mirror of
https://github.com/Unidata/netcdf-c.git
synced 2024-12-15 08:30:11 +08:00
c1fb4b0bae
Silence conversion warnings from `malloc` arguments
342 lines
9.4 KiB
C
342 lines
9.4 KiB
C
/*********************************************************************
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* Copyright 2018, UCAR/Unidata
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* See netcdf/COPYRIGHT file for copying and redistribution conditions.
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* $Header: /upc/share/CVS/netcdf-3/nctest/slabs.c,v 1.13 2009/02/11 16:17:39 ed Exp $
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*********************************************************************/
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#include <config.h>
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#include <stdlib.h> /* for free() */
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#include "netcdf.h"
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#include "testcdf.h" /* defines in-memory test cdf structure */
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#include "emalloc.h"
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#include "add.h" /* functions to update in-memory netcdf */
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#include "error.h"
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#include "tests.h"
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#define LEN_OF(array) ((sizeof array) / (sizeof array[0]))
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/* dimension sizes */
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#define NDIMS 4 /* number of dimensions */
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#define WSIZE 7 /* sizes of dimensions */
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#define XSIZE 5
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#define YSIZE 6
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#define ZSIZE 4
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/* Any function that maps dimension values 1-1 to values is OK here */
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#define VF(w) 1000*w[0]+100*w[1]+10*w[2]+w[3]
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#define NVARS 6 /* number of variables */
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/*
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* Fill typed array element with specified value, that is
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*
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* v[ii] = val;
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*/
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/* type: netcdf type of v, NC_BYTE, ..., NC_DOUBLE */
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/* v: array of specified type */
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/* ii: it's v[ii] we want to store into */
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/* val: value to store */
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static void
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val_stuff(nc_type type, void *v, int ii, long val) /* v[ii] = val */
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{
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static char pname[] = "val_stuff";
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switch (type) {
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case NC_BYTE:
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case NC_CHAR:
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((char *)v)[ii] = (char) val;
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break;
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case NC_SHORT:
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((short *)v)[ii] = (short) val;
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break;
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case NC_LONG:
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((nclong *)v)[ii] = (nclong) val;
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break;
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case NC_FLOAT:
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((float *)v)[ii] = (float) val;
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break;
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case NC_DOUBLE:
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((double *)v)[ii] = (double) val;
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break;
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default:
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error("%s: bad type, test program error", pname);
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}
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}
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/*
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* Compare typed array element with specified value, that is return
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*
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* (v[ii] != val)
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*
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* returns 0 if equal, 1 if not equal
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*/
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/* type: netcdf type of v, NC_BYTE, ..., NC_DOUBLE */
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/* v: array of specified type */
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/* ii: it's v[ii] we want to compare */
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/* val: value to compare with */
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static int
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val_diff(nc_type type, void *v, int ii, long val) /* v[ii] != val */
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{
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static char pname[] = "val_diff";
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switch (type) {
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case NC_BYTE:
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case NC_CHAR:
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return (((char *)v)[ii] != (char) val);
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case NC_SHORT:
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return (((short *)v)[ii] != (short) val);
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case NC_LONG:
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return (((nclong *)v)[ii] != (nclong) val);
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case NC_FLOAT:
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return (((float *)v)[ii] != (float) val);
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case NC_DOUBLE:
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return (((double *)v)[ii] != (double) val);
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default:
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error("%s: bad type, test program error", pname);
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return (-1);
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}
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}
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/*
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* For each type of variable, put a four-dimensional hypercube of values
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* with a single call to ncvarput. Then use ncvarget to retrieve a single
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* interior value, an interior vector of values along each of the four
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* dimensions, an interior plane of values along each of the six pairs of
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* dimensions, and an interior cube of values along each of the four
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* triples of dimensions. In each case, compare the retrieved values with
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* the written values.
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*/
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int
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test_slabs(int cdfid) /* handle of netcdf open and in data mode */
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{
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int nerrs = 0;
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static char pname[] = "test_slabs";
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static struct cdfdim dims[NDIMS] = {
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{"w", WSIZE},
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{"x", XSIZE},
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{"y", YSIZE},
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{"z", ZSIZE}
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};
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int dimids[NDIMS]; /* dimension ids */
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long corner[NDIMS], edge[NDIMS], point[NDIMS];
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static struct cdfvar va[NVARS] = { /* variables of all types */
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{"bytevar", NC_BYTE, NDIMS, ___, 0},
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{"charvar", NC_CHAR, NDIMS, ___, 0},
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{"shortvar", NC_SHORT, NDIMS, ___, 0},
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{"longvar", NC_LONG, NDIMS, ___, 0},
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{"floatvar", NC_FLOAT, NDIMS, ___, 0},
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{"doublevar", NC_DOUBLE, NDIMS, ___, 0},
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};
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void *v;
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int varid[NVARS], iv; /* variable id */
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int idim, jdim, kdim, ldim;
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int iw, ix, iy, iz, ii, jj, kk;
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if (ncredef(cdfid) == -1) {
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error("%s: cdredef failed", pname);
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ncclose(cdfid); return 1;
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}
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/* back in define mode OK, now add dimensions */
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for (idim = 0; idim < NDIMS; idim++) {
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dimids[idim] = ncdimdef(cdfid, dims[idim].name, dims[idim].size);
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if (dimids[idim] == -1) {
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error("%s: ncdimdef failed", pname);
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ncclose(cdfid);
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return 1;
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}
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add_dim(&test, &dims[idim]);
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}
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/* define a multi-dimensional variable of each type */
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for (iv = 0; iv < NVARS; iv++) {
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va[iv].dims = (int *) emalloc(sizeof(int) * (size_t)va[iv].ndims);
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for (idim = 0; idim < va[iv].ndims; idim++)
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va[iv].dims[idim] = dimids[idim];
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varid[iv] = ncvardef(cdfid, va[iv].name, va[iv].type, va[iv].ndims,
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va[iv].dims);
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if (varid[iv] == -1) {
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error("%s: ncvardef failed", pname);
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ncclose(cdfid); return 1;
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}
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add_var(&test, &va[iv]); /* keep in-memory netcdf in sync */
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free(va[iv].dims);
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}
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if (ncendef (cdfid) == -1) {
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error("%s: ncendef failed", pname);
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ncclose(cdfid); return 1;
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}
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for (iv = 0; iv < NVARS; iv++) { /* test each type of variable */
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v = emalloc(WSIZE*XSIZE*YSIZE*ZSIZE * (size_t)nctypelen(va[iv].type));
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/* fill it with values using a function of dimension indices */
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ii = 0;
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for (iw=0; iw < WSIZE; iw++) {
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corner[0] = iw;
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for (ix=0; ix < XSIZE; ix++) {
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corner[1] = ix;
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for (iy=0; iy < YSIZE; iy++) {
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corner[2] = iy;
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for (iz=0; iz < ZSIZE; iz++) {
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corner[3] = iz;
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/* v[ii++] = VF(corner); */
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val_stuff(va[iv].type, v, ii, VF(corner));
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ii++;
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}
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}
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}
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}
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for (idim = 0; idim < NDIMS; idim++) {
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corner[idim] = 0;
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edge[idim] = dims[idim].size;
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}
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/* ncvarput the whole variable */
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if (ncvarput(cdfid, varid[iv], corner, edge, (void *) v) == -1) {
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error("%s: ncvarput failed", pname);
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nerrs++;
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}
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add_data(&test, varid[iv], corner, edge); /* keep test in sync */
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/*
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* For several combinations of fixed dimensions, get a slab and compare
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* values to function values.
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*/
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/* get an interior point */
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for (idim=0; idim < NDIMS; idim++) {
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corner[idim] = dims[idim].size/2;
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edge[idim] = 1;
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point[idim] = corner[idim];
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}
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if (ncvarget(cdfid, varid[iv], corner, edge, (void *) v) == -1) {
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error("%s: ncvarget of one point failed", pname);
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nerrs++;
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}
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/* if (v[0] != VF(point)) */
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if (val_diff(va[iv].type, v, 0, VF(point))) {
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error("%s: ncvarget got wrong value for point", pname);
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nerrs++;
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}
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/* get an interior vector in each direction */
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for (idim=0; idim < NDIMS; idim++) {
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for (jdim=0; jdim < NDIMS; jdim++) {
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corner[jdim] = dims[jdim].size/2;
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edge[jdim] = 1;
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point[jdim] = corner[jdim];
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}
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corner[idim] = 1; /* get vector along dimension idim */
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edge[idim] = dims[idim].size - 2;
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if (ncvarget(cdfid, varid[iv], corner, edge, (void *) v) == -1) {
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error("%s: ncvarget of vector failed", pname);
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nerrs++;
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}
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for (ii=(int)corner[idim]; ii <= edge[idim]; ii++) {
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point[idim] = ii;
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/* if (v[ii-1] != VF(point)) */
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if (val_diff(va[iv].type, v, ii-1, VF(point))) {
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error("%s: ncvarget got wrong value for vector", pname);
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nerrs++;
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}
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}
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}
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/* get an interior plane in each direction */
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for (idim=0; idim < NDIMS; idim++) {
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for (jdim=idim+1; jdim < NDIMS; jdim++) {
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for (kdim=0; kdim < NDIMS; kdim++) { /* reset corners and edges */
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corner[kdim] = dims[kdim].size/2;
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edge[kdim] = 1;
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point[kdim] = corner[kdim];
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}
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corner[idim] = 1; /* interior plane along dimensions idim jdim */
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corner[jdim] = 1;
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edge[idim] = dims[idim].size - 2;
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edge[jdim] = dims[jdim].size - 2;
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if (ncvarget(cdfid, varid[iv], corner, edge, (void *) v) == -1) {
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error("%s: ncvarget of plane failed", pname);
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nerrs++;
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}
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for (ii=(int)corner[idim]; ii <= edge[idim]; ii++) {
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for (jj=(int)corner[jdim]; jj <= edge[jdim]; jj++) {
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point[idim] = ii;
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point[jdim] = jj;
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/* if (v[(ii-1)*edge[jdim]+jj-1] != VF(point)) { */
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if (val_diff(va[iv].type, v,
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(ii-1)*(int)edge[jdim]+jj-1, VF(point))) {
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error("%s: ncvarget got wrong value in plane", pname);
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error("idim=%d,jdim=%d,ii=%d,jj=%d",
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idim,
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jdim,
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ii,
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jj);
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nerrs++;
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}
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}
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}
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}
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}
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/* get an interior cube in each direction */
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for (idim=0; idim < NDIMS; idim++) {
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for (jdim=idim+1; jdim < NDIMS; jdim++) {
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for (kdim=jdim+1; kdim < NDIMS; kdim++) {
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for (ldim=0; ldim < NDIMS; ldim++) { /* reset corners, edges */
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corner[ldim] = dims[ldim].size/2;
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edge[ldim] = 1;
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point[ldim] = corner[ldim];
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}
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corner[idim] = 1; /* intr. cube along idim jdim kdim */
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corner[jdim] = 1;
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corner[kdim] = 1;
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edge[idim] = dims[idim].size - 2;
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edge[jdim] = dims[jdim].size - 2;
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edge[kdim] = dims[kdim].size - 2;
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if (ncvarget(cdfid, varid[iv], corner, edge, (void *) v) == -1) {
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error("%s: ncvarget of cube failed", pname);
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nerrs++;
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}
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for (ii=(int)corner[idim]; ii <= edge[idim]; ii++) {
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for (jj=(int)corner[jdim]; jj <= edge[jdim]; jj++) {
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for (kk=(int)corner[kdim]; kk <= edge[kdim]; kk++) {
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point[idim] = ii;
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point[jdim] = jj;
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point[kdim] = kk;
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/* if (v[((ii-1)*edge[jdim]+jj-1)*
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edge[kdim]+kk-1] != VF(point)) { */
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if (val_diff(va[iv].type,v,
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((ii-1)*(int)edge[jdim]+jj-1)*
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(int)edge[kdim]+kk-1,VF(point))) {
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error("%s: ncvarget got wrong value in cube", pname);
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error("idim=%d,jdim=%d,kdim=%d,ii=%d,jj=%d,kk=%d",
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idim,
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jdim,
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kdim,
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ii,
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jj,
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kk);
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nerrs++;
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}
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}
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}
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}
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}
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}
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}
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free(v);
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}
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return nerrs;
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}
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