FireRedASR-AED / cpp /src /librosa /eigen3 /bench /sparse_cholesky.cpp

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	// #define EIGEN_TAUCS_SUPPORT
	// #define EIGEN_CHOLMOD_SUPPORT
	#include <iostream>
	#include <Eigen/Sparse>

	// g++ -DSIZE=10000 -DDENSITY=0.001 sparse_cholesky.cpp -I.. -DDENSEMATRI -O3 -g0 -DNDEBUG -DNBTRIES=1 -I /home/gael/Coding/LinearAlgebra/taucs_full/src/ -I/home/gael/Coding/LinearAlgebra/taucs_full/build/linux/ -L/home/gael/Coding/LinearAlgebra/taucs_full/lib/linux/ -ltaucs /home/gael/Coding/LinearAlgebra/GotoBLAS/libgoto.a -lpthread -I /home/gael/Coding/LinearAlgebra/SuiteSparse/CHOLMOD/Include/ $CHOLLIB -I /home/gael/Coding/LinearAlgebra/SuiteSparse/UFconfig/ /home/gael/Coding/LinearAlgebra/SuiteSparse/CCOLAMD/Lib/libccolamd.a /home/gael/Coding/LinearAlgebra/SuiteSparse/CHOLMOD/Lib/libcholmod.a -lmetis /home/gael/Coding/LinearAlgebra/SuiteSparse/AMD/Lib/libamd.a /home/gael/Coding/LinearAlgebra/SuiteSparse/CAMD/Lib/libcamd.a /home/gael/Coding/LinearAlgebra/SuiteSparse/CCOLAMD/Lib/libccolamd.a /home/gael/Coding/LinearAlgebra/SuiteSparse/COLAMD/Lib/libcolamd.a -llapack && ./a.out

	#define NOGMM
	#define NOMTL

	#ifndef SIZE
	#define SIZE 10
	#endif

	#ifndef DENSITY
	#define DENSITY 0.01
	#endif

	#ifndef REPEAT
	#define REPEAT 1
	#endif

	#include "BenchSparseUtil.h"

	#ifndef MINDENSITY
	#define MINDENSITY 0.0004
	#endif

	#ifndef NBTRIES
	#define NBTRIES 10
	#endif

	#define BENCH(X) \
	timer.reset(); \
	for (int _j=0; _j<NBTRIES; ++_j) { \
	timer.start(); \
	for (int _k=0; _k<REPEAT; ++_k) { \
	X \
	} timer.stop(); }

	// typedef SparseMatrix<Scalar,UpperTriangular> EigenSparseTriMatrix;
	typedef SparseMatrix<Scalar,SelfAdjoint\|LowerTriangular> EigenSparseSelfAdjointMatrix;

	void fillSpdMatrix(float density, int rows, int cols, EigenSparseSelfAdjointMatrix& dst)
	{
	dst.startFill(rowscolsdensity);
	for(int j = 0; j < cols; j++)
	{
	dst.fill(j,j) = internal::random<Scalar>(10,20);
	for(int i = j+1; i < rows; i++)
	{
	Scalar v = (internal::random<float>(0,1) < density) ? internal::random<Scalar>() : 0;
	if (v!=0)
	dst.fill(i,j) = v;
	}

	}
	dst.endFill();
	}

	#include <Eigen/Cholesky>

	template<int Backend>
	void doEigen(const char* name, const EigenSparseSelfAdjointMatrix& sm1, int flags = 0)
	{
	std::cout << name << "..." << std::flush;
	BenchTimer timer;
	timer.start();
	SparseLLT<EigenSparseSelfAdjointMatrix,Backend> chol(sm1, flags);
	timer.stop();
	std::cout << ":\t" << timer.value() << endl;

	std::cout << " nnz: " << sm1.nonZeros() << " => " << chol.matrixL().nonZeros() << "\n";
	// std::cout << "sparse\n" << chol.matrixL() << "%\n";
	}

	int main(int argc, char *argv[])
	{
	int rows = SIZE;
	int cols = SIZE;
	float density = DENSITY;
	BenchTimer timer;

	VectorXf b = VectorXf::Random(cols);
	VectorXf x = VectorXf::Random(cols);

	bool densedone = false;

	//for (float density = DENSITY; density>=MINDENSITY; density*=0.5)
	// float density = 0.5;
	{
	EigenSparseSelfAdjointMatrix sm1(rows, cols);
	std::cout << "Generate sparse matrix (might take a while)...\n";
	fillSpdMatrix(density, rows, cols, sm1);
	std::cout << "DONE\n\n";

	// dense matrices
	#ifdef DENSEMATRIX
	if (!densedone)
	{
	densedone = true;
	std::cout << "Eigen Dense\t" << density*100 << "%\n";
	DenseMatrix m1(rows,cols);
	eiToDense(sm1, m1);
	m1 = (m1 + m1.transpose()).eval();
	m1.diagonal() *= 0.5;

	// BENCH(LLT<DenseMatrix> chol(m1);)
	// std::cout << "dense:\t" << timer.value() << endl;

	BenchTimer timer;
	timer.start();
	LLT<DenseMatrix> chol(m1);
	timer.stop();
	std::cout << "dense:\t" << timer.value() << endl;
	int count = 0;
	for (int j=0; j<cols; ++j)
	for (int i=j; i<rows; ++i)
	if (!internal::isMuchSmallerThan(internal::abs(chol.matrixL()(i,j)), 0.1))
	count++;
	std::cout << "dense: " << "nnz = " << count << "\n";
	// std::cout << "dense:\n" << m1 << "\n\n" << chol.matrixL() << endl;
	}
	#endif

	// eigen sparse matrices
	doEigen<Eigen::DefaultBackend>("Eigen/Sparse", sm1, Eigen::IncompleteFactorization);

	#ifdef EIGEN_CHOLMOD_SUPPORT
	doEigen<Eigen::Cholmod>("Eigen/Cholmod", sm1, Eigen::IncompleteFactorization);
	#endif

	#ifdef EIGEN_TAUCS_SUPPORT
	doEigen<Eigen::Taucs>("Eigen/Taucs", sm1, Eigen::IncompleteFactorization);
	#endif

	#if 0
	// TAUCS
	{
	taucs_ccs_matrix A = sm1.asTaucsMatrix();

	//BENCH(taucs_ccs_matrix* chol = taucs_ccs_factor_llt(&A, 0, 0);)
	// BENCH(taucs_supernodal_factor_to_ccs(taucs_ccs_factor_llt_ll(&A));)
	// std::cout << "taucs:\t" << timer.value() << endl;

	taucs_ccs_matrix* chol = taucs_ccs_factor_llt(&A, 0, 0);

	for (int j=0; j<cols; ++j)
	{
	for (int i=chol->colptr[j]; i<chol->colptr[j+1]; ++i)
	std::cout << chol->values.d[i] << " ";
	}
	}

	// CHOLMOD
	#ifdef EIGEN_CHOLMOD_SUPPORT
	{
	cholmod_common c;
	cholmod_start (&c);
	cholmod_sparse A;
	cholmod_factor *L;

	A = sm1.asCholmodMatrix();
	BenchTimer timer;
	// timer.reset();
	timer.start();
	std::vector<int> perm(cols);
	// std::vector<int> set(ncols);
	for (int i=0; i<cols; ++i)
	perm[i] = i;
	// c.nmethods = 1;
	// c.method[0] = 1;

	c.nmethods = 1;
	c.method [0].ordering = CHOLMOD_NATURAL;
	c.postorder = 0;
	c.final_ll = 1;

	L = cholmod_analyze_p(&A, &perm[0], &perm[0], cols, &c);
	timer.stop();
	std::cout << "cholmod/analyze:\t" << timer.value() << endl;
	timer.reset();
	timer.start();
	cholmod_factorize(&A, L, &c);
	timer.stop();
	std::cout << "cholmod/factorize:\t" << timer.value() << endl;

	cholmod_sparse* cholmat = cholmod_factor_to_sparse(L, &c);

	cholmod_print_factor(L, "Factors", &c);

	cholmod_print_sparse(cholmat, "Chol", &c);
	cholmod_write_sparse(stdout, cholmat, 0, 0, &c);
	//
	// cholmod_print_sparse(&A, "A", &c);
	// cholmod_write_sparse(stdout, &A, 0, 0, &c);


	// for (int j=0; j<cols; ++j)
	// {
	// for (int i=chol->colptr[j]; i<chol->colptr[j+1]; ++i)
	// std::cout << chol->values.s[i] << " ";
	// }
	}
	#endif

	#endif



	}


	return 0;
	}