Mercurial > octave-nkf
view libinterp/operators/op-sm-s.cc @ 18840:4a4edf0f2077 nkf-ready
fix LLVM 3.4 build (bug #41061)
* configure.ac: Call new functions OCTAVE_LLVM_RAW_FD_OSTREAM_API and
OCTAVE_LLVM_LEGACY_PASSMANAGER_API, check for Verifier.h header file
* m4/acinclude.m4 (OCTAVE_LLVM_RAW_FD_OSTREAM_API): New function to
detect correct raw_fd_ostream API
* m4/acinclude.m4 (OCTAVE_LLVM_LEGACY_PASSMANAGER_API): New function
to detect legacy passmanager API
* libinterp/corefcn/jit-util.h: Use legacy passmanager namespace if
necessary
* libinterp/corefcn/pt-jit.h (class tree_jit): Use legacy passmanager
class if necessary
* libinterp/corefcn/pt-jit.cc: Include appropriate header files
* libinterp/corefcn/pt-jit.cc (tree_jit::initialize): Use legacy
passmanager if necessary
* libinterp/corefcn/pt-jit.cc (tree_jit::optimize): Use correct API
* libinterp/corefcn/jit-typeinfo.cc: Include appropriate header file
author | Stefan Mahr <dac922@gmx.de> |
---|---|
date | Sun, 11 May 2014 02:28:33 +0200 |
parents | 175b392e91fe |
children | 4197fc428c7d |
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/* Copyright (C) 2004-2013 David Bateman Copyright (C) 1998-2004 Andy Adler This file is part of Octave. Octave is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. Octave is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with Octave; see the file COPYING. If not, see <http://www.gnu.org/licenses/>. */ #ifdef HAVE_CONFIG_H #include <config.h> #endif #include "gripes.h" #include "oct-obj.h" #include "ov.h" #include "ov-typeinfo.h" #include "ov-scalar.h" #include "ops.h" #include "xpow.h" #include "sparse-xpow.h" #include "sparse-xdiv.h" #include "ov-re-sparse.h" // sparse matrix by scalar ops. DEFBINOP_OP (add, sparse_matrix, scalar, +) DEFBINOP_OP (sub, sparse_matrix, scalar, -) DEFBINOP_OP (mul, sparse_matrix, scalar, *) DEFBINOP (div, sparse_matrix, scalar) { CAST_BINOP_ARGS (const octave_sparse_matrix&, const octave_scalar&); double d = v2.double_value (); octave_value retval; if (d == 0.0) gripe_divide_by_zero (); retval = octave_value (v1.sparse_matrix_value () / d); return retval; } DEFBINOP (pow, sparse_matrix, scalar) { CAST_BINOP_ARGS (const octave_sparse_matrix&, const octave_scalar&); double tmp = v2.scalar_value (); if (static_cast<int> (tmp) == tmp) return xpow (v1.sparse_matrix_value (), tmp); else return xpow (v1.matrix_value (), tmp); } DEFBINOP (ldiv, sparse_matrix, scalar) { CAST_BINOP_ARGS (const octave_sparse_matrix&, const octave_scalar&); if (v1.rows () == 1 && v1.columns () == 1) { double d = v1.scalar_value (); if (d == 0.0) gripe_divide_by_zero (); return octave_value (SparseMatrix(1, 1, v2.scalar_value () / d)); } else { MatrixType typ = v1.matrix_type (); SparseMatrix m1 = v1.sparse_matrix_value (); Matrix m2 = Matrix (1, 1, v2.scalar_value ()); Matrix ret = xleftdiv (m1, m2, typ); v1.matrix_type (typ); return ret; } } DEFBINOP_FN (lt, sparse_matrix, scalar, mx_el_lt) DEFBINOP_FN (le, sparse_matrix, scalar, mx_el_le) DEFBINOP_FN (eq, sparse_matrix, scalar, mx_el_eq) DEFBINOP_FN (ge, sparse_matrix, scalar, mx_el_ge) DEFBINOP_FN (gt, sparse_matrix, scalar, mx_el_gt) DEFBINOP_FN (ne, sparse_matrix, scalar, mx_el_ne) DEFBINOP_OP (el_mul, sparse_matrix, scalar, *) DEFBINOP (el_div, sparse_matrix, scalar) { CAST_BINOP_ARGS (const octave_sparse_matrix&, const octave_scalar&); double d = v2.double_value (); octave_value retval; if (d == 0.0) gripe_divide_by_zero (); retval = octave_value (v1.sparse_matrix_value () / d); return retval; } DEFBINOP_FN (el_pow, sparse_matrix, scalar, elem_xpow) DEFBINOP (el_ldiv, sparse_matrix, scalar) { CAST_BINOP_ARGS (const octave_sparse_matrix&, const octave_scalar&); return octave_value (x_el_div (v2.complex_value (), v1.sparse_matrix_value ())); } DEFBINOP_FN (el_and, sparse_matrix, scalar, mx_el_and) DEFBINOP_FN (el_or, sparse_matrix, scalar, mx_el_or) DEFCATOP (sm_s, sparse_matrix, scalar) { CAST_BINOP_ARGS (octave_sparse_matrix&, const octave_scalar&); SparseMatrix tmp (1, 1, v2.scalar_value ()); return octave_value (v1.sparse_matrix_value (). concat (tmp, ra_idx)); } DEFASSIGNOP (assign, sparse_matrix, scalar) { CAST_BINOP_ARGS (octave_sparse_matrix&, const octave_scalar&); SparseMatrix tmp (1, 1, v2.scalar_value ()); v1.assign (idx, tmp); return octave_value (); } void install_sm_s_ops (void) { INSTALL_BINOP (op_add, octave_sparse_matrix, octave_scalar, add); INSTALL_BINOP (op_sub, octave_sparse_matrix, octave_scalar, sub); INSTALL_BINOP (op_mul, octave_sparse_matrix, octave_scalar, mul); INSTALL_BINOP (op_div, octave_sparse_matrix, octave_scalar, div); INSTALL_BINOP (op_pow, octave_sparse_matrix, octave_scalar, pow); INSTALL_BINOP (op_ldiv, octave_sparse_matrix, octave_scalar, ldiv); INSTALL_BINOP (op_lt, octave_sparse_matrix, octave_scalar, lt); INSTALL_BINOP (op_le, octave_sparse_matrix, octave_scalar, le); INSTALL_BINOP (op_eq, octave_sparse_matrix, octave_scalar, eq); INSTALL_BINOP (op_ge, octave_sparse_matrix, octave_scalar, ge); INSTALL_BINOP (op_gt, octave_sparse_matrix, octave_scalar, gt); INSTALL_BINOP (op_ne, octave_sparse_matrix, octave_scalar, ne); INSTALL_BINOP (op_el_mul, octave_sparse_matrix, octave_scalar, el_mul); INSTALL_BINOP (op_el_div, octave_sparse_matrix, octave_scalar, el_div); INSTALL_BINOP (op_el_pow, octave_sparse_matrix, octave_scalar, el_pow); INSTALL_BINOP (op_el_ldiv, octave_sparse_matrix, octave_scalar, el_ldiv); INSTALL_BINOP (op_el_and, octave_sparse_matrix, octave_scalar, el_and); INSTALL_BINOP (op_el_or, octave_sparse_matrix, octave_scalar, el_or); INSTALL_CATOP (octave_sparse_matrix, octave_scalar, sm_s); INSTALL_ASSIGNOP (op_asn_eq, octave_sparse_matrix, octave_scalar, assign); }