dnl This is m4 source. dnl Process using m4 to produce 'C' language file. dnl undefine(`begin')dnl undefine(`index')dnl undefine(`len')dnl dnl dnl If you see this line, you can ignore the next one. /* Do not edit this file. It is produced from the corresponding .m4 source */ dnl /* * Copyright 2018, University Corporation for Atmospheric Research * See netcdf/COPYRIGHT file for copying and redistribution conditions. */ /* $Id: putget.m4 2783 2014-10-26 05:19:35Z wkliao $ */ #if HAVE_CONFIG_H #include #endif #include #include #include #include "netcdf.h" #include "nc3dispatch.h" #include "nc3internal.h" #include "ncx.h" #include "fbits.h" #include "onstack.h" #undef MIN /* system may define MIN somewhere and complain */ #define MIN(mm,nn) (((mm) < (nn)) ? (mm) : (nn)) static int readNCv(const NC3_INFO* ncp, const NC_var* varp, const size_t* start, const size_t nelems, void* value, const nc_type memtype); static int writeNCv(NC3_INFO* ncp, const NC_var* varp, const size_t* start, const size_t nelems, const void* value, const nc_type memtype); /* #define ODEBUG 1 */ #if ODEBUG #include /* * Print the values of an array of size_t */ void arrayp(const char *label, size_t count, const size_t *array) { (void) fprintf(stderr, "%s", label); (void) fputc('\t',stderr); for(; count > 0; count--, array++) (void) fprintf(stderr," %lu", (unsigned long)*array); (void) fputc('\n',stderr); } #endif /* ODEBUG */ /* Begin fill */ /* * This is tunable parameter. * It essentially controls the tradeoff between the number of times * memcpy() gets called to copy the external data to fill * a large buffer vs the number of times its called to * prepare the external data. */ #if _SX /* NEC SX specific optimization */ #define NFILL 2048 #else #define NFILL 16 #endif dnl dnl NCFILL(Type, Xtype, XSize, Fill) dnl define(`NCFILL',dnl `dnl static int NC_fill_$2( void **xpp, size_t nelems) /* how many */ { $1 fillp[NFILL * sizeof(double)/$3]; assert(nelems <= sizeof(fillp)/sizeof(fillp[0])); { $1 *vp = fillp; /* lower bound of area to be filled */ const $1 *const end = vp + nelems; while(vp < end) { *vp++ = $4; } } return ncx_putn_$2_$1(xpp, nelems, fillp ifelse(`$1',`char',,`,NULL')); } ')dnl /* * Next 6 type specific functions * Fill a some memory with the default special value. * Formerly NC_arrayfill() */ NCFILL(schar, schar, X_SIZEOF_CHAR, NC_FILL_BYTE) NCFILL(char, char, X_SIZEOF_CHAR, NC_FILL_CHAR) NCFILL(short, short, X_SIZEOF_SHORT, NC_FILL_SHORT) #if (SIZEOF_INT >= X_SIZEOF_INT) NCFILL(int, int, X_SIZEOF_INT, NC_FILL_INT) #elif SIZEOF_LONG == X_SIZEOF_INT NCFILL(long, int, X_SIZEOF_INT, NC_FILL_INT) #else #error "NC_fill_int implementation" #endif NCFILL(float, float, X_SIZEOF_FLOAT, NC_FILL_FLOAT) NCFILL(double, double, X_SIZEOF_DOUBLE, NC_FILL_DOUBLE) NCFILL(uchar, uchar, X_SIZEOF_UBYTE, NC_FILL_UBYTE) NCFILL(ushort, ushort, X_SIZEOF_USHORT, NC_FILL_USHORT) NCFILL(uint, uint, X_SIZEOF_UINT, NC_FILL_UINT) NCFILL(longlong, longlong, X_SIZEOF_LONGLONG, NC_FILL_INT64) NCFILL(ulonglong, ulonglong, X_SIZEOF_ULONGLONG, NC_FILL_UINT64) /* * Fill the external space for variable 'varp' values at 'recno' with * the appropriate value. If 'varp' is not a record variable, fill the * whole thing. For the special case when 'varp' is the only record * variable and it is of type byte, char, or short, varsize should be * ncp->recsize, otherwise it should be varp->len. * Formerly xdr_NC_fill() */ int fill_NC_var(NC3_INFO* ncp, const NC_var *varp, long long varsize, size_t recno) { char xfillp[NFILL * X_SIZEOF_DOUBLE]; const size_t step = varp->xsz; const size_t nelems = sizeof(xfillp)/step; const size_t xsz = varp->xsz * nelems; NC_attr **attrpp = NULL; off_t offset; long long remaining = varsize; void *xp; int status = NC_NOERR; /* * Set up fill value */ attrpp = NC_findattr(&varp->attrs, _FillValue); if( attrpp != NULL ) { /* User defined fill value */ if( (*attrpp)->type != varp->type || (*attrpp)->nelems != 1 ) { return NC_EBADTYPE; } else { /* Use the user defined value */ char *cp = xfillp; const char *const end = &xfillp[sizeof(xfillp)]; assert(step <= (*attrpp)->xsz); for( /*NADA*/; cp < end; cp += step) { (void) memcpy(cp, (*attrpp)->xvalue, step); } } } else { /* use the default */ assert(xsz % X_ALIGN == 0); assert(xsz <= sizeof(xfillp)); xp = xfillp; switch(varp->type){ case NC_BYTE : status = NC_fill_schar(&xp, nelems); break; case NC_CHAR : status = NC_fill_char(&xp, nelems); break; case NC_SHORT : status = NC_fill_short(&xp, nelems); break; case NC_INT : status = NC_fill_int(&xp, nelems); break; case NC_FLOAT : status = NC_fill_float(&xp, nelems); break; case NC_DOUBLE : status = NC_fill_double(&xp, nelems); break; case NC_UBYTE : status = NC_fill_uchar(&xp, nelems); break; case NC_USHORT : status = NC_fill_ushort(&xp, nelems); break; case NC_UINT : status = NC_fill_uint(&xp, nelems); break; case NC_INT64 : status = NC_fill_longlong(&xp, nelems); break; case NC_UINT64 : status = NC_fill_ulonglong(&xp, nelems); break; default : assert("fill_NC_var invalid type" == 0); status = NC_EBADTYPE; break; } if(status != NC_NOERR) return status; assert(xp == xfillp + xsz); } /* * copyout: * xfillp now contains 'nelems' elements of the fill value * in external representation. */ /* * Copy it out. */ offset = varp->begin; if(IS_RECVAR(varp)) { offset += (off_t)ncp->recsize * recno; } assert(remaining > 0); for(;;) { const size_t chunksz = MIN(remaining, ncp->chunk); size_t ii; status = ncio_get(ncp->nciop, offset, chunksz, RGN_WRITE, &xp); if(status != NC_NOERR) { return status; } /* * fill the chunksz buffer in units of xsz */ for(ii = 0; ii < chunksz/xsz; ii++) { (void) memcpy(xp, xfillp, xsz); xp = (char *)xp + xsz; } /* * Deal with any remainder */ { const size_t rem = chunksz % xsz; if(rem != 0) { (void) memcpy(xp, xfillp, rem); /* xp = (char *)xp + xsz; */ } } status = ncio_rel(ncp->nciop, offset, RGN_MODIFIED); if(status != NC_NOERR) { break; } remaining -= chunksz; if(remaining == 0) break; /* normal loop exit */ offset += chunksz; } return status; } /* End fill */ /* * Add a record containing the fill values. */ static int NCfillrecord(NC3_INFO* ncp, const NC_var *const *varpp, size_t recno) { size_t ii = 0; for(; ii < ncp->vars.nelems; ii++, varpp++) { if( !IS_RECVAR(*varpp) ) { continue; /* skip non-record variables */ } { const int status = fill_NC_var(ncp, *varpp, (*varpp)->len, recno); if(status != NC_NOERR) return status; } } return NC_NOERR; } /* * Add a record containing the fill values in the special case when * there is exactly one record variable, where we don't require each * record to be four-byte aligned (no record padding). */ static int NCfillspecialrecord(NC3_INFO* ncp, const NC_var *varp, size_t recno) { int status; assert(IS_RECVAR(varp)); status = fill_NC_var(ncp, varp, ncp->recsize, recno); if(status != NC_NOERR) return status; return NC_NOERR; } /* * It is advantageous to * #define TOUCH_LAST * when using memory mapped io. */ #if TOUCH_LAST /* * Grow the file to a size which can contain recno */ static int NCtouchlast(NC3_INFO* ncp, const NC_var *const *varpp, size_t recno) { int status = NC_NOERR; const NC_var *varp = NULL; { size_t ii = 0; for(; ii < ncp->vars.nelems; ii++, varpp++) { if( !IS_RECVAR(*varpp) ) { continue; /* skip non-record variables */ } varp = *varpp; } } assert(varp != NULL); assert( IS_RECVAR(varp) ); { const off_t offset = varp->begin + (off_t)(recno-1) * (off_t)ncp->recsize + (off_t)(varp->len - varp->xsz); void *xp; status = ncio_get(ncp->nciop, offset, varp->xsz, RGN_WRITE, &xp); if(status != NC_NOERR) return status; (void)memset(xp, 0, varp->xsz); status = ncio_rel(ncp->nciop, offset, RGN_MODIFIED); } return status; } #endif /* TOUCH_LAST */ /* * Ensure that the netcdf file has 'numrecs' records, * add records and fill as necessary. */ static int NCvnrecs(NC3_INFO* ncp, size_t numrecs) { int status = NC_NOERR; if(numrecs > NC_get_numrecs(ncp)) { #if TOUCH_LAST status = NCtouchlast(ncp, (const NC_var *const*)ncp->vars.value, numrecs); if(status != NC_NOERR) goto common_return; #endif /* TOUCH_LAST */ set_NC_ndirty(ncp); if(!NC_dofill(ncp)) { /* Simply set the new numrecs value */ NC_set_numrecs(ncp, numrecs); } else { /* Treat two cases differently: - exactly one record variable (no padding) - multiple record variables (each record padded to 4-byte alignment) */ NC_var **vpp = (NC_var **)ncp->vars.value; NC_var *const *const end = &vpp[ncp->vars.nelems]; NC_var *recvarp = NULL; /* last record var */ int numrecvars = 0; size_t cur_nrecs; /* determine how many record variables */ for( /*NADA*/; vpp < end; vpp++) { if(IS_RECVAR(*vpp)) { recvarp = *vpp; numrecvars++; } } if (numrecvars != 1) { /* usual case */ /* Fill each record out to numrecs */ while((cur_nrecs = NC_get_numrecs(ncp)) < numrecs) { status = NCfillrecord(ncp, (const NC_var *const*)ncp->vars.value, cur_nrecs); if(status != NC_NOERR) { break; } NC_increase_numrecs(ncp, cur_nrecs +1); } if(status != NC_NOERR) goto common_return; } else { /* special case */ /* Fill each record out to numrecs */ while((cur_nrecs = NC_get_numrecs(ncp)) < numrecs) { status = NCfillspecialrecord(ncp, recvarp, cur_nrecs); if(status != NC_NOERR) { break; } NC_increase_numrecs(ncp, cur_nrecs +1); } if(status != NC_NOERR) goto common_return; } } if(NC_doNsync(ncp)) { status = write_numrecs(ncp); } } common_return: return status; } /* * Check whether 'coord' values are valid for the variable. */ static int NCcoordck(NC3_INFO* ncp, const NC_var *varp, const size_t *coord) { const size_t *ip; size_t *up; if(varp->ndims == 0) return NC_NOERR; /* 'scalar' variable */ if(IS_RECVAR(varp)) { if(*coord > X_UINT_MAX) /* rkr: bug fix from previous X_INT_MAX */ return NC_EINVALCOORDS; /* sanity check */ if(NC_readonly(ncp) && *coord > NC_get_numrecs(ncp)) { if(!NC_doNsync(ncp)) return NC_EINVALCOORDS; /* else */ { /* Update from disk and check again */ const int status = read_numrecs(ncp); if(status != NC_NOERR) return status; if(*coord > NC_get_numrecs(ncp)) return NC_EINVALCOORDS; } } ip = coord + 1; up = varp->shape + 1; } else { ip = coord; up = varp->shape; } #ifdef CDEBUG fprintf(stderr," NCcoordck: coord %ld, count %d, ip %ld\n", coord, varp->ndims, ip ); #endif /* CDEBUG */ for(; ip < coord + varp->ndims; ip++, up++) { #ifdef CDEBUG fprintf(stderr," NCcoordck: ip %p, *ip %ld, up %p, *up %lu\n", ip, *ip, up, *up ); #endif /* CDEBUG */ /* cast needed for braindead systems with signed size_t */ if((unsigned long) *ip > (unsigned long) *up ) return NC_EINVALCOORDS; } return NC_NOERR; } /* * Check whether 'edges' are valid for the variable and 'start' */ /*ARGSUSED*/ static int NCedgeck(const NC3_INFO* ncp, const NC_var *varp, const size_t *start, const size_t *edges) { const size_t *const end = start + varp->ndims; const size_t *shp = varp->shape; if(varp->ndims == 0) return NC_NOERR; /* 'scalar' variable */ if(IS_RECVAR(varp)) { if (NC_readonly(ncp) && (start[0] == NC_get_numrecs(ncp) && edges[0] > 0)) return(NC_EINVALCOORDS); start++; edges++; shp++; } for(; start < end; start++, edges++, shp++) { if ((unsigned long) *start == *shp && *edges > 0) return(NC_EINVALCOORDS); /* cast needed for braindead systems with signed size_t */ if((unsigned long) *edges > *shp || (unsigned long) *start + (unsigned long) *edges > *shp) { return(NC_EEDGE); } } return NC_NOERR; } /* * Translate the (variable, coord) pair into a seek index */ static off_t NC_varoffset(const NC3_INFO* ncp, const NC_var *varp, const size_t *coord) { if(varp->ndims == 0) /* 'scalar' variable */ return varp->begin; if(varp->ndims == 1) { if(IS_RECVAR(varp)) return varp->begin + (off_t)(*coord) * (off_t)ncp->recsize; /* else */ return varp->begin + (off_t)(*coord) * (off_t)varp->xsz; } /* else */ { off_t lcoord = (off_t)coord[varp->ndims -1]; off_t *up = varp->dsizes +1; const size_t *ip = coord; const off_t *const end = varp->dsizes + varp->ndims; if(IS_RECVAR(varp)) up++, ip++; for(; up < end; up++, ip++) lcoord += (off_t)(*up) * (off_t)(*ip); lcoord *= varp->xsz; if(IS_RECVAR(varp)) lcoord += (off_t)(*coord) * ncp->recsize; lcoord += varp->begin; return lcoord; } } dnl dnl Output 'nelems' items of contiguous data of type "Type" dnl for variable 'varp' at 'start'. dnl "Xtype" had better match 'varp->type'. dnl--- dnl dnl PUTNCVX(Xtype, Type) dnl define(`PUTNCVX',dnl `dnl static int putNCvx_$1_$2(NC3_INFO* ncp, const NC_var *varp, const size_t *start, size_t nelems, const $2 *value) { off_t offset = NC_varoffset(ncp, varp, start); size_t remaining = varp->xsz * nelems; int status = NC_NOERR; void *xp; void *fillp=NULL; NC_UNUSED(fillp); if(nelems == 0) return NC_NOERR; assert(value != NULL); #ifdef ERANGE_FILL fillp = malloc(varp->xsz); status = NC3_inq_var_fill(varp, fillp); #endif for(;;) { size_t extent = MIN(remaining, ncp->chunk); size_t nput = ncx_howmany(varp->type, extent); int lstatus = ncio_get(ncp->nciop, offset, extent, RGN_WRITE, &xp); if(lstatus != NC_NOERR) return lstatus; lstatus = ncx_putn_$1_$2(&xp, nput, value ifelse(`$1',`char',,`,fillp')); if(lstatus != NC_NOERR && status == NC_NOERR) { /* not fatal to the loop */ status = lstatus; } (void) ncio_rel(ncp->nciop, offset, RGN_MODIFIED); remaining -= extent; if(remaining == 0) break; /* normal loop exit */ offset += (off_t)extent; value += nput; } #ifdef ERANGE_FILL free(fillp); #endif return status; } ')dnl PUTNCVX(char, char) PUTNCVX(schar, schar) PUTNCVX(schar, uchar) PUTNCVX(schar, short) PUTNCVX(schar, int) PUTNCVX(schar, float) PUTNCVX(schar, double) PUTNCVX(schar, longlong) PUTNCVX(schar, ushort) PUTNCVX(schar, uint) PUTNCVX(schar, ulonglong) PUTNCVX(short, schar) PUTNCVX(short, uchar) PUTNCVX(short, short) PUTNCVX(short, int) PUTNCVX(short, float) PUTNCVX(short, double) PUTNCVX(short, longlong) PUTNCVX(short, ushort) PUTNCVX(short, uint) PUTNCVX(short, ulonglong) PUTNCVX(int, schar) PUTNCVX(int, uchar) PUTNCVX(int, short) PUTNCVX(int, int) PUTNCVX(int, float) PUTNCVX(int, double) PUTNCVX(int, longlong) PUTNCVX(int, ushort) PUTNCVX(int, uint) PUTNCVX(int, ulonglong) PUTNCVX(float, schar) PUTNCVX(float, uchar) PUTNCVX(float, short) PUTNCVX(float, int) PUTNCVX(float, float) PUTNCVX(float, double) PUTNCVX(float, longlong) PUTNCVX(float, ushort) PUTNCVX(float, uint) PUTNCVX(float, ulonglong) PUTNCVX(double, schar) PUTNCVX(double, uchar) PUTNCVX(double, short) PUTNCVX(double, int) PUTNCVX(double, float) PUTNCVX(double, double) PUTNCVX(double, longlong) PUTNCVX(double, ushort) PUTNCVX(double, uint) PUTNCVX(double, ulonglong) PUTNCVX(uchar, schar) PUTNCVX(uchar, uchar) PUTNCVX(uchar, short) PUTNCVX(uchar, int) PUTNCVX(uchar, float) PUTNCVX(uchar, double) PUTNCVX(uchar, longlong) PUTNCVX(uchar, ushort) PUTNCVX(uchar, uint) PUTNCVX(uchar, ulonglong) PUTNCVX(ushort, schar) PUTNCVX(ushort, uchar) PUTNCVX(ushort, short) PUTNCVX(ushort, int) PUTNCVX(ushort, float) PUTNCVX(ushort, double) PUTNCVX(ushort, longlong) PUTNCVX(ushort, ushort) PUTNCVX(ushort, uint) PUTNCVX(ushort, ulonglong) PUTNCVX(uint, schar) PUTNCVX(uint, uchar) PUTNCVX(uint, short) PUTNCVX(uint, int) PUTNCVX(uint, float) PUTNCVX(uint, double) PUTNCVX(uint, longlong) PUTNCVX(uint, ushort) PUTNCVX(uint, uint) PUTNCVX(uint, ulonglong) PUTNCVX(longlong, schar) PUTNCVX(longlong, uchar) PUTNCVX(longlong, short) PUTNCVX(longlong, int) PUTNCVX(longlong, float) PUTNCVX(longlong, double) PUTNCVX(longlong, longlong) PUTNCVX(longlong, ushort) PUTNCVX(longlong, uint) PUTNCVX(longlong, ulonglong) PUTNCVX(ulonglong, schar) PUTNCVX(ulonglong, uchar) PUTNCVX(ulonglong, short) PUTNCVX(ulonglong, int) PUTNCVX(ulonglong, float) PUTNCVX(ulonglong, double) PUTNCVX(ulonglong, longlong) PUTNCVX(ulonglong, ushort) PUTNCVX(ulonglong, uint) PUTNCVX(ulonglong, ulonglong) dnl dnl GETNCVX(XType, Type) dnl define(`GETNCVX',dnl `dnl static int getNCvx_$1_$2(const NC3_INFO* ncp, const NC_var *varp, const size_t *start, size_t nelems, $2 *value) { off_t offset = NC_varoffset(ncp, varp, start); size_t remaining = varp->xsz * nelems; int status = NC_NOERR; const void *xp; if(nelems == 0) return NC_NOERR; assert(value != NULL); for(;;) { size_t extent = MIN(remaining, ncp->chunk); size_t nget = ncx_howmany(varp->type, extent); int lstatus = ncio_get(ncp->nciop, offset, extent, 0, (void **)&xp); /* cast away const */ if(lstatus != NC_NOERR) return lstatus; lstatus = ncx_getn_$1_$2(&xp, nget, value); if(lstatus != NC_NOERR && status == NC_NOERR) status = lstatus; (void) ncio_rel(ncp->nciop, offset, 0); remaining -= extent; if(remaining == 0) break; /* normal loop exit */ offset += (off_t)extent; value += nget; } return status; } ')dnl #if 0 /*unused*/ GETNCVX(char, char) #endif GETNCVX(schar, schar) GETNCVX(schar, short) GETNCVX(schar, int) GETNCVX(schar, float) GETNCVX(schar, double) GETNCVX(schar, longlong) GETNCVX(schar, uint) GETNCVX(schar, ulonglong) GETNCVX(schar, uchar) GETNCVX(schar, ushort) GETNCVX(short, schar) GETNCVX(short, uchar) GETNCVX(short, short) GETNCVX(short, int) GETNCVX(short, float) GETNCVX(short, double) GETNCVX(short, longlong) GETNCVX(short, uint) GETNCVX(short, ulonglong) GETNCVX(short, ushort) GETNCVX(int, schar) GETNCVX(int, uchar) GETNCVX(int, short) GETNCVX(int, int) GETNCVX(int, float) GETNCVX(int, double) GETNCVX(int, longlong) GETNCVX(int, uint) GETNCVX(int, ulonglong) GETNCVX(int, ushort) GETNCVX(float, schar) GETNCVX(float, uchar) GETNCVX(float, short) GETNCVX(float, int) GETNCVX(float, float) GETNCVX(float, double) GETNCVX(float, longlong) GETNCVX(float, uint) GETNCVX(float, ulonglong) GETNCVX(float, ushort) GETNCVX(double, schar) GETNCVX(double, uchar) GETNCVX(double, short) GETNCVX(double, int) GETNCVX(double, float) GETNCVX(double, double) GETNCVX(double, longlong) GETNCVX(double, uint) GETNCVX(double, ulonglong) GETNCVX(double, ushort) GETNCVX(uchar, schar) GETNCVX(uchar, uchar) GETNCVX(uchar, short) GETNCVX(uchar, int) GETNCVX(uchar, float) GETNCVX(uchar, double) GETNCVX(uchar, longlong) GETNCVX(uchar, uint) GETNCVX(uchar, ulonglong) GETNCVX(uchar, ushort) GETNCVX(ushort, schar) GETNCVX(ushort, uchar) GETNCVX(ushort, short) GETNCVX(ushort, int) GETNCVX(ushort, float) GETNCVX(ushort, double) GETNCVX(ushort, longlong) GETNCVX(ushort, uint) GETNCVX(ushort, ulonglong) GETNCVX(ushort, ushort) GETNCVX(uint, schar) GETNCVX(uint, uchar) GETNCVX(uint, short) GETNCVX(uint, int) GETNCVX(uint, float) GETNCVX(uint, double) GETNCVX(uint, longlong) GETNCVX(uint, uint) GETNCVX(uint, ulonglong) GETNCVX(uint, ushort) GETNCVX(longlong, schar) GETNCVX(longlong, uchar) GETNCVX(longlong, short) GETNCVX(longlong, int) GETNCVX(longlong, float) GETNCVX(longlong, double) GETNCVX(longlong, longlong) GETNCVX(longlong, uint) GETNCVX(longlong, ulonglong) GETNCVX(longlong, ushort) GETNCVX(ulonglong, schar) GETNCVX(ulonglong, uchar) GETNCVX(ulonglong, short) GETNCVX(ulonglong, int) GETNCVX(ulonglong, float) GETNCVX(ulonglong, double) GETNCVX(ulonglong, longlong) GETNCVX(ulonglong, uint) GETNCVX(ulonglong, ulonglong) GETNCVX(ulonglong, ushort) dnl Following are not currently uses #ifdef NOTUSED GETNCVX(schar, uchar) #endif /*NOTUSED*/ /* * For ncvar{put,get}, * find the largest contiguous block from within 'edges'. * returns the index to the left of this (which may be -1). * Compute the number of contiguous elements and return * that in *iocountp. * The presence of "record" variables makes this routine * overly subtle. */ static int NCiocount(const NC3_INFO* const ncp, const NC_var *const varp, const size_t *const edges, size_t *const iocountp) { const size_t *edp0 = edges; const size_t *edp = edges + varp->ndims; const size_t *shp = varp->shape + varp->ndims; if(IS_RECVAR(varp)) { if(varp->ndims == 1 && ncp->recsize <= varp->len) { /* one dimensional && the only 'record' variable */ *iocountp = *edges; return(0); } /* else */ edp0++; } assert(edges != NULL); /* find max contiguous */ while(edp > edp0) { shp--; edp--; if(*edp < *shp ) { const size_t *zedp = edp; while(zedp >= edp0) { if(*zedp == 0) { *iocountp = 0; goto done; } /* Tip of the hat to segmented architectures */ if(zedp == edp0) break; zedp--; } break; } assert(*edp == *shp); } /* * edp, shp reference rightmost index s.t. *(edp +1) == *(shp +1) * * Or there is only one dimension. * If there is only one dimension and it is 'non record' dimension, * edp is &edges[0] and we will return -1. * If there is only one dimension and and it is a "record dimension", * edp is &edges[1] (out of bounds) and we will return 0; */ assert(shp >= varp->shape + varp->ndims -1 || *(edp +1) == *(shp +1)); /* now accumulate max count for a single io operation */ for(*iocountp = 1, edp0 = edp; edp0 < edges + varp->ndims; edp0++) { *iocountp *= *edp0; } done: return((int)(edp - edges) - 1); } /* * Set the elements of the array 'upp' to * the sum of the corresponding elements of * 'stp' and 'edp'. 'end' should be &stp[nelems]. */ static void set_upper(size_t *upp, /* modified on return */ const size_t *stp, const size_t *edp, const size_t *const end) { while(upp < end) { *upp++ = *stp++ + *edp++; } } /* * The infamous and oft-discussed odometer code. * * 'start[]' is the starting coordinate. * 'upper[]' is the upper bound s.t. start[ii] < upper[ii]. * 'coord[]' is the register, the current coordinate value. * For some ii, * upp == &upper[ii] * cdp == &coord[ii] * * Running this routine increments *cdp. * * If after the increment, *cdp is equal to *upp * (and cdp is not the leftmost dimension), * *cdp is "zeroed" to the starting value and * we need to "carry", eg, increment one place to * the left. * * TODO: Some architectures hate recursion? * Reimplement non-recursively. */ static void odo1(const size_t *const start, const size_t *const upper, size_t *const coord, /* modified on return */ const size_t *upp, size_t *cdp) { assert(coord <= cdp && cdp <= coord + NC_MAX_VAR_DIMS); assert(upper <= upp && upp <= upper + NC_MAX_VAR_DIMS); assert(upp - upper == cdp - coord); assert(*cdp <= *upp); (*cdp)++; if(cdp != coord && *cdp >= *upp) { *cdp = start[cdp - coord]; odo1(start, upper, coord, upp -1, cdp -1); } } #ifdef _CRAYC #pragma _CRI noinline odo1 #endif dnl dnl NCTEXTCOND(Abbrv) dnl This is used inside the NC{PUT,GET} macros below dnl define(`NCTEXTCOND',dnl `dnl ifelse($1, text,dnl `dnl if(varp->type != NC_CHAR) return NC_ECHAR; ',dnl `dnl if(varp->type == NC_CHAR) return NC_ECHAR; ')dnl ')dnl /* Define a macro to allow hash on two type values */ #define CASE(nc1,nc2) (nc1*256+nc2) static int readNCv(const NC3_INFO* ncp, const NC_var* varp, const size_t* start, const size_t nelems, void* value, const nc_type memtype) { int status = NC_NOERR; switch (CASE(varp->type,memtype)) { case CASE(NC_CHAR,NC_CHAR): case CASE(NC_CHAR,NC_UBYTE): return getNCvx_schar_schar(ncp,varp,start,nelems,(signed char*)value); break; case CASE(NC_BYTE,NC_BYTE): return getNCvx_schar_schar(ncp,varp,start,nelems, (schar*)value); break; case CASE(NC_BYTE,NC_UBYTE): if (fIsSet(ncp->flags,NC_64BIT_DATA)) return getNCvx_schar_uchar(ncp,varp,start,nelems,(unsigned char*)value); else /* for CDF-1 and CDF-2, NC_BYTE is treated the same type as uchar memtype */ return getNCvx_uchar_uchar(ncp,varp,start,nelems,(unsigned char*)value); break; case CASE(NC_BYTE,NC_SHORT): return getNCvx_schar_short(ncp,varp,start,nelems,(short*)value); break; case CASE(NC_BYTE,NC_INT): return getNCvx_schar_int(ncp,varp,start,nelems,(int*)value); break; case CASE(NC_BYTE,NC_FLOAT): return getNCvx_schar_float(ncp,varp,start,nelems,(float*)value); break; case CASE(NC_BYTE,NC_DOUBLE): return getNCvx_schar_double(ncp,varp,start,nelems,(double *)value); break; case CASE(NC_BYTE,NC_INT64): return getNCvx_schar_longlong(ncp,varp,start,nelems,(long long*)value); break; case CASE(NC_BYTE,NC_UINT): return getNCvx_schar_uint(ncp,varp,start,nelems,(unsigned int*)value); break; case CASE(NC_BYTE,NC_UINT64): return getNCvx_schar_ulonglong(ncp,varp,start,nelems,(unsigned long long*)value); break; case CASE(NC_BYTE,NC_USHORT): return getNCvx_schar_ushort(ncp,varp,start,nelems,(unsigned short*)value); break; case CASE(NC_SHORT,NC_BYTE): return getNCvx_short_schar(ncp,varp,start,nelems,(schar*)value); break; case CASE(NC_SHORT,NC_UBYTE): return getNCvx_short_uchar(ncp,varp,start,nelems,(unsigned char*)value); break; case CASE(NC_SHORT,NC_SHORT): return getNCvx_short_short(ncp,varp,start,nelems,(short*)value); break; case CASE(NC_SHORT,NC_INT): return getNCvx_short_int(ncp,varp,start,nelems,(int*)value); break; case CASE(NC_SHORT,NC_FLOAT): return getNCvx_short_float(ncp,varp,start,nelems,(float*)value); break; case CASE(NC_SHORT,NC_DOUBLE): return getNCvx_short_double(ncp,varp,start,nelems,(double*)value); break; case CASE(NC_SHORT,NC_INT64): return getNCvx_short_longlong(ncp,varp,start,nelems,(long long*)value); break; case CASE(NC_SHORT,NC_UINT): return getNCvx_short_uint(ncp,varp,start,nelems,(unsigned int*)value); break; case CASE(NC_SHORT,NC_UINT64): return getNCvx_short_ulonglong(ncp,varp,start,nelems,(unsigned long long*)value); break; case CASE(NC_SHORT,NC_USHORT): return getNCvx_short_ushort(ncp,varp,start,nelems,(unsigned short*)value); break; case CASE(NC_INT,NC_BYTE): return getNCvx_int_schar(ncp,varp,start,nelems,(schar*)value); break; case CASE(NC_INT,NC_UBYTE): return getNCvx_int_uchar(ncp,varp,start,nelems,(unsigned char*)value); break; case CASE(NC_INT,NC_SHORT): return getNCvx_int_short(ncp,varp,start,nelems,(short*)value); break; case CASE(NC_INT,NC_INT): return getNCvx_int_int(ncp,varp,start,nelems,(int*)value); break; case CASE(NC_INT,NC_FLOAT): return getNCvx_int_float(ncp,varp,start,nelems,(float*)value); break; case CASE(NC_INT,NC_DOUBLE): return getNCvx_int_double(ncp,varp,start,nelems,(double*)value); break; case CASE(NC_INT,NC_INT64): return getNCvx_int_longlong(ncp,varp,start,nelems,(long long*)value); break; case CASE(NC_INT,NC_UINT): return getNCvx_int_uint(ncp,varp,start,nelems,(unsigned int*)value); break; case CASE(NC_INT,NC_UINT64): return getNCvx_int_ulonglong(ncp,varp,start,nelems,(unsigned long long*)value); break; case CASE(NC_INT,NC_USHORT): return getNCvx_int_ushort(ncp,varp,start,nelems,(unsigned short*)value); break; case CASE(NC_FLOAT,NC_BYTE): return getNCvx_float_schar(ncp,varp,start,nelems,(schar*)value); break; case CASE(NC_FLOAT,NC_UBYTE): return getNCvx_float_uchar(ncp,varp,start,nelems,(unsigned char*)value); break; case CASE(NC_FLOAT,NC_SHORT): return getNCvx_float_short(ncp,varp,start,nelems,(short*)value); break; case CASE(NC_FLOAT,NC_INT): return getNCvx_float_int(ncp,varp,start,nelems,(int*)value); break; case CASE(NC_FLOAT,NC_FLOAT): return getNCvx_float_float(ncp,varp,start,nelems,(float*)value); break; case CASE(NC_FLOAT,NC_DOUBLE): return getNCvx_float_double(ncp,varp,start,nelems,(double*)value); break; case CASE(NC_FLOAT,NC_INT64): return getNCvx_float_longlong(ncp,varp,start,nelems,(long long*)value); break; case CASE(NC_FLOAT,NC_UINT): return getNCvx_float_uint(ncp,varp,start,nelems,(unsigned int*)value); break; case CASE(NC_FLOAT,NC_UINT64): return getNCvx_float_ulonglong(ncp,varp,start,nelems,(unsigned long long*)value); break; case CASE(NC_FLOAT,NC_USHORT): return getNCvx_float_ushort(ncp,varp,start,nelems,(unsigned short*)value); break; case CASE(NC_DOUBLE,NC_BYTE): return getNCvx_double_schar(ncp,varp,start,nelems,(schar*)value); break; case CASE(NC_DOUBLE,NC_UBYTE): return getNCvx_double_uchar(ncp,varp,start,nelems,(unsigned char*)value); break; case CASE(NC_DOUBLE,NC_SHORT): return getNCvx_double_short(ncp,varp,start,nelems,(short*)value); break; case CASE(NC_DOUBLE,NC_INT): return getNCvx_double_int(ncp,varp,start,nelems,(int*)value); break; case CASE(NC_DOUBLE,NC_FLOAT): return getNCvx_double_float(ncp,varp,start,nelems,(float*)value); break; case CASE(NC_DOUBLE,NC_DOUBLE): return getNCvx_double_double(ncp,varp,start,nelems,(double*)value); break; case CASE(NC_DOUBLE,NC_INT64): return getNCvx_double_longlong(ncp,varp,start,nelems,(long long*)value); break; case CASE(NC_DOUBLE,NC_UINT): return getNCvx_double_uint(ncp,varp,start,nelems,(unsigned int*)value); break; case CASE(NC_DOUBLE,NC_UINT64): return getNCvx_double_ulonglong(ncp,varp,start,nelems,(unsigned long long*)value); break; case CASE(NC_DOUBLE,NC_USHORT): return getNCvx_double_ushort(ncp,varp,start,nelems,(unsigned short*)value); break; case CASE(NC_UBYTE,NC_UBYTE): return getNCvx_uchar_uchar(ncp,varp,start,nelems,(unsigned char*)value); break; case CASE(NC_UBYTE,NC_BYTE): return getNCvx_uchar_schar(ncp,varp,start,nelems,(schar*)value); break; case CASE(NC_UBYTE,NC_SHORT): return getNCvx_uchar_short(ncp,varp,start,nelems,(short*)value); break; case CASE(NC_UBYTE,NC_INT): return getNCvx_uchar_int(ncp,varp,start,nelems,(int*)value); break; case CASE(NC_UBYTE,NC_FLOAT): return getNCvx_uchar_float(ncp,varp,start,nelems,(float*)value); break; case CASE(NC_UBYTE,NC_DOUBLE): return getNCvx_uchar_double(ncp,varp,start,nelems,(double *)value); break; case CASE(NC_UBYTE,NC_INT64): return getNCvx_uchar_longlong(ncp,varp,start,nelems,(long long*)value); break; case CASE(NC_UBYTE,NC_UINT): return getNCvx_uchar_uint(ncp,varp,start,nelems,(unsigned int*)value); break; case CASE(NC_UBYTE,NC_UINT64): return getNCvx_uchar_ulonglong(ncp,varp,start,nelems,(unsigned long long*)value); break; case CASE(NC_UBYTE,NC_USHORT): return getNCvx_uchar_ushort(ncp,varp,start,nelems,(unsigned short*)value); break; case CASE(NC_USHORT,NC_BYTE): return getNCvx_ushort_schar(ncp,varp,start,nelems,(schar*)value); break; case CASE(NC_USHORT,NC_UBYTE): return getNCvx_ushort_uchar(ncp,varp,start,nelems,(unsigned char*)value); break; case CASE(NC_USHORT,NC_SHORT): return getNCvx_ushort_short(ncp,varp,start,nelems,(short*)value); break; case CASE(NC_USHORT,NC_INT): return getNCvx_ushort_int(ncp,varp,start,nelems,(int*)value); break; case CASE(NC_USHORT,NC_FLOAT): return getNCvx_ushort_float(ncp,varp,start,nelems,(float*)value); break; case CASE(NC_USHORT,NC_DOUBLE): return getNCvx_ushort_double(ncp,varp,start,nelems,(double*)value); break; case CASE(NC_USHORT,NC_INT64): return getNCvx_ushort_longlong(ncp,varp,start,nelems,(long long*)value); break; case CASE(NC_USHORT,NC_UINT): return getNCvx_ushort_uint(ncp,varp,start,nelems,(unsigned int*)value); break; case CASE(NC_USHORT,NC_UINT64): return getNCvx_ushort_ulonglong(ncp,varp,start,nelems,(unsigned long long*)value); break; case CASE(NC_USHORT,NC_USHORT): return getNCvx_ushort_ushort(ncp,varp,start,nelems,(unsigned short*)value); break; case CASE(NC_UINT,NC_BYTE): return getNCvx_uint_schar(ncp,varp,start,nelems,(schar*)value); break; case CASE(NC_UINT,NC_UBYTE): return getNCvx_uint_uchar(ncp,varp,start,nelems,(unsigned char*)value); break; case CASE(NC_UINT,NC_SHORT): return getNCvx_uint_short(ncp,varp,start,nelems,(short*)value); break; case CASE(NC_UINT,NC_INT): return getNCvx_uint_int(ncp,varp,start,nelems,(int*)value); break; case CASE(NC_UINT,NC_FLOAT): return getNCvx_uint_float(ncp,varp,start,nelems,(float*)value); break; case CASE(NC_UINT,NC_DOUBLE): return getNCvx_uint_double(ncp,varp,start,nelems,(double*)value); break; case CASE(NC_UINT,NC_INT64): return getNCvx_uint_longlong(ncp,varp,start,nelems,(long long*)value); break; case CASE(NC_UINT,NC_UINT): return getNCvx_uint_uint(ncp,varp,start,nelems,(unsigned int*)value); break; case CASE(NC_UINT,NC_UINT64): return getNCvx_uint_ulonglong(ncp,varp,start,nelems,(unsigned long long*)value); break; case CASE(NC_UINT,NC_USHORT): return getNCvx_uint_ushort(ncp,varp,start,nelems,(unsigned short*)value); break; case CASE(NC_INT64,NC_BYTE): return getNCvx_longlong_schar(ncp,varp,start,nelems,(schar*)value); break; case CASE(NC_INT64,NC_UBYTE): return getNCvx_longlong_uchar(ncp,varp,start,nelems,(unsigned char*)value); break; case CASE(NC_INT64,NC_SHORT): return getNCvx_longlong_short(ncp,varp,start,nelems,(short*)value); break; case CASE(NC_INT64,NC_INT): return getNCvx_longlong_int(ncp,varp,start,nelems,(int*)value); break; case CASE(NC_INT64,NC_FLOAT): return getNCvx_longlong_float(ncp,varp,start,nelems,(float*)value); break; case CASE(NC_INT64,NC_DOUBLE): return getNCvx_longlong_double(ncp,varp,start,nelems,(double*)value); break; case CASE(NC_INT64,NC_INT64): return getNCvx_longlong_longlong(ncp,varp,start,nelems,(long long*)value); break; case CASE(NC_INT64,NC_UINT): return getNCvx_longlong_uint(ncp,varp,start,nelems,(unsigned int*)value); break; case CASE(NC_INT64,NC_UINT64): return getNCvx_longlong_ulonglong(ncp,varp,start,nelems,(unsigned long long*)value); break; case CASE(NC_INT64,NC_USHORT): return getNCvx_longlong_ushort(ncp,varp,start,nelems,(unsigned short*)value); break; case CASE(NC_UINT64,NC_BYTE): return getNCvx_ulonglong_schar(ncp,varp,start,nelems,(schar*)value); break; case CASE(NC_UINT64,NC_UBYTE): return getNCvx_ulonglong_uchar(ncp,varp,start,nelems,(unsigned char*)value); break; case CASE(NC_UINT64,NC_SHORT): return getNCvx_ulonglong_short(ncp,varp,start,nelems,(short*)value); break; case CASE(NC_UINT64,NC_INT): return getNCvx_ulonglong_int(ncp,varp,start,nelems,(int*)value); break; case CASE(NC_UINT64,NC_FLOAT): return getNCvx_ulonglong_float(ncp,varp,start,nelems,(float*)value); break; case CASE(NC_UINT64,NC_DOUBLE): return getNCvx_ulonglong_double(ncp,varp,start,nelems,(double*)value); break; case CASE(NC_UINT64,NC_INT64): return getNCvx_ulonglong_longlong(ncp,varp,start,nelems,(long long*)value); break; case CASE(NC_UINT64,NC_UINT): return getNCvx_ulonglong_uint(ncp,varp,start,nelems,(unsigned int*)value); break; case CASE(NC_UINT64,NC_UINT64): return getNCvx_ulonglong_ulonglong(ncp,varp,start,nelems,(unsigned long long*)value); break; case CASE(NC_UINT64,NC_USHORT): return getNCvx_ulonglong_ushort(ncp,varp,start,nelems,(unsigned short*)value); break; default: return NC_EBADTYPE; break; } return status; } static int writeNCv(NC3_INFO* ncp, const NC_var* varp, const size_t* start, const size_t nelems, const void* value, const nc_type memtype) { int status = NC_NOERR; switch (CASE(varp->type,memtype)) { case CASE(NC_CHAR,NC_CHAR): case CASE(NC_CHAR,NC_UBYTE): return putNCvx_char_char(ncp,varp,start,nelems,(char*)value); break; case CASE(NC_BYTE,NC_BYTE): return putNCvx_schar_schar(ncp,varp,start,nelems,(schar*)value); break; case CASE(NC_BYTE,NC_UBYTE): if (fIsSet(ncp->flags,NC_64BIT_DATA)) return putNCvx_schar_uchar(ncp,varp,start,nelems,(unsigned char*)value); else /* for CDF-1 and CDF-2, NC_BYTE is treated the same type as uchar memtype */ return putNCvx_uchar_uchar(ncp,varp,start,nelems,(unsigned char*)value); break; case CASE(NC_BYTE,NC_SHORT): return putNCvx_schar_short(ncp,varp,start,nelems,(short*)value); break; case CASE(NC_BYTE,NC_INT): return putNCvx_schar_int(ncp,varp,start,nelems,(int*)value); break; case CASE(NC_BYTE,NC_FLOAT): return putNCvx_schar_float(ncp,varp,start,nelems,(float*)value); break; case CASE(NC_BYTE,NC_DOUBLE): return putNCvx_schar_double(ncp,varp,start,nelems,(double *)value); break; case CASE(NC_BYTE,NC_INT64): return putNCvx_schar_longlong(ncp,varp,start,nelems,(long long*)value); break; case CASE(NC_BYTE,NC_UINT): return putNCvx_schar_uint(ncp,varp,start,nelems,(unsigned int*)value); break; case CASE(NC_BYTE,NC_UINT64): return putNCvx_schar_ulonglong(ncp,varp,start,nelems,(unsigned long long*)value); break; case CASE(NC_BYTE,NC_USHORT): return putNCvx_schar_ushort(ncp,varp,start,nelems,(unsigned short*)value); break; case CASE(NC_SHORT,NC_BYTE): return putNCvx_short_schar(ncp,varp,start,nelems,(schar*)value); break; case CASE(NC_SHORT,NC_UBYTE): return putNCvx_short_uchar(ncp,varp,start,nelems,(unsigned char*)value); break; case CASE(NC_SHORT,NC_SHORT): return putNCvx_short_short(ncp,varp,start,nelems,(short*)value); break; case CASE(NC_SHORT,NC_INT): return putNCvx_short_int(ncp,varp,start,nelems,(int*)value); break; case CASE(NC_SHORT,NC_FLOAT): return putNCvx_short_float(ncp,varp,start,nelems,(float*)value); break; case CASE(NC_SHORT,NC_DOUBLE): return putNCvx_short_double(ncp,varp,start,nelems,(double*)value); break; case CASE(NC_SHORT,NC_INT64): return putNCvx_short_longlong(ncp,varp,start,nelems,(long long*)value); break; case CASE(NC_SHORT,NC_UINT): return putNCvx_short_uint(ncp,varp,start,nelems,(unsigned int*)value); break; case CASE(NC_SHORT,NC_UINT64): return putNCvx_short_ulonglong(ncp,varp,start,nelems,(unsigned long long*)value); break; case CASE(NC_SHORT,NC_USHORT): return putNCvx_short_ushort(ncp,varp,start,nelems,(unsigned short*)value); break; case CASE(NC_INT,NC_BYTE): return putNCvx_int_schar(ncp,varp,start,nelems,(schar*)value); break; case CASE(NC_INT,NC_UBYTE): return putNCvx_int_uchar(ncp,varp,start,nelems,(unsigned char*)value); break; case CASE(NC_INT,NC_SHORT): return putNCvx_int_short(ncp,varp,start,nelems,(short*)value); break; case CASE(NC_INT,NC_INT): return putNCvx_int_int(ncp,varp,start,nelems,(int*)value); break; case CASE(NC_INT,NC_FLOAT): return putNCvx_int_float(ncp,varp,start,nelems,(float*)value); break; case CASE(NC_INT,NC_DOUBLE): return putNCvx_int_double(ncp,varp,start,nelems,(double*)value); break; case CASE(NC_INT,NC_INT64): return putNCvx_int_longlong(ncp,varp,start,nelems,(long long*)value); break; case CASE(NC_INT,NC_UINT): return putNCvx_int_uint(ncp,varp,start,nelems,(unsigned int*)value); break; case CASE(NC_INT,NC_UINT64): return putNCvx_int_ulonglong(ncp,varp,start,nelems,(unsigned long long*)value); break; case CASE(NC_INT,NC_USHORT): return putNCvx_int_ushort(ncp,varp,start,nelems,(unsigned short*)value); break; case CASE(NC_FLOAT,NC_BYTE): return putNCvx_float_schar(ncp,varp,start,nelems,(schar*)value); break; case CASE(NC_FLOAT,NC_UBYTE): return putNCvx_float_uchar(ncp,varp,start,nelems,(unsigned char*)value); break; case CASE(NC_FLOAT,NC_SHORT): return putNCvx_float_short(ncp,varp,start,nelems,(short*)value); break; case CASE(NC_FLOAT,NC_INT): return putNCvx_float_int(ncp,varp,start,nelems,(int*)value); break; case CASE(NC_FLOAT,NC_FLOAT): return putNCvx_float_float(ncp,varp,start,nelems,(float*)value); break; case CASE(NC_FLOAT,NC_DOUBLE): return putNCvx_float_double(ncp,varp,start,nelems,(double*)value); break; case CASE(NC_FLOAT,NC_INT64): return putNCvx_float_longlong(ncp,varp,start,nelems,(long long*)value); break; case CASE(NC_FLOAT,NC_UINT): return putNCvx_float_uint(ncp,varp,start,nelems,(unsigned int*)value); break; case CASE(NC_FLOAT,NC_UINT64): return putNCvx_float_ulonglong(ncp,varp,start,nelems,(unsigned long long*)value); break; case CASE(NC_FLOAT,NC_USHORT): return putNCvx_float_ushort(ncp,varp,start,nelems,(unsigned short*)value); break; case CASE(NC_DOUBLE,NC_BYTE): return putNCvx_double_schar(ncp,varp,start,nelems,(schar*)value); break; case CASE(NC_DOUBLE,NC_UBYTE): return putNCvx_double_uchar(ncp,varp,start,nelems,(unsigned char*)value); break; case CASE(NC_DOUBLE,NC_SHORT): return putNCvx_double_short(ncp,varp,start,nelems,(short*)value); break; case CASE(NC_DOUBLE,NC_INT): return putNCvx_double_int(ncp,varp,start,nelems,(int*)value); break; case CASE(NC_DOUBLE,NC_FLOAT): return putNCvx_double_float(ncp,varp,start,nelems,(float*)value); break; case CASE(NC_DOUBLE,NC_DOUBLE): return putNCvx_double_double(ncp,varp,start,nelems,(double*)value); break; case CASE(NC_DOUBLE,NC_INT64): return putNCvx_double_longlong(ncp,varp,start,nelems,(long long*)value); break; case CASE(NC_DOUBLE,NC_UINT): return putNCvx_double_uint(ncp,varp,start,nelems,(unsigned int*)value); break; case CASE(NC_DOUBLE,NC_UINT64): return putNCvx_double_ulonglong(ncp,varp,start,nelems,(unsigned long long*)value); break; case CASE(NC_DOUBLE,NC_USHORT): return putNCvx_double_ushort(ncp,varp,start,nelems,(unsigned short*)value); break; case CASE(NC_UBYTE,NC_UBYTE): return putNCvx_uchar_uchar(ncp,varp,start,nelems,(unsigned char*)value); break; case CASE(NC_UBYTE,NC_BYTE): return putNCvx_uchar_schar(ncp,varp,start,nelems,(schar*)value); break; case CASE(NC_UBYTE,NC_SHORT): return putNCvx_uchar_short(ncp,varp,start,nelems,(short*)value); break; case CASE(NC_UBYTE,NC_INT): return putNCvx_uchar_int(ncp,varp,start,nelems,(int*)value); break; case CASE(NC_UBYTE,NC_FLOAT): return putNCvx_uchar_float(ncp,varp,start,nelems,(float*)value); break; case CASE(NC_UBYTE,NC_DOUBLE): return putNCvx_uchar_double(ncp,varp,start,nelems,(double *)value); break; case CASE(NC_UBYTE,NC_INT64): return putNCvx_uchar_longlong(ncp,varp,start,nelems,(long long*)value); break; case CASE(NC_UBYTE,NC_UINT): return putNCvx_uchar_uint(ncp,varp,start,nelems,(unsigned int*)value); break; case CASE(NC_UBYTE,NC_UINT64): return putNCvx_uchar_ulonglong(ncp,varp,start,nelems,(unsigned long long*)value); break; case CASE(NC_UBYTE,NC_USHORT): return putNCvx_uchar_ushort(ncp,varp,start,nelems,(unsigned short*)value); break; case CASE(NC_USHORT,NC_BYTE): return putNCvx_ushort_schar(ncp,varp,start,nelems,(schar*)value); break; case CASE(NC_USHORT,NC_UBYTE): return putNCvx_ushort_uchar(ncp,varp,start,nelems,(unsigned char*)value); break; case CASE(NC_USHORT,NC_SHORT): return putNCvx_ushort_short(ncp,varp,start,nelems,(short*)value); break; case CASE(NC_USHORT,NC_INT): return putNCvx_ushort_int(ncp,varp,start,nelems,(int*)value); break; case CASE(NC_USHORT,NC_FLOAT): return putNCvx_ushort_float(ncp,varp,start,nelems,(float*)value); break; case CASE(NC_USHORT,NC_DOUBLE): return putNCvx_ushort_double(ncp,varp,start,nelems,(double*)value); break; case CASE(NC_USHORT,NC_INT64): return putNCvx_ushort_longlong(ncp,varp,start,nelems,(long long*)value); break; case CASE(NC_USHORT,NC_UINT): return putNCvx_ushort_uint(ncp,varp,start,nelems,(unsigned int*)value); break; case CASE(NC_USHORT,NC_UINT64): return putNCvx_ushort_ulonglong(ncp,varp,start,nelems,(unsigned long long*)value); break; case CASE(NC_USHORT,NC_USHORT): return putNCvx_ushort_ushort(ncp,varp,start,nelems,(unsigned short*)value); break; case CASE(NC_UINT,NC_BYTE): return putNCvx_uint_schar(ncp,varp,start,nelems,(schar*)value); break; case CASE(NC_UINT,NC_UBYTE): return putNCvx_uint_uchar(ncp,varp,start,nelems,(unsigned char*)value); break; case CASE(NC_UINT,NC_SHORT): return putNCvx_uint_short(ncp,varp,start,nelems,(short*)value); break; case CASE(NC_UINT,NC_INT): return putNCvx_uint_int(ncp,varp,start,nelems,(int*)value); break; case CASE(NC_UINT,NC_FLOAT): return putNCvx_uint_float(ncp,varp,start,nelems,(float*)value); break; case CASE(NC_UINT,NC_DOUBLE): return putNCvx_uint_double(ncp,varp,start,nelems,(double*)value); break; case CASE(NC_UINT,NC_INT64): return putNCvx_uint_longlong(ncp,varp,start,nelems,(long long*)value); break; case CASE(NC_UINT,NC_UINT): return putNCvx_uint_uint(ncp,varp,start,nelems,(unsigned int*)value); break; case CASE(NC_UINT,NC_UINT64): return putNCvx_uint_ulonglong(ncp,varp,start,nelems,(unsigned long long*)value); break; case CASE(NC_UINT,NC_USHORT): return putNCvx_uint_ushort(ncp,varp,start,nelems,(unsigned short*)value); break; case CASE(NC_INT64,NC_BYTE): return putNCvx_longlong_schar(ncp,varp,start,nelems,(schar*)value); break; case CASE(NC_INT64,NC_UBYTE): return putNCvx_longlong_uchar(ncp,varp,start,nelems,(unsigned char*)value); break; case CASE(NC_INT64,NC_SHORT): return putNCvx_longlong_short(ncp,varp,start,nelems,(short*)value); break; case CASE(NC_INT64,NC_INT): return putNCvx_longlong_int(ncp,varp,start,nelems,(int*)value); break; case CASE(NC_INT64,NC_FLOAT): return putNCvx_longlong_float(ncp,varp,start,nelems,(float*)value); break; case CASE(NC_INT64,NC_DOUBLE): return putNCvx_longlong_double(ncp,varp,start,nelems,(double*)value); break; case CASE(NC_INT64,NC_INT64): return putNCvx_longlong_longlong(ncp,varp,start,nelems,(long long*)value); break; case CASE(NC_INT64,NC_UINT): return putNCvx_longlong_uint(ncp,varp,start,nelems,(unsigned int*)value); break; case CASE(NC_INT64,NC_UINT64): return putNCvx_longlong_ulonglong(ncp,varp,start,nelems,(unsigned long long*)value); break; case CASE(NC_INT64,NC_USHORT): return putNCvx_longlong_ushort(ncp,varp,start,nelems,(unsigned short*)value); break; case CASE(NC_UINT64,NC_BYTE): return putNCvx_ulonglong_schar(ncp,varp,start,nelems,(schar*)value); break; case CASE(NC_UINT64,NC_UBYTE): return putNCvx_ulonglong_uchar(ncp,varp,start,nelems,(unsigned char*)value); break; case CASE(NC_UINT64,NC_SHORT): return putNCvx_ulonglong_short(ncp,varp,start,nelems,(short*)value); break; case CASE(NC_UINT64,NC_INT): return putNCvx_ulonglong_int(ncp,varp,start,nelems,(int*)value); break; case CASE(NC_UINT64,NC_FLOAT): return putNCvx_ulonglong_float(ncp,varp,start,nelems,(float*)value); break; case CASE(NC_UINT64,NC_DOUBLE): return putNCvx_ulonglong_double(ncp,varp,start,nelems,(double*)value); break; case CASE(NC_UINT64,NC_INT64): return putNCvx_ulonglong_longlong(ncp,varp,start,nelems,(long long*)value); break; case CASE(NC_UINT64,NC_UINT): return putNCvx_ulonglong_uint(ncp,varp,start,nelems,(unsigned int*)value); break; case CASE(NC_UINT64,NC_UINT64): return putNCvx_ulonglong_ulonglong(ncp,varp,start,nelems,(unsigned long long*)value); break; case CASE(NC_UINT64,NC_USHORT): return putNCvx_ulonglong_ushort(ncp,varp,start,nelems,(unsigned short*)value); break; default: return NC_EBADTYPE; break; } return status; } /**************************************************/ int NC3_get_vara(int ncid, int varid, const size_t *start, const size_t *edges0, void *value0, nc_type memtype) { int status = NC_NOERR; NC* nc; NC3_INFO* nc3; NC_var *varp; int ii; size_t iocount; size_t memtypelen; signed char* value = (signed char*) value0; /* legally allow ptr arithmetic */ const size_t* edges = edges0; /* so we can modify for special cases */ size_t modedges[NC_MAX_VAR_DIMS]; status = NC_check_id(ncid, &nc); if(status != NC_NOERR) return status; nc3 = NC3_DATA(nc); if(NC_indef(nc3)) return NC_EINDEFINE; status = NC_lookupvar(nc3, varid, &varp); if(status != NC_NOERR) return status; if(memtype == NC_NAT) memtype=varp->type; if(memtype == NC_CHAR && varp->type != NC_CHAR) return NC_ECHAR; else if(memtype != NC_CHAR && varp->type == NC_CHAR) return NC_ECHAR; /* If edges is NULL, then this was called from nc_get_var() */ if(edges == NULL && varp->ndims > 0) { /* If this is a record variable, then we have to substitute the number of records into dimension 0. */ if(varp->shape[0] == 0) { (void)memcpy((void*)modedges,(void*)varp->shape, sizeof(size_t)*varp->ndims); modedges[0] = NC_get_numrecs(nc3); edges = modedges; } else edges = varp->shape; } status = NCcoordck(nc3, varp, start); if(status != NC_NOERR) return status; status = NCedgeck(nc3, varp, start, edges); if(status != NC_NOERR) return status; /* Get the size of the memtype */ memtypelen = nctypelen(memtype); if(varp->ndims == 0) /* scalar variable */ { return( readNCv(nc3, varp, start, 1, (void*)value, memtype) ); } if(IS_RECVAR(varp)) { if(*start + *edges > NC_get_numrecs(nc3)) return NC_EEDGE; if(varp->ndims == 1 && nc3->recsize <= varp->len) { /* one dimensional && the only record variable */ return( readNCv(nc3, varp, start, *edges, (void*)value, memtype) ); } } /* * find max contiguous * and accumulate max count for a single io operation */ ii = NCiocount(nc3, varp, edges, &iocount); if(ii == -1) { return( readNCv(nc3, varp, start, iocount, (void*)value, memtype) ); } assert(ii >= 0); { /* inline */ ALLOC_ONSTACK(coord, size_t, varp->ndims); ALLOC_ONSTACK(upper, size_t, varp->ndims); const size_t index = ii; /* copy in starting indices */ (void) memcpy(coord, start, varp->ndims * sizeof(size_t)); /* set up in maximum indices */ set_upper(upper, start, edges, &upper[varp->ndims]); /* ripple counter */ while(*coord < *upper) { const int lstatus = readNCv(nc3, varp, coord, iocount, (void*)value, memtype); if(lstatus != NC_NOERR) { if(lstatus != NC_ERANGE) { status = lstatus; /* fatal for the loop */ break; } /* else NC_ERANGE, not fatal for the loop */ if(status == NC_NOERR) status = lstatus; } value += (iocount * memtypelen); odo1(start, upper, coord, &upper[index], &coord[index]); } FREE_ONSTACK(upper); FREE_ONSTACK(coord); } /* end inline */ return status; } int NC3_put_vara(int ncid, int varid, const size_t *start, const size_t *edges0, const void *value0, nc_type memtype) { int status = NC_NOERR; NC *nc; NC3_INFO* nc3; NC_var *varp; int ii; size_t iocount; size_t memtypelen; signed char* value = (signed char*) value0; /* legally allow ptr arithmetic */ const size_t* edges = edges0; /* so we can modify for special cases */ size_t modedges[NC_MAX_VAR_DIMS]; status = NC_check_id(ncid, &nc); if(status != NC_NOERR) return status; nc3 = NC3_DATA(nc); if(NC_readonly(nc3)) return NC_EPERM; if(NC_indef(nc3)) return NC_EINDEFINE; status = NC_lookupvar(nc3, varid, &varp); if(status != NC_NOERR) return status; /*invalid varid */ if(memtype == NC_NAT) memtype=varp->type; if(memtype == NC_CHAR && varp->type != NC_CHAR) return NC_ECHAR; else if(memtype != NC_CHAR && varp->type == NC_CHAR) return NC_ECHAR; /* Get the size of the memtype */ memtypelen = nctypelen(memtype); /* If edges is NULL, then this was called from nc_get_var() */ if(edges == NULL && varp->ndims > 0) { /* If this is a record variable, then we have to substitute the number of records into dimension 0. */ if(varp->shape[0] == 0) { (void)memcpy((void*)modedges,(void*)varp->shape, sizeof(size_t)*varp->ndims); modedges[0] = NC_get_numrecs(nc3); edges = modedges; } else edges = varp->shape; } status = NCcoordck(nc3, varp, start); if(status != NC_NOERR) return status; status = NCedgeck(nc3, varp, start, edges); if(status != NC_NOERR) return status; if(varp->ndims == 0) /* scalar variable */ { return( writeNCv(nc3, varp, start, 1, (void*)value, memtype) ); } if(IS_RECVAR(varp)) { status = NCvnrecs(nc3, *start + *edges); if(status != NC_NOERR) return status; if(varp->ndims == 1 && nc3->recsize <= varp->len) { /* one dimensional && the only record variable */ return( writeNCv(nc3, varp, start, *edges, (void*)value, memtype) ); } } /* * find max contiguous * and accumulate max count for a single io operation */ ii = NCiocount(nc3, varp, edges, &iocount); if(ii == -1) { return( writeNCv(nc3, varp, start, iocount, (void*)value, memtype) ); } assert(ii >= 0); { /* inline */ ALLOC_ONSTACK(coord, size_t, varp->ndims); ALLOC_ONSTACK(upper, size_t, varp->ndims); const size_t index = ii; /* copy in starting indices */ (void) memcpy(coord, start, varp->ndims * sizeof(size_t)); /* set up in maximum indices */ set_upper(upper, start, edges, &upper[varp->ndims]); /* ripple counter */ while(*coord < *upper) { const int lstatus = writeNCv(nc3, varp, coord, iocount, (void*)value, memtype); if(lstatus != NC_NOERR) { if(lstatus != NC_ERANGE) { status = lstatus; /* fatal for the loop */ break; } /* else NC_ERANGE, not fatal for the loop */ if(status == NC_NOERR) status = lstatus; } value += (iocount * memtypelen); odo1(start, upper, coord, &upper[index], &coord[index]); } FREE_ONSTACK(upper); FREE_ONSTACK(coord); } /* end inline */ return status; }