/*============================================================================ WCSLIB 6.2 - an implementation of the FITS WCS standard. Copyright (C) 1995-2018, Mark Calabretta This file is part of WCSLIB. WCSLIB is free software: you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. WCSLIB 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 Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with WCSLIB. If not, see http://www.gnu.org/licenses. Direct correspondence concerning WCSLIB to mark@calabretta.id.au Author: Mark Calabretta, Australia Telescope National Facility, CSIRO. http://www.atnf.csiro.au/people/Mark.Calabretta $Id: lin.c,v 6.2 2018/10/20 10:03:13 mcalabre Exp $ *===========================================================================*/ #include #include #include #include #include "wcserr.h" #include "wcsprintf.h" #include "lin.h" #include "dis.h" const int LINSET = 137; /* Map status return value to message. */ const char *lin_errmsg[] = { "Success", "Null linprm pointer passed", "Memory allocation failed", "PCi_ja matrix is singular", "Failed to initialize distortion functions", "Distort error", "De-distort error"}; /* Map error returns for lower-level routines. */ const int lin_diserr[] = { LINERR_SUCCESS, /* 0: DISERR_SUCCESS */ LINERR_NULL_POINTER, /* 1: DISERR_NULL_POINTER */ LINERR_MEMORY, /* 2: DISERR_MEMORY */ LINERR_DISTORT_INIT, /* 3: DISERR_BAD_PARAM */ LINERR_DISTORT, /* 4: DISERR_DISTORT */ LINERR_DEDISTORT /* 5: DISERR_DEDISTORT */ }; /* Convenience macro for invoking wcserr_set(). */ #define LIN_ERRMSG(status) WCSERR_SET(status), lin_errmsg[status] /*--------------------------------------------------------------------------*/ int linini(int alloc, int naxis, struct linprm *lin) { return lininit(alloc, naxis, lin, -1); } /*--------------------------------------------------------------------------*/ int lininit(int alloc, int naxis, struct linprm *lin, int ndpmax) { static const char *function = "lininit"; int i, j; double *pc; struct wcserr **err; if (lin == 0x0) return LINERR_NULL_POINTER; /* Initialize error message handling. */ err = &(lin->err); if (lin->flag != -1) { if (lin->err) free(lin->err); } lin->err = 0x0; /* Initialize memory management. */ if (lin->flag == -1 || lin->m_flag != LINSET) { if (lin->flag == -1) { lin->dispre = 0x0; lin->disseq = 0x0; lin->tmpcrd = 0x0; } lin->m_flag = 0; lin->m_naxis = 0; lin->m_crpix = 0x0; lin->m_pc = 0x0; lin->m_cdelt = 0x0; lin->m_dispre = 0x0; lin->m_disseq = 0x0; } if (naxis < 0) { return wcserr_set(WCSERR_SET(LINERR_MEMORY), "naxis must not be negative (got %d)", naxis); } /* Allocate memory for arrays if required. */ if (alloc || lin->crpix == 0x0 || lin->pc == 0x0 || lin->cdelt == 0x0) { /* Was sufficient allocated previously? */ if (lin->m_flag == LINSET && lin->m_naxis < naxis) { /* No, free it. */ linfree(lin); } if (alloc || lin->crpix == 0x0) { if (lin->m_crpix) { /* In case the caller fiddled with it. */ lin->crpix = lin->m_crpix; } else { if ((lin->crpix = calloc(naxis, sizeof(double))) == 0x0) { return wcserr_set(LIN_ERRMSG(LINERR_MEMORY)); } lin->m_flag = LINSET; lin->m_naxis = naxis; lin->m_crpix = lin->crpix; } } if (alloc || lin->pc == 0x0) { if (lin->m_pc) { /* In case the caller fiddled with it. */ lin->pc = lin->m_pc; } else { if ((lin->pc = calloc(naxis*naxis, sizeof(double))) == 0x0) { linfree(lin); return wcserr_set(LIN_ERRMSG(LINERR_MEMORY)); } lin->m_flag = LINSET; lin->m_naxis = naxis; lin->m_pc = lin->pc; } } if (alloc || lin->cdelt == 0x0) { if (lin->m_cdelt) { /* In case the caller fiddled with it. */ lin->cdelt = lin->m_cdelt; } else { if ((lin->cdelt = calloc(naxis, sizeof(double))) == 0x0) { linfree(lin); return wcserr_set(LIN_ERRMSG(LINERR_MEMORY)); } lin->m_flag = LINSET; lin->m_naxis = naxis; lin->m_cdelt = lin->cdelt; } } } /* Reinitialize disprm structs if we are managing them. */ if (lin->m_dispre) { disinit(1, naxis, lin->dispre, ndpmax); } if (lin->m_disseq) { disinit(1, naxis, lin->disseq, ndpmax); } /* Free memory allocated by linset(). */ if (lin->flag == LINSET) { if (lin->piximg) free(lin->piximg); if (lin->imgpix) free(lin->imgpix); if (lin->tmpcrd) free(lin->tmpcrd); } lin->piximg = 0x0; lin->imgpix = 0x0; lin->i_naxis = 0; lin->unity = 0; lin->affine = 0; lin->simple = 0; lin->tmpcrd = 0x0; lin->flag = 0; lin->naxis = naxis; /* CRPIXja defaults to 0.0. */ for (j = 0; j < naxis; j++) { lin->crpix[j] = 0.0; } /* PCi_ja defaults to the unit matrix. */ pc = lin->pc; for (i = 0; i < naxis; i++) { for (j = 0; j < naxis; j++) { if (j == i) { *pc = 1.0; } else { *pc = 0.0; } pc++; } } /* CDELTia defaults to 1.0. */ for (i = 0; i < naxis; i++) { lin->cdelt[i] = 1.0; } return 0; } /*--------------------------------------------------------------------------*/ int lindis(int sequence, struct linprm *lin, struct disprm *dis) { return lindist(sequence, lin, dis, -1); } /*--------------------------------------------------------------------------*/ int lindist(int sequence, struct linprm *lin, struct disprm *dis, int ndpmax) { static const char *function = "lindist"; int status; struct wcserr **err; if (lin == 0x0) return LINERR_NULL_POINTER; err = &(lin->err); if (sequence == 1) { if (lin->m_dispre) { disfree(lin->m_dispre); free(lin->m_dispre); } lin->dispre = dis; lin->m_flag = LINSET; lin->m_dispre = dis; } else if (sequence == 2) { if (lin->m_disseq) { disfree(lin->m_disseq); free(lin->m_disseq); } lin->disseq = dis; lin->m_flag = LINSET; lin->m_disseq = dis; } else { return wcserr_set(WCSERR_SET(LINERR_DISTORT_INIT), "Invalid sequence (%d)", sequence); } if (dis) { if ((status = disinit(1, lin->naxis, dis, ndpmax))) { return wcserr_set(LIN_ERRMSG(lin_diserr[status])); } } return 0; } /*--------------------------------------------------------------------------*/ int lincpy(int alloc, const struct linprm *linsrc, struct linprm *lindst) { static const char *function = "lincpy"; int i, j, naxis, status; const double *srcp; double *dstp; struct wcserr **err; if (linsrc == 0x0) return LINERR_NULL_POINTER; if (lindst == 0x0) return LINERR_NULL_POINTER; err = &(lindst->err); naxis = linsrc->naxis; if (naxis < 1) { return wcserr_set(WCSERR_SET(LINERR_MEMORY), "naxis must be positive (got %d)", naxis); } if ((status = lininit(alloc, naxis, lindst, 0))) { return status; } srcp = linsrc->crpix; dstp = lindst->crpix; for (j = 0; j < naxis; j++) { *(dstp++) = *(srcp++); } srcp = linsrc->pc; dstp = lindst->pc; for (i = 0; i < naxis; i++) { for (j = 0; j < naxis; j++) { *(dstp++) = *(srcp++); } } srcp = linsrc->cdelt; dstp = lindst->cdelt; for (i = 0; i < naxis; i++) { *(dstp++) = *(srcp++); } if (linsrc->dispre) { if (!lindst->dispre) { if ((lindst->dispre = calloc(1, sizeof(struct disprm))) == 0x0) { return wcserr_set(LIN_ERRMSG(LINERR_MEMORY)); } lindst->m_dispre = lindst->dispre; } if ((status = discpy(alloc, linsrc->dispre, lindst->dispre))) { status = wcserr_set(LIN_ERRMSG(lin_diserr[status])); goto cleanup; } } if (linsrc->disseq) { if (!lindst->disseq) { if ((lindst->disseq = calloc(1, sizeof(struct disprm))) == 0x0) { return wcserr_set(LIN_ERRMSG(LINERR_MEMORY)); } lindst->m_disseq = lindst->disseq; } if ((status = discpy(alloc, linsrc->disseq, lindst->disseq))) { status = wcserr_set(LIN_ERRMSG(lin_diserr[status])); goto cleanup; } } cleanup: if (status) { if (lindst->m_dispre) { disfree(lindst->m_dispre); free(lindst->m_dispre); lindst->m_dispre = 0x0; lindst->dispre = 0x0; } if (lindst->m_disseq) { disfree(lindst->m_disseq); free(lindst->m_disseq); lindst->m_disseq = 0x0; lindst->disseq = 0x0; } } return status; } /*--------------------------------------------------------------------------*/ int linfree(struct linprm *lin) { if (lin == 0x0) return LINERR_NULL_POINTER; if (lin->flag != -1) { /* Optionally allocated by lininit() for given parameters. */ if (lin->m_flag == LINSET) { if (lin->crpix == lin->m_crpix) lin->crpix = 0x0; if (lin->pc == lin->m_pc) lin->pc = 0x0; if (lin->cdelt == lin->m_cdelt) lin->cdelt = 0x0; if (lin->dispre == lin->m_dispre) lin->dispre = 0x0; if (lin->disseq == lin->m_disseq) lin->disseq = 0x0; if (lin->m_crpix) free(lin->m_crpix); if (lin->m_pc) free(lin->m_pc); if (lin->m_cdelt) free(lin->m_cdelt); if (lin->m_dispre) { disfree(lin->m_dispre); free(lin->m_dispre); } if (lin->m_disseq) { disfree(lin->m_disseq); free(lin->m_disseq); } } /* Allocated unconditionally by linset(). */ if (lin->piximg) free(lin->piximg); if (lin->imgpix) free(lin->imgpix); if (lin->tmpcrd) free(lin->tmpcrd); if (lin->err) free(lin->err); } lin->m_flag = 0; lin->m_naxis = 0; lin->m_crpix = 0x0; lin->m_pc = 0x0; lin->m_cdelt = 0x0; lin->m_dispre = 0x0; lin->m_disseq = 0x0; lin->piximg = 0x0; lin->imgpix = 0x0; lin->i_naxis = 0; lin->tmpcrd = 0x0; lin->err = 0x0; lin->flag = 0; return 0; } /*--------------------------------------------------------------------------*/ int linprt(const struct linprm *lin) { int i, j, k; if (lin == 0x0) return LINERR_NULL_POINTER; if (lin->flag != LINSET) { wcsprintf("The linprm struct is UNINITIALIZED.\n"); return 0; } wcsprintf(" flag: %d\n", lin->flag); /* Parameters supplied. */ wcsprintf(" naxis: %d\n", lin->naxis); WCSPRINTF_PTR(" crpix: ", lin->crpix, "\n"); wcsprintf(" "); for (j = 0; j < lin->naxis; j++) { wcsprintf(" %#- 11.5g", lin->crpix[j]); } wcsprintf("\n"); k = 0; WCSPRINTF_PTR(" pc: ", lin->pc, "\n"); for (i = 0; i < lin->naxis; i++) { wcsprintf(" pc[%d][]:", i); for (j = 0; j < lin->naxis; j++) { wcsprintf(" %#- 11.5g", lin->pc[k++]); } wcsprintf("\n"); } WCSPRINTF_PTR(" cdelt: ", lin->cdelt, "\n"); wcsprintf(" "); for (i = 0; i < lin->naxis; i++) { wcsprintf(" %#- 11.5g", lin->cdelt[i]); } wcsprintf("\n"); WCSPRINTF_PTR(" dispre: ", lin->dispre, ""); if (lin->dispre != 0x0) wcsprintf(" (see below)"); wcsprintf("\n"); WCSPRINTF_PTR(" disseq: ", lin->disseq, ""); if (lin->disseq != 0x0) wcsprintf(" (see below)"); wcsprintf("\n"); /* Derived values. */ if (lin->piximg == 0x0) { wcsprintf(" piximg: (nil)\n"); } else { k = 0; for (i = 0; i < lin->naxis; i++) { wcsprintf("piximg[%d][]:", i); for (j = 0; j < lin->naxis; j++) { wcsprintf(" %#- 11.5g", lin->piximg[k++]); } wcsprintf("\n"); } } if (lin->imgpix == 0x0) { wcsprintf(" imgpix: (nil)\n"); } else { k = 0; for (i = 0; i < lin->naxis; i++) { wcsprintf("imgpix[%d][]:", i); for (j = 0; j < lin->naxis; j++) { wcsprintf(" %#- 11.5g", lin->imgpix[k++]); } wcsprintf("\n"); } } wcsprintf(" i_naxis: %d\n", lin->i_naxis); wcsprintf(" unity: %d\n", lin->unity); wcsprintf(" affine: %d\n", lin->affine); wcsprintf(" simple: %d\n", lin->simple); /* Error handling. */ WCSPRINTF_PTR(" err: ", lin->err, "\n"); if (lin->err) { wcserr_prt(lin->err, " "); } /* Work arrays. */ WCSPRINTF_PTR(" tmpcrd: ", lin->tmpcrd, "\n"); /* Memory management. */ wcsprintf(" m_flag: %d\n", lin->m_flag); wcsprintf(" m_naxis: %d\n", lin->m_naxis); WCSPRINTF_PTR(" m_crpix: ", lin->m_crpix, ""); if (lin->m_crpix == lin->crpix) wcsprintf(" (= crpix)"); wcsprintf("\n"); WCSPRINTF_PTR(" m_pc: ", lin->m_pc, ""); if (lin->m_pc == lin->pc) wcsprintf(" (= pc)"); wcsprintf("\n"); WCSPRINTF_PTR(" m_cdelt: ", lin->m_cdelt, ""); if (lin->m_cdelt == lin->cdelt) wcsprintf(" (= cdelt)"); wcsprintf("\n"); WCSPRINTF_PTR(" m_dispre: ", lin->m_dispre, ""); if (lin->dispre && lin->m_dispre == lin->dispre) wcsprintf(" (= dispre)"); wcsprintf("\n"); WCSPRINTF_PTR(" m_disseq: ", lin->m_disseq, ""); if (lin->disseq && lin->m_disseq == lin->disseq) wcsprintf(" (= disseq)"); wcsprintf("\n"); /* Distortion parameters (from above). */ if (lin->dispre) { wcsprintf("\n"); wcsprintf("dispre.*\n"); disprt(lin->dispre); } if (lin->disseq) { wcsprintf("\n"); wcsprintf("disseq.*\n"); disprt(lin->disseq); } return 0; } /*--------------------------------------------------------------------------*/ int linperr(const struct linprm *lin, const char *prefix) { if (lin == 0x0) return LINERR_NULL_POINTER; if (lin->err && wcserr_prt(lin->err, prefix) == 0) { if (lin->dispre) wcserr_prt(lin->dispre->err, prefix); if (lin->disseq) wcserr_prt(lin->disseq->err, prefix); } return 0; } /*--------------------------------------------------------------------------*/ int linset(struct linprm *lin) { static const char *function = "linset"; int i, j, naxis, status; double *pc, *piximg; struct wcserr **err; if (lin == 0x0) return LINERR_NULL_POINTER; err = &(lin->err); naxis = lin->naxis; /* Check for a unit matrix. */ lin->unity = 1; pc = lin->pc; for (i = 0; i < naxis; i++) { for (j = 0; j < naxis; j++) { if (j == i) { if (*(pc++) != 1.0) { lin->unity = 0; break; } } else { if (*(pc++) != 0.0) { lin->unity = 0; break; } } } } if (lin->unity) { if (lin->flag == LINSET) { /* Free memory that may have been allocated previously. */ if (lin->piximg) free(lin->piximg); if (lin->imgpix) free(lin->imgpix); } lin->piximg = 0x0; lin->imgpix = 0x0; lin->i_naxis = 0; /* Check cdelt. */ for (i = 0; i < naxis; i++) { if (lin->cdelt[i] == 0.0) { return wcserr_set(LIN_ERRMSG(LINERR_SINGULAR_MTX)); } } } else { if (lin->flag != LINSET || lin->i_naxis < naxis) { if (lin->flag == LINSET) { /* Free memory that may have been allocated previously. */ if (lin->piximg) free(lin->piximg); if (lin->imgpix) free(lin->imgpix); } /* Allocate memory for internal arrays. */ if ((lin->piximg = calloc(naxis*naxis, sizeof(double))) == 0x0) { return wcserr_set(LIN_ERRMSG(LINERR_MEMORY)); } if ((lin->imgpix = calloc(naxis*naxis, sizeof(double))) == 0x0) { free(lin->piximg); return wcserr_set(LIN_ERRMSG(LINERR_MEMORY)); } lin->i_naxis = naxis; } /* Compute the pixel-to-image transformation matrix. */ pc = lin->pc; piximg = lin->piximg; for (i = 0; i < naxis; i++) { for (j = 0; j < naxis; j++) { if (lin->disseq == 0x0) { /* No sequent distortions, incorporate cdelt into piximg. */ *(piximg++) = lin->cdelt[i] * (*(pc++)); } else { *(piximg++) = *(pc++); } } } /* Compute the image-to-pixel transformation matrix. */ if ((status = matinv(naxis, lin->piximg, lin->imgpix))) { return wcserr_set(LIN_ERRMSG(status)); } } /* Set up the distortion functions. */ lin->affine = 1; if (lin->dispre) { if ((status = disset(lin->dispre))) { return wcserr_set(LIN_ERRMSG(lin_diserr[status])); } lin->affine = 0; } if (lin->disseq) { if ((status = disset(lin->disseq))) { return wcserr_set(LIN_ERRMSG(lin_diserr[status])); } lin->affine = 0; } lin->simple = lin->unity && lin->affine; /* Create work arrays. */ if (lin->tmpcrd) free(lin->tmpcrd); if ((lin->tmpcrd = calloc(naxis, sizeof(double))) == 0x0) { linfree(lin); return wcserr_set(LIN_ERRMSG(LINERR_MEMORY)); } lin->flag = LINSET; return 0; } /*--------------------------------------------------------------------------*/ int linp2x( struct linprm *lin, int ncoord, int nelem, const double pixcrd[], double imgcrd[]) { static const char *function = "linp2x"; int i, j, k, n, ndbl, nelemn, status; double temp; register const double *pix; register double *img, *piximg, *tmp; struct wcserr **err; /* Initialize. */ if (lin == 0x0) return LINERR_NULL_POINTER; err = &(lin->err); if (lin->flag != LINSET) { if ((status = linset(lin))) return status; } n = lin->naxis; /* Convert pixel coordinates to intermediate world coordinates. */ pix = pixcrd; img = imgcrd; if (lin->simple) { /* Handle the simplest and most common case with maximum efficiency. */ nelemn = nelem - n; for (k = 0; k < ncoord; k++) { for (i = 0; i < n; i++) { *(img++) = lin->cdelt[i] * (*(pix++) - lin->crpix[i]); } pix += nelemn; img += nelemn; } } else if (lin->affine) { /* No distortions. */ ndbl = n * sizeof(double); nelemn = nelem - n; for (k = 0; k < ncoord; k++) { memset(img, 0, ndbl); for (j = 0; j < n; j++) { /* cdelt will have been incorporated into piximg. */ piximg = lin->piximg + j; /* Column-wise multiplication allows this to be cached. */ temp = *(pix++) - lin->crpix[j]; for (i = 0; i < n; i++, piximg += n) { img[i] += *piximg * temp; } } pix += nelemn; img += nelem; } } else { /* Distortions are present. */ ndbl = n * sizeof(double); tmp = lin->tmpcrd; for (k = 0; k < ncoord; k++) { if (lin->dispre) { if ((status = disp2x(lin->dispre, pix, tmp))) { return wcserr_set(LIN_ERRMSG(lin_diserr[status])); } } else { memcpy(tmp, pix, ndbl); } if (lin->unity) { for (i = 0; i < n; i++) { img[i] = tmp[i] - lin->crpix[i]; } } else { for (j = 0; j < n; j++) { tmp[j] -= lin->crpix[j]; } piximg = lin->piximg; for (i = 0; i < n; i++) { img[i] = 0.0; for (j = 0; j < n; j++) { img[i] += *(piximg++) * tmp[j]; } } } if (lin->disseq) { if ((status = disp2x(lin->disseq, img, tmp))) { return wcserr_set(LIN_ERRMSG(lin_diserr[status])); } /* With sequent distortions, cdelt is not incorporated into piximg. */ for (i = 0; i < n; i++) { img[i] = lin->cdelt[i] * tmp[i]; } } else if (lin->unity) { /* ...nor if the matrix is unity. */ for (i = 0; i < n; i++) { img[i] *= lin->cdelt[i]; } } pix += nelem; img += nelem; } } return 0; } /*--------------------------------------------------------------------------*/ int linx2p( struct linprm *lin, int ncoord, int nelem, const double imgcrd[], double pixcrd[]) { static const char *function = "linx2p"; int i, j, k, n, ndbl, nelemn, status; register const double *img; register double *imgpix, *pix, *tmp; struct wcserr **err; /* Initialize. */ if (lin == 0x0) return LINERR_NULL_POINTER; err = &(lin->err); if (lin->flag != LINSET) { if ((status = linset(lin))) return status; } n = lin->naxis; /* Convert intermediate world coordinates to pixel coordinates. */ img = imgcrd; pix = pixcrd; if (lin->simple) { /* Handle the simplest and most common case with maximum efficiency. */ nelemn = nelem - n; for (k = 0; k < ncoord; k++) { for (j = 0; j < n; j++) { *(pix++) = (*(img++) / lin->cdelt[j]) + lin->crpix[j]; } img += nelemn; pix += nelemn; } } else if (lin->affine) { /* No distortions. */ nelemn = nelem - n; for (k = 0; k < ncoord; k++) { /* cdelt will have been incorporated into imgpix. */ imgpix = lin->imgpix; for (j = 0; j < n; j++) { *pix = 0.0; for (i = 0; i < n; i++) { *pix += *imgpix * img[i]; imgpix++; } *(pix++) += lin->crpix[j]; } img += nelem; pix += nelemn; } } else { /* Distortions are present. */ ndbl = n * sizeof(double); tmp = lin->tmpcrd; for (k = 0; k < ncoord; k++) { if (lin->disseq) { /* With sequent distortions, cdelt is not incorporated into imgpix. */ for (i = 0; i < n; i++) { tmp[i] = img[i] / lin->cdelt[i]; } if ((status = disx2p(lin->disseq, tmp, pix))) { return wcserr_set(LIN_ERRMSG(lin_diserr[status])); } memcpy(tmp, pix, ndbl); } else if (lin->unity) { /* ...nor if the matrix is unity. */ for (i = 0; i < n; i++) { tmp[i] = img[i] / lin->cdelt[i]; } } else { /* cdelt will have been incorporated into imgpix. */ memcpy(tmp, img, ndbl); } if (lin->unity) { for (j = 0; j < n; j++) { pix[j] = tmp[j] + lin->crpix[j]; } } else { imgpix = lin->imgpix; for (j = 0; j < n; j++) { pix[j] = lin->crpix[j]; for (i = 0; i < n; i++) { pix[j] += *(imgpix++) * tmp[i]; } } } if (lin->dispre) { memcpy(tmp, pix, ndbl); if ((status = disx2p(lin->dispre, tmp, pix))) { return wcserr_set(LIN_ERRMSG(lin_diserr[status])); } } img += nelem; pix += nelem; } } return 0; } /*--------------------------------------------------------------------------*/ int linwarp( struct linprm *lin, const double pixblc[], const double pixtrc[], const double pixsamp[], int *nsamp, double maxdis[], double *maxtot, double avgdis[], double *avgtot, double rmsdis[], double *rmstot) { static const char *function = "linwarp"; int carry, i, j, naxis, ncoord, status = 0; double dpix, dpx2, dssq, *img, *pix0, *pix0p, *pix1, *pix1p, *pixend, *pixinc, pixspan, *ssqdis, ssqtot, *sumdis, sumtot, totdis; struct linprm affine; struct wcserr **err; /* Initialize. */ if (lin == 0x0) return LINERR_NULL_POINTER; err = &(lin->err); naxis = lin->naxis; if (nsamp) *nsamp = 0; for (j = 0; j < naxis; j++) { if (maxdis) maxdis[j] = 0.0; if (avgdis) avgdis[j] = 0.0; if (rmsdis) rmsdis[j] = 0.0; } if (maxtot) *maxtot = 0.0; if (avgtot) *avgtot = 0.0; if (rmstot) *rmstot = 0.0; /* Quick return if no distortions. */ if (lin->affine) return 0; /* It's easier if there are no sequent distortions! */ if (lin->disseq == 0x0) { status = diswarp(lin->dispre, pixblc, pixtrc, pixsamp, nsamp, maxdis, maxtot, avgdis, avgtot, rmsdis, rmstot); return wcserr_set(LIN_ERRMSG(lin_diserr[status])); } /* Make a reference copy of lin without distortions. */ affine.flag = -1; if ((status = (lincpy(1, lin, &affine) || lindist(1, &affine, 0x0, 0) || lindist(2, &affine, 0x0, 0) || linset(&affine)))) { return wcserr_set(LIN_ERRMSG(status)); } /* Work out increments on each axis. */ pixinc = lin->tmpcrd; ncoord = 0; for (j = 0; j < naxis; j++) { pixspan = pixtrc[j] - (pixblc ? pixblc[j] : 1.0); if (pixsamp == 0x0) { pixinc[j] = 1.0; } else if (pixsamp[j] == 0.0) { pixinc[j] = 1.0; } else if (pixsamp[j] > 0.0) { pixinc[j] = pixsamp[j]; } else if (pixsamp[j] > -1.5) { pixinc[j] = 2.0*pixspan; } else { pixinc[j] = pixspan / ((int)(-pixsamp[j] - 0.5)); } if (j == 0) { /* Number of samples on axis 1. */ ncoord = 1 + (int)((pixspan/pixinc[0]) + 0.5); } } /* Get memory for processing the image row by row. */ if ((pix0 = calloc((3*ncoord+4)*naxis, sizeof(double))) == 0x0) { return wcserr_set(LIN_ERRMSG(LINERR_MEMORY)); } img = pix0 + naxis*ncoord; pix1 = img + naxis*ncoord; pixinc = pix1 + naxis*ncoord; pixend = pixinc + naxis; sumdis = pixend + naxis; ssqdis = sumdis + naxis; /* Copy tmpcrd since linp2x() will overwrite it. */ memcpy(pixinc, lin->tmpcrd, naxis*sizeof(double)); /* Set up the array of pixel coordinates. */ for (j = 0; j < naxis; j++) { pix0[j] = pixblc ? pixblc[j] : 1.0; pixend[j] = pixtrc[j] + 0.5*pixinc[j]; } pix0p = pix0 + naxis; for (i = 1; i < ncoord; i++) { *(pix0p++) = pix0[0] + i*pixinc[0]; for (j = 1; j < naxis; j++) { *(pix0p++) = pix0[j]; } } /* Initialize accumulators. */ for (j = 0; j < naxis; j++) { sumdis[j] = 0.0; ssqdis[j] = 0.0; } sumtot = 0.0; ssqtot = 0.0; /* Loop over N dimensions. */ carry = 0; while (carry == 0) { if ((status = linp2x(lin, ncoord, naxis, pix0, img))) { /* (Preserve the error message set by linp2x().) */ goto cleanup; } if ((status = linx2p(&affine, ncoord, naxis, img, pix1))) { /* (Preserve the error message set by linx2p().) */ goto cleanup; } /* Accumulate statistics. */ pix0p = pix0; pix1p = pix1; for (i = 0; i < ncoord; i++) { (*nsamp)++; dssq = 0.0; for (j = 0; j < naxis; j++) { dpix = *(pix1p++) - *(pix0p++); dpx2 = dpix*dpix; sumdis[j] += dpix; ssqdis[j] += dpx2; if (maxdis && (dpix = fabs(dpix)) > maxdis[j]) maxdis[j] = dpix; dssq += dpx2; } totdis = sqrt(dssq); sumtot += totdis; ssqtot += totdis*totdis; if (maxtot && *maxtot < totdis) *maxtot = totdis; } /* Next array of pixel coordinates. */ for (j = 1; j < naxis; j++) { pix0[j] += pixinc[j]; if ((carry = (pix0[j] > pixend[j]))) { pix0[j] = pixblc ? pixblc[j] : 1.0; } pix0p = pix0 + naxis + j; for (i = 1; i < ncoord; i++) { *pix0p = pix0[j]; pix0p += naxis; } if (carry == 0) break; } } /* Compute the means and RMSs. */ for (j = 0; j < naxis; j++) { ssqdis[j] /= *nsamp; sumdis[j] /= *nsamp; if (avgdis) avgdis[j] = sumdis[j]; if (rmsdis) rmsdis[j] = sqrt(ssqdis[j] - sumdis[j]*sumdis[j]); } ssqtot /= *nsamp; sumtot /= *nsamp; if (avgtot) *avgtot = sumtot; if (rmstot) *rmstot = sqrt(ssqtot - sumtot*sumtot); cleanup: linfree(&affine); free(pix0); return status; } /*--------------------------------------------------------------------------*/ int matinv(int n, const double mat[], double inv[]) { register int i, ij, ik, j, k, kj, pj; int itemp, *mxl, *lxm, pivot; double colmax, *lu, *rowmax, dtemp; /* Allocate memory for internal arrays. */ if ((mxl = calloc(n, sizeof(int))) == 0x0) { return LINERR_MEMORY; } if ((lxm = calloc(n, sizeof(int))) == 0x0) { free(mxl); return LINERR_MEMORY; } if ((rowmax = calloc(n, sizeof(double))) == 0x0) { free(mxl); free(lxm); return LINERR_MEMORY; } if ((lu = calloc(n*n, sizeof(double))) == 0x0) { free(mxl); free(lxm); free(rowmax); return LINERR_MEMORY; } /* Initialize arrays. */ for (i = 0, ij = 0; i < n; i++) { /* Vector that records row interchanges. */ mxl[i] = i; rowmax[i] = 0.0; for (j = 0; j < n; j++, ij++) { dtemp = fabs(mat[ij]); if (dtemp > rowmax[i]) rowmax[i] = dtemp; lu[ij] = mat[ij]; } /* A row of zeroes indicates a singular matrix. */ if (rowmax[i] == 0.0) { free(mxl); free(lxm); free(rowmax); free(lu); return LINERR_SINGULAR_MTX; } } /* Form the LU triangular factorization using scaled partial pivoting. */ for (k = 0; k < n; k++) { /* Decide whether to pivot. */ colmax = fabs(lu[k*n+k]) / rowmax[k]; pivot = k; for (i = k+1; i < n; i++) { ik = i*n + k; dtemp = fabs(lu[ik]) / rowmax[i]; if (dtemp > colmax) { colmax = dtemp; pivot = i; } } if (pivot > k) { /* We must pivot, interchange the rows of the design matrix. */ for (j = 0, pj = pivot*n, kj = k*n; j < n; j++, pj++, kj++) { dtemp = lu[pj]; lu[pj] = lu[kj]; lu[kj] = dtemp; } /* Amend the vector of row maxima. */ dtemp = rowmax[pivot]; rowmax[pivot] = rowmax[k]; rowmax[k] = dtemp; /* Record the interchange for later use. */ itemp = mxl[pivot]; mxl[pivot] = mxl[k]; mxl[k] = itemp; } /* Gaussian elimination. */ for (i = k+1; i < n; i++) { ik = i*n + k; /* Nothing to do if lu[ik] is zero. */ if (lu[ik] != 0.0) { /* Save the scaling factor. */ lu[ik] /= lu[k*n+k]; /* Subtract rows. */ for (j = k+1; j < n; j++) { lu[i*n+j] -= lu[ik]*lu[k*n+j]; } } } } /* mxl[i] records which row of mat corresponds to row i of lu. */ /* lxm[i] records which row of lu corresponds to row i of mat. */ for (i = 0; i < n; i++) { lxm[mxl[i]] = i; } /* Determine the inverse matrix. */ for (i = 0, ij = 0; i < n; i++) { for (j = 0; j < n; j++, ij++) { inv[ij] = 0.0; } } for (k = 0; k < n; k++) { inv[lxm[k]*n+k] = 1.0; /* Forward substitution. */ for (i = lxm[k]+1; i < n; i++) { for (j = lxm[k]; j < i; j++) { inv[i*n+k] -= lu[i*n+j]*inv[j*n+k]; } } /* Backward substitution. */ for (i = n-1; i >= 0; i--) { for (j = i+1; j < n; j++) { inv[i*n+k] -= lu[i*n+j]*inv[j*n+k]; } inv[i*n+k] /= lu[i*n+i]; } } free(mxl); free(lxm); free(rowmax); free(lu); return 0; }