#include "dsyMatrix.h" SEXP symmetricMatrix_validate(SEXP obj) { SEXP val = GET_SLOT(obj, Matrix_DimSym); if (LENGTH(val) < 2) return mkString(_("'Dim' slot has length less than two")); if (INTEGER(val)[0] != INTEGER(val)[1]) return mkString(_("Matrix is not square")); if (isString(val = check_scalar_string(GET_SLOT(obj, Matrix_uploSym), "LU", "uplo"))) return val; return ScalarLogical(1); } SEXP dsyMatrix_validate(SEXP obj) { /* since "dsy" inherits from "symmetric", and "dMatrix", only need this:*/ return dense_nonpacked_validate(obj); } double get_norm_sy(SEXP obj, const char *typstr) { char typnm[] = {'\0', '\0'}; int *dims = INTEGER(GET_SLOT(obj, Matrix_DimSym)); double *work = (double *) NULL; typnm[0] = La_norm_type(typstr); if (*typnm == 'I' || *typnm == 'O') { work = (double *) R_alloc(dims[0], sizeof(double)); } return F77_CALL(dlansy)(typnm, uplo_P(obj), dims, REAL(GET_SLOT(obj, Matrix_xSym)), dims, work); } SEXP dsyMatrix_norm(SEXP obj, SEXP type) { return ScalarReal(get_norm_sy(obj, CHAR(asChar(type)))); } SEXP dsyMatrix_rcond(SEXP obj, SEXP type) { SEXP trf = dsyMatrix_trf(obj); char typnm[] = {'\0', '\0'}; int *dims = INTEGER(GET_SLOT(obj, Matrix_DimSym)), info; double anorm = get_norm_sy(obj, "O"); double rcond; typnm[0] = La_rcond_type(CHAR(asChar(type))); F77_CALL(dsycon)(uplo_P(trf), dims, REAL (GET_SLOT(trf, Matrix_xSym)), dims, INTEGER(GET_SLOT(trf, Matrix_permSym)), &anorm, &rcond, (double *) R_alloc(2*dims[0], sizeof(double)), (int *) R_alloc(dims[0], sizeof(int)), &info); return ScalarReal(rcond); } SEXP dsyMatrix_solve(SEXP a) { SEXP trf = dsyMatrix_trf(a); SEXP val = PROTECT(NEW_OBJECT(MAKE_CLASS("dsyMatrix"))); int *dims = INTEGER(GET_SLOT(trf, Matrix_DimSym)), info; slot_dup(val, trf, Matrix_uploSym); slot_dup(val, trf, Matrix_xSym); slot_dup(val, trf, Matrix_DimSym); F77_CALL(dsytri)(uplo_P(val), dims, REAL(GET_SLOT(val, Matrix_xSym)), dims, INTEGER(GET_SLOT(trf, Matrix_permSym)), (double *) R_alloc((long) dims[0], sizeof(double)), &info); UNPROTECT(1); return val; } SEXP dsyMatrix_matrix_solve(SEXP a, SEXP b) { SEXP trf = dsyMatrix_trf(a), val = PROTECT(dup_mMatrix_as_dgeMatrix(b)); int *adims = INTEGER(GET_SLOT(a, Matrix_DimSym)), *bdims = INTEGER(GET_SLOT(val, Matrix_DimSym)), info; if (*adims != *bdims || bdims[1] < 1 || *adims < 1) error(_("Dimensions of system to be solved are inconsistent")); F77_CALL(dsytrs)(uplo_P(trf), adims, bdims + 1, REAL(GET_SLOT(trf, Matrix_xSym)), adims, INTEGER(GET_SLOT(trf, Matrix_permSym)), REAL(GET_SLOT(val, Matrix_xSym)), bdims, &info); UNPROTECT(1); return val; } SEXP dsyMatrix_as_matrix(SEXP from, SEXP keep_dimnames) { int n = INTEGER(GET_SLOT(from, Matrix_DimSym))[0]; SEXP val = PROTECT(allocMatrix(REALSXP, n, n)); make_d_matrix_symmetric(Memcpy(REAL(val), REAL(GET_SLOT(from, Matrix_xSym)), n * n), from); if(asLogical(keep_dimnames)) setAttrib(val, R_DimNamesSymbol, GET_SLOT(from, Matrix_DimNamesSym)); UNPROTECT(1); return val; } SEXP dsyMatrix_matrix_mm(SEXP a, SEXP b, SEXP rtP) { SEXP val = PROTECT(dup_mMatrix_as_dgeMatrix(b)); int rt = asLogical(rtP); /* if(rt), compute b %*% a, else a %*% b */ int *adims = INTEGER(GET_SLOT(a, Matrix_DimSym)), *bdims = INTEGER(GET_SLOT(val, Matrix_DimSym)), m = bdims[0], n = bdims[1]; double one = 1., zero = 0.; double *vx = REAL(GET_SLOT(val, Matrix_xSym)); double *bcp = Memcpy(Alloca(m * n, double), vx, m * n); R_CheckStack(); if ((rt && n != adims[0]) || (!rt && m != adims[0])) error(_("Matrices are not conformable for multiplication")); if (m < 1 || n < 1) { /* error(_("Matrices with zero extents cannot be multiplied")); */ } else F77_CALL(dsymm)(rt ? "R" :"L", uplo_P(a), &m, &n, &one, REAL(GET_SLOT(a, Matrix_xSym)), adims, bcp, &m, &zero, vx, &m); UNPROTECT(1); return val; } SEXP dsyMatrix_trf(SEXP x) { SEXP val = get_factors(x, "BunchKaufman"), dimP = GET_SLOT(x, Matrix_DimSym), uploP = GET_SLOT(x, Matrix_uploSym); int *dims = INTEGER(dimP), *perm, info; int lwork = -1, n = dims[0]; const char *uplo = CHAR(STRING_ELT(uploP, 0)); double tmp, *vx, *work; if (val != R_NilValue) return val; dims = INTEGER(dimP); val = PROTECT(NEW_OBJECT(MAKE_CLASS("BunchKaufman"))); SET_SLOT(val, Matrix_uploSym, duplicate(uploP)); SET_SLOT(val, Matrix_diagSym, mkString("N")); SET_SLOT(val, Matrix_DimSym, duplicate(dimP)); vx = REAL(ALLOC_SLOT(val, Matrix_xSym, REALSXP, n * n)); AZERO(vx, n * n); F77_CALL(dlacpy)(uplo, &n, &n, REAL(GET_SLOT(x, Matrix_xSym)), &n, vx, &n); perm = INTEGER(ALLOC_SLOT(val, Matrix_permSym, INTSXP, n)); F77_CALL(dsytrf)(uplo, &n, vx, &n, perm, &tmp, &lwork, &info); lwork = (int) tmp; work = Alloca(lwork, double); R_CheckStack(); F77_CALL(dsytrf)(uplo, &n, vx, &n, perm, work, &lwork, &info); if (info) error(_("Lapack routine dsytrf returned error code %d"), info); UNPROTECT(1); return set_factors(x, val, "BunchKaufman"); } SEXP dsyMatrix_as_dspMatrix(SEXP from) { SEXP val = PROTECT(NEW_OBJECT(MAKE_CLASS("dspMatrix"))), uplo = GET_SLOT(from, Matrix_uploSym), dimP = GET_SLOT(from, Matrix_DimSym); int n = *INTEGER(dimP); SET_SLOT(val, Matrix_DimSym, duplicate(dimP)); SET_SLOT(val, Matrix_uploSym, duplicate(uplo)); full_to_packed_double( REAL(ALLOC_SLOT(val, Matrix_xSym, REALSXP, (n*(n+1))/2)), REAL(GET_SLOT(from, Matrix_xSym)), n, *CHAR(STRING_ELT(uplo, 0)) == 'U' ? UPP : LOW, NUN); SET_SLOT(val, Matrix_DimNamesSym, duplicate(GET_SLOT(from, Matrix_DimNamesSym))); UNPROTECT(1); return val; }