Mercurial > hg > smallbox
view util/ksvd utils/col2imstep.c @ 218:c38d965b5a1d luisf_dev
Moved CVX_add_const_Audio_declipping.m from solvers to the examples/AudioInpainting folder.
author | Aris Gretsistas <aris.gretsistas@eecs.qmul.ac.uk> |
---|---|
date | Thu, 22 Mar 2012 15:37:45 +0000 |
parents | c3eca463202d |
children |
line wrap: on
line source
/************************************************************************** * * File name: col2imstep.c * * Ron Rubinstein * Computer Science Department * Technion, Haifa 32000 Israel * ronrubin@cs * * Last Updated: 31.8.2009 * *************************************************************************/ #include "mex.h" /* Input Arguments */ #define B_IN prhs[0] #define N_IN prhs[1] #define SZ_IN prhs[2] #define S_IN prhs[3] /* Output Arguments */ #define X_OUT plhs[0] void mexFunction(int nlhs, mxArray *plhs[], int nrhs, const mxArray*prhs[]) { double *x, *b, *s; mwSize sz[3], stepsize[3], n[3], ndims; mwIndex i, j, k, l, m, t, blocknum; /* Check for proper number of arguments */ if (nrhs < 3 || nrhs > 4) { mexErrMsgTxt("Invalid number of input arguments."); } else if (nlhs > 1) { mexErrMsgTxt("Too many output arguments."); } /* Check the the input dimensions */ if (!mxIsDouble(B_IN) || mxIsComplex(B_IN) || mxGetNumberOfDimensions(B_IN)>2) { mexErrMsgTxt("B should be a double matrix."); } if (!mxIsDouble(N_IN) || mxIsComplex(N_IN) || mxGetNumberOfDimensions(N_IN)>2) { mexErrMsgTxt("Invalid output matrix size."); } ndims = mxGetM(N_IN)*mxGetN(N_IN); if (ndims<2 || ndims>3) { mexErrMsgTxt("Output matrix can only be 2-D or 3-D."); } if (!mxIsDouble(SZ_IN) || mxIsComplex(SZ_IN) || mxGetNumberOfDimensions(SZ_IN)>2 || mxGetM(SZ_IN)*mxGetN(SZ_IN)!=ndims) { mexErrMsgTxt("Invalid block size."); } if (nrhs == 4) { if (!mxIsDouble(S_IN) || mxIsComplex(S_IN) || mxGetNumberOfDimensions(S_IN)>2 || mxGetM(S_IN)*mxGetN(S_IN)!=ndims) { mexErrMsgTxt("Invalid step size."); } } /* Get parameters */ s = mxGetPr(N_IN); if (s[0]<1 || s[1]<1 || (ndims==3 && s[2]<1)) { mexErrMsgTxt("Invalid output matrix size."); } n[0] = (mwSize)(s[0] + 0.01); n[1] = (mwSize)(s[1] + 0.01); n[2] = ndims==3 ? (mwSize)(s[2] + 0.01) : 1; s = mxGetPr(SZ_IN); if (s[0]<1 || s[1]<1 || (ndims==3 && s[2]<1)) { mexErrMsgTxt("Invalid block size."); } sz[0] = (mwSize)(s[0] + 0.01); sz[1] = (mwSize)(s[1] + 0.01); sz[2] = ndims==3 ? (mwSize)(s[2] + 0.01) : 1; if (nrhs == 4) { s = mxGetPr(S_IN); if (s[0]<1 || s[1]<1 || (ndims==3 && s[2]<1)) { mexErrMsgTxt("Invalid step size."); } stepsize[0] = (mwSize)(s[0] + 0.01); stepsize[1] = (mwSize)(s[1] + 0.01); stepsize[2] = ndims==3 ? (mwSize)(s[2] + 0.01) : 1; } else { stepsize[0] = stepsize[1] = stepsize[2] = 1; } if (n[0]<sz[0] || n[1]<sz[1] || (ndims==3 && n[2]<sz[2])) { mexErrMsgTxt("Block size too large."); } if (mxGetN(B_IN) != ((n[0]-sz[0])/stepsize[0]+1)*((n[1]-sz[1])/stepsize[1]+1)*((n[2]-sz[2])/stepsize[2]+1)) { mexErrMsgTxt("Invalid number of columns in B. Please use IM2COLSTEP to compute B."); } /* Create a matrix for the return argument */ X_OUT = mxCreateNumericArray(ndims, n, mxDOUBLE_CLASS, mxREAL); /* Assign pointers */ b = mxGetPr(B_IN); x = mxGetPr(X_OUT); /* Do the actual computation */ blocknum = 0; /* iterate over all blocks */ for (k=0; k<=n[2]-sz[2]; k+=stepsize[2]) { for (j=0; j<=n[1]-sz[1]; j+=stepsize[1]) { for (i=0; i<=n[0]-sz[0]; i+=stepsize[0]) { /* add single block */ for (m=0; m<sz[2]; m++) { for (l=0; l<sz[1]; l++) { for (t=0; t<sz[0]; t++) { (x+(k+m)*n[0]*n[1]+(j+l)*n[0]+i)[t] += (b + blocknum*sz[0]*sz[1]*sz[2] + m*sz[0]*sz[1] + l*sz[0])[t]; } } } blocknum++; } } } return; }