIFY_IS_APPROX(reverse_output_both_parts(i) + c_offset, reverse_golden_result[i] + c_offset);
	VERIFY_IS_APPROX(reverse_output_real_part(i) + r_offset, reverse_golden_result[i].real() + r_offset);
	VERIFY_IS_APPROX(reverse_output_imag_part(i) + r_offset, reverse_golden_result[i].imag() + r_offset);
	}
	}


	template <int DataLayout, typename RealScalar, bool isComplexInput, int FFTResultType, int FFTDirection, int TensorRank>
	static void test_fft_real_input_energy() {

	Eigen::DSizes<ptrdiff_t, TensorRank> dimensions;
	ptrdiff_t total_size = 1;
	for (int i = 0; i < TensorRank; ++i) {
	dimensions[i] = rand() % 20 + 1;
	total_size *= dimensions[i];
	}
	const DSizes<ptrdiff_t, TensorRank> arr = dimensions;

	typedef std::conditional_t<isComplexInput == true, std::complex<RealScalar>, RealScalar> InputScalar;

	Tensor<InputScalar, TensorRank, DataLayout> input;
	input.resize(arr);
	input.setRandom();

	array<ptrdiff_t, TensorRank> fft;
	for (int i = 0; i < TensorRank; ++i) {
	fft[i] = i;
	}

	typedef std::conditional_t<FFTResultType == Eigen::BothParts, std::complex<RealScalar>, RealScalar> OutputScalar;
	Tensor<OutputScalar, TensorRank, DataLayout> output;
	output = input.template fft<FFTResultType, FFTDirection>(fft);

	for (int i = 0; i < TensorRank; ++i) {
	VERIFY_IS_EQUAL(output.dimension(i), input.dimension(i));
	}

	RealScalar energy_original = 0.0;
	RealScalar energy_after_fft = 0.0;

	for (int i = 0; i < total_size; ++i) {
	energy_original += numext::abs2(input(i));
	}

	for (int i = 0; i < total_size; ++i) {
	energy_after_fft += numext::abs2(output(i));
	}

	if(FFTDirection == FFT_FORWARD) {
	VERIFY_IS_APPROX(energy_original, energy_after_fft / total_size);
	}
	else {
	VERIFY_IS_APPROX(energy_original, energy_after_fft * total_size);
	}
	}

	template <typename RealScalar>
	static void test_fft_non_power_of_2_round_trip(int exponent) {
	int n = (1 << exponent) + 1;

	Eigen::DSizes<ptrdiff_t, 1> dimensions;
	dimensions[0] = n;
	const DSizes<ptrdiff_t, 1> arr = dimensions;
	Tensor<RealScalar, 1, ColMajor, ptrdiff_t> input;

	input.resize(arr);
	input.setRandom();

	array<int, 1> fft;
	fft[0] = 0;

	Tensor<std::complex<RealScalar>, 1, ColMajor> forward =
	input.template fft<BothParts, FFT_FORWARD>(fft);

	Tensor<RealScalar, 1, ColMajor, ptrdiff_t> output =
	forward.template fft<RealPart, FFT_REVERSE>(fft);

	for (int i = 0; i < n; ++i) {
	RealScalar tol = test_precision<RealScalar>() *
	(std::abs(input[i]) + std::abs(output[i]) + 1);
	VERIFY_IS_APPROX_OR_LESS_THAN(std::abs(input[i] - output[i]), tol);
	}
	}

	EIGEN_DECLARE_TEST(cxx11_tensor_fft) {
	test_fft_complex_input_golden();
	test_fft_real_input_golden();

	test_fft_2D_golden<ColMajor>();
	test_fft_2D_golden<RowMajor>();

	test_fft_real_input_energy<ColMajor, float, true, Eigen::BothParts, FFT_FORWARD, 1>();
	test_fft_real_input_energy<ColMajor, double, true, Eigen::BothParts, FFT_FORWARD, 1>();
	test_fft_real_input_energy<ColMajor, float, false, Eigen::BothParts, FFT_FORWARD, 1>();
	test_fft_real_input_energy<ColMajor, double, false, Eigen::BothParts, FFT_FORWARD, 1>();

	test_fft_real_input_energy<ColMajor, float, true, Eigen::BothParts, FFT_FORWARD, 2>();
	test_fft_real_input_energy<ColMajor, double, true, Eigen::BothParts, FFT_FORWARD, 2>();
	test_fft_real_input_energy<ColMajor, float, false, Eigen::BothParts, FFT_FORWARD, 2>();
	test_fft_real_input_energy<ColMajor, double, false, Eigen::BothParts, FFT_FORWARD, 2>();

	test_fft_real_input_energy<ColMajor, float, true, Eigen::BothParts, FFT_FORWARD, 3>();
	test_fft_real_input_energy<ColMajor, double, true, Eigen::BothParts, FFT_FORWARD, 3>();
	test_fft_real_input_energy<ColMajor, float, false, Eigen::BothParts, FFT_FORWARD, 3>();
	test_fft_real_input_energy<ColMajor, double, false, Eigen::BothParts, FFT_FORWARD, 3>();

	test_fft_real_input_energy<ColMajor, float, true, Eigen::BothParts, FFT_FORWARD, 4>();
	test_fft_real_input_energy<ColMajor, double, true, Eigen::BothParts, FFT_FORWARD, 4>();
	test_fft_real_input_energy<ColMajor, float, false, Eigen::BothParts, FFT_FORWARD, 4>();
	test_fft_real_input_energy<ColMajor, double, false, Eigen::BothParts, FFT_FORWARD, 4>();

	test_fft_real_input_energy<RowMajor, float, true, Eigen::BothParts, FFT_FORWARD, 1>();
	test_fft_real_input_energy<RowMajor, double, true, Eigen::BothParts, FFT_FORWARD, 1>();
	test_fft_real_input_energy<RowMajor, float, false, Eigen::BothParts, FFT_FORWARD, 1>();
	test_fft_real_input_energy<RowMajor, double, false, Eigen::BothParts, FFT_FORWARD, 1>();

	test_fft_real_input_energy<RowMajor, float, true, Eigen::BothParts, FFT_FORWARD, 2>();
	test_fft_real_input_energy<RowMajor, double, true, Eigen::BothParts, FFT_FORWARD, 2>();
	test_fft_real_input_energy<RowMajor, float, false, Eigen::BothParts, FFT_FORWARD, 2>();
	test_fft_real_input_energy<RowMajor, double, false, Eigen::BothParts, FFT_FORWARD, 2>();

	test_fft_real_input_energy<RowMajor, float, true, Eigen::BothParts, FFT_FORWARD, 3>();
	test_fft_real_input_energy<RowMajor, double, true, Eigen::BothParts, FFT_FORWARD, 3>();
	test_fft_real_input_energy<RowMajor, float, false, Eigen::BothParts, FFT_FORWARD, 3>();
	test_fft_real_input_energy<RowMajor, double, false, Eigen::BothParts, FFT_FORWARD, 3>();

	test_fft_real_input_energy<RowMajor, float, true, Eigen::BothParts, FFT_FORWARD, 4>();
	test_fft_real_input_energy<RowMajor, double, true, Eigen::BothParts, FFT_FORWARD, 4>();
	test_fft_real_input_energy<RowMajor, float, false, Eigen::BothParts, FFT_FORWARD, 4>();
	test_fft_real_input_energy<RowMajor, double, false, Eigen::BothParts, FFT_FORWARD, 4>();

	test_fft_non_power_of_2_round_trip<float>(7);
	test_fft_non_power_of_2_round_trip<double>(7);
	}