/* ************************************************************************ * Copyright (c) 2021 Advanced Micro Devices, Inc. * ************************************************************************ */ #include "roclapack_sygv_hegv.hpp" template rocblas_status rocsolver_sygv_hegv_strided_batched_impl(rocblas_handle handle, const rocblas_eform itype, const rocblas_evect evect, const rocblas_fill uplo, const rocblas_int n, U A, const rocblas_int lda, const rocblas_stride strideA, U B, const rocblas_int ldb, const rocblas_stride strideB, S* D, const rocblas_stride strideD, S* E, const rocblas_stride strideE, rocblas_int* info, const rocblas_int batch_count) { const char* name = (!is_complex ? "sygv_strided_batched" : "hegv_strided_batched"); ROCSOLVER_ENTER_TOP(name, "--itype", itype, "--evect", evect, "--uplo", uplo, "-n", n, "--lda", lda, "--strideA", strideA, "--ldb", ldb, "--strideB", strideB, "--strideD", strideD, "--strideE", strideE, "--batch_count", batch_count); if(!handle) return rocblas_status_invalid_handle; // argument checking rocblas_status st = rocsolver_sygv_hegv_argCheck(handle, itype, evect, uplo, n, lda, ldb, A, B, D, E, info, batch_count); if(st != rocblas_status_continue) return st; // working with unshifted arrays rocblas_int shiftA = 0; rocblas_int shiftB = 0; // memory workspace sizes: // size for constants in rocblas calls size_t size_scalars; // size of reusable workspaces (and for calling TRSM, SYGST/HEGST, and SYEV/HEEV) bool optim_mem; size_t size_work1, size_work2, size_work3, size_work4; // extra requirements for calling POTRF and SYEV/HEEV size_t size_pivots_workArr; // size of temporary info array size_t size_iinfo; rocsolver_sygv_hegv_getMemorySize( itype, evect, uplo, n, batch_count, &size_scalars, &size_work1, &size_work2, &size_work3, &size_work4, &size_pivots_workArr, &size_iinfo, &optim_mem); if(rocblas_is_device_memory_size_query(handle)) return rocblas_set_optimal_device_memory_size(handle, size_scalars, size_work1, size_work2, size_work3, size_work4, size_pivots_workArr, size_iinfo); // memory workspace allocation void *scalars, *work1, *work2, *work3, *work4, *pivots_workArr, *iinfo; rocblas_device_malloc mem(handle, size_scalars, size_work1, size_work2, size_work3, size_work4, size_pivots_workArr, size_iinfo); if(!mem) return rocblas_status_memory_error; scalars = mem[0]; work1 = mem[1]; work2 = mem[2]; work3 = mem[3]; work4 = mem[4]; pivots_workArr = mem[5]; iinfo = mem[6]; if(size_scalars > 0) init_scalars(handle, (T*)scalars); // execution return rocsolver_sygv_hegv_template( handle, itype, evect, uplo, n, A, shiftA, lda, strideA, B, shiftB, ldb, strideB, D, strideD, E, strideE, info, batch_count, (T*)scalars, work1, work2, work3, work4, pivots_workArr, (rocblas_int*)iinfo, optim_mem); } /* * =========================================================================== * C wrapper * =========================================================================== */ extern "C" { rocblas_status rocsolver_ssygv_strided_batched(rocblas_handle handle, const rocblas_eform itype, const rocblas_evect evect, const rocblas_fill uplo, const rocblas_int n, float* A, const rocblas_int lda, const rocblas_stride strideA, float* B, const rocblas_int ldb, const rocblas_stride strideB, float* D, const rocblas_stride strideD, float* E, const rocblas_stride strideE, rocblas_int* info, const rocblas_int batch_count) { return rocsolver_sygv_hegv_strided_batched_impl(handle, itype, evect, uplo, n, A, lda, strideA, B, ldb, strideB, D, strideD, E, strideE, info, batch_count); } rocblas_status rocsolver_dsygv_strided_batched(rocblas_handle handle, const rocblas_eform itype, const rocblas_evect evect, const rocblas_fill uplo, const rocblas_int n, double* A, const rocblas_int lda, const rocblas_stride strideA, double* B, const rocblas_int ldb, const rocblas_stride strideB, double* D, const rocblas_stride strideD, double* E, const rocblas_stride strideE, rocblas_int* info, const rocblas_int batch_count) { return rocsolver_sygv_hegv_strided_batched_impl(handle, itype, evect, uplo, n, A, lda, strideA, B, ldb, strideB, D, strideD, E, strideE, info, batch_count); } rocblas_status rocsolver_chegv_strided_batched(rocblas_handle handle, const rocblas_eform itype, const rocblas_evect evect, const rocblas_fill uplo, const rocblas_int n, rocblas_float_complex* A, const rocblas_int lda, const rocblas_stride strideA, rocblas_float_complex* B, const rocblas_int ldb, const rocblas_stride strideB, float* D, const rocblas_stride strideD, float* E, const rocblas_stride strideE, rocblas_int* info, const rocblas_int batch_count) { return rocsolver_sygv_hegv_strided_batched_impl( handle, itype, evect, uplo, n, A, lda, strideA, B, ldb, strideB, D, strideD, E, strideE, info, batch_count); } rocblas_status rocsolver_zhegv_strided_batched(rocblas_handle handle, const rocblas_eform itype, const rocblas_evect evect, const rocblas_fill uplo, const rocblas_int n, rocblas_double_complex* A, const rocblas_int lda, const rocblas_stride strideA, rocblas_double_complex* B, const rocblas_int ldb, const rocblas_stride strideB, double* D, const rocblas_stride strideD, double* E, const rocblas_stride strideE, rocblas_int* info, const rocblas_int batch_count) { return rocsolver_sygv_hegv_strided_batched_impl( handle, itype, evect, uplo, n, A, lda, strideA, B, ldb, strideB, D, strideD, E, strideE, info, batch_count); } } // extern C