aten/src/ATen/native/BatchLinearAlgebra.cpp

#include <ATen/ATen.h>
#include <ATen/CPUApplyUtils.h>
#include <ATen/Dispatch.h>
#include <ATen/NativeFunctions.h>
#include <ATen/ExpandUtils.h>

#include <ATen/native/LinearAlgebraUtils.h>
#include <ATen/native/cpu/zmath.h>
#include <ATen/Parallel.h>

#include <TH/TH.h>  // for USE_LAPACK

#include <vector>

// First the required LAPACK implementations are registered here.
// A comment above the registered LAPACK routine suggest which batched
// linear algebra function uses that routine
#ifdef USE_LAPACK

// gesv
extern "C" void zgesv_(int *n, int *nrhs, std::complex<double> *a, int *lda, int *ipiv, std::complex<double> *b, int *ldb, int *info);
extern "C" void cgesv_(int *n, int *nrhs, std::complex<float> *a, int *lda, int *ipiv, std::complex<float> *b, int *ldb, int *info);
extern "C" void dgesv_(int *n, int *nrhs, double *a, int *lda, int *ipiv, double *b, int *ldb, int *info);
extern "C" void sgesv_(int *n, int *nrhs, float *a, int *lda, int *ipiv, float *b, int *ldb, int *info);

// getrf
extern "C" void zgetrf_(int *m, int *n, std::complex<double> *a, int *lda, int *ipiv, int *info);
extern "C" void cgetrf_(int *m, int *n, std::complex<float> *a, int *lda, int *ipiv, int *info);
extern "C" void dgetrf_(int *m, int *n, double *a, int *lda, int *ipiv, int *info);
extern "C" void sgetrf_(int *m, int *n, float *a, int *lda, int *ipiv, int *info);

// getri
extern "C" void zgetri_(int *n, std::complex<double> *a, int *lda, int *ipiv, std::complex<double> *work, int *lwork, int *info);
extern "C" void cgetri_(int *n, std::complex<float> *a, int *lda, int *ipiv, std::complex<float> *work, int *lwork, int *info);
extern "C" void dgetri_(int *n, double *a, int *lda, int *ipiv, double *work, int *lwork, int *info);
extern "C" void sgetri_(int *n, float *a, int *lda, int *ipiv, float *work, int *lwork, int *info);

// potrs
extern "C" void zpotrs_(char *uplo, int *n, int *nrhs, std::complex<double> *a, int *lda, std::complex<double> *b, int *ldb, int *info);
extern "C" void cpotrs_(char *uplo, int *n, int *nrhs, std::complex<float> *a, int *lda, std::complex<float> *b, int *ldb, int *info);
extern "C" void dpotrs_(char *uplo, int *n, int *nrhs, double *a, int *lda, double *b, int *ldb, int *info);
extern "C" void spotrs_(char *uplo, int *n, int *nrhs, float *a, int *lda, float *b, int *ldb, int *info);

// potrf
extern "C" void zpotrf_(char *uplo, int *n, std::complex<double> *a, int *lda, int *info);
extern "C" void cpotrf_(char *uplo, int *n, std::complex<float> *a, int *lda, int *info);
extern "C" void dpotrf_(char *uplo, int *n, double *a, int *lda, int *info);
extern "C" void spotrf_(char *uplo, int *n, float *a, int *lda, int *info);

// trtrs
extern "C" void ztrtrs_(char *uplo, char *trans, char *diag, int *n, int *nrhs, std::complex<double> *a, int *lda, std::complex<double> *b, int *ldb, int *info);
extern "C" void ctrtrs_(char *uplo, char *trans, char *diag, int *n, int *nrhs, std::complex<float> *a, int *lda, std::complex<float> *b, int *ldb, int *info);
extern "C" void dtrtrs_(char *uplo, char *trans, char *diag, int *n, int *nrhs, double *a, int *lda, double *b, int *ldb, int *info);
extern "C" void strtrs_(char *uplo, char *trans, char *diag, int *n, int *nrhs, float *a, int *lda, float *b, int *ldb, int *info);

// geqrf
extern "C" void zgeqrf_(int *m, int *n, std::complex<double> *a, int *lda, std::complex<double> *tau, std::complex<double> *work, int *lwork, int *info);
extern "C" void cgeqrf_(int *m, int *n, std::complex<float> *a, int *lda, std::complex<float> *tau, std::complex<float> *work, int *lwork, int *info);
extern "C" void dgeqrf_(int *m, int *n, double *a, int *lda, double *tau, double *work, int *lwork, int *info);
extern "C" void sgeqrf_(int *m, int *n, float *a, int *lda, float *tau, float *work, int *lwork, int *info);

// orgqr
extern "C" void zungqr_(int *m, int *n, int *k, std::complex<double> *a, int *lda, std::complex<double> *tau, std::complex<double> *work, int *lwork, int *info);
extern "C" void cungqr_(int *m, int *n, int *k, std::complex<float> *a, int *lda, std::complex<float> *tau, std::complex<float> *work, int *lwork, int *info);
extern "C" void dorgqr_(int *m, int *n, int *k, double *a, int *lda, double *tau, double *work, int *lwork, int *info);
extern "C" void sorgqr_(int *m, int *n, int *k, float *a, int *lda, float *tau, float *work, int *lwork, int *info);

// syev
extern "C" void zheev_(char *jobz, char *uplo, int *n, std::complex<double> *a, int *lda, double *w, std::complex<double> *work, int *lwork, double *rwork, int *info);
extern "C" void cheev_(char *jobz, char *uplo, int *n, std::complex<float> *a, int *lda, float *w, std::complex<float> *work, int *lwork, float *rwork, int *info);
extern "C" void dsyev_(char *jobz, char *uplo, int *n, double *a, int *lda, double *w, double *work, int *lwork, int *info);
extern "C" void ssyev_(char *jobz, char *uplo, int *n, float *a, int *lda, float *w, float *work, int *lwork, int *info);

// gesdd
extern "C" void zgesdd_(char *jobz, int *m, int *n, std::complex<double> *a, int *lda,
                        double *s, std::complex<double> *u, int *ldu, std::complex<double> *vt, int *ldvt, std::complex<double> *work, int *lwork, double *rwork, int *iwork, int *info);
extern "C" void cgesdd_(char *jobz, int *m, int *n, std::complex<float> *a, int *lda,
                        float *s, std::complex<float> *u, int *ldu, std::complex<float> *vt, int *ldvt, std::complex<float> *work, int *lwork, float *rwork, int *iwork, int *info);
extern "C" void dgesdd_(char *jobz, int *m, int *n, double *a, int *lda,
                        double *s, double *u, int *ldu, double *vt, int *ldvt, double *work, int *lwork, int *iwork, int *info);
extern "C" void sgesdd_(char *jobz, int *m, int *n, float *a, int *lda,
                        float *s, float *u, int *ldu, float *vt, int *ldvt, float *work, int *lwork, int *iwork, int *info);

// getrs
extern "C" void zgetrs_(char *trans, int *n, int *nrhs, std::complex<double> *a, int *lda, int *ipiv, std::complex<double> *b, int *ldb, int *info);
extern "C" void cgetrs_(char *trans, int *n, int *nrhs, std::complex<float> *a, int *lda, int *ipiv, std::complex<float> *b, int *ldb, int *info);
extern "C" void dgetrs_(char *trans, int *n, int *nrhs, double *a, int *lda, int *ipiv, double *b, int *ldb, int *info);
extern "C" void sgetrs_(char *trans, int *n, int *nrhs, float *a, int *lda, int *ipiv, float *b, int *ldb, int *info);
#endif

namespace at {
namespace native {

#ifdef USE_LAPACK
// Define the per-batch functions to be used in the main implementation of the batched
// linear algebra operations
template<class scalar_t>
void lapackSolve(int n, int nrhs, scalar_t *a, int lda, int *ipiv, scalar_t *b, int ldb, int *info);

template<class scalar_t>
void lapackLu(int m, int n, scalar_t *a, int lda, int *ipiv, int *info);

template<class scalar_t>
void lapackGetri(int n, scalar_t *a, int lda, int *ipiv, scalar_t *work, int lwork, int *info);

template<class scalar_t>
void lapackCholeskySolve(char uplo, int n, int nrhs, scalar_t *a, int lda, scalar_t *b, int ldb, int *info);

template<class scalar_t>
void lapackCholesky(char uplo, int n, scalar_t *a, int lda, int *info);

template<class scalar_t>
void lapackTriangularSolve(char uplo, char trans, char diag, int n, int nrhs, scalar_t *a, int lda, scalar_t *b, int ldb, int *info);

template<class scalar_t>
void lapackGeqrf(int m, int n, scalar_t *a, int lda, scalar_t *tau, scalar_t *work, int lwork, int *info);

template<class scalar_t>
void lapackOrgqr(int m, int n, int k, scalar_t *a, int lda, scalar_t *tau, scalar_t *work, int lwork, int *info);

template<class scalar_t, class value_t=scalar_t>
void lapackSymeig(char jobz, char uplo, int n, scalar_t *a, int lda, value_t *w, scalar_t *work, int lwork, value_t *rwork, int *info);

template<class scalar_t, class value_t=scalar_t>
void lapackSvd(char jobz, int m, int n, scalar_t *a, int lda,
               value_t *s, scalar_t *u, int ldu, scalar_t *vt, int ldvt, scalar_t *work, int lwork, value_t *rwork, int *iwork, int *info);

template<class scalar_t>
void lapackLuSolve(char trans, int n, int nrhs, scalar_t *a, int lda, int *ipiv, scalar_t *b, int ldb, int *info);


template<> void lapackSolve<c10::complex<double>>(int n, int nrhs, c10::complex<double> *a, int lda, int *ipiv, c10::complex<double> *b, int ldb, int *info) {
  zgesv_(&n, &nrhs, reinterpret_cast<std::complex<double>*>(a), &lda, ipiv, reinterpret_cast<std::complex<double>*>(b), &ldb, info);
}

template<> void lapackSolve<c10::complex<float>>(int n, int nrhs, c10::complex<float> *a, int lda, int *ipiv, c10::complex<float> *b, int ldb, int *info) {
  cgesv_(&n, &nrhs, reinterpret_cast<std::complex<float>*>(a), &lda, ipiv, reinterpret_cast<std::complex<float>*>(b), &ldb, info);
}

template<> void lapackSolve<double>(int n, int nrhs, double *a, int lda, int *ipiv, double *b, int ldb, int *info) {
  dgesv_(&n, &nrhs, a, &lda, ipiv, b, &ldb, info);
}

template<> void lapackSolve<float>(int n, int nrhs, float *a, int lda, int *ipiv, float *b, int ldb, int *info) {
  sgesv_(&n, &nrhs, a, &lda, ipiv, b, &ldb, info);
}

template<> void lapackGetri<c10::complex<double>>(int n, c10::complex<double> *a, int lda, int *ipiv, c10::complex<double> *work, int lwork, int *info) {
  zgetri_(&n, reinterpret_cast<std::complex<double>*>(a), &lda, ipiv, reinterpret_cast<std::complex<double>*>(work), &lwork, info);
}

template<> void lapackGetri<c10::complex<float>>(int n, c10::complex<float> *a, int lda, int *ipiv, c10::complex<float> *work, int lwork, int *info) {
  cgetri_(&n, reinterpret_cast<std::complex<float>*>(a), &lda, ipiv, reinterpret_cast<std::complex<float>*>(work), &lwork, info);
}

template<> void lapackGetri<double>(int n, double *a, int lda, int *ipiv, double *work, int lwork, int *info) {
  dgetri_(&n, a, &lda, ipiv, work, &lwork, info);
}

template<> void lapackGetri<float>(int n, float *a, int lda, int *ipiv, float *work, int lwork, int *info) {
  sgetri_(&n, a, &lda, ipiv, work, &lwork, info);
}

template<> void lapackLu<c10::complex<double>>(int m, int n, c10::complex<double> *a, int lda, int *ipiv, int *info) {
  zgetrf_(&m, &n, reinterpret_cast<std::complex<double>*>(a), &lda, ipiv, info);
}

template<> void lapackLu<c10::complex<float>>(int m, int n, c10::complex<float> *a, int lda, int *ipiv, int *info) {
  cgetrf_(&m, &n, reinterpret_cast<std::complex<float>*>(a), &lda, ipiv, info);
}

template<> void lapackLu<double>(int m, int n, double *a, int lda, int *ipiv, int *info) {
  dgetrf_(&m, &n, a, &lda, ipiv, info);
}

template<> void lapackLu<float>(int m, int n, float *a, int lda, int *ipiv, int *info) {
  sgetrf_(&m, &n, a, &lda, ipiv, info);
}

template<> void lapackCholeskySolve<c10::complex<double>>(char uplo, int n, int nrhs, c10::complex<double> *a, int lda, c10::complex<double> *b, int ldb, int *info) {
  zpotrs_(&uplo, &n, &nrhs, reinterpret_cast<std::complex<double>*>(a), &lda, reinterpret_cast<std::complex<double>*>(b), &ldb, info);
}

template<> void lapackCholeskySolve<c10::complex<float>>(char uplo, int n, int nrhs, c10::complex<float> *a, int lda, c10::complex<float> *b, int ldb, int *info) {
  cpotrs_(&uplo, &n, &nrhs, reinterpret_cast<std::complex<float>*>(a), &lda, reinterpret_cast<std::complex<float>*>(b), &ldb, info);
}

template<> void lapackCholeskySolve<double>(char uplo, int n, int nrhs, double *a, int lda, double *b, int ldb, int *info) {
  dpotrs_(&uplo, &n, &nrhs, a, &lda, b, &ldb, info);
}

template<> void lapackCholeskySolve<float>(char uplo, int n, int nrhs, float *a, int lda, float *b, int ldb, int *info) {
  spotrs_(&uplo, &n, &nrhs, a, &lda, b, &ldb, info);
}

template<> void lapackCholesky<c10::complex<double>>(char uplo, int n, c10::complex<double> *a, int lda, int *info) {
  zpotrf_(&uplo, &n, reinterpret_cast<std::complex<double>*>(a), &lda, info);
}

template<> void lapackCholesky<c10::complex<float>>(char uplo, int n, c10::complex<float> *a, int lda, int *info) {
  cpotrf_(&uplo, &n, reinterpret_cast<std::complex<float>*>(a), &lda, info);
}

template<> void lapackCholesky<double>(char uplo, int n, double *a, int lda, int *info) {
  dpotrf_(&uplo, &n, a, &lda, info);
}

template<> void lapackCholesky<float>(char uplo, int n, float *a, int lda, int *info) {
  spotrf_(&uplo, &n, a, &lda, info);
}

template<> void lapackTriangularSolve<c10::complex<double>>(char uplo, char trans, char diag, int n, int nrhs, c10::complex<double> *a, int lda, c10::complex<double> *b, int ldb, int *info) {
  ztrtrs_(&uplo, &trans, &diag, &n, &nrhs, reinterpret_cast<std::complex<double>*>(a), &lda, reinterpret_cast<std::complex<double>*>(b), &ldb, info);
}

template<> void lapackTriangularSolve<c10::complex<float>>(char uplo, char trans, char diag, int n, int nrhs, c10::complex<float> *a, int lda, c10::complex<float> *b, int ldb, int *info) {
  ctrtrs_(&uplo, &trans, &diag, &n, &nrhs, reinterpret_cast<std::complex<float>*>(a), &lda, reinterpret_cast<std::complex<float>*>(b), &ldb, info);
}

template<> void lapackTriangularSolve<double>(char uplo, char trans, char diag, int n, int nrhs, double *a, int lda, double *b, int ldb, int *info) {
  dtrtrs_(&uplo, &trans, &diag, &n, &nrhs, a, &lda, b, &ldb, info);
}

template<> void lapackTriangularSolve<float>(char uplo, char trans, char diag, int n, int nrhs, float *a, int lda, float *b, int ldb, int *info) {
  strtrs_(&uplo, &trans, &diag, &n, &nrhs, a, &lda, b, &ldb, info);
}

template<> void lapackGeqrf<c10::complex<double>>(int m, int n, c10::complex<double> *a, int lda, c10::complex<double> *tau, c10::complex<double> *work, int lwork, int *info) {
  zgeqrf_(&m, &n, reinterpret_cast<std::complex<double>*>(a), &lda, reinterpret_cast<std::complex<double>*>(tau), reinterpret_cast<std::complex<double>*>(work), &lwork, info);
}

template<> void lapackGeqrf<c10::complex<float>>(int m, int n, c10::complex<float> *a, int lda, c10::complex<float> *tau, c10::complex<float> *work, int lwork, int *info) {
  cgeqrf_(&m, &n, reinterpret_cast<std::complex<float>*>(a), &lda, reinterpret_cast<std::complex<float>*>(tau), reinterpret_cast<std::complex<float>*>(work), &lwork, info);
}

template<> void lapackGeqrf<double>(int m, int n, double *a, int lda, double *tau, double *work, int lwork, int *info) {
  dgeqrf_(&m, &n, a, &lda, tau, work, &lwork, info);
}

template<> void lapackGeqrf<float>(int m, int n, float *a, int lda, float *tau, float *work, int lwork, int *info) {
  sgeqrf_(&m, &n, a, &lda, tau, work, &lwork, info);
}

template<> void lapackOrgqr<c10::complex<double>>(int m, int n, int k, c10::complex<double> *a, int lda, c10::complex<double> *tau, c10::complex<double> *work, int lwork, int *info) {
  zungqr_(&m, &n, &k, reinterpret_cast<std::complex<double>*>(a), &lda, reinterpret_cast<std::complex<double>*>(tau), reinterpret_cast<std::complex<double>*>(work), &lwork, info);
}

template<> void lapackOrgqr<c10::complex<float>>(int m, int n, int k, c10::complex<float> *a, int lda, c10::complex<float> *tau, c10::complex<float> *work, int lwork, int *info) {
  cungqr_(&m, &n, &k, reinterpret_cast<std::complex<float>*>(a), &lda, reinterpret_cast<std::complex<float>*>(tau), reinterpret_cast<std::complex<float>*>(work), &lwork, info);
}

template<> void lapackOrgqr<double>(int m, int n, int k, double *a, int lda, double *tau, double *work, int lwork, int *info) {
  dorgqr_(&m, &n, &k, a, &lda, tau, work, &lwork, info);
}

template<> void lapackOrgqr<float>(int m, int n, int k, float *a, int lda, float *tau, float *work, int lwork, int *info) {
  sorgqr_(&m, &n, &k, a, &lda, tau, work, &lwork, info);
}

template<> void lapackSymeig<c10::complex<double>, double>(char jobz, char uplo, int n, c10::complex<double> *a, int lda, double *w, c10::complex<double> *work, int lwork, double *rwork, int *info) {
  zheev_(&jobz, &uplo, &n, reinterpret_cast<std::complex<double>*>(a), &lda, w, reinterpret_cast<std::complex<double>*>(work), &lwork, rwork, info);
}

template<> void lapackSymeig<c10::complex<float>, float>(char jobz, char uplo, int n, c10::complex<float> *a, int lda, float *w, c10::complex<float> *work, int lwork, float *rwork, int *info) {
  cheev_(&jobz, &uplo, &n, reinterpret_cast<std::complex<float>*>(a), &lda, w, reinterpret_cast<std::complex<float>*>(work), &lwork, rwork, info);
}

template<> void lapackSymeig<double>(char jobz, char uplo, int n, double *a, int lda, double *w, double *work, int lwork, double* rwork, int *info) {
  (void)rwork;  // unused
  dsyev_(&jobz, &uplo, &n, a, &lda, w, work, &lwork, info);
}

template<> void lapackSymeig<float>(char jobz, char uplo, int n, float *a, int lda, float *w, float *work, int lwork, float* rwork, int *info) {
  (void)rwork;  // unused
  ssyev_(&jobz, &uplo, &n, a, &lda, w, work, &lwork, info);
}

template<> void lapackSvd<c10::complex<double>, double>(char jobz, int m, int n, c10::complex<double> *a, int lda,
                                  double *s, c10::complex<double> *u, int ldu, c10::complex<double> *vt, int ldvt, c10::complex<double> *work, int lwork, double *rwork, int *iwork, int *info) {
  zgesdd_(&jobz, &m, &n, reinterpret_cast<std::complex<double>*>(a), &lda, s, reinterpret_cast<std::complex<double>*>(u), &ldu,
          reinterpret_cast<std::complex<double>*>(vt), &ldvt, reinterpret_cast<std::complex<double>*>(work), &lwork, rwork, iwork, info);
}

template<> void lapackSvd<c10::complex<float>, float>(char jobz, int m, int n, c10::complex<float> *a, int lda,
                                 float *s, c10::complex<float> *u, int ldu, c10::complex<float> *vt, int ldvt, c10::complex<float> *work, int lwork, float *rwork, int *iwork, int *info) {
  cgesdd_(&jobz, &m, &n, reinterpret_cast<std::complex<float>*>(a), &lda, s, reinterpret_cast<std::complex<float>*>(u), &ldu,
          reinterpret_cast<std::complex<float>*>(vt), &ldvt, reinterpret_cast<std::complex<float>*>(work), &lwork, rwork, iwork, info);
}

template<> void lapackSvd<double>(char jobz, int m, int n, double *a, int lda,
                                  double *s, double *u, int ldu, double *vt, int ldvt, double *work, int lwork, double *rwork, int *iwork, int *info) {
  dgesdd_(&jobz, &m, &n, a, &lda, s, u, &ldu, vt, &ldvt, work, &lwork, iwork, info);
}

template<> void lapackSvd<float>(char jobz, int m, int n, float *a, int lda,
                                 float *s, float *u, int ldu, float *vt, int ldvt, float *work, int lwork, float *rwork, int *iwork, int *info) {
  sgesdd_(&jobz, &m, &n, a, &lda, s, u, &ldu, vt, &ldvt, work, &lwork, iwork, info);
}

template<> void lapackLuSolve<c10::complex<double>>(char trans, int n, int nrhs, c10::complex<double> *a, int lda, int *ipiv, c10::complex<double> *b, int ldb, int *info) {
  zgetrs_(&trans, &n, &nrhs, reinterpret_cast<std::complex<double>*>(a), &lda, ipiv, reinterpret_cast<std::complex<double>*>(b), &ldb, info);
}

template<> void lapackLuSolve<c10::complex<float>>(char trans, int n, int nrhs, c10::complex<float> *a, int lda, int *ipiv, c10::complex<float> *b, int ldb, int *info) {
  cgetrs_(&trans, &n, &nrhs, reinterpret_cast<std::complex<float>*>(a), &lda, ipiv, reinterpret_cast<std::complex<float>*>(b), &ldb, info);
}

template<> void lapackLuSolve<double>(char trans, int n, int nrhs, double *a, int lda, int *ipiv, double *b, int ldb, int *info) {
  dgetrs_(&trans, &n, &nrhs, a, &lda, ipiv, b, &ldb, info);
}

template<> void lapackLuSolve<float>(char trans, int n, int nrhs, float *a, int lda, int *ipiv, float *b, int ldb, int *info) {
  sgetrs_(&trans, &n, &nrhs, a, &lda, ipiv, b, &ldb, info);
}
#endif

// Below of the definitions of the functions operating on a batch that are going to be dispatched
// in the main helper functions for the linear algebra operations

// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ solve ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

template<typename scalar_t>
static void apply_solve(Tensor& b, Tensor& A, std::vector<int64_t>& infos) {
#ifndef USE_LAPACK
  AT_ERROR("solve: LAPACK library not found in compilation");
#else
  auto A_data = A.data_ptr<scalar_t>();
  auto b_data = b.data_ptr<scalar_t>();
  auto A_mat_stride = matrixStride(A);
  auto b_mat_stride = matrixStride(b);
  auto batch_size = batchCount(A);
  auto n = A.size(-2);
  auto nrhs = b.size(-1);
  auto lda = std::max(int64_t{1}, n);

  auto ipiv = at::empty({n}, b.options().dtype(kInt));
  auto ipiv_data = ipiv.data_ptr<int>();

  int info;
  for (int64_t i = 0; i < batch_size; i++) {
    scalar_t* A_working_ptr = &A_data[i * A_mat_stride];
    scalar_t* b_working_ptr = &b_data[i * b_mat_stride];
    lapackSolve<scalar_t>(n, nrhs, A_working_ptr, lda, ipiv_data, b_working_ptr, lda, &info);
    infos[i] = info;
    if (info != 0) {
      return;
    }
  }
#endif
}

std::tuple<Tensor, Tensor> _solve_helper_cpu(const Tensor& self, const Tensor& A) {
  auto self_working_copy = cloneBatchedColumnMajor(self);
  auto A_working_copy = cloneBatchedColumnMajor(A);
  std::vector<int64_t> infos(batchCount(self), 0);
  AT_DISPATCH_FLOATING_AND_COMPLEX_TYPES(self.scalar_type(), "solve_cpu", [&]{
    apply_solve<scalar_t>(self_working_copy, A_working_copy, infos);
  });
  if (self.dim() > 2) {
    batchCheckErrors(infos, "solve_cpu");
  } else {
    singleCheckErrors(infos[0], "solve_cpu");
  }
  return std::tuple<Tensor, Tensor>(self_working_copy, A_working_copy);
}

// Supports arbitrary batch dimensions for self and A
std::tuple<Tensor,Tensor> solve(const Tensor& self, const Tensor& A) {
  TORCH_CHECK(self.dim() >= 2,
           "B should have at least 2 dimensions, but has ", self.dim(), " dimensions instead");
  TORCH_CHECK(A.dim() >= 2,
           "A should have at least 2 dimensions, but has ", A.dim(), " dimensions instead");
  Tensor self_broadcasted, A_broadcasted;
  std::tie(self_broadcasted, A_broadcasted) = _linalg_broadcast_batch_dims(self, A, "solve");
  return at::_solve_helper(self_broadcasted, A_broadcasted);
}

std::tuple<Tensor&,Tensor&> solve_out(Tensor& solution, Tensor& lu, const Tensor& self, const Tensor& A) {
  Tensor solution_tmp, lu_tmp;
  std::tie(solution_tmp, lu_tmp) = at::_solve_helper(self, A);
  solution.resize_as_(solution_tmp).copy_(solution_tmp);
  lu.resize_as_(lu_tmp).copy_(lu_tmp);
  return std::tuple<Tensor&, Tensor&>(solution, lu);
}

// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ inverse ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

template <typename scalar_t>
static void apply_inverse(Tensor& self, std::vector<int64_t>& infos) {
#ifndef USE_LAPACK
  AT_ERROR("inverse: LAPACK library not found in compilation");
#else
  using value_t = typename c10::scalar_value_type<scalar_t>::type;
  auto self_data = self.data_ptr<scalar_t>();
  auto self_matrix_stride = matrixStride(self);
  auto batch_size = batchCount(self);
  auto n = self.size(-2);

  auto ipiv = at::empty({n}, self.options().dtype(kInt));
  auto ipiv_data = ipiv.data_ptr<int>();

  int info;
  // Run once, first to get the optimum work size
  // Since we deal with batches of matrices with the same dimensions, doing this outside
  // the loop saves (batch_size - 1) workspace queries which would provide the same result
  // and (batch_size - 1) calls to allocate and deallocate workspace using at::empty()
  int lwork = -1;
  scalar_t wkopt;
  lapackGetri<scalar_t>(n, self_data, n, ipiv_data, &wkopt, lwork, &info);
  lwork = static_cast<int>(real_impl<scalar_t, value_t>(wkopt));
  Tensor work = at::empty({lwork}, self.options());
  auto work_data = work.data_ptr<scalar_t>();

  for (int64_t i = 0; i < batch_size; i++) {
    scalar_t* self_working_ptr = &self_data[i * self_matrix_stride];
    lapackLu<scalar_t>(n, n, self_working_ptr, n, ipiv_data, &info);
    infos[i] = info;
    if (info != 0) {
      return;
    }

    // now compute the actual inverse
    lapackGetri<scalar_t>(n, self_working_ptr, n, ipiv_data, work_data, lwork, &info);
    infos[i] = info;
    if (info != 0) {
      return;
    }
  }
#endif
}

Tensor _inverse_helper_cpu(const Tensor& self) {
  std::vector<int64_t> infos(batchCount(self), 0);
  auto self_working_copy = cloneBatchedColumnMajor(self);
  AT_DISPATCH_FLOATING_AND_COMPLEX_TYPES(self.scalar_type(), "inverse_cpu", [&]{
    apply_inverse<scalar_t>(self_working_copy, infos);
  });
  if (self.dim() > 2) {
    batchCheckErrors(infos, "inverse_cpu");
  } else {
    singleCheckErrors(infos[0], "inverse_cpu");
  }
  return self_working_copy;
}

Tensor inverse(const Tensor &self) {
  if (self.numel() == 0) {
    return at::empty_like(self, LEGACY_CONTIGUOUS_MEMORY_FORMAT);
  }
  squareCheckInputs(self);
  return at::_inverse_helper(self);
}

Tensor& inverse_out(Tensor &result, const Tensor &self) {
  if (self.size(-1) == 0) {
    return result.resize_as_(self);
  }
  result.copy_(native::inverse(self));
  return result;
}

// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ cholesky_solve ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

template<typename scalar_t>
static void apply_cholesky_solve(Tensor& b, Tensor& A, bool upper, std::vector<int64_t>& infos) {
#ifndef USE_LAPACK
  AT_ERROR("cholesky_solve: LAPACK library not found in compilation");
#else
  char uplo = upper ? 'U' : 'L';

  auto A_data = A.data_ptr<scalar_t>();
  auto b_data = b.data_ptr<scalar_t>();
  auto A_mat_stride = matrixStride(A);
  auto b_mat_stride = matrixStride(b);
  auto batch_size = batchCount(A);
  auto n = A.size(-2);
  auto nrhs = b.size(-1);

  int info;
  for (int64_t i = 0; i < batch_size; i++) {
    scalar_t* A_working_ptr = &A_data[i * A_mat_stride];
    scalar_t* b_working_ptr = &b_data[i * b_mat_stride];
    lapackCholeskySolve<scalar_t>(uplo, n, nrhs, A_working_ptr, n, b_working_ptr, n, &info);
    infos[i] = info;
    if (info != 0) {
      return;
    }
  }
#endif
}

Tensor _cholesky_solve_helper_cpu(const Tensor& self, const Tensor& A, bool upper) {
  auto self_working_copy = cloneBatchedColumnMajor(self);
  auto A_working_copy = cloneBatchedColumnMajor(A);
  std::vector<int64_t> infos(batchCount(self), 0);
  AT_DISPATCH_FLOATING_AND_COMPLEX_TYPES(self.scalar_type(), "cholesky_solve_cpu", [&]{
    apply_cholesky_solve<scalar_t>(self_working_copy, A_working_copy, upper, infos);
  });
  if (self.dim() > 2) {
    batchCheckErrors(infos, "cholesky_solve_cpu");
  } else {
    singleCheckErrors(infos[0], "cholesky_solve_cpu");
  }
  return self_working_copy;
}

// Supports arbitrary batch dimensions for self and A
Tensor cholesky_solve(const Tensor& self, const Tensor& A, bool upper) {
  TORCH_CHECK(self.dim() >= 2,
           "b should have at least 2 dimensions, but has ", self.dim(), " dimensions instead");
  TORCH_CHECK(A.dim() >= 2,
           "u should have at least 2 dimensions, but has ", A.dim(), " dimensions instead");
  Tensor self_broadcasted, A_broadcasted;
  std::tie(self_broadcasted, A_broadcasted) = _linalg_broadcast_batch_dims(self, A, "cholesky_solve");
  return at::_cholesky_solve_helper(self_broadcasted, A_broadcasted, upper);
}

Tensor& cholesky_solve_out(Tensor& result, const Tensor& self, const Tensor& A, bool upper) {
  Tensor result_tmp;
  result_tmp = at::cholesky_solve(self, A, upper);
  result.resize_as_(result_tmp).copy_(result_tmp);
  return result;
}

// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ cholesky ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

template<typename scalar_t>
static void apply_cholesky(Tensor& self, bool upper, std::vector<int64_t>& infos) {
#ifndef USE_LAPACK
  AT_ERROR("cholesky: LAPACK library not found in compilation");
#else
  char uplo = upper ? 'U' : 'L';

  auto self_data = self.data_ptr<scalar_t>();
  auto self_matrix_stride = matrixStride(self);
  auto batch_size = batchCount(self);
  auto n = self.size(-2);

  int info;
  for (int64_t i = 0; i < batch_size; i++) {
    scalar_t* self_working_ptr = &self_data[i * self_matrix_stride];
    lapackCholesky<scalar_t>(uplo, n, self_working_ptr, n, &info);
    infos[i] = info;
    if (info != 0) {
      return;
    }
  }
#endif
}

Tensor _cholesky_helper_cpu(const Tensor& self, bool upper) {
  std::vector<int64_t> infos(batchCount(self), 0);
  auto self_working_copy = cloneBatchedColumnMajor(self);
  AT_DISPATCH_FLOATING_AND_COMPLEX_TYPES(self.scalar_type(), "cholesky_cpu", [&]{
    apply_cholesky<scalar_t>(self_working_copy, upper, infos);
  });
  if (self.dim() > 2) {
    batchCheckErrors(infos, "cholesky_cpu");
  } else {
    singleCheckErrors(infos[0], "cholesky_cpu");
  }
  return self_working_copy;
}

Tensor cholesky(const Tensor &self, bool upper) {
  if (self.size(-1) == 0) {
    return at::empty_like(self, LEGACY_CONTIGUOUS_MEMORY_FORMAT);
  }
  squareCheckInputs(self);

  auto raw_cholesky_output = at::_cholesky_helper(self, upper);
  if (upper) {
    return raw_cholesky_output.triu_();
  } else {
    return raw_cholesky_output.tril_();
  }
}

Tensor& cholesky_out(Tensor &result, const Tensor &self, bool upper) {
  if (self.size(-1) == 0) {
    return result.resize_as_(self);
  }
  result.copy_(native::cholesky(self, upper));
  return result;
}

// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ lu ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

template<typename scalar_t>
static void apply_lu(Tensor& self, Tensor& pivots, Tensor& infos) {
#ifndef USE_LAPACK
  AT_ERROR("lu: LAPACK library not found in compilation");
#else
  auto self_data = self.data_ptr<scalar_t>();
  auto pivots_data = pivots.data_ptr<int>();
  auto infos_data = infos.data_ptr<int>();
  auto self_matrix_stride = matrixStride(self);
  auto pivots_matrix_stride = pivots.size(-1);
  auto batch_size = batchCount(self);
  auto m = self.size(-2);
  auto n = self.size(-1);

  for (int64_t i = 0; i < batch_size; i++) {
    scalar_t* self_working_ptr = &self_data[i * self_matrix_stride];
    int* pivots_working_ptr = &pivots_data[i * pivots_matrix_stride];
    int* infos_working_ptr = &infos_data[i];
    lapackLu<scalar_t>(m, n, self_working_ptr, m, pivots_working_ptr, infos_working_ptr);
  }
#endif
}

std::tuple<Tensor, Tensor, Tensor> _lu_with_info_cpu(const Tensor& self, bool pivot, bool check_errors) {
  TORCH_CHECK(pivot, "lu without pivoting is not implemented on the CPU");
  TORCH_CHECK(self.dim() >= 2,
           "expected tensor with 2 or more dimensions, got size: ", self.sizes(),
           " instead");
  auto m = self.size(-2);
  auto n = self.size(-1);
  auto req_size = self.sizes().vec();
  req_size.pop_back();
  req_size.back() = std::min(m, n);
  auto pivots_tensor = at::empty(req_size, self.options().dtype(kInt));
  req_size.pop_back();
  auto infos_tensor = at::zeros(req_size, self.options().dtype(kInt));

  Tensor self_working_copy;
  if (self.numel() == 0) {
    self_working_copy = at::empty_like(self, LEGACY_CONTIGUOUS_MEMORY_FORMAT);
  } else {
    self_working_copy = cloneBatchedColumnMajor(self);
    AT_DISPATCH_FLOATING_AND_COMPLEX_TYPES(self.scalar_type(), "lu_cpu", [&]{
      apply_lu<scalar_t>(self_working_copy, pivots_tensor, infos_tensor);
    });
  }
  if (check_errors) {
    if (self.dim() > 2) {
      batchCheckErrors(infos_tensor, "lu", /*allow_singular=*/true);
    } else {
      singleCheckErrors(infos_tensor.item<int64_t>(), "lu", /*allow_singular=*/true);
    }
  }
  return std::make_tuple(self_working_copy, pivots_tensor, infos_tensor);
}

// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ triangular_solve ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

template<typename scalar_t>
static void apply_triangular_solve(Tensor& b, Tensor& A, Tensor& infos, bool upper, bool transpose, bool unitriangular) {
#ifndef USE_LAPACK
  AT_ERROR("triangular_solve: LAPACK library not found in compilation");
#else
  char uplo = upper ? 'U' : 'L';
  char trans = transpose ? 'T' : 'N';
  char diag = unitriangular ? 'U' : 'N';

  auto A_data = A.data_ptr<scalar_t>();
  auto b_data = b.data_ptr<scalar_t>();
  auto A_mat_stride = matrixStride(A);
  auto b_mat_stride = matrixStride(b);
  auto batch_size = batchCount(A);
  auto n = A.size(-2);
  auto nrhs = b.size(-1);
  auto infos_data = infos.data_ptr<int>();

  for (int64_t i = 0; i < batch_size; i++) {
    scalar_t* A_working_ptr = &A_data[i * A_mat_stride];
    scalar_t* b_working_ptr = &b_data[i * b_mat_stride];
    int* infos_working_ptr = &infos_data[i];
    lapackTriangularSolve<scalar_t>(uplo, trans, diag, n, nrhs, A_working_ptr, n, b_working_ptr, n, infos_working_ptr);
  }
#endif
}

std::tuple<Tensor, Tensor> _triangular_solve_helper_cpu(const Tensor& self, const Tensor& A,
                                                        bool upper, bool transpose, bool unitriangular) {
  auto self_working_copy = cloneBatchedColumnMajor(self);
  auto A_working_copy = cloneBatchedColumnMajor(A);
  auto infos_tensor = at::empty(batchCount(self), self.options().dtype(kInt));
  AT_DISPATCH_FLOATING_AND_COMPLEX_TYPES(self.scalar_type(), "triangular_solve_cpu", [&]{
    apply_triangular_solve<scalar_t>(self_working_copy, A_working_copy, infos_tensor, upper, transpose, unitriangular);
  });
  if (self.dim() > 2) {
    batchCheckErrors(infos_tensor, "triangular_solve_cpu");
  } else {
    singleCheckErrors(infos_tensor.item<int64_t>(), "triangular_solve_cpu");
  }
  return std::tuple<Tensor, Tensor>(self_working_copy, A_working_copy);
}

// Supports arbitrary batch dimensions for self and A
std::tuple<Tensor, Tensor> triangular_solve(const Tensor& self, const Tensor& A,
                                            bool upper, bool transpose, bool unitriangular) {
  TORCH_CHECK(self.dim() >= 2,
           "b should have at least 2 dimensions, but has ", self.dim(), " dimensions instead");
  TORCH_CHECK(A.dim() >= 2,
           "u should have at least 2 dimensions, but has ", A.dim(), " dimensions instead");
  Tensor self_broadcasted, A_broadcasted;
  std::tie(self_broadcasted, A_broadcasted) = _linalg_broadcast_batch_dims(self, A, "triangular_solve");
  return at::_triangular_solve_helper(self_broadcasted, A_broadcasted, upper, transpose, unitriangular);
}

std::tuple<Tensor&, Tensor&> triangular_solve_out(Tensor& result, Tensor& clone_A, const Tensor& self, const Tensor& A,
                                                  bool upper, bool transpose, bool unitriangular) {
  Tensor result_tmp, clone_A_tmp;
  std::tie(result_tmp, clone_A_tmp) = at::_triangular_solve_helper(self, A, upper, transpose, unitriangular);
  result.resize_as_(result_tmp).copy_(result_tmp);
  clone_A.resize_as_(clone_A_tmp).copy_(clone_A_tmp);
  return std::tuple<Tensor&, Tensor&>(result, clone_A);
}

// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ qr ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

template<typename scalar_t>
static void apply_geqrf(Tensor& self, Tensor& tau, int64_t m, int64_t n,
                        std::vector<int64_t>& infos) {
#ifndef USE_LAPACK
  AT_ERROR("qr: LAPACK library not found in compilation");
#else
  using value_t = typename c10::scalar_value_type<scalar_t>::type;
  auto self_data = self.data_ptr<scalar_t>();
  auto tau_data = tau.data_ptr<scalar_t>();
  auto self_matrix_stride = matrixStride(self);
  auto tau_stride = tau.size(-1);
  auto batch_size = batchCount(self);

  int info;
  // Run once, first to get the optimum work size.
  // Since we deal with batches of matrices with the same dimensions, doing this outside
  // the loop saves (batch_size - 1) workspace queries which would provide the same result
  // and (batch_size - 1) calls to allocate and deallocate workspace using at::empty()
  int lwork = -1;
  scalar_t wkopt;
  lapackGeqrf<scalar_t>(m, n, self_data, m, tau_data, &wkopt, lwork, &info);
  lwork = static_cast<int>(real_impl<scalar_t, value_t>(wkopt));
  Tensor work = at::empty({lwork}, self.options());

  for (int64_t i = 0; i < batch_size; i++) {
    scalar_t* self_working_ptr = &self_data[i * self_matrix_stride];
    scalar_t* tau_working_ptr = &tau_data[i * tau_stride];

    // now compute the actual R and TAU
    lapackGeqrf<scalar_t>(m, n, self_working_ptr, m, tau_working_ptr, work.data_ptr<scalar_t>(), lwork, &info);
    infos[i] = info;
    if (info != 0) {
      return;
    }
  }
#endif
}

template<typename scalar_t>
static void apply_orgqr(Tensor& self, const Tensor& tau, int64_t m, int64_t n_columns,
                        int64_t k, std::vector<int64_t>& infos) {
#ifndef USE_LAPACK
  AT_ERROR("qr: LAPACK library not found in compilation");
#else
  using value_t = typename c10::scalar_value_type<scalar_t>::type;
  auto self_data = self.data_ptr<scalar_t>();
  auto tau_data = tau.data_ptr<scalar_t>();
  auto self_matrix_stride = matrixStride(self);
  auto tau_stride = tau.size(-1);
  auto batch_size = batchCount(self);

  int info;
  // Run once, first to get the optimum work size.
  // Since we deal with batches of matrices with the same dimensions, doing this outside
  // the loop saves (batch_size - 1) workspace queries which would provide the same result
  // and (batch_size - 1) calls to allocate and deallocate workspace using at::empty()
  int lwork = -1;
  scalar_t wkopt;
  lapackOrgqr<scalar_t>(m, n_columns, k, self_data, m, tau_data, &wkopt, lwork, &info);
  lwork = static_cast<int>(real_impl<scalar_t, value_t>(wkopt));
  Tensor work = at::empty({lwork}, self.options());

  for (int64_t i = 0; i < batch_size; i++) {
    scalar_t* self_working_ptr = &self_data[i * self_matrix_stride];
    scalar_t* tau_working_ptr = &tau_data[i * tau_stride];

    // now compute the actual Q
    lapackOrgqr<scalar_t>(m, n_columns, k, self_working_ptr, m, tau_working_ptr, work.data_ptr<scalar_t>(), lwork, &info);
    infos[i] = info;
    if (info != 0) {
      return;
    }
  }
#endif
}

std::tuple<Tensor, Tensor> _qr_helper_cpu(const Tensor& self, bool some) {
  std::vector<int64_t> infos(batchCount(self), 0);
  int64_t m = self.size(-2), n = self.size(-1);

  // Setup inputs for apply_geqrf
  auto self_sizes = self.sizes().vec();
  self_sizes.pop_back();
  self_sizes[self.dim() - 2] = std::min(m, n);
  auto tau_working_copy = at::empty(self_sizes, self.options());
  Tensor q_working_copy;

  // Setup input geometry for apply_orgqr
  std::vector<int64_t> q_sizes, q_strides;
  int64_t n_columns_q;
  Tensor R;
  std::tie(q_sizes, q_strides, n_columns_q) = _compute_geometry_for_Q(self, some);

  // If there are no elements, then we simply return a pair of tensors of required dimensions
  if (self.numel() == 0) {
    // Fix the number of columns of q appropriately
    q_sizes[self.dim() - 1] = n_columns_q;
    q_working_copy = at::eye(q_sizes[self.dim() - 2], q_sizes[self.dim() - 1], self.options());
    q_working_copy = q_working_copy.expand_as(q_working_copy);

    // We repurpose the same q_sizes for R
    // Fix the number of rows and columns of q_working_copy appropriately
    q_sizes[self.dim() - 1] = n;
    q_sizes[self.dim() - 2] = n_columns_q;
    R = at::empty(q_sizes, self.options());
    return std::make_tuple(q_working_copy, R);
  }

  // First perform GEQRF for R and TAU (the elementary reflectors)
  // We will need to generate R from the upper triangular matrix from the
  // matrix input to GEQRF.
  q_working_copy = at::empty_strided(q_sizes, q_strides, self.options());
  q_working_copy.narrow(-1, 0, n).copy_(self);

  AT_DISPATCH_FLOATING_AND_COMPLEX_TYPES(self.scalar_type(), "qr_cpu", [&]{
    apply_geqrf<scalar_t>(q_working_copy, tau_working_copy, m, n, infos);
  });
  if (self.dim() > 2) {
    batchCheckErrors(infos, "qr_cpu");
  } else {
    singleCheckErrors(infos[0], "qr_cpu");
  }

  R = q_working_copy.slice(-2, 0, n_columns_q).slice(-1, 0, n).triu();

  // Next perform ORGQR for Q using the results (both raw R and TAU) from GEQRF
  AT_DISPATCH_FLOATING_AND_COMPLEX_TYPES(self.scalar_type(), "qr_cpu", [&]{
    apply_orgqr<scalar_t>(q_working_copy, tau_working_copy, m, n_columns_q, std::min(m, n), infos);
  });
  if (self.dim() > 2) {
    batchCheckErrors(infos, "qr_cpu");
  } else {
    singleCheckErrors(infos[0], "qr_cpu");
  }
  return std::make_tuple(q_working_copy.narrow(-1, 0, n_columns_q), R);
}

std::tuple<Tensor,Tensor> qr(const Tensor& self, bool some) {
  TORCH_CHECK(self.dim() >= 2,
              "self should have at least 2 dimensions, but has ", self.dim(), " dimensions instead");
  return at::_qr_helper(self, some);
}

std::tuple<Tensor&,Tensor&> qr_out(Tensor& Q, Tensor& R, const Tensor& self, bool some) {
  TORCH_CHECK(self.dim() >= 2,
              "self should have at least 2 dimensions, but has ", self.dim(), " dimensions instead");
  Tensor Q_tmp, R_tmp;
  std::tie(Q_tmp, R_tmp) = at::_qr_helper(self, some);
  Q.resize_as_(Q_tmp).copy_(Q_tmp);
  R.resize_as_(R_tmp).copy_(R_tmp);
  return std::tuple<Tensor&, Tensor&>(Q, R);
}

// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ symeig ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

template <typename scalar_t>
static void apply_symeig(Tensor& self, Tensor& eigvals, bool eigenvectors, bool upper, std::vector<int64_t>& infos) {
#ifndef USE_LAPACK
  AT_ERROR("symeig: LAPACK library not found in compilation");
#else
  using value_t = typename c10::scalar_value_type<scalar_t>::type;
  auto self_data = self.data_ptr<scalar_t>();
  auto eigvals_data = eigvals.data_ptr<value_t>();
  auto self_matrix_stride = matrixStride(self);
  auto eigvals_stride = eigvals.size(-1);
  auto batch_size = batchCount(self);
  auto n = self.size(-1);

  char uplo = upper ? 'U' : 'L';
  char jobz = eigenvectors ? 'V' : 'N';

  int info;
  // Run once, first to get the optimum work size.
  // Since we deal with batches of matrices with the same dimensions, doing this outside
  // the loop saves (batch_size - 1) workspace queries which would provide the same result
  // and (batch_size - 1) calls to allocate and deallocate workspace using at::empty()
  int lwork = -1;
  scalar_t wkopt;

  Tensor rwork;
  value_t* rwork_data = nullptr;
  if (isComplexType(at::typeMetaToScalarType(self.dtype()))) {
    int64_t lrwork = std::max(int64_t(1), 3 * n - 2);
    ScalarType dtype = toValueType(typeMetaToScalarType(self.dtype()));
    rwork = at::empty({lrwork}, self.options().dtype(dtype));
    rwork_data = rwork.data_ptr<value_t>();
  }

  lapackSymeig<scalar_t, value_t>(jobz, uplo, n, self_data, n, eigvals_data, &wkopt, lwork, rwork_data, &info);
  lwork = static_cast<int>(real_impl<scalar_t, value_t>(wkopt));
  Tensor work = at::empty({lwork}, self.options());

  for (int64_t i = 0; i < batch_size; i++) {
    scalar_t* self_working_ptr = &self_data[i * self_matrix_stride];
    value_t* eigvals_working_ptr = &eigvals_data[i * eigvals_stride];

    // now compute the eigenvalues and the eigenvectors (optionally)
    lapackSymeig<scalar_t, value_t>(jobz, uplo, n, self_working_ptr, n, eigvals_working_ptr, work.data_ptr<scalar_t>(), lwork, rwork_data, &info);
    infos[i] = info;
    if (info != 0) {
      return;
    }
  }
#endif
}

std::tuple<Tensor, Tensor> _symeig_helper_cpu(const Tensor& self, bool eigenvectors, bool upper) {
  std::vector<int64_t> infos(batchCount(self), 0);

  auto self_sizes = self.sizes().vec();
  self_sizes.pop_back();
  ScalarType dtype = toValueType(typeMetaToScalarType(self.dtype()));
  auto eigvals = at::empty(self_sizes, self.options().dtype(dtype));

  if (self.numel() == 0) {
    return std::tuple<Tensor, Tensor>(eigvals, at::empty_like(self, LEGACY_CONTIGUOUS_MEMORY_FORMAT));
  }

  auto self_working_copy = cloneBatchedColumnMajor(self);
  AT_DISPATCH_FLOATING_AND_COMPLEX_TYPES(self.scalar_type(), "symeig_cpu", [&]{
    apply_symeig<scalar_t>(self_working_copy, eigvals, eigenvectors, upper, infos);
  });

  if (self.dim() > 2) {
    batchCheckErrors(infos, "symeig_cpu");
  } else {
    singleCheckErrors(infos[0], "symeig_cpu");
  }
  if (eigenvectors) {
    return std::tuple<Tensor, Tensor>(eigvals, self_working_copy);
  } else {
    return std::tuple<Tensor, Tensor>(eigvals, at::empty({0}, self.options()));
  }
}

std::tuple<Tensor, Tensor> symeig(const Tensor& self, bool eigenvectors, bool upper) {
  squareCheckInputs(self);
  return at::_symeig_helper(self, eigenvectors, upper);
}

std::tuple<Tensor&, Tensor&> symeig_out(Tensor& vals, Tensor& vecs, const Tensor& self, bool eigenvectors, bool upper) {
  squareCheckInputs(self);
  Tensor vals_tmp, vecs_tmp;
  std::tie(vals_tmp, vecs_tmp) = at::_symeig_helper(self, eigenvectors, upper);
  vals.resize_as_(vals_tmp).copy_(vals_tmp);
  vecs.resize_as_(vecs_tmp).copy_(vecs_tmp);
  return std::tuple<Tensor&, Tensor&>(vals, vecs);
}

// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ svd ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

template <typename scalar_t>
static void apply_svd(Tensor& self, Tensor& U, Tensor& S, Tensor& VT,
                      char jobz, std::vector<int64_t>& infos) {
#ifndef USE_LAPACK
  AT_ERROR("svd: LAPACK library not found in compilation");
#else
  using value_t = typename c10::scalar_value_type<scalar_t>::type;
  auto self_data = self.data_ptr<scalar_t>();
  auto U_data = U.data_ptr<scalar_t>();
  auto S_data = S.data_ptr<value_t>();
  auto VT_data = VT.data_ptr<scalar_t>();
  auto self_stride = matrixStride(self);
  auto U_stride = matrixStride(U);
  auto S_stride = S.size(-1);
  auto VT_stride = matrixStride(VT);
  auto batchsize = batchCount(self);

  int info;
  auto m = self.size(-2);
  auto n = self.size(-1);
  auto mn = std::min(m, n);
  Tensor iwork = at::empty({8 * mn}, at::kInt);
  auto iwork_data = iwork.data_ptr<int>();
  Tensor rwork;
  value_t* rwork_data = nullptr;
  if (isComplexType(at::typeMetaToScalarType(self.dtype()))) {
    auto lrwork  = computeLRWorkDim(jobz, m, n);
    // rwork is an array of floats or doubles depending on the type
    rwork = at::empty({std::max(int64_t(1), lrwork)}, at::typeMetaToScalarType(S.dtype()));
    rwork_data = rwork.data_ptr<value_t>();
  }

  // Run once, first to get the optimum work size.
  // Since we deal with batches of matrices with the same dimensions, doing this outside
  // the loop saves (batch_size - 1) workspace queries which would provide the same result
  // and (batch_size - 1) calls to allocate and deallocate workspace using at::empty()
  int lwork = -1;
  scalar_t wkopt;
  lapackSvd<scalar_t, value_t>(jobz, m, n, self_data, m, S_data, U_data, m, VT_data, n, &wkopt, lwork, rwork_data, iwork_data, &info);
  lwork = static_cast<int>(real_impl<scalar_t, value_t>(wkopt));
  Tensor work = at::empty({lwork}, self.options());
  auto work_data = work.data_ptr<scalar_t>();

  for (int64_t i = 0; i < batchsize; i++) {
    scalar_t* self_working_ptr = &self_data[i * self_stride];
    value_t* S_working_ptr = &S_data[i * S_stride];
    scalar_t* U_working_ptr = &U_data[i * U_stride];
    scalar_t* VT_working_ptr = &VT_data[i * VT_stride];

    // Compute S, U (optionally) and VT (optionally)
    lapackSvd<scalar_t, value_t>(jobz, m, n, self_working_ptr, m,
                        S_working_ptr, U_working_ptr, m, VT_working_ptr, n, work_data, lwork, rwork_data, iwork_data, &info);
    infos[i] = info;
    if (info != 0) {
      return;
    }
  }
#endif
}

std::tuple<Tensor, Tensor, Tensor> _svd_helper_cpu(const Tensor& self, bool some, bool compute_uv) {
  std::vector<int64_t> infos(batchCount(self), 0);
  int64_t m = self.size(-2), n = self.size(-1);
  int64_t k = std::min(m, n);

  char jobz = compute_uv ? (some ? 'S' : 'A') : 'N';

  Tensor U_working_copy, S_working_copy, VT_working_copy;
  std::tie(U_working_copy, S_working_copy, VT_working_copy) = _create_U_S_VT(self, some, compute_uv);

  if (self.numel() > 0) {
    auto self_working_copy = cloneBatchedColumnMajor(self);

    AT_DISPATCH_FLOATING_AND_COMPLEX_TYPES(self.scalar_type(), "svd_cpu", [&]{
      apply_svd<scalar_t>(self_working_copy, U_working_copy, S_working_copy, VT_working_copy, jobz, infos);
    });

    if (self.dim() > 2) {
      batchCheckErrors(infos, "svd_cpu");
    } else {
      singleCheckErrors(infos[0], "svd_cpu");
    }

    if (compute_uv) {
      if (some) {
        VT_working_copy = VT_working_copy.narrow(-1, 0, k);
      }
    } else {
      VT_working_copy.zero_();
      U_working_copy.zero_();
    }
  } else {
    U_working_copy.zero_();
    VT_working_copy.zero_();
  }
  return std::make_tuple(U_working_copy, S_working_copy, VT_working_copy);
}

std::tuple<Tensor, Tensor, Tensor> svd(const Tensor& self, bool some, bool compute_uv) {
  TORCH_CHECK(self.dim() >= 2,
              "self should have at least 2 dimensions, but has ", self.dim(), " dimensions instead");
  return at::_svd_helper(self, some, compute_uv);
}

std::tuple<Tensor&, Tensor&, Tensor&> svd_out(Tensor& U, Tensor& S, Tensor& VT,
                                              const Tensor& self, bool some, bool compute_uv) {
  TORCH_CHECK(self.dim() >= 2,
              "self should have at least 2 dimensions, but has ", self.dim(), " dimensions instead");
  Tensor U_tmp, S_tmp, VT_tmp;
  std::tie(U_tmp, S_tmp, VT_tmp) = at::_svd_helper(self, some, compute_uv);
  U.resize_as_(U_tmp).copy_(U_tmp);
  S.resize_as_(S_tmp).copy_(S_tmp);
  VT.resize_as_(VT_tmp).copy_(VT_tmp);
  return std::tuple<Tensor&, Tensor&, Tensor&>(U, S, VT);
}

// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ lu_solve ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

template<typename scalar_t>
static void apply_lu_solve(Tensor& b, const Tensor& lu, const Tensor& pivots, std::vector<int64_t>& infos) {
#ifndef USE_LAPACK
  AT_ERROR("lu_solve: LAPACK library not found in compilation");
#else
  auto b_data = b.data_ptr<scalar_t>();
  auto lu_data = lu.data_ptr<scalar_t>();
  auto pivots_data = pivots.data_ptr<int>();
  auto b_stride = matrixStride(b);
  auto lu_stride = matrixStride(lu);
  auto pivots_stride = pivots.size(-1);
  auto batch_size = batchCount(b);

  auto n = lu.size(-2);
  auto nrhs = b.size(-1);

  int info;
  for (int64_t i = 0; i < batch_size; i++) {
    scalar_t* b_working_ptr = &b_data[i * b_stride];
    scalar_t* lu_working_ptr = &lu_data[i * lu_stride];
    int* pivots_working_ptr = &pivots_data[i * pivots_stride];
    lapackLuSolve<scalar_t>('N', n, nrhs, lu_working_ptr, n, pivots_working_ptr,
                            b_working_ptr, n, &info);
    infos[i] = info;
    if (info != 0) {
      return;
    }
  }
#endif
}

Tensor _lu_solve_helper_cpu(const Tensor& self, const Tensor& LU_data, const Tensor& LU_pivots) {
  auto self_working_copy = cloneBatchedColumnMajor(self);
  auto LU_data_working_copy = cloneBatchedColumnMajor(LU_data);
  auto LU_pivots_working_copy = LU_pivots.is_contiguous() ? LU_pivots : LU_pivots.contiguous();
  std::vector<int64_t> infos(batchCount(self), 0);

  if (self.numel() == 0 || LU_data.numel() == 0) {
    return at::zeros_like(self, LEGACY_CONTIGUOUS_MEMORY_FORMAT);
  }
  AT_DISPATCH_FLOATING_TYPES(self.scalar_type(), "lu_solve_cpu", [&]{
    apply_lu_solve<scalar_t>(self_working_copy, LU_data_working_copy, LU_pivots_working_copy, infos);
  });
  if (self.dim() > 2) {
    batchCheckErrors(infos, "lu_solve_cpu");
  } else {
    singleCheckErrors(infos[0], "lu_solve_cpu");
  }
  return self_working_copy;
}

// Supports arbitrary batch dimensions for self and LU_data (implicitly LU_pivots also)
Tensor lu_solve(const Tensor& self, const Tensor& LU_data, const Tensor& LU_pivots) {
  TORCH_CHECK(self.dim() >= 2,
              "b should have at least 2 dimensions, but has ", self.dim(), " dimensions instead");
  TORCH_CHECK(LU_data.dim() >= 2,
              "LU_data should have at least 2 dimensions, but has ", LU_data.dim(), " dimensions instead");
  TORCH_CHECK(LU_pivots.size(-1) == LU_data.size(-1),
              "Number of pivots per batch should be same as the dimension of the matrix");
  TORCH_CHECK(LU_pivots.dtype() == at::kInt,
              "LU_pivots should be a Tensor of scalar type Int");
  TORCH_CHECK(LU_pivots.device() == LU_data.device(),
              "Expected LU_pivots and LU_data to be on the same device, "
              "but found LU_pivots on ", LU_pivots.device(), " and LU_data on ",
              LU_data.device(), " instead");

  // We check whether the batch dimensions of LU_pivots match the batch dimensions of LU_data
  // e.g.: LU_pivots.sizes() = 4 x 3 x 2, LU_data.sizes() = 4 x 3 x 2 x 2 is a pair of correct inputs
  // e.g.: LU_pivots.sizes() = 4 x 3 x 2, LU_data.sizes() = 12 x 2 x 2 is a pair of incorrect inputs
  IntArrayRef pivots_sizes(LU_pivots.sizes().data(), LU_pivots.dim() - 1);
  IntArrayRef lu_sizes(LU_data.sizes().data(), LU_data.dim() - 2);
  TORCH_CHECK(pivots_sizes == lu_sizes,
              "batch dimensions of LU_pivots doesn't match batch dimensions of LU_data");

  Tensor self_broadcasted, LU_data_broadcasted;
  std::tie(self_broadcasted, LU_data_broadcasted) = _linalg_broadcast_batch_dims(self, LU_data, "lu_solve");

  // Now, we need to broadcast pivots too for the batch dimensions to match
  IntArrayRef new_pivots_sizes(LU_data_broadcasted.sizes().data(), LU_data_broadcasted.dim() - 1);
  Tensor LU_pivots_broadcasted = LU_pivots.expand(new_pivots_sizes);
  return at::_lu_solve_helper(self_broadcasted, LU_data_broadcasted, LU_pivots_broadcasted);
}

Tensor& lu_solve_out(Tensor& result, const Tensor& self, const Tensor& LU_data, const Tensor& LU_pivots) {
  Tensor result_tmp = at::lu_solve(self, LU_data, LU_pivots);
  result.resize_as_(result_tmp).copy_(result_tmp);
  return result;
}

}}  // namespace at::native