Mercurial > octave-nkf
view examples/mysparse.c @ 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 | 4d7f95eb8bfe |
children | 9ac2357f19bc |
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#include "mex.h" void mexFunction (int nlhs, mxArray *plhs[], int nrhs, const mxArray *prhs[]) { mwSize m, n, nz; mxArray *v; mwIndex i; double *pr, *pi; double *pr2, *pi2; mwIndex *ir, *jc; mwIndex *ir2, *jc2; if (nrhs != 1 || ! mxIsSparse (prhs[0])) mexErrMsgTxt ("ARG1 must be a sparse matrix"); m = mxGetM (prhs[0]); n = mxGetN (prhs[0]); nz = mxGetNzmax (prhs[0]); if (mxIsComplex (prhs[0])) { mexPrintf ("Matrix is %d-by-%d complex sparse matrix", m, n); mexPrintf (" with %d elements\n", nz); pr = mxGetPr (prhs[0]); pi = mxGetPi (prhs[0]); ir = mxGetIr (prhs[0]); jc = mxGetJc (prhs[0]); i = n; while (jc[i] == jc[i-1] && i != 0) i--; mexPrintf ("last non-zero element (%d, %d) = (%g, %g)\n", ir[nz-1]+ 1, i, pr[nz-1], pi[nz-1]); v = mxCreateSparse (m, n, nz, mxCOMPLEX); pr2 = mxGetPr (v); pi2 = mxGetPi (v); ir2 = mxGetIr (v); jc2 = mxGetJc (v); for (i = 0; i < nz; i++) { pr2[i] = 2 * pr[i]; pi2[i] = 2 * pi[i]; ir2[i] = ir[i]; } for (i = 0; i < n + 1; i++) jc2[i] = jc[i]; if (nlhs > 0) plhs[0] = v; } else if (mxIsLogical (prhs[0])) { mxLogical *pbr, *pbr2; mexPrintf ("Matrix is %d-by-%d logical sparse matrix", m, n); mexPrintf (" with %d elements\n", nz); pbr = mxGetLogicals (prhs[0]); ir = mxGetIr (prhs[0]); jc = mxGetJc (prhs[0]); i = n; while (jc[i] == jc[i-1] && i != 0) i--; mexPrintf ("last non-zero element (%d, %d) = %d\n", ir[nz-1]+ 1, i, pbr[nz-1]); v = mxCreateSparseLogicalMatrix (m, n, nz); pbr2 = mxGetLogicals (v); ir2 = mxGetIr (v); jc2 = mxGetJc (v); for (i = 0; i < nz; i++) { pbr2[i] = pbr[i]; ir2[i] = ir[i]; } for (i = 0; i < n + 1; i++) jc2[i] = jc[i]; if (nlhs > 0) plhs[0] = v; } else { mexPrintf ("Matrix is %d-by-%d real sparse matrix", m, n); mexPrintf (" with %d elements\n", nz); pr = mxGetPr (prhs[0]); ir = mxGetIr (prhs[0]); jc = mxGetJc (prhs[0]); i = n; while (jc[i] == jc[i-1] && i != 0) i--; mexPrintf ("last non-zero element (%d, %d) = %g\n", ir[nz-1]+ 1, i, pr[nz-1]); v = mxCreateSparse (m, n, nz, mxREAL); pr2 = mxGetPr (v); ir2 = mxGetIr (v); jc2 = mxGetJc (v); for (i = 0; i < nz; i++) { pr2[i] = 2 * pr[i]; ir2[i] = ir[i]; } for (i = 0; i < n + 1; i++) jc2[i] = jc[i]; if (nlhs > 0) plhs[0] = v; } }