/*============================================================================ 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: wcshdr.c,v 6.2 2018/10/20 10:03:13 mcalabre Exp $ *===========================================================================*/ #include #include #include #include #include #include "wcserr.h" #include "wcsmath.h" #include "wcsutil.h" #include "wcshdr.h" #include "wtbarr.h" #include "tab.h" #include "dis.h" #include "wcs.h" extern const int WCSSET; extern const int DIS_DOTPD; /* Map status return value to message. */ const char *wcshdr_errmsg[] = { "Success", "Null wcsprm pointer passed", "Memory allocation failed", "Invalid column selection", "Fatal error returned by Flex parser", "Invalid tabular parameters"}; /* Map error returns for lower-level routines. */ const int wcshdr_taberr[] = { WCSHDRERR_SUCCESS, /* 0: TABERR_SUCCESS */ WCSHDRERR_NULL_POINTER, /* 1: TABERR_NULL_POINTER */ WCSHDRERR_MEMORY, /* 2: TABERR_MEMORY */ WCSHDRERR_BAD_TABULAR_PARAMS /* 3: TABERR_BAD_PARAMS */ /* 4: TABERR_BAD_X */ /* 5: TABERR_BAD_WORLD */ }; /* Convenience macro for invoking wcserr_set(). */ #define WCSHDR_ERRMSG(status) WCSERR_SET(status), wcshdr_errmsg[status] /* Internal helper functions, not for general use. */ static void wcshdo_format(int, int, const double [], char *); static void wcshdo_tpdterm(int, int, char *); static void wcshdo_util(int, const char [], const char [], int, const char [], int, int, int, char, int, int [], char [], const char [], int *, char **, int *); /*--------------------------------------------------------------------------*/ int wcstab(struct wcsprm *wcs) { static const char *function = "wcstab"; char (*PSi_0a)[72] = 0x0, (*PSi_1a)[72] = 0x0, (*PSi_2a)[72] = 0x0; int *PVi_1a = 0x0, *PVi_2a = 0x0, *PVi_3a = 0x0, *tabax, *tabidx = 0x0; int getcrd, i, ip, itab, itabax, j, jtabax, m, naxis, ntabax, status; struct wtbarr *wtbp; struct tabprm *tabp; struct wcserr **err; if (wcs == 0x0) return WCSHDRERR_NULL_POINTER; err = &(wcs->err); /* Free memory previously allocated by wcstab(). */ if (wcs->flag != -1 && wcs->m_flag == WCSSET) { if (wcs->wtb == wcs->m_wtb) wcs->wtb = 0x0; if (wcs->tab == wcs->m_tab) wcs->tab = 0x0; if (wcs->m_wtb) free(wcs->m_wtb); if (wcs->m_tab) { for (j = 0; j < wcs->ntab; j++) { tabfree(wcs->m_tab + j); } free(wcs->m_tab); } } wcs->ntab = 0; wcs->nwtb = 0; wcs->wtb = 0x0; wcs->tab = 0x0; /* Determine the number of -TAB axes. */ naxis = wcs->naxis; if (!(tabax = calloc(naxis, sizeof(int)))) { return wcserr_set(WCSHDR_ERRMSG(WCSHDRERR_MEMORY)); } ntabax = 0; for (i = 0; i < naxis; i++) { /* Null fill. */ wcsutil_null_fill(72, wcs->ctype[i]); if (!strcmp(wcs->ctype[i]+4, "-TAB")) { tabax[i] = ntabax++; } else { tabax[i] = -1; } } if (ntabax == 0) { /* No lookup tables. */ status = 0; goto cleanup; } /* Collect information from the PSi_ma and PVi_ma keyvalues. */ if (!((PSi_0a = calloc(ntabax, sizeof(char[72]))) && (PVi_1a = calloc(ntabax, sizeof(int))) && (PVi_2a = calloc(ntabax, sizeof(int))) && (PSi_1a = calloc(ntabax, sizeof(char[72]))) && (PSi_2a = calloc(ntabax, sizeof(char[72]))) && (PVi_3a = calloc(ntabax, sizeof(int))) && (tabidx = calloc(ntabax, sizeof(int))))) { status = wcserr_set(WCSHDR_ERRMSG(WCSHDRERR_MEMORY)); goto cleanup; } for (itabax = 0; itabax < ntabax; itabax++) { /* Remember that calloc() zeroes allocated memory. */ PVi_1a[itabax] = 1; PVi_2a[itabax] = 1; PVi_3a[itabax] = 1; } for (ip = 0; ip < wcs->nps; ip++) { itabax = tabax[wcs->ps[ip].i - 1]; if (itabax >= 0) { switch (wcs->ps[ip].m) { case 0: /* EXTNAME. */ strcpy(PSi_0a[itabax], wcs->ps[ip].value); wcsutil_null_fill(72, PSi_0a[itabax]); break; case 1: /* TTYPEn for coordinate array. */ strcpy(PSi_1a[itabax], wcs->ps[ip].value); wcsutil_null_fill(72, PSi_1a[itabax]); break; case 2: /* TTYPEn for index vector. */ strcpy(PSi_2a[itabax], wcs->ps[ip].value); wcsutil_null_fill(72, PSi_2a[itabax]); break; } } } for (ip = 0; ip < wcs->npv; ip++) { itabax = tabax[wcs->pv[ip].i - 1]; if (itabax >= 0) { switch (wcs->pv[ip].m) { case 1: /* EXTVER. */ PVi_1a[itabax] = (int)(wcs->pv[ip].value + 0.5); break; case 2: /* EXTLEVEL. */ PVi_2a[itabax] = (int)(wcs->pv[ip].value + 0.5); break; case 3: /* Table axis number. */ PVi_3a[itabax] = (int)(wcs->pv[ip].value + 0.5); break; } } } /* Determine the number of independent tables. */ for (itabax = 0; itabax < ntabax; itabax++) { /* These have no defaults. */ if (!PSi_0a[itabax][0] || !PSi_1a[itabax][0]) { status = wcserr_set(WCSERR_SET(WCSHDRERR_BAD_TABULAR_PARAMS), "Invalid tabular parameters: PSi_0a and PSi_1a must be specified"); goto cleanup; } tabidx[itabax] = -1; for (jtabax = 0; jtabax < i; jtabax++) { /* EXTNAME, EXTVER, EXTLEVEL, and TTYPEn for the coordinate array */ /* must match for each axis of a multi-dimensional lookup table. */ if (strcmp(PSi_0a[itabax], PSi_0a[jtabax]) == 0 && strcmp(PSi_1a[itabax], PSi_1a[jtabax]) == 0 && PVi_1a[itabax] == PVi_1a[jtabax] && PVi_2a[itabax] == PVi_2a[jtabax]) { tabidx[itabax] = tabidx[jtabax]; break; } } if (jtabax == itabax) { tabidx[itabax] = wcs->ntab; wcs->ntab++; } } if (!(wcs->tab = calloc(wcs->ntab, sizeof(struct tabprm)))) { status = wcserr_set(WCSHDR_ERRMSG(WCSHDRERR_MEMORY)); goto cleanup; } wcs->m_tab = wcs->tab; /* Table dimensionality; find the largest axis number. */ for (itabax = 0; itabax < ntabax; itabax++) { tabp = wcs->tab + tabidx[itabax]; /* PVi_3a records the 1-relative table axis number. */ if (PVi_3a[itabax] > tabp->M) { tabp->M = PVi_3a[itabax]; } } for (itab = 0; itab < wcs->ntab; itab++) { if ((status = tabini(1, wcs->tab[itab].M, 0, wcs->tab + itab))) { status = wcserr_set(WCSHDR_ERRMSG(wcshdr_taberr[status])); goto cleanup; } } /* Copy parameters into the tabprm structs. */ for (i = 0; i < naxis; i++) { if ((itabax = tabax[i]) < 0) { /* Not a -TAB axis. */ continue; } /* PVi_3a records the 1-relative table axis number. */ m = PVi_3a[itabax] - 1; tabp = wcs->tab + tabidx[itabax]; tabp->map[m] = i; tabp->crval[m] = wcs->crval[i]; } /* Check for completeness. */ for (itab = 0; itab < wcs->ntab; itab++) { for (m = 0; m < wcs->tab[itab].M; m++) { if (wcs->tab[itab].map[m] < 0) { status = wcserr_set(WCSERR_SET(WCSHDRERR_BAD_TABULAR_PARAMS), "Invalid tabular parameters: the axis mapping is undefined"); goto cleanup; } } } /* Set up for reading the arrays; how many arrays are there? */ for (itabax = 0; itabax < ntabax; itabax++) { /* Does this -TAB axis have a non-degenerate index array? */ if (PSi_2a[itabax][0]) { wcs->nwtb++; } } /* Add one coordinate array for each table. */ wcs->nwtb += wcs->ntab; /* Allocate memory for structs to be returned. */ if (!(wcs->wtb = calloc(wcs->nwtb, sizeof(struct wtbarr)))) { wcs->nwtb = 0; status = wcserr_set(WCSHDR_ERRMSG(WCSHDRERR_MEMORY)); goto cleanup; } wcs->m_wtb = wcs->wtb; /* Set pointers for the index and coordinate arrays. */ wtbp = wcs->wtb; for (itab = 0; itab < wcs->ntab; itab++) { getcrd = 1; for (itabax = 0; itabax < ntabax; itabax++) { if (tabidx[itabax] != itab) continue; if (getcrd) { /* Coordinate array. */ wtbp->i = itabax + 1; wtbp->m = PVi_3a[itabax]; wtbp->kind = 'c'; strcpy(wtbp->extnam, PSi_0a[itabax]); wtbp->extver = PVi_1a[itabax]; wtbp->extlev = PVi_2a[itabax]; strcpy(wtbp->ttype, PSi_1a[itabax]); wtbp->row = 1L; wtbp->ndim = wcs->tab[itab].M + 1; wtbp->dimlen = wcs->tab[itab].K; wtbp->arrayp = &(wcs->tab[itab].coord); /* Signal for tabset() to take this memory. */ wcs->tab[itab].m_coord = (double *)0x1; wtbp++; getcrd = 0; } if (PSi_2a[itabax][0]) { /* Index array. */ wtbp->i = itabax + 1; wtbp->m = PVi_3a[itabax]; wtbp->kind = 'i'; m = wtbp->m - 1; strcpy(wtbp->extnam, PSi_0a[itabax]); wtbp->extver = PVi_1a[itabax]; wtbp->extlev = PVi_2a[itabax]; strcpy(wtbp->ttype, PSi_2a[itabax]); wtbp->row = 1L; wtbp->ndim = 1; wtbp->dimlen = wcs->tab[itab].K + m; wtbp->arrayp = wcs->tab[itab].index + m; /* Signal for tabset() to take this memory. */ wcs->tab[itab].m_indxs[m] = (double *)0x1; wtbp++; } } } status = 0; cleanup: if (tabax) free(tabax); if (tabidx) free(tabidx); if (PSi_0a) free(PSi_0a); if (PVi_1a) free(PVi_1a); if (PVi_2a) free(PVi_2a); if (PSi_1a) free(PSi_1a); if (PSi_2a) free(PSi_2a); if (PVi_3a) free(PVi_3a); if (status) { if (wcs->tab) free(wcs->tab); if (wcs->wtb) free(wcs->wtb); } return status; } /*--------------------------------------------------------------------------*/ int wcsidx(int nwcs, struct wcsprm **wcs, int alts[27]) { int a, iwcs; struct wcsprm *wcsp; for (a = 0; a < 27; a++) { alts[a] = -1; } if (wcs == 0x0) { return WCSHDRERR_NULL_POINTER; } wcsp = *wcs; for (iwcs = 0; iwcs < nwcs; iwcs++, wcsp++) { if (wcsp->colnum || wcsp->colax[0]) continue; if (wcsp->alt[0] == ' ') { a = 0; } else { a = wcsp->alt[0] - 'A' + 1; } alts[a] = iwcs; } return 0; } /*--------------------------------------------------------------------------*/ int wcsbdx(int nwcs, struct wcsprm **wcs, int type, short alts[1000][28]) { short *ip; int a, i, icol, iwcs; struct wcsprm *wcsp; for (ip = alts[0]; ip < alts[0] + 28*1000; ip++) { *ip = -1; } for (icol = 0; icol < 1000; icol++) { alts[icol][27] = 0; } if (wcs == 0x0) { return WCSHDRERR_NULL_POINTER; } wcsp = *wcs; for (iwcs = 0; iwcs < nwcs; iwcs++, wcsp++) { if (wcsp->alt[0] == ' ') { a = 0; } else { a = wcsp->alt[0] - 'A' + 1; } if (type) { /* Pixel list. */ if (wcsp->colax[0]) { for (i = 0; i < wcsp->naxis; i++) { alts[wcsp->colax[i]][a] = iwcs; alts[wcsp->colax[i]][27]++; } } else if (!wcsp->colnum) { alts[0][a] = iwcs; alts[0][27]++; } } else { /* Binary table image array. */ if (wcsp->colnum) { alts[wcsp->colnum][a] = iwcs; alts[wcsp->colnum][27]++; } else if (!wcsp->colax[0]) { alts[0][a] = iwcs; alts[0][27]++; } } } return 0; } /*--------------------------------------------------------------------------*/ int wcsvfree(int *nwcs, struct wcsprm **wcs) { int a, status = 0; struct wcsprm *wcsp; if (wcs == 0x0) { return WCSHDRERR_NULL_POINTER; } wcsp = *wcs; for (a = 0; a < *nwcs; a++, wcsp++) { status |= wcsfree(wcsp); } free(*wcs); *nwcs = 0; *wcs = 0x0; return status; } /*--------------------------------------------------------------------------*/ #define I_DTYPE 0 /* Distortion type code. */ #define I_NIPARM 1 /* Full (allocated) length of iparm[]. */ #define I_NDPARM 2 /* No. of parameters in dparm[], excl. work space. */ #define I_DOCORR 3 /* True if distortion func computes a correction. */ #define I_TPDNCO 4 /* No. of TPD coefficients, forward... */ #define I_TPDINV 5 /* ...and inverse. */ #define I_TPDAUX 6 /* True if auxiliary variables are used. */ #define I_TPDRAD 7 /* True if the radial variable is used. */ int wcshdo(int ctrl, struct wcsprm *wcs, int *nkeyrec, char **header) /* ::: CUBEFACE and STOKES handling? */ { static const char *function = "wcshdo"; const char axid[] = "xyxuvu", *cp; const int nTPD[] = {1, 4, 7, 12, 17, 24, 31, 40, 49, 60}; char alt, comment[72], ctemp[32], *ctypei, format[16], fmt01[8], keyvalue[96], keyword[16], *kp, *kp0, obsg[8] = "OBSG?", obsgeo[8] = "OBSGEO-?", pq, ptype, xtype, term[16], timeunit[16], tpdsrc[24], xyz[] = "XYZ"; int *axmap, bintab, *colax, colnum, degree, direct = 0, doaux = 0, dofmt, dosip, dotpd, dotpv, i, idis, idp, *iparm, j, jhat, k, m, naxis, ncoeff, Nhat, p, pixlist, precision, primage, q, status = 0; double *dparm, keyval; struct disprm *dis; struct dpkey *keyp; struct wcserr **err; *nkeyrec = 0; *header = 0x0; if (wcs == 0x0) return WCSHDRERR_NULL_POINTER; err = &(wcs->err); if (wcs->flag != WCSSET) { if ((status = wcsset(wcs))) return status; } if ((naxis = wcs->naxis) == 0) { return 0; } /* These are mainly for convenience. */ alt = wcs->alt[0]; if (alt == ' ') alt = '\0'; colnum = wcs->colnum; colax = wcs->colax; primage = 0; bintab = 0; pixlist = 0; if (colnum) { bintab = 1; } else if (colax[0]) { pixlist = 1; } else { primage = 1; } /* Initialize floating point format control. */ *format = '\0'; if (ctrl & WCSHDO_P17) { strcpy(format, "% 20.17G"); } else if (ctrl & WCSHDO_P16) { strcpy(format, "% 20.16G"); } else if (ctrl & WCSHDO_P15) { strcpy(format, "% 20.15G"); } else if (ctrl & WCSHDO_P14) { strcpy(format, "% 20.14G"); } else if (ctrl & WCSHDO_P13) { strcpy(format, "% 20.13G"); } else if (ctrl & WCSHDO_P12) { strcpy(format, "%20.12G"); } if (*format && (ctrl & WCSHDO_EFMT)) { if (format[6] == 'G') { format[6] = 'E'; } else { format[7] = 'E'; } } dofmt = (*format == '\0'); /* WCS dimension. */ if (!pixlist) { sprintf(keyvalue, "%20d", naxis); wcshdo_util(ctrl, "WCSAXES", "WCAX", 0, 0x0, 0, 0, 0, alt, colnum, colax, keyvalue, "Number of coordinate axes", nkeyrec, header, &status); } /* Reference pixel coordinates. */ if (dofmt) wcshdo_format('G', naxis, wcs->crpix, format); for (j = 0; j < naxis; j++) { wcsutil_double2str(keyvalue, format, wcs->crpix[j]); wcshdo_util(ctrl, "CRPIX", "CRP", WCSHDO_CRPXna, "CRPX", 0, j+1, 0, alt, colnum, colax, keyvalue, "Pixel coordinate of reference point", nkeyrec, header, &status); } /* Linear transformation matrix. */ if (dofmt) wcshdo_format('G', naxis*naxis, wcs->pc, format); k = 0; for (i = 0; i < naxis; i++) { for (j = 0; j < naxis; j++, k++) { if (i == j) { if (wcs->pc[k] == 1.0) continue; } else { if (wcs->pc[k] == 0.0) continue; } wcsutil_double2str(keyvalue, format, wcs->pc[k]); wcshdo_util(ctrl, "PC", bintab ? "PC" : "P", WCSHDO_TPCn_ka, bintab ? 0x0 : "PC", i+1, j+1, 0, alt, colnum, colax, keyvalue, "Coordinate transformation matrix element", nkeyrec, header, &status); } } /* Coordinate increment at reference point. */ if (dofmt) wcshdo_format('G', naxis, wcs->cdelt, format); for (i = 0; i < naxis; i++) { wcsutil_double2str(keyvalue, format, wcs->cdelt[i]); comment[0] = '\0'; if (wcs->cunit[i][0]) sprintf(comment, "[%s] ", wcs->cunit[i]); strcat(comment, "Coordinate increment at reference point"); wcshdo_util(ctrl, "CDELT", "CDE", WCSHDO_CRPXna, "CDLT", i+1, 0, 0, alt, colnum, colax, keyvalue, comment, nkeyrec, header, &status); } /* Units of coordinate increment and reference value. */ for (i = 0; i < naxis; i++) { if (wcs->cunit[i][0] == '\0') continue; sprintf(keyvalue, "'%s'", wcs->cunit[i]); wcshdo_util(ctrl, "CUNIT", "CUN", WCSHDO_CRPXna, "CUNI", i+1, 0, 0, alt, colnum, colax, keyvalue, "Units of coordinate increment and value", nkeyrec, header, &status); } /* May need to alter ctype for particular distortions so do basic checks */ /* now. Note that SIP, TPV, DSS, TNX, and ZPX are restricted to exactly */ /* two axes and cannot coexist with other distortion types. */ dosip = 0; dotpv = 0; dotpd = 0; if ((dis = wcs->lin.dispre)) { for (i = 0; i < naxis; i++) { if (strcmp(dis->dtype[i], "SIP") == 0) { /* Simple Imaging Polynomial (SIP). Write it in its native form */ /* if possible, unless specifically requested to write it as TPD. */ dotpd = (dis->iparm[i][I_DTYPE] & DIS_DOTPD); if (!dotpd) {; if (alt || dis->Nhat[0] != 2 || dis->Nhat[1] != 2 || dis->axmap[0][0] != 0 || dis->axmap[0][1] != 1 || dis->axmap[1][0] != 0 || dis->axmap[1][1] != 1 || dis->offset[0][0] != wcs->crpix[0] || dis->offset[0][1] != wcs->crpix[1] || dis->offset[1][0] != wcs->crpix[0] || dis->offset[1][1] != wcs->crpix[1] || dis->scale[0][0] != 1.0 || dis->scale[0][1] != 1.0 || dis->scale[1][0] != 1.0 || dis->scale[1][1] != 1.0) { /* Must have been read as a 'SIP' distortion, CPDISja = 'SIP'. */ /* Cannot be written as native SIP so write it as TPD. */ dotpd = DIS_DOTPD; } else if (strncmp(wcs->ctype[0], "RA---TAN", 8) || strncmp(wcs->ctype[1], "DEC--TAN", 8)) { /* Must have been permuted by wcssub(). */ /* Native SIP doesn't have axis mapping so write it as TPD. */ dotpd = DIS_DOTPD; } if (dotpd) { strcpy(tpdsrc, "SIP coordinates"); } else { dosip = 1; } } break; } } } if ((dis = wcs->lin.disseq)) { for (i = 0; i < naxis; i++) { if (strcmp(dis->dtype[i], "TPV") == 0) { /* TPV "projection". Write it in its native form if possible, */ /* unless specifically requested to write it as TPD. */ dotpd = (dis->iparm[i][I_DTYPE] & DIS_DOTPD); if (!dotpd) {; if (dis->axmap[wcs->lng][0] != wcs->lng || dis->axmap[wcs->lng][1] != wcs->lat || dis->axmap[wcs->lat][0] != wcs->lat || dis->axmap[wcs->lat][1] != wcs->lng || dis->offset[wcs->lng][wcs->lng] != 0.0 || dis->offset[wcs->lng][wcs->lat] != 0.0 || dis->offset[wcs->lat][wcs->lng] != 0.0 || dis->offset[wcs->lat][wcs->lat] != 0.0 || dis->scale[wcs->lng][wcs->lng] != 1.0 || dis->scale[wcs->lng][wcs->lat] != 1.0 || dis->scale[wcs->lat][wcs->lng] != 1.0 || dis->scale[wcs->lat][wcs->lat] != 1.0) { /* Must have been read as a 'TPV' distortion, CPDISja = 'TPV'. */ /* Cannot be written as native TPV so write it as TPD. */ dotpd = DIS_DOTPD; } if (dotpd) { strcpy(tpdsrc, "TPV \"projection\""); } else { dotpv = 1; } } break; } else if (strcmp(dis->dtype[i], "DSS") == 0) { /* Always written as TPD. */ dotpd = DIS_DOTPD; strcpy(tpdsrc, dis->dtype[i]); } else if (strncmp(dis->dtype[i], "WAT", 3) == 0) { /* Always written as TPD. */ dotpd = DIS_DOTPD; strcpy(tpdsrc, dis->dtype[i]+4); if (strcmp(dis->dtype[i], "DSS") == 0) { strcpy(tpdsrc, wcs->wcsname); } else { strcat(tpdsrc, " \"projection\""); } break; } } } /* Coordinate type. */ for (i = 0; i < naxis; i++) { if (wcs->ctype[i][0] == '\0') continue; sprintf(keyvalue, "'%s'", wcs->ctype[i]); strcpy(comment, "Coordinate type code"); ctypei = keyvalue + 1; if (i == wcs->lng || i == wcs->lat) { /* Alter ctype for particular distortions. */ if (dosip) { /* It could have come in as CPDISja = 'SIP'. */ strcpy(ctypei+8, "-SIP'"); } else if (dotpv) { /* Reinstate projection code edited by wcsset(). */ strcpy(ctypei+4, "-TPV'"); } if (strncmp(ctypei+8, "-SIP", 4) == 0) { strcpy(comment, "TAN (gnomonic) projection + SIP distortions"); } else if (strncmp(ctypei+4, "-TPV", 4) == 0) { strcpy(comment, "TAN (gnomonic) projection + distortions"); } else { if (strncmp(ctypei, "RA--", 4) == 0) { strcpy(comment, "Right ascension, "); } else if (strncmp(ctypei, "DEC-", 4) == 0) { strcpy(comment, "Declination, "); } else if (strncmp(ctypei+1, "LON", 3) == 0 || strncmp(ctypei+1, "LAT", 3) == 0) { ctypei[0] = toupper(ctypei[0]); switch (ctypei[0]) { case 'G': strcpy(comment, "galactic "); break; case 'E': strcpy(comment, "ecliptic "); break; case 'H': strcpy(comment, "helioecliptic "); break; case 'S': strcpy(comment, "supergalactic "); break; } if (i == wcs->lng) { strcat(comment, "longitude, "); } else { strcat(comment, "latitude, "); } } strcat(comment, wcs->cel.prj.name); strcat(comment, " projection"); } } else if (i == wcs->spec) { spctyp(wcs->ctype[i], 0x0, 0x0, comment, 0x0, &ptype, &xtype, 0x0); if (ptype == xtype) { strcat(comment, " (linear)"); } else { switch (xtype) { case 'F': strcat(comment, " (linear in frequency)"); break; case 'V': strcat(comment, " (linear in velocity)"); break; case 'W': strcat(comment, " (linear in wavelength)"); break; } } } wcshdo_util(ctrl, "CTYPE", "CTY", WCSHDO_CRPXna, "CTYP", i+1, 0, 0, alt, colnum, colax, keyvalue, comment, nkeyrec, header, &status); } /* Coordinate value at reference point. */ for (i = 0; i < naxis; i++) { if (dofmt) wcshdo_format('G', 1, wcs->crval+i, format); wcsutil_double2str(keyvalue, format, wcs->crval[i]); comment[0] = '\0'; if (wcs->cunit[i][0]) sprintf(comment, "[%s] ", wcs->cunit[i]); strcat(comment, "Coordinate value at reference point"); wcshdo_util(ctrl, "CRVAL", "CRV", WCSHDO_CRPXna, "CRVL", i+1, 0, 0, alt, colnum, colax, keyvalue, comment, nkeyrec, header, &status); } /* Parameter values. */ if (dofmt) strcpy(format, "%20.12G"); for (k = 0; k < wcs->npv; k++) { wcsutil_double2str(keyvalue, format, (wcs->pv[k]).value); if ((wcs->pv[k]).i == (wcs->lng + 1)) { switch ((wcs->pv[k]).m) { case 1: strcpy(comment, "[deg] Native longitude of the reference point"); break; case 2: strcpy(comment, "[deg] Native latitude of the reference point"); break; case 3: if (primage) { sprintf(keyword, "LONPOLE%c", alt); } else if (bintab) { sprintf(keyword, "LONP%d%c", colnum, alt); } else { sprintf(keyword, "LONP%d%c", colax[(wcs->pv[k]).i - 1], alt); } sprintf(comment, "[deg] alias for %s (has precedence)", keyword); break; case 4: if (primage) { sprintf(keyword, "LATPOLE%c", alt); } else if (bintab) { sprintf(keyword, "LATP%d%c", colnum, alt); } else { sprintf(keyword, "LATP%d%c", colax[(wcs->pv[k]).i - 1], alt); } sprintf(comment, "[deg] alias for %s (has precedence)", keyword); break; } } else if ((wcs->pv[k]).i == (wcs->lat + 1)) { sprintf(comment, "%s projection parameter", wcs->cel.prj.code); } else { strcpy(comment, "Coordinate transformation parameter"); } wcshdo_util(ctrl, "PV", "V", WCSHDO_PVn_ma, "PV", wcs->pv[k].i, -1, wcs->pv[k].m, alt, colnum, colax, keyvalue, comment, nkeyrec, header, &status); } for (k = 0; k < wcs->nps; k++) { sprintf(keyvalue, "'%s'", (wcs->ps[k]).value); wcshdo_util(ctrl, "PS", "S", WCSHDO_PVn_ma, "PS", wcs->ps[k].i, -1, wcs->ps[k].m, alt, colnum, colax, keyvalue, "Coordinate transformation parameter", nkeyrec, header, &status); } /* Celestial and spectral transformation parameters. */ if (!undefined(wcs->lonpole)) { wcsutil_double2str(keyvalue, format, wcs->lonpole); wcshdo_util(ctrl, "LONPOLE", "LONP", 0, 0x0, 0, 0, 0, alt, colnum, colax, keyvalue, "[deg] Native longitude of celestial pole", nkeyrec, header, &status); } if (!undefined(wcs->latpole)) { wcsutil_double2str(keyvalue, format, wcs->latpole); wcshdo_util(ctrl, "LATPOLE", "LATP", 0, 0x0, 0, 0, 0, alt, colnum, colax, keyvalue, "[deg] Native latitude of celestial pole", nkeyrec, header, &status); } if (wcs->restfrq != 0.0) { wcsutil_double2str(keyvalue, format, wcs->restfrq); wcshdo_util(ctrl, "RESTFRQ", "RFRQ", 0, 0x0, 0, 0, 0, alt, colnum, colax, keyvalue, "[Hz] Line rest frequency", nkeyrec, header, &status); } if (wcs->restwav != 0.0) { wcsutil_double2str(keyvalue, format, wcs->restwav); wcshdo_util(ctrl, "RESTWAV", "RWAV", 0, 0x0, 0, 0, 0, alt, colnum, colax, keyvalue, "[Hz] Line rest wavelength", nkeyrec, header, &status); } /* - - - - - - - - - - - - - - - - Auxiliary coordinate axis information. */ sprintf(timeunit, "%.15s", wcs->timeunit[0] ? wcs->timeunit : "s"); /* Coordinate axis title. */ if (wcs->cname) { for (i = 0; i < naxis; i++) { if (wcs->cname[i][0] == '\0') continue; sprintf(keyvalue, "'%s'", wcs->cname[i]); wcshdo_util(ctrl, "CNAME", "CNA", WCSHDO_CNAMna, "CNAM", i+1, 0, 0, alt, colnum, colax, keyvalue, "Axis name for labelling purposes", nkeyrec, header, &status); } } /* Random error in coordinate. */ if (wcs->crder) { for (i = 0; i < naxis; i++) { if (undefined(wcs->crder[i])) continue; wcsutil_double2str(keyvalue, format, wcs->crder[i]); comment[0] = '\0'; if (wcs->cunit[i][0]) sprintf(comment, "[%s] ", wcs->cunit[i]); strcat(comment, "Random error in coordinate"); wcshdo_util(ctrl, "CRDER", "CRD", WCSHDO_CNAMna, "CRDE", i+1, 0, 0, alt, colnum, colax, keyvalue, comment, nkeyrec, header, &status); } } /* Systematic error in coordinate. */ if (wcs->csyer) { for (i = 0; i < naxis; i++) { if (undefined(wcs->csyer[i])) continue; wcsutil_double2str(keyvalue, format, wcs->csyer[i]); comment[0] = '\0'; if (wcs->cunit[i][0]) sprintf(comment, "[%s] ", wcs->cunit[i]); strcat(comment, "Systematic error in coordinate"); wcshdo_util(ctrl, "CSYER", "CSY", WCSHDO_CNAMna, "CSYE", i+1, 0, 0, alt, colnum, colax, keyvalue, comment, nkeyrec, header, &status); } } /* Time at zero point of phase axis. */ if (wcs->czphs) { for (i = 0; i < naxis; i++) { if (undefined(wcs->czphs[i])) continue; wcsutil_double2str(keyvalue, format, wcs->czphs[i]); sprintf(comment, "[%s] Time at zero point of phase axis", timeunit); wcshdo_util(ctrl, "CZPHS", "CZP", WCSHDO_CNAMna, "CZPH", i+1, 0, 0, alt, colnum, colax, keyvalue, comment, nkeyrec, header, &status); } } /* Period of phase axis. */ if (wcs->cperi) { for (i = 0; i < naxis; i++) { if (undefined(wcs->cperi[i])) continue; wcsutil_double2str(keyvalue, format, wcs->cperi[i]); sprintf(comment, "[%s] Period of phase axis", timeunit); wcshdo_util(ctrl, "CPERI", "CPR", WCSHDO_CNAMna, "CPER", i+1, 0, 0, alt, colnum, colax, keyvalue, comment, nkeyrec, header, &status); } } /* - - - - - - - - - - - - - - - - - - - - - - Coordinate system title. */ /* Coordinate system title. */ if (wcs->wcsname[0]) { sprintf(keyvalue, "'%s'", wcs->wcsname); if (bintab) { wcshdo_util(ctrl, "WCSNAME", "WCSN", 0, 0x0, 0, 0, 0, alt, colnum, colax, keyvalue, "Coordinate system title", nkeyrec, header, &status); } else { /* TWCS was a mistake. */ wcshdo_util(ctrl, "WCSNAME", "TWCS", WCSHDO_WCSNna, "WCSN", 0, 0, 0, alt, colnum, colax, keyvalue, "Coordinate system title", nkeyrec, header, &status); } } /* - - - - - - - - - - - - - - - - Time reference system and measurement. */ /* Time scale. */ if (wcs->timesys[0]) { sprintf(keyvalue, "'%s'", wcs->timesys); wcshdo_util(ctrl, "TIMESYS", 0x0, 0, 0x0, 0, 0, 0, ' ', 0, 0x0, keyvalue, "Time scale", nkeyrec, header, &status); } /* Time reference position. */ if (wcs->trefpos[0]) { sprintf(keyvalue, "'%s'", wcs->trefpos); wcshdo_util(ctrl, "TREFPOS", 0x0, 0, 0x0, 0, 0, 0, ' ', 0, 0x0, keyvalue, "Time reference position", nkeyrec, header, &status); } /* Time reference direction. */ if (wcs->trefdir[0]) { sprintf(keyvalue, "'%s'", wcs->trefdir); wcshdo_util(ctrl, "TREFDIR", 0x0, 0, 0x0, 0, 0, 0, ' ', 0, 0x0, keyvalue, "Time reference direction", nkeyrec, header, &status); } /* Ephemerides used for pathlength delay calculation. */ if (wcs->plephem[0]) { sprintf(keyvalue, "'%s'", wcs->plephem); wcshdo_util(ctrl, "PLEPHEM", 0x0, 0, 0x0, 0, 0, 0, ' ', 0, 0x0, keyvalue, "Ephemerides used for pathlength delays", nkeyrec, header, &status); } /* Time units. */ if (wcs->timeunit[0]) { sprintf(keyvalue, "'%s'", wcs->timeunit); wcshdo_util(ctrl, "TIMEUNIT", 0x0, 0, 0x0, 0, 0, 0, ' ', 0, 0x0, keyvalue, "Time units", nkeyrec, header, &status); } /* ISO-8601 fiducial time. */ if (wcs->dateref[0]) { sprintf(keyvalue, "'%s'", wcs->dateref); wcshdo_util(ctrl, "DATEREF", 0x0, 0, 0x0, 0, 0, 0, ' ', 0, 0x0, keyvalue, "ISO-8601 fiducial time", nkeyrec, header, &status); } /* MJD of fiducial time, integer part. */ if (!undefined(wcs->mjdref[0])) { wcsutil_double2str(keyvalue, format, wcs->mjdref[0]); wcshdo_util(ctrl, "MJDREFI", 0x0, 0, 0x0, 0, 0, 0, ' ', 0, 0x0, keyvalue, "[d] MJD of fiducial time, integer part", nkeyrec, header, &status); } /* MJD of fiducial time, fractional part. */ if (!undefined(wcs->mjdref[1])) { wcsutil_double2str(keyvalue, format, wcs->mjdref[1]); wcshdo_util(ctrl, "MJDREFF", 0x0, 0, 0x0, 0, 0, 0, ' ', 0, 0x0, keyvalue, "[d] MJD of fiducial time, fractional part", nkeyrec, header, &status); } /* Clock correction. */ if (!undefined(wcs->timeoffs)) { wcsutil_double2str(keyvalue, format, wcs->timeoffs); sprintf(comment, "[%s] Clock correction", timeunit); wcshdo_util(ctrl, "TIMEOFFS", 0x0, 0, 0x0, 0, 0, 0, ' ', 0, 0x0, keyvalue, comment, nkeyrec, header, &status); } /* - - - - - - - - - - - - - - - - - - - - Data timestamps and durations. */ /* ISO-8601 time of observation. */ if (wcs->dateobs[0]) { sprintf(keyvalue, "'%s'", wcs->dateobs); strcpy(comment, "ISO-8601 time of observation"); if (ctrl & 1) { /* Allow DOBSn. */ wcshdo_util(ctrl, "DATE-OBS", "DOBS", WCSHDO_DOBSn, 0x0, 0, 0, 0, ' ', colnum, colax, keyvalue, comment, nkeyrec, header, &status); } else { /* Force DATE-OBS. */ wcshdo_util(ctrl, "DATE-OBS", 0x0, 0, 0x0, 0, 0, 0, ' ', 0, 0x0, keyvalue, comment, nkeyrec, header, &status); } } /* MJD of observation. */ if (!undefined(wcs->mjdobs)) { wcsutil_double2str(keyvalue, format, wcs->mjdobs); wcshdo_util(ctrl, "MJD-OBS", "MJDOB", 0, 0x0, 0, 0, 0, ' ', colnum, colax, keyvalue, "[d] MJD of observation", nkeyrec, header, &status); } /* Julian epoch of observation. */ if (!undefined(wcs->jepoch)) { wcsutil_double2str(keyvalue, format, wcs->jepoch); wcshdo_util(ctrl, "JEPOCH", 0x0, 0, 0x0, 0, 0, 0, ' ', 0, 0x0, keyvalue, "[a] Julian epoch of observation", nkeyrec, header, &status); } /* Besselian epoch of observation. */ if (!undefined(wcs->bepoch)) { wcsutil_double2str(keyvalue, format, wcs->bepoch); wcshdo_util(ctrl, "BEPOCH", 0x0, 0, 0x0, 0, 0, 0, ' ', 0, 0x0, keyvalue, "[a] Besselian epoch of observation", nkeyrec, header, &status); } /* ISO-8601 time at start of observation. */ if (wcs->datebeg[0]) { sprintf(keyvalue, "'%s'", wcs->datebeg); wcshdo_util(ctrl, "DATE-BEG", 0x0, 0, 0x0, 0, 0, 0, ' ', 0, 0x0, keyvalue, "ISO-8601 time at start of observation", nkeyrec, header, &status); } /* MJD at start of observation. */ if (!undefined(wcs->mjdobs)) { wcsutil_double2str(keyvalue, format, wcs->mjdobs); wcshdo_util(ctrl, "MJD-OBS", "MJDOB", 0, 0x0, 0, 0, 0, ' ', colnum, colax, keyvalue, "[d] MJD at start of observation", nkeyrec, header, &status); } /* Time elapsed at start since fiducial time. */ if (!undefined(wcs->tstart)) { wcsutil_double2str(keyvalue, format, wcs->tstart); sprintf(comment, "[%s] Time elapsed since fiducial time at start", timeunit); wcshdo_util(ctrl, "TSTART", 0x0, 0, 0x0, 0, 0, 0, ' ', 0, 0x0, keyvalue, comment, nkeyrec, header, &status); } /* ISO-8601 time at midpoint of observation. */ if (wcs->dateavg[0]) { sprintf(keyvalue, "'%s'", wcs->dateavg); wcshdo_util(ctrl, "DATE-AVG", "DAVG", 0, 0x0, 0, 0, 0, ' ', colnum, colax, keyvalue, "ISO-8601 time at midpoint of observation", nkeyrec, header, &status); } /* MJD at midpoint of observation. */ if (!undefined(wcs->mjdavg)) { wcsutil_double2str(keyvalue, format, wcs->mjdavg); wcshdo_util(ctrl, "MJD-AVG", "MJDA", 0, 0x0, 0, 0, 0, ' ', colnum, colax, keyvalue, "[d] MJD at midpoint of observation", nkeyrec, header, &status); } /* ISO-8601 time at end of observation. */ if (wcs->dateend[0]) { sprintf(keyvalue, "'%s'", wcs->dateend); wcshdo_util(ctrl, "DATE-END", 0x0, 0, 0x0, 0, 0, 0, ' ', 0, 0x0, keyvalue, "ISO-8601 time at end of observation", nkeyrec, header, &status); } /* MJD at end of observation. */ if (!undefined(wcs->mjdend)) { wcsutil_double2str(keyvalue, format, wcs->mjdend); wcshdo_util(ctrl, "MJD-END", 0x0, 0, 0x0, 0, 0, 0, ' ', 0, 0x0, keyvalue, "[d] MJD at end of observation", nkeyrec, header, &status); } /* Time elapsed at end since fiducial time. */ if (!undefined(wcs->tstop)) { wcsutil_double2str(keyvalue, format, wcs->tstop); sprintf(comment, "[%s] Time elapsed since fiducial time at end", timeunit); wcshdo_util(ctrl, "TSTOP", "", 0, 0x0, 0, 0, 0, ' ', 0, 0x0, keyvalue, comment, nkeyrec, header, &status); } /* Exposure (integration) time. */ if (!undefined(wcs->xposure)) { wcsutil_double2str(keyvalue, format, wcs->xposure); sprintf(comment, "[%s] Exposure (integration) time", timeunit); wcshdo_util(ctrl, "XPOSURE", "", 0, 0x0, 0, 0, 0, ' ', 0, 0x0, keyvalue, comment, nkeyrec, header, &status); } /* Elapsed time (start to stop). */ if (!undefined(wcs->telapse)) { wcsutil_double2str(keyvalue, format, wcs->telapse); sprintf(comment, "[%s] Elapsed time (start to stop)", timeunit); wcshdo_util(ctrl, "TELAPSE", "", 0, 0x0, 0, 0, 0, ' ', 0, 0x0, keyvalue, comment, nkeyrec, header, &status); } /* - - - - - - - - - - - - - - - - - - - - - - - - - - - Timing accuracy. */ /* Systematic error in time measurements. */ if (!undefined(wcs->timsyer)) { wcsutil_double2str(keyvalue, format, wcs->timsyer); sprintf(comment, "[%s] Systematic error in time measurements", timeunit); wcshdo_util(ctrl, "TIMSYER", "", 0, 0x0, 0, 0, 0, ' ', 0, 0x0, keyvalue, comment, nkeyrec, header, &status); } /* Relative error in time measurements. */ if (!undefined(wcs->timrder)) { wcsutil_double2str(keyvalue, format, wcs->timrder); sprintf(comment, "[%s] Relative error in time measurements", timeunit); wcshdo_util(ctrl, "TIMRDER", "", 0, 0x0, 0, 0, 0, ' ', 0, 0x0, keyvalue, comment, nkeyrec, header, &status); } /* Time resolution. */ if (!undefined(wcs->timedel)) { wcsutil_double2str(keyvalue, format, wcs->timedel); sprintf(comment, "[%s] Time resolution", timeunit); wcshdo_util(ctrl, "TIMEDEL", "", 0, 0x0, 0, 0, 0, ' ', 0, 0x0, keyvalue, comment, nkeyrec, header, &status); } /* Reference position of timestamp in binned data. */ if (!undefined(wcs->timepixr)) { wcsutil_double2str(keyvalue, format, wcs->timepixr); wcshdo_util(ctrl, "TIMEPIXR", "", 0, 0x0, 0, 0, 0, ' ', 0, 0x0, keyvalue, "Reference position of timestamp in binned data", nkeyrec, header, &status); } /* - - - - - - - - - - - - - - - - - Spatial & celestial reference frame. */ /* Observatory coordinates. */ if (!undefined(wcs->obsgeo[0]) && !undefined(wcs->obsgeo[1]) && !undefined(wcs->obsgeo[2])) { for (k = 0; k < 3; k++) { wcsutil_double2str(keyvalue, format, wcs->obsgeo[k]); sprintf(comment, "[m] observatory %c-coordinate", xyz[k]); obsgeo[7] = xyz[k]; obsg[4] = xyz[k]; wcshdo_util(ctrl, obsgeo, obsg, 0, 0x0, 0, 0, 0, ' ', colnum, colax, keyvalue, comment, nkeyrec, header, &status); } } else if ( !undefined(wcs->obsgeo[3]) && !undefined(wcs->obsgeo[4]) && !undefined(wcs->obsgeo[5])) { wcsutil_double2str(keyvalue, format, wcs->obsgeo[3]); wcshdo_util(ctrl, "OBSGEO-L", 0x0, 0, 0x0, 0, 0, 0, ' ', 0, 0x0, keyvalue, "[deg] IAU(1976) observatory longitude", nkeyrec, header, &status); wcsutil_double2str(keyvalue, format, wcs->obsgeo[4]); wcshdo_util(ctrl, "OBSGEO-B", 0x0, 0, 0x0, 0, 0, 0, ' ', 0, 0x0, keyvalue, "[deg] IAU(1976) observatory latitude", nkeyrec, header, &status); wcsutil_double2str(keyvalue, format, wcs->obsgeo[5]); wcshdo_util(ctrl, "OBSGEO-L", 0x0, 0, 0x0, 0, 0, 0, ' ', 0, 0x0, keyvalue, "[m] IAU(1976) observatory height", nkeyrec, header, &status); } /* Spacecraft orbit ephemeris file. */ if (wcs->obsorbit[0]) { sprintf(keyvalue, "'%s'", wcs->obsorbit); wcshdo_util(ctrl, "OBSORBIT", 0x0, 0, 0x0, 0, 0, 0, ' ', 0, 0x0, keyvalue, "Spacecraft orbit ephemeris file", nkeyrec, header, &status); } /* Equatorial coordinate system type. */ if (wcs->radesys[0]) { sprintf(keyvalue, "'%s'", wcs->radesys); wcshdo_util(ctrl, "RADESYS", "RADE", 0, 0x0, 0, 0, 0, alt, colnum, colax, keyvalue, "Equatorial coordinate system", nkeyrec, header, &status); } /* Equinox of equatorial coordinate system. */ if (!undefined(wcs->equinox)) { wcsutil_double2str(keyvalue, format, wcs->equinox); wcshdo_util(ctrl, "EQUINOX", "EQUI", 0, 0x0, 0, 0, 0, alt, colnum, colax, keyvalue, "[yr] Equinox of equatorial coordinates", nkeyrec, header, &status); } /* Reference frame of spectral coordinates. */ if (wcs->specsys[0]) { sprintf(keyvalue, "'%s'", wcs->specsys); wcshdo_util(ctrl, "SPECSYS", "SPEC", 0, 0x0, 0, 0, 0, alt, colnum, colax, keyvalue, "Reference frame of spectral coordinates", nkeyrec, header, &status); } /* Reference frame of spectral observation. */ if (wcs->ssysobs[0]) { sprintf(keyvalue, "'%s'", wcs->ssysobs); wcshdo_util(ctrl, "SSYSOBS", "SOBS", 0, 0x0, 0, 0, 0, alt, colnum, colax, keyvalue, "Reference frame of spectral observation", nkeyrec, header, &status); } /* Observer's velocity towards source. */ if (!undefined(wcs->velosys)) { wcsutil_double2str(keyvalue, format, wcs->velosys); wcshdo_util(ctrl, "VELOSYS", "VSYS", 0, 0x0, 0, 0, 0, alt, colnum, colax, keyvalue, "[m/s] Velocity towards source", nkeyrec, header, &status); } /* Redshift of the source. */ if (!undefined(wcs->zsource)) { wcsutil_double2str(keyvalue, format, wcs->zsource); wcshdo_util(ctrl, "ZSOURCE", "ZSOU", 0, 0x0, 0, 0, 0, alt, colnum, colax, keyvalue, "Redshift of the source", nkeyrec, header, &status); } /* Reference frame of source redshift. */ if (wcs->ssyssrc[0]) { sprintf(keyvalue, "'%s'", wcs->ssyssrc); wcshdo_util(ctrl, "SSYSSRC", "SSRC", 0, 0x0, 0, 0, 0, alt, colnum, colax, keyvalue, "Reference frame of source redshift", nkeyrec, header, &status); } /* Velocity orientation angle. */ if (!undefined(wcs->velangl)) { wcsutil_double2str(keyvalue, format, wcs->velangl); wcshdo_util(ctrl, "VELANGL", "VANG", 0, 0x0, 0, 0, 0, alt, colnum, colax, keyvalue, "[deg] Velocity orientation angle", nkeyrec, header, &status); } /* Write distortion function parameters. */ if (dosip) { /* Simple Imaging Polynomial (SIP) is handled by translating its dpkey */ /* records. Determine a suitable numerical precision for the */ /* polynomial coefficients to avoid trailing zeroes common to all of */ /* them. */ dis = wcs->lin.dispre; if (dofmt) { keyp = dis->dp; kp0 = keyvalue + 2; for (idp = 0; idp < dis->ndp; idp++, keyp++) { cp = strchr(keyp->field, '.') + 1; if (strncmp(cp, "SIP.", 4) != 0) continue; wcsutil_double2str(keyvalue, "%20.13E", dpkeyd(keyp)); kp = keyvalue + 15; while (kp0 < kp && *kp == '0') kp--; kp0 = kp; } precision = kp0 - (keyvalue + 2); if (precision < 1) precision = 1; if (13 < precision) precision = 13; sprintf(format, "%%20.%dE", precision); } /* Ensure the coefficients are written in a human-readable sequence. */ for (j = 0; j <= 1; j++) { /* Distortion function polynomial coefficients. */ wcshdo_util(ctrl, "", "", 0, 0x0, 0, 0, 0, ' ', 0, 0, "", "", nkeyrec, header, &status); if (j == 0) { strcpy(keyword, "A_"); } else { strcpy(keyword, "B_"); } ncoeff = dis->iparm[j][I_TPDNCO]; for (degree = 0; degree <= 9; degree++) { if (ncoeff <= nTPD[degree]) break; } strcpy(keyword+2, "ORDER"); sprintf(keyvalue, "%20d", degree); sprintf(comment, "SIP polynomial degree, axis %d, pixel-to-sky", j+1); wcshdo_util(ctrl, keyword, "", 0, 0x0, 0, 0, 0, ' ', 0, 0, keyvalue, comment, nkeyrec, header, &status); keyp = dis->dp; for (idp = 0; idp < dis->ndp; idp++, keyp++) { if (keyp->j != j+1) continue; if ((keyval = dpkeyd(keyp)) == 0.0) continue; cp = strchr(keyp->field, '.') + 1; if (strncmp(cp, "SIP.FWD.", 8) != 0) continue; cp += 8; strcpy(keyword+2, cp); sscanf(cp, "%d_%d", &p, &q); strncpy(term, "xxxxxxxxx", p); strncpy(term+p, "yyyyyyyyy", q); term[p+q] = '\0'; wcsutil_double2str(keyvalue, format, keyval); sprintf(comment, "SIP distortion coefficient: %s", term); wcshdo_util(ctrl, keyword, "", 0, 0x0, 0, 0, 0, ' ', 0, 0, keyvalue, comment, nkeyrec, header, &status); } if (dis->maxdis[j] != 0.0) { strcpy(keyword+2, "DMAX"); wcsutil_double2str(keyvalue, "%20.3f", dis->maxdis[j]); wcshdo_util(ctrl, keyword, "", 0, 0x0, 0, 0, 0, ' ', 0, 0, keyvalue, "Maximum value of distortion function", nkeyrec, header, &status); } /* Inverse distortion function polynomial coefficients. */ if (dis->disx2p == 0x0) continue; wcshdo_util(ctrl, "", "", 0, 0x0, 0, 0, 0, ' ', 0, 0, "", "", nkeyrec, header, &status); if (j == 0) { strcpy(keyword, "AP_"); } else { strcpy(keyword, "BP_"); } ncoeff = dis->iparm[j][I_NDPARM] - dis->iparm[j][I_TPDNCO]; for (degree = 0; degree <= 9; degree++) { if (ncoeff <= nTPD[degree]) break; } strcpy(keyword+3, "ORDER"); sprintf(keyvalue, "%20d", degree); sprintf(comment, "SIP polynomial degree, axis %d, sky-to-pixel", j+1); wcshdo_util(ctrl, keyword, "", 0, 0x0, 0, 0, 0, ' ', 0, 0, keyvalue, comment, nkeyrec, header, &status); keyp = dis->dp; for (idp = 0; idp < dis->ndp; idp++, keyp++) { if (keyp->j != j+1) continue; if ((keyval = dpkeyd(keyp)) == 0.0) continue; cp = strchr(keyp->field, '.') + 1; if (strncmp(cp, "SIP.REV.", 8) != 0) continue; cp += 8; strcpy(keyword+3, cp); sscanf(cp, "%d_%d", &p, &q); strncpy(term, "xxxxxxxxx", p); strncpy(term+p, "yyyyyyyyy", q); term[p+q] = '\0'; wcsutil_double2str(keyvalue, format, keyval); sprintf(comment, "SIP inverse coefficient: %s", term); wcshdo_util(ctrl, keyword, "", 0, 0x0, 0, 0, 0, ' ', 0, 0, keyvalue, comment, nkeyrec, header, &status); } } } for (idis = 0; idis < 2; idis++) { if (idis == 0 && (dis = wcs->lin.dispre) == 0x0) continue; if (idis == 1 && (dis = wcs->lin.disseq) == 0x0) continue; for (j = 0; j < naxis; j++) { if (dis->disp2x[j] == 0x0) continue; iparm = dis->iparm[j]; dparm = dis->dparm[j]; /* Identify the distortion type. */ if (dotpv) { /* TPV "projection" is handled by translating its dpkey records, */ /* which were originally translated from PVi_ma by wcsset(), or */ /* possibly input directly as a CQDISia = 'TPV' distortion type. */ /* Determine a suitable numerical precision for the polynomial */ /* coefficients to avoid trailing zeroes common to all of them. */ if (dofmt) wcshdo_format('E', iparm[I_NDPARM], dparm, format); sprintf(fmt01, "%.3ss", format); wcshdo_util(ctrl, "", "", 0, 0x0, 0, 0, 0, ' ', 0, 0, "", "", nkeyrec, header, &status); /* Distortion function polynomial coefficients. */ sprintf(keyword, "PV%d_", j+1); kp = keyword + strlen(keyword); keyp = dis->dp; for (idp = 0; idp < dis->ndp; idp++, keyp++) { if (keyp->j != j+1) continue; if ((keyval = dpkeyd(keyp)) == 0.0) continue; cp = strchr(keyp->field, '.') + 1; if (strncmp(cp, "TPV.", 4) != 0) continue; strcpy(kp, cp+4); /* Identify the term of the TPV polynomial for human readers. */ sscanf(cp+4, "%d", &m); wcshdo_tpdterm(m, j == wcs->lng, term); sprintf(comment, "TPV coefficient: %s", term); if (keyval == 1.0) { sprintf(keyvalue, fmt01, "1.0"); } else { wcsutil_double2str(keyvalue, format, keyval); } wcshdo_util(ctrl, keyword, "", 0, 0x0, 0, 0, 0, alt, 0, 0, keyvalue, comment, nkeyrec, header, &status); } } else if (strcmp(dis->dtype[j], "TPD") == 0 || dotpd || strcmp(dis->dtype[j], "Polynomial") == 0 || strcmp(dis->dtype[j], "Polynomial*") == 0) { /* One of the Paper IV type polynomial distortions. */ wcshdo_util(ctrl, "", "", 0, 0x0, 0, 0, 0, ' ', 0, 0, "", "", nkeyrec, header, &status); if (strcmp(dis->dtype[j], "TPD") == 0) { /* Pure TPD. */ dotpd = 1; } else if (strncmp(dis->dtype[j], "Polynomial", 10) == 0) { /* Polynomial distortion. Write it as TPD by request? */ dotpd = (iparm[I_DTYPE] & DIS_DOTPD); strcpy(tpdsrc, "Polynomial distortion"); } pq = idis ? 'Q' : 'P'; Nhat = dis->Nhat[j]; /* CPDISja/CQDISia */ sprintf(keyword, "C%cDIS%d", pq, j+1); if (idis == 0) { strcpy(comment, "P = prior, "); } else { strcpy(comment, "Q = sequent, "); } if (dotpd) { strcpy(keyvalue, "'TPD'"); strcat(comment, "Template Polynomial Distortion"); /* For identifying terms of the TPD polynomial. */ axmap = dis->axmap[j]; direct = 1; doaux = iparm[I_TPDAUX]; if (Nhat == 2) { /* Associate x with longitude, y with latitude. */ if (axmap[0] == wcs->lng && axmap[1] == wcs->lat) { direct = 1; } else if (axmap[0] == wcs->lat && axmap[1] == wcs->lng) { direct = 0; } else { /* Non-celestial. */ direct = (axmap[0] < axmap[1]); } } } else { strcpy(keyvalue, "'Polynomial'"); strcat(comment, "general Polynomial distortion"); } wcshdo_util(ctrl, keyword, "", 0, 0x0, 0, 0, 0, alt, 0, 0, keyvalue, comment, nkeyrec, header, &status); /* NAXES. */ sprintf(keyword, "D%c%d", pq, j+1); sprintf(keyvalue, "'NAXES: %d'", Nhat); if (Nhat == 1) { strcpy(comment, "One independent variable"); } else if (Nhat == 2) { strcpy(comment, "Two independent variables"); } else { strcpy(comment, "Number of independent variables"); } wcshdo_util(ctrl, keyword, "", 0, 0x0, 0, 0, 0, alt, 0, 0, keyvalue, comment, nkeyrec, header, &status); /* AXIS.jhat */ for (jhat = 0; jhat < Nhat; jhat++) { axmap = dis->axmap[j]; sprintf(keyvalue, "'AXIS.%d: %d'", jhat+1, axmap[jhat]+1); if (jhat == 0) { strcpy(comment, "1st"); } else if (jhat == 1) { strcpy(comment, "2nd"); } else if (jhat == 2) { strcpy(comment, "3rd"); } else { sprintf(comment, "%dth", jhat+1); } sprintf(comment+strlen(comment), " independent variable: axis %d", axmap[jhat]+1); if (dotpd) { /* axid is "xyxuvu". */ cp = axid; if (!direct) cp++; if (doaux) cp += 3; sprintf(comment+strlen(comment), " (= %c)", cp[jhat]); } wcshdo_util(ctrl, keyword, "", 0, 0x0, 0, 0, 0, alt, 0, 0, keyvalue, comment, nkeyrec, header, &status); } /* OFFSET.jhat */ if (dofmt) wcshdo_format('f', Nhat, dis->offset[j], format); for (jhat = 0; jhat < Nhat; jhat++) { if (dis->offset[j][jhat] == 0.0) continue; wcsutil_double2str(ctemp, format, dis->offset[j][jhat]); sprintf(keyvalue, "'OFFSET.%d: %s'", jhat+1, ctemp); sprintf(comment, "Variable %d renormalization offset", jhat+1); wcshdo_util(ctrl, keyword, "", 0, 0x0, 0, 0, 0, alt, 0, 0, keyvalue, comment, nkeyrec, header, &status); } /* SCALE.jhat */ if (dofmt) wcshdo_format('f', Nhat, dis->scale[j], format); for (jhat = 0; jhat < Nhat; jhat++) { if (dis->scale[j][jhat] == 1.0) continue; wcsutil_double2str(ctemp, format, dis->scale[j][jhat]); sprintf(keyvalue, "'SCALE.%d: %s'", jhat+1, ctemp); sprintf(comment, "Variable %d renormalization scale", jhat+1); wcshdo_util(ctrl, keyword, "", 0, 0x0, 0, 0, 0, alt, 0, 0, keyvalue, comment, nkeyrec, header, &status); } /* Does the distortion function compute a correction? */ if (iparm[I_DOCORR]) { wcshdo_util(ctrl, keyword, "", 0, 0x0, 0, 0, 0, alt, 0, 0, "'DOCORR: 1'", "Distortion function computes a correction", nkeyrec, header, &status); } if (dotpd) { /* Template Polynomial Distortion (TPD). As it may have been */ /* translated from SIP, TPV, DSS, TNX, ZPX, or perhaps */ /* Polynomial, the dpkey records may not relate to TPD. */ /* Output is therefore handled via dparm. */ if (dofmt) wcshdo_format('E', iparm[I_NDPARM], dparm, format); sprintf(fmt01, "%.3ss", format); /* AUX.jhat.COEFF.m */ if (doaux) { for (idp = 0; idp < 6; idp++) { if (dparm[idp] == 0.0) { sprintf(ctemp, fmt01, "0.0"); } else if (dparm[idp] == 1.0) { sprintf(ctemp, fmt01, "1.0"); } else { wcsutil_double2str(ctemp, format, dparm[idp]); } if (idp < 3) { sprintf(keyvalue, "'AUX.1.COEFF.%d: %s'", idp%3, ctemp); sprintf(comment, "TPD: x = c0 + c1*u + c2*v"); } else { sprintf(keyvalue, "'AUX.2.COEFF.%d: %s'", idp%3, ctemp); sprintf(comment, "TPD: y = d0 + d1*u + d2*v"); } wcshdo_util(ctrl, keyword, "", 0, 0x0, 0, 0, 0, alt, 0, 0, keyvalue, comment, nkeyrec, header, &status); } dparm += 6; } /* TPD.FWD.m */ for (idp = 0; idp < iparm[I_TPDNCO]; idp++) { if (dparm[idp] == 0.0) continue; if (dparm[idp] == 1.0) { sprintf(ctemp, fmt01, "1.0"); } else { wcsutil_double2str(ctemp, format, dparm[idp]); } m = idp; sprintf(keyvalue, "'TPD.FWD.%d:%s %s'", m, (m<10)?" ":"", ctemp); wcshdo_tpdterm(m, direct, term); sprintf(comment, "TPD coefficient: %s", term); wcshdo_util(ctrl, keyword, "", 0, 0x0, 0, 0, 0, alt, 0, 0, keyvalue, comment, nkeyrec, header, &status); } /* CPERRja/CQERRia */ if (dis->maxdis[j] != 0.0) { sprintf(keyword, "C%cERR%d", pq, j+1); sprintf(keyvalue, "%20.2f", dis->maxdis[j]); sprintf(comment, "%sMaximum absolute value of distortion", idis?"":"[pix] "); wcshdo_util(ctrl, keyword, "", 0, 0x0, 0, 0, 0, alt, 0, 0, keyvalue, comment, nkeyrec, header, &status); } /* Inverse distortion function polynomial coefficients. */ if (dis->disx2p[j] == 0x0) continue; wcshdo_util(ctrl, "", "", 0, 0x0, 0, 0, 0, ' ', 0, 0, "", "", nkeyrec, header, &status); /* TPD.REV.m */ sprintf(keyword, "D%c%d", pq, j+1); for (idp = iparm[I_TPDNCO]; idp < iparm[I_NDPARM]; idp++) { if (dparm[idp] == 0.0) continue; wcsutil_double2str(ctemp, format, dparm[idp]); m = idp - iparm[I_TPDNCO]; sprintf(keyvalue, "'TPD.REV.%d:%s %s'", m, (m<10)?" ":"", ctemp); wcshdo_tpdterm(m, direct, term); sprintf(comment, "TPD coefficient: %s", term); wcshdo_util(ctrl, keyword, "", 0, 0x0, 0, 0, 0, alt, 0, 0, keyvalue, comment, nkeyrec, header, &status); } } else { /* General polynomial distortion, handled via its dpkey records */ /* since iparm and dparm may hold a translation to TPD. */ /* Do auxiliary variables first. */ keyp = dis->dp; for (idp = 0; idp < dis->ndp; idp++, keyp++) { if (keyp->j != j+1) continue; cp = strchr(keyp->field, '.') + 1; if (strncmp(cp, "NAUX", 4) != 0) continue; sprintf(keyvalue, "'%s: %d'", cp, dpkeyi(keyp)); wcshdo_util(ctrl, keyword, "", 0, 0x0, 0, 0, 0, alt, 0, 0, keyvalue, "Number of auxiliary variables", nkeyrec, header, &status); keyp = dis->dp; for (idp = 0; idp < dis->ndp; idp++, keyp++) { if (keyp->j != j+1) continue; keyval = dpkeyd(keyp); cp = strchr(keyp->field, '.') + 1; if (strncmp(cp, "AUX.", 4) != 0) continue; sscanf(cp+4, "%d", &m); sprintf(keyvalue, "'%s:", cp); cp = strchr(cp+4, '.') + 1; kp = keyvalue + strlen(keyvalue); if ((double)((int)keyval) == keyval) { sprintf(kp, "%4d'", (int)keyval); } else if (keyval == 0.5) { strcat(kp, " 0.5'"); } else { wcsutil_double2str(kp, "%21.13E", keyval); strcat(keyvalue, "'"); } sscanf(cp+6, "%d", &p); if (strncmp(cp, "POWER.", 4) == 0) { if (p) { sprintf(comment, "Aux %d: var %d power", m, p); } else { sprintf(comment, "Aux %d: power of sum of terms", m); } } else { if (p) { sprintf(comment, "Aux %d: var %d coefficient", m, p); } else { sprintf(comment, "Aux %d: offset term", m); } } wcshdo_util(ctrl, keyword, "", 0, 0x0, 0, 0, 0, alt, 0, 0, keyvalue, comment, nkeyrec, header, &status); } break; } /* Do polynomial terms. */ keyp = dis->dp; for (idp = 0; idp < dis->ndp; idp++, keyp++) { if (keyp->j != j+1) continue; cp = strchr(keyp->field, '.') + 1; if (strncmp(cp, "NTERMS", 6) != 0) continue; sprintf(keyvalue, "'%s: %d'", cp, dpkeyi(keyp)); wcshdo_util(ctrl, keyword, "", 0, 0x0, 0, 0, 0, alt, 0, 0, keyvalue, "Number of terms in the polynomial", nkeyrec, header, &status); } keyp = dis->dp; for (idp = 0; idp < dis->ndp; idp++, keyp++) { if (keyp->j != j+1) continue; if ((keyval = dpkeyd(keyp)) == 0.0) continue; cp = strchr(keyp->field, '.') + 1; if (strncmp(cp, "TERM.", 5) != 0) continue; sscanf(cp+5, "%d", &m); sprintf(keyvalue, "'%s:%s ", cp, (m<10)?" ":""); cp = strchr(cp+5, '.') + 1; kp = keyvalue + strlen(keyvalue); if (strncmp(cp, "VAR.", 4) == 0) { if ((double)((int)keyval) == keyval) { sprintf(kp, "%20d", (int)keyval); } else { wcsutil_double2str(kp, "%20.13f", keyval); } sscanf(cp+4, "%d", &p); if (p <= Nhat) { sprintf(comment, "Poly term %d: var %d power", m, p); } else { sprintf(comment, "Poly term %d: aux %d power", m, p-Nhat); } } else { wcsutil_double2str(kp, "%20.13E", keyval); sprintf(comment, "Poly term %d: coefficient", m); } strcat(keyvalue, "'"); wcshdo_util(ctrl, keyword, "", 0, 0x0, 0, 0, 0, alt, 0, 0, keyvalue, comment, nkeyrec, header, &status); } /* CPERRja/CQERRia */ if (dis->maxdis[j] != 0.0) { sprintf(keyword, "C%cERR%d", pq, j+1); sprintf(keyvalue, "%20.2f", dis->maxdis[j]); sprintf(comment, "%sMaximum absolute value of distortion", idis?"":"[pix] "); wcshdo_util(ctrl, keyword, "", 0, 0x0, 0, 0, 0, alt, 0, 0, keyvalue, comment, nkeyrec, header, &status); } } } } /* DVERRa */ if (dis->totdis != 0.0) { sprintf(keyvalue, "%20.2f", dis->totdis); sprintf(comment, "Maximum combined distortion"); wcshdo_util(ctrl, "DVERR", "", 0, 0x0, 0, 0, 0, alt, 0, 0, keyvalue, comment, nkeyrec, header, &status); } } /* Add identification. */ wcshdo_util(ctrl, "", "", 0, 0x0, 0, 0, 0, ' ', 0, 0, "", "", nkeyrec, header, &status); if (dotpd == DIS_DOTPD) { /* TPD by translation. */ sprintf(comment, "Translated from %s to TPD by WCSLIB %s", tpdsrc, wcslib_version(0x0)); } else { sprintf(comment, "WCS header keyrecords produced by WCSLIB %s", wcslib_version(0x0)); } wcshdo_util(ctrl, "COMMENT", "", 0, 0x0, 0, 0, 0, ' ', 0, 0, "", comment, nkeyrec, header, &status); if (status == WCSHDRERR_MEMORY) { wcserr_set(WCSHDR_ERRMSG(status)); } return status; } /*--------------------------------------------------------------------------*/ /* Determine a suitable floating point format for a set of parameters. */ void wcshdo_format( int fmt, int nval, const double val[], char *format) { char *cp, *cp0, cval[24]; int i, expmax, expon, nsig, precision; if (fmt == 'G') { fmt = 'f'; for (i = 0; i < nval; i++) { if (fabs(val[i]) < 1e-4 || 1e12 < val[i]) { fmt = 'E'; break; } } } cp0 = cval + 2; expmax = -999; for (i = 0; i < nval; i++) { /* Double precision has at least 15 significant digits, and up to 17: */ /* http://en.wikipedia.org/wiki/Double-precision_floating-point_format */ wcsutil_double2str(cval, "%21.14E", val[i]); cp = cval + 16; while (cp0 < cp && *cp == '0') cp--; cp0 = cp; sscanf(cval+18, "%d", &expon); if (expmax < expon) expmax = expon; } nsig = cp0 - (cval + 2) + 1; if (fmt == 'f') { precision = nsig - (expmax + 1); if (precision < 1) precision = 1; if (17 < precision) precision = 17; sprintf(format, "%%20.%df", precision); } else { precision = nsig - 1; if (precision < 1) precision = 1; if (14 < precision) precision = 14; if (precision < 14) { sprintf(format, "%%20.%dE", precision); } else { sprintf(format, "%%21.%dE", precision); } } } /*--------------------------------------------------------------------------*/ /* Construct a string that identifies the term of a TPD or TPV polynomial. */ void wcshdo_tpdterm( int m, int direct, char *term) { const int nTPD[] = {1, 4, 7, 12, 17, 24, 31, 40, 49, 60}; int degree, k; for (degree = 0; degree <= 9; degree++) { if (m < nTPD[degree]) break; } if (degree == 0) { strcpy(term, "1"); } else { k = degree - (m - nTPD[degree-1]); if (k < 0) { strncpy(term, "rrrrrrrrr", degree); } else if (direct) { strncpy(term, "xxxxxxxxx", k); strncpy(term+k, "yyyyyyyyy", degree-k); } else { strncpy(term, "yyyyyyyyy", k); strncpy(term+k, "xxxxxxxxx", degree-k); } term[degree] = '\0'; } } /*--------------------------------------------------------------------------*/ /* Construct a keyrecord from the components given. */ void wcshdo_util( int relax, const char pikey[], const char tbkey[], int level, const char tlkey[], int i, int j, int m, char alt, int btcol, int plcol[], char keyvalue[], const char keycomment[], int *nkeyrec, char **header, int *status) { char ch0, ch1, *hptr, keyword[32], *kptr; int nbyte, nc = 47, nv; if (*status) return; /* Reallocate memory in blocks of 2880 bytes. */ if ((*nkeyrec)%32 == 0) { nbyte = ((*nkeyrec)/32 + 1) * 2880; if (!(hptr = realloc(*header, nbyte))) { *status = WCSHDRERR_MEMORY; return; } *header = hptr; } /* Construct the keyword. */ if (alt == ' ') alt = '\0'; if (btcol) { /* Binary table image array. */ if (i > 0 && j) { if (j > 0) { sprintf(keyword, "%d%d%s%d%c", i, j, tbkey, btcol, alt); } else { sprintf(keyword, "%d%s%d_%d%c", i, tbkey, btcol, m, alt); } } else if (i > 0) { sprintf(keyword, "%d%s%d%c", i, tbkey, btcol, alt); } else if (j > 0) { sprintf(keyword, "%d%s%d%c", j, tbkey, btcol, alt); } else { sprintf(keyword, "%s%d%c", tbkey, btcol, alt); } if ((strlen(keyword) < 8) && tlkey && (relax & level)) { /* Use the long form. */ if (i > 0 && j) { if (j > 0) { sprintf(keyword, "%d%d%s%d%c", i, j, tlkey, btcol, alt); } else { sprintf(keyword, "%d%s%d_%d%c", i, tlkey, btcol, m, alt); } } else if (i > 0) { sprintf(keyword, "%d%s%d%c", i, tlkey, btcol, alt); } else if (j > 0) { sprintf(keyword, "%d%s%d%c", j, tlkey, btcol, alt); } else { sprintf(keyword, "%s%d%c", tlkey, btcol, alt); } } } else if (plcol && plcol[0]) { /* Pixel list. */ if (i > 0 && j) { if (j > 0) { sprintf(keyword, "T%s%d_%d%c", tbkey, plcol[i-1], plcol[j-1], alt); } else { sprintf(keyword, "T%s%d_%d%c", tbkey, plcol[i-1], m, alt); } } else if (i > 0) { sprintf(keyword, "T%s%d%c", tbkey, plcol[i-1], alt); } else if (j > 0) { sprintf(keyword, "T%s%d%c", tbkey, plcol[j-1], alt); } else { sprintf(keyword, "%s%d%c", tbkey, plcol[0], alt); } if ((strlen(keyword) < 8) && tlkey && (relax & level)) { /* Use the long form. */ if (i > 0 && j) { if (j > 0) { sprintf(keyword, "T%s%d_%d%c", tlkey, plcol[i-1], plcol[j-1], alt); } else { sprintf(keyword, "T%s%d_%d%c", tlkey, plcol[i-1], m, alt); } } else if (i > 0) { sprintf(keyword, "T%s%d%c", tlkey, plcol[i-1], alt); } else if (j > 0) { sprintf(keyword, "T%s%d%c", tlkey, plcol[j-1], alt); } else { sprintf(keyword, "%s%d%c", tlkey, plcol[0], alt); } } } else { if (i > 0 && j) { if (j > 0) { sprintf(keyword, "%s%d_%d%c", pikey, i, j, alt); } else { sprintf(keyword, "%s%d_%d%c", pikey, i, m, alt); } } else if (i > 0) { sprintf(keyword, "%s%d%c", pikey, i, alt); } else if (j > 0) { sprintf(keyword, "%s%d%c", pikey, j, alt); } else { sprintf(keyword, "%s%c", pikey, alt); } } /* Double-up single-quotes in string keyvalues. */ if (*keyvalue == '\'') { hptr = keyvalue + 1; while (*hptr) { if (*hptr == '\'') { kptr = hptr++; if (*hptr) { ch0 = *kptr; while (*kptr) { ch1 = *(++kptr); *kptr = ch0; ch0 = ch1; } } else { break; } } hptr++; } /* Check length. */ if (strlen(keyvalue) > 70) { /* Truncate. */ keyvalue[69] = '\''; keyvalue[70] = '\0'; } } else { /* Check length. */ if (strlen(keyvalue) > 70) { /* Truncate. */ keyvalue[70] = '\0'; } } if ((nv = strlen(keyvalue) > 20)) { /* Rob the keycomment to make space for the keyvalue. */ nc -= (nv - 20); } hptr = *header + (80 * ((*nkeyrec)++)); if (*keyword == '\0') { sprintf(hptr, "%80.80s", " "); } else if (strcmp(keyword, "COMMENT") == 0) { sprintf(hptr, "%-8.8s %-71.71s", keyword, keycomment); } else { sprintf(hptr, "%-8.8s= %-20s / %-*.*s", keyword, keyvalue, nc, nc, keycomment); } }