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ddot.c
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ddot.c
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/*
% ddotX = ddot(d,X,blkstart [, Xblkjc])
% DDOT Given N x m matrix X, creates (blkstart(end)-blkstart(1)) x m matrix
% ddotX, having entries d[i]'* xj[i] for each (Lorentz norm bound) block
% blkstart(i):blkstart(i+1)-1. If X is sparse, then Xblkjc(:,2:3) should
% point to first and 1-beyond-last nonzero in blkstart range for each column.
%
% SEE ALSO sedumi, partitA.
% ********** INTERNAL FUNCTION OF SEDUMI **********
function ddotX = ddot(d,X,blkstart, Xblkjc)
% This file is part of SeDuMi 1.1 by Imre Polik and Oleksandr Romanko
% Copyright (C) 2005 McMaster University, Hamilton, CANADA (since 1.1)
%
% Copyright (C) 2001 Jos F. Sturm (up to 1.05R5)
% Dept. Econometrics & O.R., Tilburg University, the Netherlands.
% Supported by the Netherlands Organization for Scientific Research (NWO).
%
% Affiliation SeDuMi 1.03 and 1.04Beta (2000):
% Dept. Quantitative Economics, Maastricht University, the Netherlands.
%
% Affiliations up to SeDuMi 1.02 (AUG1998):
% CRL, McMaster University, Canada.
% Supported by the Netherlands Organization for Scientific Research (NWO).
%
% This program 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 2 of the License, or
% (at your option) any later version.
%
% This program 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 this program; if not, write to the Free Software
% Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA
% 02110-1301, USA
*/
#include <string.h>
#include "mex.h"
#include "blksdp.h"
#define DDOTX_OUT plhs[0]
#define NPAROUT 1
#define D_IN prhs[0]
#define X_IN prhs[1]
#define BLKSTART_IN prhs[2]
#define NPARINMIN 3
#define XBLKJC_IN prhs[3]
#define NPARIN 4
/* ************************************************************
PROCEDURE ddotxj -Compute y[k]= d[k]'*xpr[k] for each lorentz block k.
INPUT
d - qDim scaling vector with qDim := blkstart[nblk]-blkstart[0].
xpr - qDim data vector.
blkstart - length nblk+1 array, listing 1st subscript per block.
NOTE: should have blkstart[0] == 0.
nblk - Number of blocks.
OUTPUT
ypr - nblk vector. Gives d[k]'*xj[k] for each block.
************************************************************ */
void ddotxj(double *ypr, const double *d, const double *xpr,
const mwIndex *blkstart, const mwIndex nblk)
{
mwIndex k;
mxAssert(blkstart[0] == 0,"");
for(k = 0; k < nblk; k++)
ypr[k] = realdot(d+blkstart[k],xpr+blkstart[k], blkstart[k+1]-blkstart[k]);
}
/* ************************************************************
PROCEDURE spddotxj - Compute y[k] = d_k'*xj_k for each nonzero
block in xj.
INPUT
d - qDim scaling vector with qDim := blkstart[nblk]-blkstart[0].
xir, xpr - sparse matrix. We compute d[k]'*xj[k] for each (lorentz) block
where the column xj has nonzeros.
xjc0, xjc1 - Length m arrays, subscripts of column j in blkstart-range
are between xjc0(j) and xjc1(j).
blkstart - length nblk+1 array. Lorentz block k has subscripts
blkstart[k]:blkstart[k+1]-1.
xblk - length qDim array, with k = xblk(i-blkstart[0]) iff
blkstart[k] <= i < blkstart[k+1], k=0:nblk-1.
OUTPUT
y - sparse nblk x m matrix, with y.jc[m] <= sum(xjc1-xjc0).
y(k,j) = d[k]'*xj[k]
************************************************************ */
void spddotxj(jcir y, const double *d,
const mwIndex *xir, const double *xpr, const mwIndex *xjc0,
const mwIndex *xjc1, const mwIndex *xblk, const mwIndex *blkstart,
const mwIndex nblk, const mwIndex m)
{
mwIndex knz, nexti, inz, i, j, k, lend;
double yk;
/* ------------------------------------------------------------
INIT: Let blkstart[0] point to 1st nonzero in d and xblk, and
let knz poin to 1st available entry in y.
Let lend := blkstart[nblk] be 1 beyond valid subscripts.
------------------------------------------------------------ */
d -= blkstart[0]; /* Make d=d(blkstart[0]:blkstart[lorN]) */
xblk -= blkstart[0];
knz = 0;
lend = blkstart[nblk];
for(j = 0; j < m; j++){
y.jc[j] = knz;
/* ------------------------------------------------------------
Process column only if nonzero subscripts in blkstart[0:nblk].
------------------------------------------------------------ */
if((inz = xjc0[j]) < xjc1[j])
if( (i = xir[inz]) < lend){
/* ------------------------------------------------------------
Open initial block k; current block has subscripts smaller than nexti.
Accumulate yk = ddotxj[k].
------------------------------------------------------------ */
k = xblk[i];
nexti = blkstart[k + 1];
yk = d[i] * xpr[inz];
/* ------------------------------------------------------------
Browse through nonzeros in xj
------------------------------------------------------------ */
for(++inz; inz < xjc1[j]; inz++)
if( (i = xir[inz]) < nexti)
yk += d[i] * xpr[inz];
else if(i < lend){
/* ------------------------------------------------------------
If we finished the previous nonzero Lorentz block, then write entry,
and initialize new block.
------------------------------------------------------------ */
y.ir[knz] = k; /* yir lists Lorentz blocks */
y.pr[knz++] = yk;
k = xblk[i]; /* init new Lorentz block */
nexti = blkstart[k + 1];
yk = d[i] * xpr[inz];
}
else /* finished with all Lorentz blocks */
break;
/* ------------------------------------------------------------
Write last yk = ddotxj[k] entry into y(:,j).
------------------------------------------------------------ */
y.ir[knz] = k; /* yir lists Lorentz blocks */
y.pr[knz++] = yk;
} /* If column j has valid nonzeros */
} /* j=0:m-1 */
/* ------------------------------------------------------------
Close last column of y
------------------------------------------------------------ */
y.jc[m] = knz;
}
/* ============================================================
MEXFUNCTION
============================================================ */
/* ************************************************************
PROCEDURE mexFunction - Entry for Matlab
************************************************************ */
void mexFunction(int nlhs, mxArray *plhs[],
int nrhs, const mxArray *prhs[])
{
mwIndex i, j, k, m, nrows, maxnnz, nblk, qDim;
const double *d, *XjcPr, *blkstartPr;
mwIndex *xjc1, *xblk, *blkstart;
jcir X, ddotx;
/* ------------------------------------------------------------
Check for proper number of arguments
------------------------------------------------------------ */
mxAssert(nrhs >= NPARINMIN, "ddot requires more input arguments.");
mxAssert(nlhs <= NPAROUT, "ddot generates less output arguments.");
/* ------------------------------------------------------------
Get INPUTS d, X, blkstart.
------------------------------------------------------------ */
d = mxGetPr(D_IN);
qDim = mxGetM(D_IN) * mxGetN(D_IN);
nrows = mxGetM(X_IN);
m = mxGetN(X_IN);
X.pr = mxGetPr(X_IN);
blkstartPr = mxGetPr(BLKSTART_IN);
nblk = mxGetM(BLKSTART_IN) * mxGetN(BLKSTART_IN) - 1;
mxAssert(nblk >= 0, "blkstart size mismatch.");
/* ------------------------------------------------------------
Allocate mwIndex working array blkstart(nblk+1).
------------------------------------------------------------ */
blkstart = (mwIndex *) mxCalloc(nblk + 1, sizeof(mwIndex));
/* ------------------------------------------------------------
Convert Fortran double to C mwIndex
------------------------------------------------------------ */
for(i = 0; i <= nblk; i++){
j = (mwIndex) blkstartPr[i]; /* double to mwIndex */
mxAssert(j>0,"");
blkstart[i] = --j;
}
if(qDim != blkstart[nblk] - blkstart[0]){
mxAssert(qDim >= blkstart[nblk], "d size mismatch.");
d += blkstart[0]; /* Point to Lorentz norm-bound */
qDim = blkstart[nblk] - blkstart[0];
}
/* ------------------------------------------------------------
CASE THAT X IS FULL:
------------------------------------------------------------ */
if(!mxIsSparse(X_IN)){
if(nrows != qDim) {
if(nrows < blkstart[nblk]){
mxAssert(nrows == nblk + qDim, "X size mismatch");
X.pr += nblk; /* Lorentz tr + norm bound */
}
else { /* LP, Lorentz, PSD */
X.pr += blkstart[0]; /* Point to Lorentz norm-bound */
}
}
/* ------------------------------------------------------------
DDOTX is full nblk x m.
------------------------------------------------------------ */
DDOTX_OUT = mxCreateDoubleMatrix(nblk, m, mxREAL);
ddotx.pr = mxGetPr(DDOTX_OUT);
/* ------------------------------------------------------------
Let blkstart -= blkstart[0], so that blkstart[0] = 0.
------------------------------------------------------------ */
j = blkstart[0];
for(i = 0; i <= nblk; i++)
blkstart[i] -= j;
/* ------------------------------------------------------------
Compute d[k]'*x[k,i] for all Lorentz blocks k.
------------------------------------------------------------ */
for(i = 0; i < m; i++){
ddotxj(ddotx.pr, d, X.pr, blkstart, nblk);
ddotx.pr += nblk;
X.pr += nrows; /* to next column */
}
}
else{
/* ------------------------------------------------------------
The CASE that X is SPARSE:
------------------------------------------------------------ */
mxAssert(nrows >= blkstart[nblk], "X size mismatch");
X.jc = mxGetJc(X_IN);
X.ir = mxGetIr(X_IN);
/* ------------------------------------------------------------
Get XqjcPr, pointing to start of Lorentz blocks in X.
------------------------------------------------------------ */
mxAssert(nrhs >= NPARIN, "ddot with sparse X requires more input arguments.");
mxAssert(mxGetM(XBLKJC_IN) == m && mxGetN(XBLKJC_IN) >= 3, "Xjc size mismatch");
XjcPr = mxGetPr(XBLKJC_IN) + m; /* Point to Xjc(:,2) */
/* ------------------------------------------------------------
Allocate working arrays:
mwIndex xjc1(2*m), xblk(qDim).
------------------------------------------------------------ */
xjc1 = (mwIndex *) mxCalloc(MAX(2*m,1), sizeof(mwIndex) );
xblk = (mwIndex *) mxCalloc(MAX(qDim,1), sizeof(mwIndex) );
/* ------------------------------------------------------------
Convert double to mwIndex:
------------------------------------------------------------ */
for(i = 0; i < 2*m; i++)
xjc1[i] = (mwIndex) XjcPr[i]; /* double to mwIndex */
/* ------------------------------------------------------------
Let k = xblk(j-blkstart[0]) iff
blkstart[k] <= j < blkstart[k+1], k=0:nblk-1.
------------------------------------------------------------ */
j = 0;
for(k = 0; k < nblk; k++){
i = blkstart[k+1] - blkstart[0];
while(j < i)
xblk[j++] = k;
}
/* ------------------------------------------------------------
Let maxnnz := sum(xjc1(:,2)-xjc1(:,1)).
Create sparse output ddotX(nblk,m,maxnnz)
------------------------------------------------------------ */
maxnnz = 0;
for(i = 0; i < m; i++)
maxnnz += xjc1[m+i] - xjc1[i];
maxnnz = MAX(1, maxnnz);
DDOTX_OUT = mxCreateSparse(nblk,m, maxnnz,mxREAL);
ddotx.jc = mxGetJc(DDOTX_OUT);
ddotx.ir = mxGetIr(DDOTX_OUT);
ddotx.pr = mxGetPr(DDOTX_OUT);
/* ------------------------------------------------------------
The real job:
------------------------------------------------------------ */
spddotxj(ddotx, d, X.ir, X.pr,xjc1,xjc1+m, xblk,blkstart,nblk,m);
/* ------------------------------------------------------------
REALLOC (shrink) ddotx to ddotx.jc[m] nonzeros.
------------------------------------------------------------ */
maxnnz = MAX(1,ddotx.jc[m]);
if((ddotx.ir = (mwIndex *) mxRealloc(ddotx.ir, maxnnz * sizeof(mwIndex))) == NULL)
mexErrMsgTxt("Memory allocation error");
if((ddotx.pr = (double *) mxRealloc(ddotx.pr, maxnnz*sizeof(double)))
== NULL)
mexErrMsgTxt("Memory allocation error");
mxSetPr(DDOTX_OUT,ddotx.pr);
mxSetIr(DDOTX_OUT,ddotx.ir);
mxSetNzmax(DDOTX_OUT,maxnnz);
/* ------------------------------------------------------------
Release working arrays (SPARSE PART).
------------------------------------------------------------ */
mxFree(xjc1);
mxFree(xblk);
}
/* ------------------------------------------------------------
Release common working arrays.
------------------------------------------------------------ */
mxFree(blkstart);
}