test/cuda_basic.cu - external/gitlab.com/libeigen/eigen - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2015-2016 Gael Guennebaud <gael.guennebaud@inria.fr>
 //
 // 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/.

 // workaround issue between gcc >= 4.7 and cuda 5.5
 #if (defined __GNUC__) && (__GNUC__>4 || __GNUC_MINOR__>=7)
   #undef _GLIBCXX_ATOMIC_BUILTINS
   #undef _GLIBCXX_USE_INT128
 #endif

 #define EIGEN_TEST_NO_LONGDOUBLE
 #define EIGEN_TEST_NO_COMPLEX
 #define EIGEN_TEST_FUNC cuda_basic
 #define EIGEN_DEFAULT_DENSE_INDEX_TYPE int

 #include <math_constants.h>
 #include <cuda.h>
 #include "main.h"
 #include "cuda_common.h"

 // Check that dense modules can be properly parsed by nvcc
 #include <Eigen/Dense>

 // struct Foo{
 //   EIGEN_DEVICE_FUNC
 //   void operator()(int i, const float* mats, float* vecs) const {
 //     using namespace Eigen;
 //   //   Matrix3f M(data);
 //   //   Vector3f x(data+9);
 //   //   Map<Vector3f>(data+9) = M.inverse() * x;
 //     Matrix3f M(mats+i/16);
 //     Vector3f x(vecs+i*3);
 //   //   using std::min;
 //   //   using std::sqrt;
 //     Map<Vector3f>(vecs+i*3) << x.minCoeff(), 1, 2;// / x.dot(x);//(M.inverse() *  x) / x.x();
 //     //x = x*2 + x.y() * x + x * x.maxCoeff() - x / x.sum();
 //   }
 // };

 template<typename T>
 struct coeff_wise {
   EIGEN_DEVICE_FUNC
   void operator()(int i, const typename T::Scalar* in, typename T::Scalar* out) const
   {
     using namespace Eigen;
     T x1(in+i);
     T x2(in+i+1);
     T x3(in+i+2);
     Map<T> res(out+i*T::MaxSizeAtCompileTime);

     res.array() += (in[0] * x1 + x2).array() * x3.array();
   }
 };

 template<typename T>
 struct replicate {
   EIGEN_DEVICE_FUNC
   void operator()(int i, const typename T::Scalar* in, typename T::Scalar* out) const
   {
     using namespace Eigen;
     T x1(in+i);
     int step   = x1.size() * 4;
     int stride = 3 * step;

     typedef Map<Array<typename T::Scalar,Dynamic,Dynamic> > MapType;
     MapType(out+i*stride+0*step, x1.rows()*2, x1.cols()*2) = x1.replicate(2,2);
     MapType(out+i*stride+1*step, x1.rows()*3, x1.cols()) = in[i] * x1.colwise().replicate(3);
     MapType(out+i*stride+2*step, x1.rows(), x1.cols()*3) = in[i] * x1.rowwise().replicate(3);
   }
 };

 template<typename T>
 struct redux {
   EIGEN_DEVICE_FUNC
   void operator()(int i, const typename T::Scalar* in, typename T::Scalar* out) const
   {
     using namespace Eigen;
     int N = 10;
     T x1(in+i);
     out[i*N+0] = x1.minCoeff();
     out[i*N+1] = x1.maxCoeff();
     out[i*N+2] = x1.sum();
     out[i*N+3] = x1.prod();
     out[i*N+4] = x1.matrix().squaredNorm();
     out[i*N+5] = x1.matrix().norm();
     out[i*N+6] = x1.colwise().sum().maxCoeff();
     out[i*N+7] = x1.rowwise().maxCoeff().sum();
     out[i*N+8] = x1.matrix().colwise().squaredNorm().sum();
   }
 };

 template<typename T1, typename T2>
 struct prod_test {
   EIGEN_DEVICE_FUNC
   void operator()(int i, const typename T1::Scalar* in, typename T1::Scalar* out) const
   {
     using namespace Eigen;
     typedef Matrix<typename T1::Scalar, T1::RowsAtCompileTime, T2::ColsAtCompileTime> T3;
     T1 x1(in+i);
     T2 x2(in+i+1);
     Map<T3> res(out+i*T3::MaxSizeAtCompileTime);
     res += in[i] * x1 * x2;
   }
 };

 template<typename T1, typename T2>
 struct diagonal {
   EIGEN_DEVICE_FUNC
   void operator()(int i, const typename T1::Scalar* in, typename T1::Scalar* out) const
   {
     using namespace Eigen;
     T1 x1(in+i);
     Map<T2> res(out+i*T2::MaxSizeAtCompileTime);
     res += x1.diagonal();
   }
 };

 template<typename T>
 struct eigenvalues {
   EIGEN_DEVICE_FUNC
   void operator()(int i, const typename T::Scalar* in, typename T::Scalar* out) const
   {
     using namespace Eigen;
     typedef Matrix<typename T::Scalar, T::RowsAtCompileTime, 1> Vec;
     T M(in+i);
     Map<Vec> res(out+i*Vec::MaxSizeAtCompileTime);
     T A = M*M.adjoint();
     SelfAdjointEigenSolver<T> eig;
     eig.computeDirect(M);
     res = eig.eigenvalues();
   }
 };

 void test_cuda_basic()
 {
   ei_test_init_cuda();

   int nthreads = 100;
   Eigen::VectorXf in, out;

   #ifndef __CUDA_ARCH__
   int data_size = nthreads * 512;
   in.setRandom(data_size);
   out.setRandom(data_size);
   #endif

   CALL_SUBTEST( run_and_compare_to_cuda(coeff_wise<Vector3f>(), nthreads, in, out) );
   CALL_SUBTEST( run_and_compare_to_cuda(coeff_wise<Array44f>(), nthreads, in, out) );

   CALL_SUBTEST( run_and_compare_to_cuda(replicate<Array4f>(), nthreads, in, out) );
   CALL_SUBTEST( run_and_compare_to_cuda(replicate<Array33f>(), nthreads, in, out) );

   CALL_SUBTEST( run_and_compare_to_cuda(redux<Array4f>(), nthreads, in, out) );
   CALL_SUBTEST( run_and_compare_to_cuda(redux<Matrix3f>(), nthreads, in, out) );

   CALL_SUBTEST( run_and_compare_to_cuda(prod_test<Matrix3f,Matrix3f>(), nthreads, in, out) );
   CALL_SUBTEST( run_and_compare_to_cuda(prod_test<Matrix4f,Vector4f>(), nthreads, in, out) );

   CALL_SUBTEST( run_and_compare_to_cuda(diagonal<Matrix3f,Vector3f>(), nthreads, in, out) );
   CALL_SUBTEST( run_and_compare_to_cuda(diagonal<Matrix4f,Vector4f>(), nthreads, in, out) );

   CALL_SUBTEST( run_and_compare_to_cuda(eigenvalues<Matrix3f>(), nthreads, in, out) );
   CALL_SUBTEST( run_and_compare_to_cuda(eigenvalues<Matrix2f>(), nthreads, in, out) );

 }
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2015-2016 Gael Guennebaud <gael.guennebaud@inria.fr>
	//
	// 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/.

	// workaround issue between gcc >= 4.7 and cuda 5.5
	#if (defined __GNUC__) && (__GNUC__>4 \|\| __GNUC_MINOR__>=7)
	#undef _GLIBCXX_ATOMIC_BUILTINS
	#undef _GLIBCXX_USE_INT128
	#endif

	#define EIGEN_TEST_NO_LONGDOUBLE
	#define EIGEN_TEST_NO_COMPLEX
	#define EIGEN_TEST_FUNC cuda_basic
	#define EIGEN_DEFAULT_DENSE_INDEX_TYPE int

	#include <math_constants.h>
	#include <cuda.h>
	#include "main.h"
	#include "cuda_common.h"

	// Check that dense modules can be properly parsed by nvcc
	#include <Eigen/Dense>

	// struct Foo{
	// EIGEN_DEVICE_FUNC
	// void operator()(int i, const float* mats, float* vecs) const {
	// using namespace Eigen;
	// // Matrix3f M(data);
	// // Vector3f x(data+9);
	// // Map<Vector3f>(data+9) = M.inverse() * x;
	// Matrix3f M(mats+i/16);
	// Vector3f x(vecs+i*3);
	// // using std::min;
	// // using std::sqrt;
	// Map<Vector3f>(vecs+i3) << x.minCoeff(), 1, 2;// / x.dot(x);//(M.inverse() x) / x.x();
	// //x = x2 + x.y() x + x * x.maxCoeff() - x / x.sum();
	// }
	// };

	template<typename T>
	struct coeff_wise {
	EIGEN_DEVICE_FUNC
	void operator()(int i, const typename T::Scalar* in, typename T::Scalar* out) const
	{
	using namespace Eigen;
	T x1(in+i);
	T x2(in+i+1);
	T x3(in+i+2);
	Map<T> res(out+i*T::MaxSizeAtCompileTime);

	res.array() += (in[0] * x1 + x2).array() * x3.array();
	}
	};

	template<typename T>
	struct replicate {
	EIGEN_DEVICE_FUNC
	void operator()(int i, const typename T::Scalar* in, typename T::Scalar* out) const
	{
	using namespace Eigen;
	T x1(in+i);
	int step = x1.size() * 4;
	int stride = 3 * step;

	typedef Map<Array<typename T::Scalar,Dynamic,Dynamic> > MapType;
	MapType(out+istride+0step, x1.rows()2, x1.cols()2) = x1.replicate(2,2);
	MapType(out+istride+1step, x1.rows()3, x1.cols()) = in[i] x1.colwise().replicate(3);
	MapType(out+istride+2step, x1.rows(), x1.cols()3) = in[i] x1.rowwise().replicate(3);
	}
	};

	template<typename T>
	struct redux {
	EIGEN_DEVICE_FUNC
	void operator()(int i, const typename T::Scalar* in, typename T::Scalar* out) const
	{
	using namespace Eigen;
	int N = 10;
	T x1(in+i);
	out[i*N+0] = x1.minCoeff();
	out[i*N+1] = x1.maxCoeff();
	out[i*N+2] = x1.sum();
	out[i*N+3] = x1.prod();
	out[i*N+4] = x1.matrix().squaredNorm();
	out[i*N+5] = x1.matrix().norm();
	out[i*N+6] = x1.colwise().sum().maxCoeff();
	out[i*N+7] = x1.rowwise().maxCoeff().sum();
	out[i*N+8] = x1.matrix().colwise().squaredNorm().sum();
	}
	};

	template<typename T1, typename T2>
	struct prod_test {
	EIGEN_DEVICE_FUNC
	void operator()(int i, const typename T1::Scalar* in, typename T1::Scalar* out) const
	{
	using namespace Eigen;
	typedef Matrix<typename T1::Scalar, T1::RowsAtCompileTime, T2::ColsAtCompileTime> T3;
	T1 x1(in+i);
	T2 x2(in+i+1);
	Map<T3> res(out+i*T3::MaxSizeAtCompileTime);
	res += in[i] * x1 * x2;
	}
	};

	template<typename T1, typename T2>
	struct diagonal {
	EIGEN_DEVICE_FUNC
	void operator()(int i, const typename T1::Scalar* in, typename T1::Scalar* out) const
	{
	using namespace Eigen;
	T1 x1(in+i);
	Map<T2> res(out+i*T2::MaxSizeAtCompileTime);
	res += x1.diagonal();
	}
	};

	template<typename T>
	struct eigenvalues {
	EIGEN_DEVICE_FUNC
	void operator()(int i, const typename T::Scalar* in, typename T::Scalar* out) const
	{
	using namespace Eigen;
	typedef Matrix<typename T::Scalar, T::RowsAtCompileTime, 1> Vec;
	T M(in+i);
	Map<Vec> res(out+i*Vec::MaxSizeAtCompileTime);
	T A = M*M.adjoint();
	SelfAdjointEigenSolver<T> eig;
	eig.computeDirect(M);
	res = eig.eigenvalues();
	}
	};

	void test_cuda_basic()
	{
	ei_test_init_cuda();

	int nthreads = 100;
	Eigen::VectorXf in, out;

	#ifndef __CUDA_ARCH__
	int data_size = nthreads * 512;
	in.setRandom(data_size);
	out.setRandom(data_size);
	#endif

	CALL_SUBTEST( run_and_compare_to_cuda(coeff_wise<Vector3f>(), nthreads, in, out) );
	CALL_SUBTEST( run_and_compare_to_cuda(coeff_wise<Array44f>(), nthreads, in, out) );

	CALL_SUBTEST( run_and_compare_to_cuda(replicate<Array4f>(), nthreads, in, out) );
	CALL_SUBTEST( run_and_compare_to_cuda(replicate<Array33f>(), nthreads, in, out) );

	CALL_SUBTEST( run_and_compare_to_cuda(redux<Array4f>(), nthreads, in, out) );
	CALL_SUBTEST( run_and_compare_to_cuda(redux<Matrix3f>(), nthreads, in, out) );

	CALL_SUBTEST( run_and_compare_to_cuda(prod_test<Matrix3f,Matrix3f>(), nthreads, in, out) );
	CALL_SUBTEST( run_and_compare_to_cuda(prod_test<Matrix4f,Vector4f>(), nthreads, in, out) );

	CALL_SUBTEST( run_and_compare_to_cuda(diagonal<Matrix3f,Vector3f>(), nthreads, in, out) );
	CALL_SUBTEST( run_and_compare_to_cuda(diagonal<Matrix4f,Vector4f>(), nthreads, in, out) );

	CALL_SUBTEST( run_and_compare_to_cuda(eigenvalues<Matrix3f>(), nthreads, in, out) );
	CALL_SUBTEST( run_and_compare_to_cuda(eigenvalues<Matrix2f>(), nthreads, in, out) );

	}