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netcdf-c/ncdump/nccopy.c
Ward Fisher e32e0b1eb2
Merge branch 'master' into filterexpr.dmh
2019-02-12 09:48:03 -07:00

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/*********************************************************************
* Copyright 2018, University Corporation for Atmospheric Research
* See netcdf/README file for copying and redistribution conditions.
* Thanks to Philippe Poilbarbe and Antonio S. Cofiño for
* compression additions.
* $Id: nccopy.c 400 2010-08-27 21:02:52Z russ $
*********************************************************************/
#include "config.h" /* for USE_NETCDF4 macro */
#include <stdlib.h>
#include <stdio.h>
#ifdef HAVE_GETOPT_H
#include <getopt.h>
#endif
#ifdef HAVE_UNISTD_H
#include <unistd.h>
#endif
#include <string.h>
#include "netcdf.h"
#include "netcdf_filter.h"
#include "nciter.h"
#include "utils.h"
#include "chunkspec.h"
#include "dimmap.h"
#include "nccomps.h"
#include "list.h"
#undef DEBUGFILTER
#ifdef _MSC_VER
#include "XGetopt.h"
#define snprintf _snprintf
int opterr;
int optind;
#endif
/* default bytes of memory we are willing to allocate for variable
* values during copy */
#define COPY_BUFFER_SIZE (5000000)
#define COPY_CHUNKCACHE_PREEMPTION (1.0f) /* for copying, can eject fully read chunks */
#define SAME_AS_INPUT (-1) /* default, if kind not specified */
#define CHUNK_THRESHOLD (8192) /* non-record variables with fewer bytes don't get chunked */
#ifndef USE_NETCDF4
#define NC_CLASSIC_MODEL 0x0100 /* Enforce classic model if netCDF-4 not available. */
#endif
/* Ascii characters requiring escaping as lead*/
#define ESCAPESD "0123456789"
#define ESCAPES " !\"#$%&'()*,:;<=>?[]\\^`{|}~"
#define DFALTUNLIMSIZE (4* 1<<20) /*4 megabytes */
#ifdef USE_NETCDF4
/* The unique id for a variable requires also the enclosing group id */
typedef struct VarID {
int grpid;
int varid;
} VarID;
#define MAX_FILTER_SPECS 64
#define MAX_FILTER_PARAMS 256
struct FilterSpec {
char* fqn;
int nofilter; /* 1=> do not apply any filters to this variable */
unsigned int filterid;
size_t nparams;
unsigned int* params;
};
static List* filterspecs = NULL;
static int suppressfilters = 0; /* 1 => do not apply any output filters unless specified */
#endif
/* table of formats for legal -k values */
static struct Kvalues {
char* name;
int kind;
} legalkinds[] = {
/* NetCDF-3 classic format (32-bit offsets) */
{"classic", NC_FORMAT_CLASSIC}, /* canonical format name */
{"nc3", NC_FORMAT_CLASSIC}, /* short format name */
{"1", NC_FORMAT_CLASSIC}, /* deprecated, use "-3" or "-k nc3" instead */
/* NetCDF-3 64-bit offset format */
{"64-bit offset", NC_FORMAT_64BIT_OFFSET}, /* canonical format name */
{"nc6", NC_FORMAT_64BIT_OFFSET}, /* short format name */
{"2", NC_FORMAT_64BIT_OFFSET}, /* deprecated, use "-6" or "-k nc6" instead */
{"64-bit-offset", NC_FORMAT_64BIT_OFFSET}, /* deprecated alias */
/* NetCDF-4 HDF5-based format */
{"netCDF-4", NC_FORMAT_NETCDF4}, /* canonical format name */
{"nc4", NC_FORMAT_NETCDF4}, /* short format name */
{"3", NC_FORMAT_NETCDF4}, /* deprecated, use "-4" or "-k nc4" instead */
{"netCDF4", NC_FORMAT_NETCDF4}, /* deprecated aliases */
{"hdf5", NC_FORMAT_NETCDF4},
{"enhanced", NC_FORMAT_NETCDF4},
/* NetCDF-4 HDF5-based format, restricted to classic data model */
{"netCDF-4 classic model", NC_FORMAT_NETCDF4_CLASSIC}, /* canonical format name */
{"nc7", NC_FORMAT_NETCDF4_CLASSIC}, /* short format name */
{"4", NC_FORMAT_NETCDF4_CLASSIC}, /* deprecated, use "-7" or -k nc7" */
{"netCDF-4-classic", NC_FORMAT_NETCDF4_CLASSIC}, /* deprecated aliases */
{"netCDF-4_classic", NC_FORMAT_NETCDF4_CLASSIC},
{"netCDF4_classic", NC_FORMAT_NETCDF4_CLASSIC},
{"hdf5-nc3", NC_FORMAT_NETCDF4_CLASSIC},
{"enhanced-nc3", NC_FORMAT_NETCDF4_CLASSIC},
/* The 64-bit data (CDF5) kind (5) */
{"5", NC_FORMAT_CDF5},
{"64-bit-data", NC_FORMAT_CDF5},
{"64-bit data", NC_FORMAT_CDF5},
{"nc5", NC_FORMAT_CDF5},
{"cdf5", NC_FORMAT_CDF5},
/* null terminate*/
{NULL,0}
};
/* Global variables for command-line requests */
char *progname; /* for error messages */
static int option_kind = SAME_AS_INPUT;
static int option_deflate_level = -1; /* default, compress output only if input compressed */
static int option_shuffle_vars = NC_NOSHUFFLE; /* default, no shuffling on compression */
static int option_fix_unlimdims = 0; /* default, preserve unlimited dimensions */
static List* option_chunkspecs = NULL; /* default, no chunk specification */
static size_t option_copy_buffer_size = COPY_BUFFER_SIZE;
static size_t option_chunk_cache_size = CHUNK_CACHE_SIZE; /* default from config.h */
static size_t option_chunk_cache_nelems = CHUNK_CACHE_NELEMS; /* default from config.h */
static int option_read_diskless = 0; /* default, don't read input into memory on open */
static int option_write_diskless = 0; /* default, don't write output to diskless file */
#ifdef USE_NETCDF4
static size_t option_min_chunk_bytes = CHUNK_THRESHOLD; /* default, don't chunk variable if prod of
* chunksizes of its dimensions is smaller
* than this */
#endif
static int option_nlgrps = 0; /* Number of groups specified with -g
* option on command line */
static char** option_lgrps = 0; /* list of group names specified with -g
* option on command line */
static idnode_t* option_grpids = 0; /* list of grpids matching list specified with -g option */
static bool_t option_grpstruct = false; /* if -g set, copy structure for non-selected groups */
static int option_nlvars = 0; /* Number of variables specified with -v * option on command line */
static char** option_lvars = 0; /* list of variable names specified with -v
* option on command line */
static bool_t option_varstruct = false; /* if -v set, copy structure for non-selected vars */
static int option_compute_chunkcaches = 0; /* default, don't try still flaky estimate of
* chunk cache for each variable */
/* get group id in output corresponding to group igrp in input,
* given parent group id (or root group id) parid in output. */
static int
get_grpid(int igrp, int parid, int *ogrpp) {
int stat = NC_NOERR;
int ogid = parid; /* like igrp but in output file */
#ifdef USE_NETCDF4
int inparid;
/* if not root group, get corresponding output groupid from group name */
stat = nc_inq_grp_parent(igrp, &inparid);
if(stat == NC_NOERR) { /* not root group */
char grpname[NC_MAX_NAME + 1];
NC_CHECK(nc_inq_grpname(igrp, grpname));
NC_CHECK(nc_inq_grp_ncid(parid, grpname, &ogid));
} else if(stat == NC_ENOGRP) { /* root group */
stat = NC_NOERR;
} else {
NC_CHECK(stat);
}
#endif /* USE_NETCDF4 */
*ogrpp = ogid;
return stat;
}
/* Return size in bytes of a variable value */
static size_t
val_size(int grpid, int varid) {
nc_type vartype;
size_t value_size;
NC_CHECK(nc_inq_vartype(grpid, varid, &vartype));
NC_CHECK(nc_inq_type(grpid, vartype, NULL, &value_size));
return value_size;
}
#ifdef USE_NETCDF4
/* Get parent id needed to define a new group from its full name in an
* open file identified by ncid. Assumes all intermediate groups are
* already defined. */
static int
nc_inq_parid(int ncid, const char *fullname, int *locidp) {
char *parent = strdup(fullname);
char *slash = "/"; /* groupname separator */
char *last_slash;
if(parent == NULL) {
return NC_ENOMEM; /* exits */
}
last_slash = strrchr(parent, '/');
if(last_slash == parent || last_slash == NULL) { /* parent is root */
free(parent);
parent = strdup(slash);
} else {
*last_slash = '\0'; /* truncate to get parent name */
}
NC_CHECK(nc_inq_grp_full_ncid(ncid, parent, locidp));
free(parent);
return NC_NOERR;
}
/* Compute the fully qualified name of a (grpid,varid) pair; caller must free */
static int
computeFQN(VarID vid, char** fqnp)
{
int stat = NC_NOERR;
size_t len;
char* fqn = NULL;
char vname[NC_MAX_NAME+1];
char escname[(2*NC_MAX_NAME)+1];
int first;
char *p, *q;
if((stat = nc_inq_grpname_full(vid.grpid,&len,NULL))) goto done;
fqn = (char*)malloc(len+1+(2*NC_MAX_NAME)+1);
if(fqn == NULL) {stat = NC_ENOMEM; goto done;}
if((stat=nc_inq_grpname_full(vid.grpid,&len,fqn))) goto done;
fqn[len] = '\0'; /* guarantee */
if((stat=nc_inq_varname(vid.grpid,vid.varid,vname))) goto done;
vname[NC_MAX_NAME] = '\0';
if(strlen(fqn) > 1) strcat(fqn,"/");
p = vname;
q = escname;
for(first=1;*p;first=0) {
if((first && strchr(ESCAPESD,*p) != NULL)
|| strchr(ESCAPES,*p) != NULL) *q++ = '\\';
*q++ = *p++;
}
*q++ = '\0'; /* guarantee */
strcat(fqn,escname);
done:
if(stat == NC_NOERR && fqnp != NULL) *fqnp = fqn;
return stat;
}
static int
parsevarlist(char* vars, List* vlist)
{
int stat = NC_NOERR;
char* q = NULL;
int nvars = 0;
/* Special case 1: empty set of vars */
if(vars == NULL || strlen(vars)==0) {stat = NC_EINVAL; goto done;}
/* Special case 2: "*" */
if(strcmp(vars,"*")==0) {
listpush(vlist,strdup("*"));
goto done;
}
/* Walk delimitng on '|' separators */
for(q=vars;*q;q++) {
if(*q == '\\') q++;
else if(*q == '|') {*q = '\0'; nvars++;}
/* else continue */
}
nvars++; /*for last var*/
/* Rewalk to capture the variables */
for(q=vars;nvars > 0; nvars--) {
listpush(vlist,strdup(q));
q += (strlen(q)+1); /* move to next */
}
done:
return stat;
}
static int
parsefilterspec(const char* optarg0, List* speclist)
{
int stat = NC_NOERR;
char* optarg = NULL;
unsigned int* params = NULL;
size_t nparams;
unsigned int id;
char* p = NULL;
char* remainder = NULL;
List* vlist = NULL;
int i;
int isnone = 0;
if(optarg0 == NULL || strlen(optarg0) == 0 || speclist == NULL) return 0;
optarg = strdup(optarg0);
/* Delimit the initial set of variables, taking escapes into account */
p = optarg;
remainder = NULL;
for(;;p++) {
if(*p == '\0') {remainder = p; break;}
else if(*p == ',') {*p = '\0'; remainder = p+1; break;}
else if(*p == '\\') p++;
/* else continue */
}
/* Parse the variable list */
if((vlist = listnew()) == NULL) {stat = NC_ENOMEM; goto done;}
if((stat=parsevarlist(optarg,vlist))) goto done;
if(strcasecmp(remainder,"none") != 0) {
/* Collect the id+parameters */
if((stat=NC_parsefilterspec(remainder,&id,&nparams,&params))) goto done;
} else
isnone = 1;
/* Construct a spec entry for each element in vlist */
for(i=0;i<listlength(vlist);i++) {
size_t vlen;
struct FilterSpec* spec = NULL;
const char* var = listget(vlist,i);
if(var == NULL || strlen(var) == 0) continue;
if((spec = calloc(1,sizeof(struct FilterSpec)))==NULL)
{stat = NC_ENOMEM; goto done;}
vlen = strlen(var);
spec->fqn = malloc(vlen+1+1); /* make room for nul and possible prefix '/' */
if(spec->fqn == NULL) {stat = NC_ENOMEM; goto done;}
spec->fqn[0] = '\0'; /* for strlcat */
if(strcmp(var,"*") != 0 && var[0] != '/') strlcat(spec->fqn,"/",vlen+2);
strlcat(spec->fqn,var,vlen+2);
if(isnone)
spec->nofilter = 1;
else {
spec->filterid = id;
spec->nparams = nparams;
/* Duplicate the params */
spec->params = malloc(nparams*sizeof(unsigned int));
if(spec->params == NULL) {stat = NC_ENOMEM; goto done;}
memcpy(spec->params,params,nparams*sizeof(unsigned int));
}
listpush(speclist,spec);
spec = NULL;
}
done:
if(params) free(params);
if(vlist) listfreeall(vlist);
if(optarg) free(optarg);
return stat;
}
/* Return size of chunk in bytes for a variable varid in a group igrp, or 0 if
* layout is contiguous */
static int
inq_var_chunksize(int igrp, int varid, size_t* chunksizep) {
int stat = NC_NOERR;
int ndims;
size_t *chunksizes;
int dim;
int contig = 1;
nc_type vartype;
size_t value_size;
size_t prod;
NC_CHECK(nc_inq_vartype(igrp, varid, &vartype));
/* from type, get size in memory needed for each value */
NC_CHECK(nc_inq_type(igrp, vartype, NULL, &value_size));
prod = value_size;
NC_CHECK(nc_inq_varndims(igrp, varid, &ndims));
chunksizes = (size_t *) emalloc((ndims + 1) * sizeof(size_t));
if(ndims > 0) {
NC_CHECK(nc_inq_var_chunking(igrp, varid, &contig, NULL));
}
if(contig == 1) {
*chunksizep = 0;
} else {
NC_CHECK(nc_inq_var_chunking(igrp, varid, &contig, chunksizes));
for(dim = 0; dim < ndims; dim++) {
prod *= chunksizes[dim];
}
*chunksizep = prod;
}
free(chunksizes);
return stat;
}
/* Return estimated number of elems required in chunk cache and
* estimated size of chunk cache adequate to efficiently copy input
* variable ivarid to output variable ovarid, which may have different
* chunk size and shape */
static int
inq_var_chunking_params(int igrp, int ivarid, int ogrp, int ovarid,
size_t* chunkcache_sizep,
size_t *chunkcache_nelemsp,
float * chunkcache_preemptionp)
{
int stat = NC_NOERR;
int ndims;
size_t *ichunksizes, *ochunksizes;
int dim;
int icontig = 1, ocontig = 1;
nc_type vartype;
size_t value_size;
size_t prod, iprod, oprod;
size_t nelems;
*chunkcache_nelemsp = CHUNK_CACHE_NELEMS;
*chunkcache_sizep = CHUNK_CACHE_SIZE;
*chunkcache_preemptionp = COPY_CHUNKCACHE_PREEMPTION;
NC_CHECK(nc_inq_varndims(igrp, ivarid, &ndims));
if(ndims > 0) {
NC_CHECK(nc_inq_var_chunking(igrp, ivarid, &icontig, NULL));
NC_CHECK(nc_inq_var_chunking(ogrp, ovarid, &ocontig, NULL));
}
if(icontig == 1 && ocontig == 1) { /* no chunking in input or output */
*chunkcache_nelemsp = 0;
*chunkcache_sizep = 0;
*chunkcache_preemptionp = 0;
return stat;
}
NC_CHECK(nc_inq_vartype(igrp, ivarid, &vartype));
NC_CHECK(nc_inq_type(igrp, vartype, NULL, &value_size));
iprod = value_size;
if(icontig == 0 && ocontig == 1) { /* chunking only in input */
*chunkcache_nelemsp = 1; /* read one input chunk at a time */
*chunkcache_sizep = iprod;
*chunkcache_preemptionp = 1.0f;
return stat;
}
ichunksizes = (size_t *) emalloc((ndims + 1) * sizeof(size_t));
if(icontig == 1) { /* if input contiguous, treat as if chunked on
* first dimension */
ichunksizes[0] = 1;
for(dim = 1; dim < ndims; dim++) {
ichunksizes[dim] = dim;
}
} else {
NC_CHECK(nc_inq_var_chunking(igrp, ivarid, &icontig, ichunksizes));
}
/* now can assume chunking in both input and output */
ochunksizes = (size_t *) emalloc((ndims + 1) * sizeof(size_t));
NC_CHECK(nc_inq_var_chunking(ogrp, ovarid, &ocontig, ochunksizes));
nelems = 1;
oprod = value_size;
for(dim = 0; dim < ndims; dim++) {
nelems += 1 + (ichunksizes[dim] - 1) / ochunksizes[dim];
iprod *= ichunksizes[dim];
oprod *= ochunksizes[dim];
}
prod = iprod + oprod * (nelems - 1);
*chunkcache_nelemsp = nelems;
*chunkcache_sizep = prod;
free(ichunksizes);
free(ochunksizes);
return stat;
}
/* Forward declaration, because copy_type, copy_vlen_type call each other */
static int copy_type(int igrp, nc_type typeid, int ogrp);
/*
* copy a user-defined variable length type in the group igrp to the
* group ogrp
*/
static int
copy_vlen_type(int igrp, nc_type itype, int ogrp)
{
int stat = NC_NOERR;
nc_type ibasetype;
nc_type obasetype; /* base type in target group */
char name[NC_MAX_NAME];
size_t size;
char basename[NC_MAX_NAME];
size_t basesize;
nc_type vlen_type;
NC_CHECK(nc_inq_vlen(igrp, itype, name, &size, &ibasetype));
/* to get base type id in target group, use name of base type in
* source group */
NC_CHECK(nc_inq_type(igrp, ibasetype, basename, &basesize));
stat = nc_inq_typeid(ogrp, basename, &obasetype);
/* if no such type, create it now */
if(stat == NC_EBADTYPE) {
NC_CHECK(copy_type(igrp, ibasetype, ogrp));
stat = nc_inq_typeid(ogrp, basename, &obasetype);
}
NC_CHECK(stat);
/* Now we know base type exists in output and we know its type id */
NC_CHECK(nc_def_vlen(ogrp, name, obasetype, &vlen_type));
return stat;
}
/*
* copy a user-defined opaque type in the group igrp to the group ogrp
*/
static int
copy_opaque_type(int igrp, nc_type itype, int ogrp)
{
int stat = NC_NOERR;
nc_type otype;
char name[NC_MAX_NAME];
size_t size;
NC_CHECK(nc_inq_opaque(igrp, itype, name, &size));
NC_CHECK(nc_def_opaque(ogrp, size, name, &otype));
return stat;
}
/*
* copy a user-defined enum type in the group igrp to the group ogrp
*/
static int
copy_enum_type(int igrp, nc_type itype, int ogrp)
{
int stat = NC_NOERR;
nc_type otype;
nc_type basetype;
size_t basesize;
size_t nmembers;
char name[NC_MAX_NAME];
int i;
NC_CHECK(nc_inq_enum(igrp, itype, name, &basetype, &basesize, &nmembers));
NC_CHECK(nc_def_enum(ogrp, basetype, name, &otype));
for(i = 0; i < nmembers; i++) { /* insert enum members */
char ename[NC_MAX_NAME];
long long val; /* large enough to hold any integer type */
NC_CHECK(nc_inq_enum_member(igrp, itype, i, ename, &val));
NC_CHECK(nc_insert_enum(ogrp, otype, ename, &val));
}
return stat;
}
/*
* copy a user-defined compound type in the group igrp to the group ogrp
*/
static int
copy_compound_type(int igrp, nc_type itype, int ogrp)
{
int stat = NC_NOERR;
char name[NC_MAX_NAME];
size_t size;
size_t nfields;
nc_type otype;
int fid;
NC_CHECK(nc_inq_compound(igrp, itype, name, &size, &nfields));
NC_CHECK(nc_def_compound(ogrp, size, name, &otype));
for (fid = 0; fid < nfields; fid++) {
char fname[NC_MAX_NAME];
char ftypename[NC_MAX_NAME];
size_t foff;
nc_type iftype, oftype;
int fndims;
NC_CHECK(nc_inq_compound_field(igrp, itype, fid, fname, &foff, &iftype, &fndims, NULL));
/* type ids in source don't necessarily correspond to same
* typeids in destination, so look up destination typeid by using
* field type name */
NC_CHECK(nc_inq_type(igrp, iftype, ftypename, NULL));
NC_CHECK(nc_inq_typeid(ogrp, ftypename, &oftype));
if(fndims == 0) {
NC_CHECK(nc_insert_compound(ogrp, otype, fname, foff, oftype));
} else { /* field is array type */
int *fdimsizes;
fdimsizes = (int *) emalloc((fndims + 1) * sizeof(int));
stat = nc_inq_compound_field(igrp, itype, fid, NULL, NULL, NULL,
NULL, fdimsizes);
NC_CHECK(nc_insert_array_compound(ogrp, otype, fname, foff, oftype, fndims, fdimsizes));
free(fdimsizes);
}
}
return stat;
}
/*
* copy a user-defined type in the group igrp to the group ogrp
*/
static int
copy_type(int igrp, nc_type typeid, int ogrp)
{
int stat = NC_NOERR;
nc_type type_class;
NC_CHECK(nc_inq_user_type(igrp, typeid, NULL, NULL, NULL, NULL, &type_class));
switch(type_class) {
case NC_VLEN:
NC_CHECK(copy_vlen_type(igrp, typeid, ogrp));
break;
case NC_OPAQUE:
NC_CHECK(copy_opaque_type(igrp, typeid, ogrp));
break;
case NC_ENUM:
NC_CHECK(copy_enum_type(igrp, typeid, ogrp));
break;
case NC_COMPOUND:
NC_CHECK(copy_compound_type(igrp, typeid, ogrp));
break;
default:
NC_CHECK(NC_EBADTYPE);
}
return stat;
}
/* Copy a group and all its subgroups, recursively, from iroot to
* oroot, the ncids of input file and output file. This just creates
* all the groups in the destination, but doesn't copy anything that's
* in the groups yet. */
static int
copy_groups(int iroot, int oroot)
{
int stat = NC_NOERR;
int numgrps;
int *grpids;
int i;
/* get total number of groups and their ids, including all descendants */
NC_CHECK(nc_inq_grps_full(iroot, &numgrps, NULL));
if(numgrps > 1) { /* there's always 1 root group */
grpids = emalloc(numgrps * sizeof(int));
NC_CHECK(nc_inq_grps_full(iroot, NULL, grpids));
/* create corresponding new groups in ogrp, except for root group */
for(i = 1; i < numgrps; i++) {
char *grpname_full;
char grpname[NC_MAX_NAME];
size_t len_name;
int ogid = 0, oparid = 0, iparid = 0;
/* get full group name of input group */
NC_CHECK(nc_inq_grpname(grpids[i], grpname));
if (option_grpstruct || group_wanted(grpids[i], option_nlgrps, option_grpids)) {
NC_CHECK(nc_inq_grpname_full(grpids[i], &len_name, NULL));
grpname_full = emalloc(len_name + 1);
NC_CHECK(nc_inq_grpname_full(grpids[i], &len_name, grpname_full));
/* Make sure, the parent group is also wanted (root group is always wanted) */
NC_CHECK(nc_inq_parid(iroot, grpname_full, &iparid));
if (!option_grpstruct && !group_wanted(iparid, option_nlgrps, option_grpids)
&& iparid != iroot) {
error("ERROR: trying to copy a group but not the parent: %s", grpname_full);
}
/* get id of parent group of corresponding group in output.
* Note that this exists, because nc_inq_groups returned
* grpids in preorder, so parents are always copied before
* their subgroups */
NC_CHECK(nc_inq_parid(oroot, grpname_full, &oparid));
NC_CHECK(nc_inq_grpname(grpids[i], grpname));
/* define corresponding group in output */
NC_CHECK(nc_def_grp(oparid, grpname, &ogid));
free(grpname_full);
}
}
free(grpids);
}
return stat;
}
/*
* Copy the user-defined types in this group (igrp) and all its
* subgroups, recursively, to corresponding group in output (ogrp)
*/
static int
copy_types(int igrp, int ogrp)
{
int stat = NC_NOERR;
int ntypes;
nc_type *types = NULL;
int numgrps;
int *grpids = NULL;
int i;
NC_CHECK(nc_inq_typeids(igrp, &ntypes, NULL));
if(ntypes > 0) {
types = (nc_type *) emalloc(ntypes * sizeof(nc_type));
NC_CHECK(nc_inq_typeids(igrp, &ntypes, types));
for (i = 0; i < ntypes; i++) {
NC_CHECK(copy_type(igrp, types[i], ogrp));
}
free(types);
}
/* Copy types from subgroups */
NC_CHECK(nc_inq_grps(igrp, &numgrps, NULL));
if(numgrps > 0) {
grpids = (int *)emalloc(sizeof(int) * numgrps);
NC_CHECK(nc_inq_grps(igrp, &numgrps, grpids));
for(i = 0; i < numgrps; i++) {
if (option_grpstruct || group_wanted(grpids[i], option_nlgrps, option_grpids)) {
int ogid;
/* get groupid in output corresponding to grpids[i] in
* input, given parent group (or root group) ogrp in
* output */
NC_CHECK(get_grpid(grpids[i], ogrp, &ogid));
NC_CHECK(copy_types(grpids[i], ogid));
}
}
free(grpids);
}
return stat;
}
/* Copy netCDF-4 specific variable filter properties */
/* Watch out if input is netcdf-3 */
static int
copy_var_filter(int igrp, int varid, int ogrp, int o_varid, int inkind, int outkind)
{
int stat = NC_NOERR;
VarID vid = {igrp,varid};
VarID ovid = {ogrp,o_varid};
/* handle filter parameters, copying from input, overriding with command-line options */
struct FilterSpec* ospec = NULL;
struct FilterSpec inspec;
struct FilterSpec nospec;
struct FilterSpec* actualspec = NULL;
int i;
char* ofqn = NULL;
int inputdefined, outputdefined, unfiltered;
int innc4 = (inkind == NC_FORMAT_NETCDF4 || inkind == NC_FORMAT_NETCDF4_CLASSIC);
int outnc4 = (outkind == NC_FORMAT_NETCDF4 || outkind == NC_FORMAT_NETCDF4_CLASSIC);
if(!outnc4)
goto done; /* Can only use filter when output is some netcdf4 variant */
/* Compute the output vid's FQN */
if((stat = computeFQN(ovid,&ofqn))) goto done;
/* Clear the in and out specs */
memset(&inspec,0,sizeof(inspec));
memset(&nospec,0,sizeof(nospec));
nospec.nofilter = 1;
actualspec = NULL;
ospec = NULL;
/* Is there a filter on the output variable */
outputdefined = 0; /* default is no filter defined */
/* Only bother to look if output is netcdf-4 variant */
if(outnc4) {
/* See if any output filter spec is defined for this output variable */
for(i=0;i<listlength(filterspecs);i++) {
struct FilterSpec* spec = listget(filterspecs,i);
if(strcmp(spec->fqn,"*")==0 || strcmp(spec->fqn,ofqn)==0) {
ospec = spec;
outputdefined = 1;
break;
}
}
}
/* Is there a filter on the input variable */
inputdefined = 0; /* default is no filter defined */
/* Only bother to look if input is netcdf-4 variant */
if(innc4) {
stat=nc_inq_var_filter(vid.grpid,vid.varid,&inspec.filterid,&inspec.nparams,NULL);
if(stat && stat != NC_EFILTER)
goto done; /* true error */
if(stat == NC_NOERR) {/* input has a filter */
inspec.params = (unsigned int*)malloc(sizeof(unsigned int)*inspec.nparams);
if((stat=nc_inq_var_filter(vid.grpid,vid.varid,&inspec.filterid,&inspec.nparams,inspec.params)))
goto done;
inputdefined = 1;
}
}
/* Rules for choosing output filter are as follows:
global output input Actual Output
suppress filter filter filter
-----------------------------------------------
true undefined NA unfiltered
true 'none' NA unfiltered
true defined NA use output filter
false undefined defined use input filter
false 'none' NA unfiltered
false defined NA use output filter
false undefined undefined unfiltered
*/
unfiltered = 0;
if(suppressfilters && !outputdefined) /* row 1 */
unfiltered = 1;
else if(suppressfilters && outputdefined && ospec->nofilter) /* row 2 */
unfiltered = 1;
else if(suppressfilters && outputdefined) /* row 3 */
actualspec = ospec;
else if(!suppressfilters && !outputdefined && inputdefined) /* row 4 */
actualspec = &inspec;
else if(!suppressfilters && outputdefined && ospec->nofilter) /* row 5 */
unfiltered = 1;
else if(!suppressfilters && outputdefined) /* row 6 */
actualspec = ospec;
else if(!suppressfilters && !outputdefined && !inputdefined) /* row 7 */
actualspec = &nospec;
/* Apply actual filter spec if any */
if(!unfiltered) {
if((stat=nc_def_var_filter(ovid.grpid,ovid.varid,
actualspec->filterid,
actualspec->nparams,
actualspec->params)))
goto done;
}
done:
/* Cleanup */
if(ofqn != NULL) free(ofqn);
if(inspec.fqn) free(inspec.fqn);
if(inspec.params) free(inspec.params);
/* Note we do not clean actualspec because it is a copy of in|out spec */
return stat;
}
/* Propagate chunking from input to output taking -c flags into account. */
/* Subsumes old set_var_chunked */
static int
copy_chunking(int igrp, int i_varid, int ogrp, int o_varid, int ndims, int inkind, int outkind)
{
int stat = NC_NOERR;
int innc4 = (inkind == NC_FORMAT_NETCDF4 || inkind == NC_FORMAT_NETCDF4_CLASSIC);
int outnc4 = (outkind == NC_FORMAT_NETCDF4 || outkind == NC_FORMAT_NETCDF4_CLASSIC);
/* First, check the file kinds */
if(!outnc4)
return stat; /* no chunking */
/* See if a scalar */
if(ndims == 0)
return stat; /* scalars cannot be chunked */
/* If var specific chunking was specified for this output variable
then it overrides all else.
*/
/* Note, using goto done instead of nested if-then-else */
if(varchunkspec_exists(igrp,i_varid)) {
if(varchunkspec_omit(igrp,i_varid)) {
NC_CHECK(nc_def_var_chunking(ogrp, o_varid, NC_CONTIGUOUS, NULL));
} else {
size_t* ochunkp = varchunkspec_chunksizes(igrp,i_varid);
NC_CHECK(nc_def_var_chunking(ogrp, o_varid, NC_CHUNKED, ochunkp));
}
goto done;
}
{ /* Try dim-specific chunking */
int idim;
/* size of a chunk: product of dimension chunksizes and size of value */
size_t csprod;
int is_unlimited = 0;
size_t typesize;
size_t ichunkp[NC_MAX_VAR_DIMS];
size_t ochunkp[NC_MAX_VAR_DIMS];
int dimids[NC_MAX_VAR_DIMS];
int icontig = 1;
int ocontig = 1; /* until proven otherwise */
/* See if chunking was suppressed */
if(dimchunkspec_omit())
goto done; /* do nothing */
/* Setup for chunking */
typesize = val_size(ogrp, o_varid);
csprod = typesize;
memset(&dimids,0,sizeof(dimids));
memset(&ichunkp,0,sizeof(ichunkp));
memset(&ochunkp,0,sizeof(ochunkp));
/* Get the chunking, if any, on the current input variable */
NC_CHECK(nc_inq_var_chunking(igrp, i_varid, &icontig, ichunkp));
if(!icontig)
ocontig = 0; /* If input is chunked, then so is output */
/* Prepare to iterate over the dimids of this input variable */
NC_CHECK(nc_inq_vardimid(igrp, i_varid, dimids));
/* Assign chunk sizes for all dimensions of variable;
even if we decide to not chunk */
for(idim = 0; idim < ndims; idim++) {
int idimid = dimids[idim];
int odimid = dimmap_odimid(idimid);
size_t chunksize;
size_t dimlen;
/* Get input dimension length */
NC_CHECK(nc_inq_dimlen(igrp, idimid, &dimlen));
/* Check for unlimited */
if(dimmap_ounlim(odimid)) {
is_unlimited = 1;
ocontig = 0; /* force chunking */
}
/* If the -c set a chunk size for this dimension, use it */
chunksize = dimchunkspec_size(idimid);
if(chunksize > 0) { /* found in chunkspec */
ochunkp[idim] = chunksize;
ocontig = 0; /* cannot use contiguous */
goto next;
}
/* Not specified in -c; Apply defaulting rules as defined in nccopy.1 */
/* If input is chunked, then use that chunk size */
if(!icontig) {
ochunkp[idim] = ichunkp[idim];
ocontig = 0;
goto next;
}
/* If input is netcdf-4 then use the input size as the chunk size;
but do not force chunking.
*/
if(!innc4) {
ochunkp[idim] = dimlen;
goto next;
}
/* Default for unlimited is max(4 megabytes, current dim size) */
if(is_unlimited) {
size_t mb4dimsize = DFALTUNLIMSIZE / typesize;
ochunkp[idim] = (dimlen > mb4dimsize ? mb4dimsize : dimlen);
} else {
/* final default is the current dimension size */
ochunkp[idim] = dimlen;
}
next:
/* compute on-going dimension product */
csprod *= ochunkp[idim];
}
/* Finally, if total chunksize is too small (and dim is not unlimited) => do not chunk */
if(csprod < option_min_chunk_bytes && !is_unlimited) {
ocontig = 1; /* Force contiguous */
}
/* Apply the chunking, if any */
if(ocontig) { /* We can use contiguous output */
NC_CHECK(nc_def_var_chunking(ogrp, o_varid, NC_CONTIGUOUS, NULL));
} else {
NC_CHECK(nc_def_var_chunking(ogrp, o_varid, NC_CHUNKED, ochunkp));
}
}
done:
return stat;
}
/* Copy all netCDF-4 specific variable properties such as chunking,
* endianness, deflation, checksumming, fill, etc. */
static int
copy_var_specials(int igrp, int varid, int ogrp, int o_varid, int inkind, int outkind)
{
int stat = NC_NOERR;
int innc4 = (inkind == NC_FORMAT_NETCDF4 || inkind == NC_FORMAT_NETCDF4_CLASSIC);
int outnc4 = (outkind == NC_FORMAT_NETCDF4 || outkind == NC_FORMAT_NETCDF4_CLASSIC);
int deflated = 0; /* true iff deflation is applied */
if(!outnc4)
return stat; /* Ignore non-netcdf4 files */
{ /* handle chunking parameters */
int ndims;
NC_CHECK(nc_inq_varndims(igrp, varid, &ndims));
if (ndims > 0) { /* no chunking for scalar variables */
NC_CHECK(copy_chunking(igrp, varid, ogrp, o_varid, ndims, inkind, outkind));
}
}
{ /* handle compression parameters, copying from input, overriding
* with command-line options */
int shuffle_in=0, deflate_in=0, deflate_level_in=0;
int shuffle_out=0, deflate_out=0, deflate_level_out=0;
if(innc4) { /* See if the input variable has deflation applied */
NC_CHECK(nc_inq_var_deflate(igrp, varid, &shuffle_in, &deflate_in, &deflate_level_in));
}
if(option_deflate_level == -1) {
/* not specified by -d flag, copy input compression and shuffling */
shuffle_out = shuffle_in;
deflate_out = deflate_in;
deflate_level_out = deflate_level_in;
} else if(option_deflate_level > 0) { /* change to specified compression, shuffling */
shuffle_out = option_shuffle_vars;
deflate_out=1;
deflate_level_out = option_deflate_level;
} else if(option_deflate_level == 0) { /* special case; force off */
shuffle_out = 0;
deflate_out = 0;
deflate_level_out = 0;
}
/* Apply output deflation */
if(outnc4) {
/* Note that if we invoke this function and even if shuffle and deflate flags are 0,
then default chunking will be turned on; so do a special check for that. */
if(shuffle_out != 0 || deflate_out != 0)
NC_CHECK(nc_def_var_deflate(ogrp, o_varid, shuffle_out, deflate_out, deflate_level_out));
deflated = deflate_out;
}
}
if(innc4 && outnc4)
{ /* handle checksum parameters */
int fletcher32 = 0;
NC_CHECK(nc_inq_var_fletcher32(igrp, varid, &fletcher32));
if(fletcher32 != 0) {
NC_CHECK(nc_def_var_fletcher32(ogrp, o_varid, fletcher32));
}
}
if(innc4 && outnc4)
{ /* handle endianness */
int endianness = 0;
NC_CHECK(nc_inq_var_endian(igrp, varid, &endianness));
if(endianness != NC_ENDIAN_NATIVE) { /* native is the default */
NC_CHECK(nc_def_var_endian(ogrp, o_varid, endianness));
}
}
if(!deflated) {
/* handle other general filters */
NC_CHECK(copy_var_filter(igrp, varid, ogrp, o_varid, inkind, outkind));
}
return stat;
}
#if 0
Subsumed into copy_chunking.
/* Set output variable o_varid (in group ogrp) to use chunking
* specified on command line, only called for classic format input and
* netCDF-4 format output, so no existing chunk lengths to override. */
static int
set_var_chunked(int ogrp, int o_varid)
{
int stat = NC_NOERR;
int ndims;
int odim;
size_t chunk_threshold = CHUNK_THRESHOLD;
if(dimchunkspec_ndims() == 0) /* no chunking specified on command line */
return stat;
NC_CHECK(nc_inq_varndims(ogrp, o_varid, &ndims));
if (ndims > 0) { /* no chunking for scalar variables */
int chunked = 0;
int *dimids = (int *) emalloc(ndims * sizeof(int));
size_t varsize;
nc_type vartype;
size_t value_size;
int is_unlimited = 0;
NC_CHECK(nc_inq_vardimid (ogrp, o_varid, dimids));
NC_CHECK(nc_inq_vartype(ogrp, o_varid, &vartype));
/* from type, get size in memory needed for each value */
NC_CHECK(nc_inq_type(ogrp, vartype, NULL, &value_size));
varsize = value_size;
/* Determine if this variable should be chunked. A variable
* should be chunked if any of its dims are in command-line
* chunk spec. It will also be chunked if any of its
* dims are unlimited. */
for(odim = 0; odim < ndims; odim++) {
int odimid = dimids[odim];
int idimid = dimmap_idimid(odimid); /* corresponding dimid in input file */
if(dimmap_ounlim(odimid))
is_unlimited = 1; /* whether vriable is unlimited */
if(idimid != -1) {
size_t chunksize = dimchunkspec_size(idimid); /* from chunkspec */
size_t dimlen;
NC_CHECK(nc_inq_dimlen(ogrp, odimid, &dimlen));
if( (chunksize > 0) || dimmap_ounlim(odimid)) {
chunked = 1;
}
if(dimlen > 0) { /* dimlen for unlimited dims is still 0 before copying data */
varsize *= dimlen;
}
}
}
/* Don't chunk small variables that don't use an unlimited
* dimension. */
if(varsize < chunk_threshold && !is_unlimited)
chunked = 0;
if(chunked) {
/* Allocate chunksizes and set defaults to dimsize for any
* dimensions not mentioned in chunkspec, except use 1 for unlimited dims. */
size_t *chunkp = (size_t *) emalloc(ndims * sizeof(size_t));
for(odim = 0; odim < ndims; odim++) {
int odimid = dimids[odim];
int idimid = dimmap_idimid(odimid);
size_t chunksize = dimchunkspec_size(idimid);
if(chunksize > 0) {
chunkp[odim] = chunksize;
} else {
if(dimmap_ounlim(odimid)){
chunkp[odim] = 1;
} else {
NC_CHECK(nc_inq_dimlen(ogrp, odimid, &chunkp[odim]));
}
}
}
NC_CHECK(nc_def_var_chunking(ogrp, o_varid, NC_CHUNKED, chunkp));
free(chunkp);
}
free(dimids);
}
return stat;
}
#endif
#if 0
/* Set variable to compression specified on command line */
static int
set_var_compressed(int ogrp, int o_varid)
{
int stat = NC_NOERR;
if (option_deflate_level > 0) {
int deflate = 1;
NC_CHECK(nc_def_var_deflate(ogrp, o_varid, option_shuffle_vars, deflate, option_deflate_level));
}
return stat;
}
#endif
/* Release the variable chunk cache allocated for variable varid in
* group grp. This is not necessary, but will save some memory when
* processing one variable at a time. */
#ifdef UNUSED
static int
free_var_chunk_cache(int grp, int varid)
{
int stat = NC_NOERR;
size_t chunk_cache_size = 1;
size_t cache_nelems = 1;
float cache_preemp = 0;
int kind;
NC_CHECK(nc_inq_format(grp, &kind));
if(kind == NC_FORMAT_NETCDF4 || kind == NC_FORMAT_NETCDF4_CLASSIC) {
int contig = 1;
NC_CHECK(nc_inq_var_chunking(grp, varid, &contig, NULL));
if(contig == 0) { /* chunked */
NC_CHECK(nc_set_var_chunk_cache(grp, varid, chunk_cache_size, cache_nelems, cache_preemp));
}
}
return stat;
}
#endif
#endif /* USE_NETCDF4 */
/* Copy dimensions from group igrp to group ogrp, also associate input
* dimids with output dimids (they need not match, because the input
* dimensions may have been defined in a different order than we define
* the output dimensions here. */
static int
copy_dims(int igrp, int ogrp)
{
int stat = NC_NOERR;
int ndims;
int dgrp;
#ifdef USE_NETCDF4
int nunlims;
int *dimids;
int *unlimids;
#else
int unlimid;
#endif /* USE_NETCDF4 */
NC_CHECK(nc_inq_ndims(igrp, &ndims));
#ifdef USE_NETCDF4
/* In netCDF-4 files, dimids may not be sequential because they
* may be defined in various groups, and we are only looking at one
* group at a time. */
/* Find the dimension ids in this group, don't include parents. */
dimids = (int *) emalloc((ndims + 1) * sizeof(int));
NC_CHECK(nc_inq_dimids(igrp, NULL, dimids, 0));
/* Find the number of unlimited dimensions and get their IDs */
NC_CHECK(nc_inq_unlimdims(igrp, &nunlims, NULL));
unlimids = (int *) emalloc((nunlims + 1) * sizeof(int));
NC_CHECK(nc_inq_unlimdims(igrp, NULL, unlimids));
#else
NC_CHECK(nc_inq_unlimdim(igrp, &unlimid));
#endif /* USE_NETCDF4 */
/* Copy each dimension to output, including unlimited dimension(s) */
for (dgrp = 0; dgrp < ndims; dgrp++) {
char name[NC_MAX_NAME];
size_t length;
int i_is_unlim;
int o_is_unlim;
int idimid, odimid;
#ifdef USE_NETCDF4
int uld;
#endif
i_is_unlim = 0;
#ifdef USE_NETCDF4
idimid = dimids[dgrp];
for (uld = 0; uld < nunlims; uld++) {
if(idimid == unlimids[uld]) {
i_is_unlim = 1;
break;
}
}
#else
idimid = dgrp;
if(unlimid != -1 && (idimid == unlimid)) {
i_is_unlim = 1;
}
#endif /* USE_NETCDF4 */
stat = nc_inq_dim(igrp, idimid, name, &length);
if (stat == NC_EDIMSIZE && sizeof(size_t) < 8) {
error("dimension \"%s\" requires 64-bit platform", name);
}
NC_CHECK(stat);
o_is_unlim = i_is_unlim;
if(i_is_unlim && !option_fix_unlimdims) {
NC_CHECK(nc_def_dim(ogrp, name, NC_UNLIMITED, &odimid));
} else {
NC_CHECK(nc_def_dim(ogrp, name, length, &odimid));
o_is_unlim = 0;
}
/* Store (idimid, odimid) mapping for later use, also whether unlimited */
dimmap_store(idimid, odimid, i_is_unlim, o_is_unlim);
}
#ifdef USE_NETCDF4
free(dimids);
free(unlimids);
#endif /* USE_NETCDF4 */
return stat;
}
/* Copy the attributes for variable ivar in group igrp to variable
* ovar in group ogrp. Global (group) attributes are specified by
* using the varid NC_GLOBAL */
static int
copy_atts(int igrp, int ivar, int ogrp, int ovar)
{
int natts;
int iatt;
int stat = NC_NOERR;
NC_CHECK(nc_inq_varnatts(igrp, ivar, &natts));
for(iatt = 0; iatt < natts; iatt++) {
char name[NC_MAX_NAME];
NC_CHECK(nc_inq_attname(igrp, ivar, iatt, name));
if(!strcmp(name,"_NCProperties"))
return stat;
NC_CHECK(nc_copy_att(igrp, ivar, name, ogrp, ovar));
}
return stat;
}
/* copy the schema for a single variable in group igrp to group ogrp */
static int
copy_var(int igrp, int varid, int ogrp)
{
int stat = NC_NOERR;
int ndims;
int *idimids; /* ids of dims for input variable */
int *odimids; /* ids of dims for output variable */
char name[NC_MAX_NAME];
nc_type typeid, o_typeid;
int natts;
int i;
int o_varid;
NC_CHECK(nc_inq_varndims(igrp, varid, &ndims));
idimids = (int *) emalloc((ndims + 1) * sizeof(int));
NC_CHECK(nc_inq_var(igrp, varid, name, &typeid, NULL, idimids, &natts));
o_typeid = typeid;
#ifdef USE_NETCDF4
if (typeid > NC_STRING) { /* user-defined type */
/* type ids in source don't necessarily correspond to same
* typeids in destination, so look up destination typeid by
* using type name */
char type_name[NC_MAX_NAME];
NC_CHECK(nc_inq_type(igrp, typeid, type_name, NULL));
NC_CHECK(nc_inq_typeid(ogrp, type_name, &o_typeid));
}
#endif /* USE_NETCDF4 */
/* get the corresponding dimids in the output file */
odimids = (int *) emalloc((ndims + 1) * sizeof(int));
for(i = 0; i < ndims; i++) {
odimids[i] = dimmap_odimid(idimids[i]);
if(odimids[i] == -1) {
error("Oops, no dimension in output associated with input dimid %d", idimids[i]);
}
}
/* define the output variable */
NC_CHECK(nc_def_var(ogrp, name, o_typeid, ndims, odimids, &o_varid));
/* attach the variable attributes to the output variable */
NC_CHECK(copy_atts(igrp, varid, ogrp, o_varid));
#ifdef USE_NETCDF4
{
int inkind;
int outkind;
NC_CHECK(nc_inq_format(igrp, &inkind));
NC_CHECK(nc_inq_format(ogrp, &outkind));
/* Copy all variable properties such as
* chunking, endianness, deflation, checksumming, fill, etc.
* Ok to call if outkind is netcdf-3
*/
NC_CHECK(copy_var_specials(igrp, varid, ogrp, o_varid, inkind, outkind));
}
#endif /* USE_NETCDF4 */
free(idimids);
free(odimids);
return stat;
}
/* copy the schema for all the variables in group igrp to group ogrp */
static int
copy_vars(int igrp, int ogrp)
{
int stat = NC_NOERR;
int nvars;
int varid;
int iv; /* variable number */
idnode_t* vlist = 0; /* list for vars specified with -v option */
/*
* If any vars were specified with -v option, get list of
* associated variable ids relative to this group. Assume vars
* specified with syntax like "grp1/grp2/varname" or
* "/grp1/grp2/varname" if they are in groups.
*/
vlist = newidlist(); /* list for vars specified with -v option */
for (iv=0; iv < option_nlvars; iv++) {
if(nc_inq_gvarid(igrp, option_lvars[iv], &varid) == NC_NOERR)
idadd(vlist, varid);
}
NC_CHECK(nc_inq_nvars(igrp, &nvars));
for (varid = 0; varid < nvars; varid++) {
if (!option_varstruct && option_nlvars > 0 && ! idmember(vlist, varid))
continue;
NC_CHECK(copy_var(igrp, varid, ogrp));
}
freeidlist(vlist);
return stat;
}
/* Copy the schema in a group and all its subgroups, recursively, from
* group igrp in input to parent group ogrp in destination. Use
* dimmap array to map input dimids to output dimids. */
static int
copy_schema(int igrp, int ogrp)
{
int stat = NC_NOERR;
int ogid; /* like igrp but in output file */
/* get groupid in output corresponding to group igrp in input,
* given parent group (or root group) ogrp in output */
NC_CHECK(get_grpid(igrp, ogrp, &ogid));
NC_CHECK(copy_dims(igrp, ogid));
NC_CHECK(copy_atts(igrp, NC_GLOBAL, ogid, NC_GLOBAL));
NC_CHECK(copy_vars(igrp, ogid));
#ifdef USE_NETCDF4
{
int numgrps;
int *grpids;
int i;
/* Copy schema from subgroups */
stat = nc_inq_grps(igrp, &numgrps, NULL);
grpids = (int *)emalloc((numgrps + 1) * sizeof(int));
NC_CHECK(nc_inq_grps(igrp, &numgrps, grpids));
for(i = 0; i < numgrps; i++) {
if (option_grpstruct || group_wanted(grpids[i], option_nlgrps, option_grpids)) {
NC_CHECK(copy_schema(grpids[i], ogid));
}
}
free(grpids);
}
#endif /* USE_NETCDF4 */
return stat;
}
/* Return number of values for a variable varid in a group igrp */
static int
inq_nvals(int igrp, int varid, long long *nvalsp) {
int stat = NC_NOERR;
int ndims;
int *dimids;
int dim;
long long nvals = 1;
NC_CHECK(nc_inq_varndims(igrp, varid, &ndims));
dimids = (int *) emalloc((ndims + 1) * sizeof(int));
NC_CHECK(nc_inq_vardimid (igrp, varid, dimids));
for(dim = 0; dim < ndims; dim++) {
size_t len;
NC_CHECK(nc_inq_dimlen(igrp, dimids[dim], &len));
nvals *= len;
}
if(nvalsp)
*nvalsp = nvals;
free(dimids);
return stat;
}
/* Copy data from variable varid in group igrp to corresponding group
* ogrp. */
static int
copy_var_data(int igrp, int varid, int ogrp) {
int stat = NC_NOERR;
nc_type vartype;
long long nvalues; /* number of values for this variable */
size_t ntoget; /* number of values to access this iteration */
size_t value_size; /* size of a single value of this variable */
static void *buf = 0; /* buffer for the variable values */
char varname[NC_MAX_NAME];
int ovarid;
size_t *start;
size_t *count;
nciter_t *iterp; /* opaque structure for iteration status */
int do_realloc = 0;
#ifdef USE_NETCDF4
int okind;
size_t chunksize;
#endif
NC_CHECK(inq_nvals(igrp, varid, &nvalues));
if(nvalues == 0)
return stat;
/* get corresponding output variable */
NC_CHECK(nc_inq_varname(igrp, varid, varname));
NC_CHECK(nc_inq_varid(ogrp, varname, &ovarid));
NC_CHECK(nc_inq_vartype(igrp, varid, &vartype));
value_size = val_size(igrp, varid);
if(value_size > option_copy_buffer_size) {
option_copy_buffer_size = value_size;
do_realloc = 1;
}
#ifdef USE_NETCDF4
NC_CHECK(nc_inq_format(ogrp, &okind));
if(okind == NC_FORMAT_NETCDF4 || okind == NC_FORMAT_NETCDF4_CLASSIC) {
/* if this variable chunked, set variable chunk cache size */
int contig = 1;
NC_CHECK(nc_inq_var_chunking(ogrp, ovarid, &contig, NULL));
if(contig == 0) { /* chunked */
if(option_compute_chunkcaches) {
/* Try to estimate variable-specific chunk cache,
* depending on specific size and shape of this
* variable's chunks. This doesn't work yet. */
size_t chunkcache_size, chunkcache_nelems;
float chunkcache_preemption;
NC_CHECK(inq_var_chunking_params(igrp, varid, ogrp, ovarid,
&chunkcache_size,
&chunkcache_nelems,
&chunkcache_preemption));
NC_CHECK(nc_set_var_chunk_cache(ogrp, ovarid,
chunkcache_size,
chunkcache_nelems,
chunkcache_preemption));
} else {
/* by default, use same chunk cache for all chunked variables */
NC_CHECK(nc_set_var_chunk_cache(ogrp, ovarid,
option_chunk_cache_size,
option_chunk_cache_nelems,
COPY_CHUNKCACHE_PREEMPTION));
}
}
}
/* For chunked variables, option_copy_buffer_size must also be at least as large as
* size of a chunk in input, otherwise resize it. */
{
NC_CHECK(inq_var_chunksize(igrp, varid, &chunksize));
if(chunksize > option_copy_buffer_size) {
option_copy_buffer_size = chunksize;
do_realloc = 1;
}
}
#endif /* USE_NETCDF4 */
if(buf && do_realloc) {
free(buf);
buf = 0;
}
if(buf == 0) { /* first time or needs to grow */
buf = emalloc(option_copy_buffer_size);
memset((void*)buf,0,option_copy_buffer_size);
}
/* initialize variable iteration */
NC_CHECK(nc_get_iter(igrp, varid, option_copy_buffer_size, &iterp));
start = (size_t *) emalloc((iterp->rank + 1) * sizeof(size_t));
count = (size_t *) emalloc((iterp->rank + 1) * sizeof(size_t));
/* nc_next_iter() initializes start and count on first call,
* changes start and count to iterate through whole variable on
* subsequent calls. */
while((ntoget = nc_next_iter(iterp, start, count)) > 0) {
NC_CHECK(nc_get_vara(igrp, varid, start, count, buf));
NC_CHECK(nc_put_vara(ogrp, ovarid, start, count, buf));
#ifdef USE_NETCDF4
/* we have to explicitly free values for strings and vlens */
if(vartype == NC_STRING) {
NC_CHECK(nc_free_string(ntoget, (char **)buf));
} else if(vartype > NC_STRING) { /* user-defined type */
nc_type vclass;
NC_CHECK(nc_inq_user_type(igrp, vartype, NULL, NULL, NULL, NULL, &vclass));
if(vclass == NC_VLEN) {
NC_CHECK(nc_free_vlens(ntoget, (nc_vlen_t *)buf));
}
}
#endif /* USE_NETCDF4 */
} /* end main iteration loop */
#ifdef USE_NETCDF4
/* We're all done with this input and output variable, so if
* either variable is chunked, free up its variable chunk cache */
/* NC_CHECK(free_var_chunk_cache(igrp, varid)); */
/* NC_CHECK(free_var_chunk_cache(ogrp, ovarid)); */
#endif /* USE_NETCDF4 */
free(start);
free(count);
NC_CHECK(nc_free_iter(iterp));
return stat;
}
/* Copy data from variables in group igrp to variables in
* corresponding group with parent ogrp, and all subgroups
* recursively */
static int
copy_data(int igrp, int ogrp)
{
int stat = NC_NOERR;
int ogid;
int nvars;
int varid;
#ifdef USE_NETCDF4
int numgrps;
int *grpids;
int i;
#endif
int iv; /* variable number */
idnode_t* vlist = NULL; /* list for vars specified with -v option */
/*
* If any vars were specified with -v option, get list of
* associated variable ids relative to this group. Assume vars
* specified with syntax like "grp1/grp2/varname" or
* "/grp1/grp2/varname" if they are in groups.
*/
vlist = newidlist(); /* list for vars specified with -v option */
for (iv=0; iv < option_nlvars; iv++) {
if(nc_inq_gvarid(igrp, option_lvars[iv], &varid) == NC_NOERR)
idadd(vlist, varid);
}
/* get groupid in output corresponding to group igrp in input,
* given parent group (or root group) ogrp in output */
NC_CHECK(get_grpid(igrp, ogrp, &ogid));
/* Copy data from this group */
NC_CHECK(nc_inq_nvars(igrp, &nvars));
for (varid = 0; varid < nvars; varid++) {
if (option_nlvars > 0 && ! idmember(vlist, varid))
continue;
if (!group_wanted(igrp, option_nlgrps, option_grpids))
continue;
NC_CHECK(copy_var_data(igrp, varid, ogid));
}
#ifdef USE_NETCDF4
/* Copy data from subgroups */
stat = nc_inq_grps(igrp, &numgrps, NULL);
grpids = (int *)emalloc((numgrps + 1) * sizeof(int));
NC_CHECK(nc_inq_grps(igrp, &numgrps, grpids));
for(i = 0; i < numgrps; i++) {
if (!option_grpstruct && !group_wanted(grpids[i], option_nlgrps, option_grpids))
continue;
NC_CHECK(copy_data(grpids[i], ogid));
}
free(grpids);
#endif /* USE_NETCDF4 */
freeidlist(vlist);
return stat;
}
/* Count total number of dimensions in ncid and all its descendant subgroups */
int
count_dims(int ncid) {
#ifdef USE_NETCDF4
int numgrps;
#endif
int ndims;
NC_CHECK(nc_inq_ndims(ncid, &ndims));
#ifdef USE_NETCDF4
NC_CHECK(nc_inq_grps(ncid, &numgrps, NULL));
if(numgrps > 0) {
int igrp;
int *grpids = emalloc(numgrps * sizeof(int));
NC_CHECK(nc_inq_grps(ncid, &numgrps, grpids));
for(igrp = 0; igrp < numgrps; igrp++) {
ndims += count_dims(grpids[igrp]);
}
free(grpids);
}
#endif /* USE_NETCDF4 */
return ndims;
}
/* Test if special case: netCDF-3 file with more than one record
* variable. Performance can be very slow for this case when the disk
* block size is large, there are many record variables, and a
* record's worth of data for some variables is smaller than the disk
* block size. In this case, copying the record variables a variable
* at a time causes much rereading of record data, so instead we want
* to copy data a record at a time. */
static int
nc3_special_case(int ncid, int kind) {
if (kind == NC_FORMAT_CLASSIC || kind == NC_FORMAT_64BIT_OFFSET
|| kind == NC_FORMAT_CDF5) {
int recdimid = 0;
NC_CHECK(nc_inq_unlimdim(ncid, &recdimid));
if (recdimid != -1) { /* we have a record dimension */
int nvars;
int varid;
NC_CHECK(nc_inq_nvars(ncid, &nvars));
for (varid = 0; varid < nvars; varid++) {
int *dimids = 0;
int ndims;
NC_CHECK( nc_inq_varndims(ncid, varid, &ndims) );
if (ndims > 0) {
int dimids0;
dimids = (int *) emalloc((ndims + 1) * sizeof(int));
NC_CHECK( nc_inq_vardimid(ncid, varid, dimids) );
dimids0 = dimids[0];
free(dimids);
if(dimids0 == recdimid) {
return 1; /* found a record variable */
}
}
}
}
}
return 0;
}
/* Classify variables in ncid as either fixed-size variables (with no
* unlimited dimension) or as record variables (with an unlimited
* dimension) */
static int
classify_vars(
int ncid, /* netCDF ID */
size_t *nf, /* for returning number of fixed-size variables */
int **fvars, /* the array of fixed_size variable IDS, caller should free */
size_t *nr, /* for returning number of record variables */
int **rvars) /* the array of record variable IDs, caller should free */
{
int varid;
int varindex = 0;
int nvars;
NC_CHECK(nc_inq_nvars(ncid, &nvars));
*nf = 0;
*fvars = (int *) emalloc(nvars * sizeof(int));
*nr = 0;
*rvars = (int *) emalloc(nvars * sizeof(int));
if(option_nlvars > 0) {
for (varindex = 0; varindex < option_nlvars; varindex++) {
nc_inq_varid(ncid,option_lvars[varindex],&varid);
if (isrecvar(ncid, varid)) {
(*rvars)[*nr] = varid;
(*nr)++;
} else {
(*fvars)[*nf] = varid;
(*nf)++;
}
}
} else {
for (varid = 0; varid < nvars; varid++) {
if (isrecvar(ncid, varid)) {
(*rvars)[*nr] = varid;
(*nr)++;
} else {
(*fvars)[*nf] = varid;
(*nf)++;
}
}
}
return NC_NOERR;
}
/* Only called for classic format or 64-bit offset format files, to speed up special case */
static int
copy_fixed_size_data(int igrp, int ogrp, size_t nfixed_vars, int *fixed_varids) {
size_t ivar;
/* for each fixed-size variable, copy data */
for (ivar = 0; ivar < nfixed_vars; ivar++) {
int varid = fixed_varids[ivar];
NC_CHECK(copy_var_data(igrp, varid, ogrp));
}
if (fixed_varids)
free(fixed_varids);
return NC_NOERR;
}
/* copy a record's worth of data for a variable from input to output */
static int
copy_rec_var_data(int ncid, /* input */
int ogrp, /* output */
int irec, /* record number */
int varid, /* input variable id */
int ovarid, /* output variable id */
size_t *start, /* start indices for record data */
size_t *count, /* edge lengths for record data */
void *buf /* buffer large enough to hold data */
)
{
NC_CHECK(nc_get_vara(ncid, varid, start, count, buf));
NC_CHECK(nc_put_vara(ogrp, ovarid, start, count, buf));
return NC_NOERR;
}
/* Only called for classic format or 64-bit offset format files, to speed up special case */
static int
copy_record_data(int ncid, int ogrp, size_t nrec_vars, int *rec_varids) {
int unlimid;
size_t nrecs = 0; /* how many records? */
size_t irec;
size_t ivar;
void **buf; /* space for reading in data for each variable */
int *rec_ovarids; /* corresponding varids in output */
size_t **start;
size_t **count;
NC_CHECK(nc_inq_unlimdim(ncid, &unlimid));
NC_CHECK(nc_inq_dimlen(ncid, unlimid, &nrecs));
buf = (void **) emalloc(nrec_vars * sizeof(void *));
rec_ovarids = (int *) emalloc(nrec_vars * sizeof(int));
start = (size_t **) emalloc(nrec_vars * sizeof(size_t*));
count = (size_t **) emalloc(nrec_vars * sizeof(size_t*));
/* get space to hold one record's worth of data for each record variable */
for (ivar = 0; ivar < nrec_vars; ivar++) {
int varid;
int ndims;
int *dimids;
size_t value_size;
int dimid;
int ii;
size_t nvals;
char varname[NC_MAX_NAME];
varid = rec_varids[ivar];
NC_CHECK(nc_inq_varndims(ncid, varid, &ndims));
dimids = (int *) emalloc((1 + ndims) * sizeof(int));
start[ivar] = (size_t *) emalloc(ndims * sizeof(size_t));
count[ivar] = (size_t *) emalloc(ndims * sizeof(size_t));
NC_CHECK(nc_inq_vardimid (ncid, varid, dimids));
value_size = val_size(ncid, varid);
nvals = 1;
for(ii = 1; ii < ndims; ii++) { /* for rec size, don't include first record dimension */
size_t dimlen;
dimid = dimids[ii];
NC_CHECK(nc_inq_dimlen(ncid, dimid, &dimlen));
nvals *= dimlen;
start[ivar][ii] = 0;
count[ivar][ii] = dimlen;
}
start[ivar][0] = 0;
count[ivar][0] = 1; /* 1 record */
buf[ivar] = (void *) emalloc(nvals * value_size);
NC_CHECK(nc_inq_varname(ncid, varid, varname));
NC_CHECK(nc_inq_varid(ogrp, varname, &rec_ovarids[ivar]));
if(dimids)
free(dimids);
}
/* for each record, copy all variable data */
for(irec = 0; irec < nrecs; irec++) {
for (ivar = 0; ivar < nrec_vars; ivar++) {
int varid, ovarid;
varid = rec_varids[ivar];
ovarid = rec_ovarids[ivar];
start[ivar][0] = irec;
NC_CHECK(copy_rec_var_data(ncid, ogrp, irec, varid, ovarid,
start[ivar], count[ivar], buf[ivar]));
}
}
for (ivar = 0; ivar < nrec_vars; ivar++) {
if(start[ivar])
free(start[ivar]);
if(count[ivar])
free(count[ivar]);
}
if(start)
free(start);
if(count)
free(count);
for (ivar = 0; ivar < nrec_vars; ivar++) {
if(buf[ivar]) {
free(buf[ivar]);
}
}
if (rec_varids)
free(rec_varids);
if(buf)
free(buf);
if(rec_ovarids)
free(rec_ovarids);
return NC_NOERR;
}
/* copy infile to outfile using netCDF API
*/
static int
copy(char* infile, char* outfile)
{
int stat = NC_NOERR;
int igrp, ogrp;
int inkind, outkind;
int open_mode = NC_NOWRITE;
int create_mode = NC_CLOBBER;
size_t ndims;
if(option_read_diskless) {
open_mode |= NC_DISKLESS;
}
NC_CHECK(nc_open(infile, open_mode, &igrp));
NC_CHECK(nc_inq_format(igrp, &inkind));
/* option_kind specifies which netCDF format for output, one of
*
* SAME_AS_INPUT, NC_FORMAT_CLASSIC, NC_FORMAT_64BIT,
* NC_FORMAT_NETCDF4, NC_FORMAT_NETCDF4_CLASSIC
*
* However, if compression or shuffling was specified and kind was SAME_AS_INPUT,
* option_kind is changed to NC_FORMAT_NETCDF4_CLASSIC, if input format is
* NC_FORMAT_CLASSIC or NC_FORMAT_64BIT .
*/
outkind = option_kind;
if (option_kind == SAME_AS_INPUT) { /* default, kind not specified */
outkind = inkind;
/* Deduce output kind if netCDF-4 features requested */
if (inkind == NC_FORMAT_CLASSIC || inkind == NC_FORMAT_64BIT_OFFSET
|| inkind == NC_FORMAT_CDF5) {
if (option_deflate_level > 0 ||
option_shuffle_vars == NC_SHUFFLE ||
listlength(option_chunkspecs) > 0)
{
outkind = NC_FORMAT_NETCDF4_CLASSIC;
}
}
}
#ifdef USE_NETCDF4
if(listlength(option_chunkspecs) > 0) {
int i;
/* Now that input is open, can parse option_chunkspecs into binary
* structure. */
for(i=0;i<listlength(option_chunkspecs);i++) {
char* spec = (char*)listget(option_chunkspecs,i);
NC_CHECK(chunkspec_parse(igrp, spec));
}
}
#endif /* USE_NETCDF4 */
/* Check if any vars in -v don't exist */
if(missing_vars(igrp, option_nlvars, option_lvars))
exit(EXIT_FAILURE);
if(option_nlgrps > 0) {
if(inkind != NC_FORMAT_NETCDF4) {
error("Group list (-g ...) only permitted for netCDF-4 file");
exit(EXIT_FAILURE);
}
/* Check if any grps in -g don't exist */
if(grp_matches(igrp, option_nlgrps, option_lgrps, option_grpids) == 0)
exit(EXIT_FAILURE);
}
if(option_write_diskless)
create_mode |= NC_WRITE | NC_DISKLESS; /* NC_WRITE persists diskless file on close */
switch(outkind) {
case NC_FORMAT_CLASSIC:
/* nothing to do */
break;
case NC_FORMAT_64BIT_OFFSET:
create_mode |= NC_64BIT_OFFSET;
break;
case NC_FORMAT_CDF5:
#ifdef ENABLE_CDF5
create_mode |= NC_64BIT_DATA;
break;
#else
error("netCDF library built without CDF5 support, can't create CDF5 files");
break;
#endif
#ifdef USE_NETCDF4
case NC_FORMAT_NETCDF4:
create_mode |= NC_NETCDF4;
break;
case NC_FORMAT_NETCDF4_CLASSIC:
create_mode |= NC_NETCDF4 | NC_CLASSIC_MODEL;
break;
#else
case NC_FORMAT_NETCDF4:
case NC_FORMAT_NETCDF4_CLASSIC:
error("netCDF library built with --disable-netcdf4, can't create netCDF-4 files");
break;
#endif /* USE_NETCDF4 */
default:
error("bad value for option specifying desired output format, see usage\n");
break;
}
NC_CHECK(nc_create(outfile, create_mode, &ogrp));
NC_CHECK(nc_set_fill(ogrp, NC_NOFILL, NULL));
#ifdef USE_NETCDF4
/* Because types in one group may depend on types in a different
* group, need to create all groups before defining types */
if(inkind == NC_FORMAT_NETCDF4) {
NC_CHECK(copy_groups(igrp, ogrp));
NC_CHECK(copy_types(igrp, ogrp));
}
#endif /* USE_NETCDF4 */
ndims = count_dims(igrp);
NC_CHECK(dimmap_init(ndims));
NC_CHECK(copy_schema(igrp, ogrp));
NC_CHECK(nc_enddef(ogrp));
/* For performance, special case netCDF-3 input or output file with record
* variables, to copy a record-at-a-time instead of a
* variable-at-a-time. */
/* TODO: check that these special cases work with -v option */
if(nc3_special_case(igrp, inkind)) {
size_t nfixed_vars, nrec_vars;
int *fixed_varids;
int *rec_varids;
NC_CHECK(classify_vars(igrp, &nfixed_vars, &fixed_varids, &nrec_vars, &rec_varids));
NC_CHECK(copy_fixed_size_data(igrp, ogrp, nfixed_vars, fixed_varids));
NC_CHECK(copy_record_data(igrp, ogrp, nrec_vars, rec_varids));
} else if (nc3_special_case(ogrp, outkind)) {
size_t nfixed_vars, nrec_vars;
int *fixed_varids;
int *rec_varids;
/* classifies output vars, but returns input varids */
NC_CHECK(classify_vars(ogrp, &nfixed_vars, &fixed_varids, &nrec_vars, &rec_varids));
NC_CHECK(copy_fixed_size_data(igrp, ogrp, nfixed_vars, fixed_varids));
NC_CHECK(copy_record_data(igrp, ogrp, nrec_vars, rec_varids));
} else {
NC_CHECK(copy_data(igrp, ogrp)); /* recursive, to handle nested groups */
}
NC_CHECK(nc_close(igrp));
NC_CHECK(nc_close(ogrp));
return stat;
}
/*
* For non-negative numeric string with multiplier suffix K, M, G, T,
* or P (or lower-case equivalent), return corresponding value
* incorporating multiplier 1000, 1000000, 1.0d9, ... 1.0d15, or -1.0
* for error.
*/
static double
double_with_suffix(char *str) {
double dval;
char *suffix = 0;
errno = 0;
dval = strtod(str, &suffix);
if(dval < 0 || errno != 0)
return -1.0;
if(*suffix) {
switch (*suffix) {
case 'k': case 'K':
dval *= 1000;
break;
case 'm': case 'M':
dval *= 1000000;
break;
case 'g': case 'G':
dval *= 1000000000;
break;
case 't': case 'T':
dval *= 1.0e12;
break;
case 'p': case 'P':
dval *= 1.0e15;
break;
default:
dval = -1.0; /* error, suffix multiplier must be K, M, G, or T */
}
}
return dval;
}
static void
usage(void)
{
#define USAGE "\
[-k kind] specify kind of netCDF format for output file, default same as input\n\
kind strings: 'classic', '64-bit offset', 'cdf5',\n\
'netCDF-4', 'netCDF-4 classic model'\n\
[-3] netCDF classic output (same as -k 'classic')\n\
[-6] 64-bit-offset output (same as -k '64-bit offset')\n\
[-4] netCDF-4 output (same as -k 'netCDF-4')\n\
[-7] netCDF-4-classic output (same as -k 'netCDF-4 classic model')\n\
[-5] CDF5 output (same as -k 'cdf5)\n\
[-d n] set output deflation compression level, default same as input (0=none 9=max)\n\
[-s] add shuffle option to deflation compression\n\
[-c chunkspec] specify chunking for dimensions, e.g. \"dim1/N1,dim2/N2,...\"\n\
[-u] convert unlimited dimensions to fixed-size dimensions in output copy\n\
[-w] write whole output file from diskless netCDF on close\n\
[-v var1,...] include data for only listed variables, but definitions for all variables\n\
[-V var1,...] include definitions and data for only listed variables\n\
[-g grp1,...] include data for only variables in listed groups, but all definitions\n\
[-G grp1,...] include definitions and data only for variables in listed groups\n\
[-m n] set size in bytes of copy buffer, default is 5000000 bytes\n\
[-h n] set size in bytes of chunk_cache for chunked variables\n\
[-e n] set number of elements that chunk_cache can hold\n\
[-r] read whole input file into diskless file on open (classic or 64-bit offset or cdf5 formats only)\n\
[-F filterspec] specify the compression algorithm to apply to an output variable.\n\
[-Ln] set log level to n (>= 0); ignored if logging isn't enabled.\n\
[-Mn] set minimum chunk size to n bytes (n >= 0)\n\
infile name of netCDF input file\n\
outfile name for netCDF output file\n"
/* Don't document this flaky option until it works better */
/* [-x] use experimental computed estimates for variable-specific chunk caches\n\ */
error("%s [-k kind] [-[3|4|6|7]] [-d n] [-s] [-c chunkspec] [-u] [-w] [-[v|V] varlist] [-[g|G] grplist] [-m n] [-h n] [-e n] [-r] [-F filterspec] [-Ln] [-Mn] infile outfile\n%s\nnetCDF library version %s",
progname, USAGE, nc_inq_libvers());
}
int
main(int argc, char**argv)
{
int exitcode = EXIT_SUCCESS;
char* inputfile = NULL;
char* outputfile = NULL;
int c;
chunkspecinit();
option_chunkspecs = listnew();
opterr = 1;
progname = argv[0];
if (argc <= 1)
{
usage();
}
while ((c = getopt(argc, argv, "k:3467d:sum:c:h:e:rwxg:G:v:V:F:L:M:")) != -1) {
switch(c) {
case 'k': /* for specifying variant of netCDF format to be generated
Format names:
"classic" or "nc3"
"64-bit offset" or "nc6"
"netCDF-4" or "nc4"
"netCDF-4 classic model" or "nc7"
"64-bit-data" | "64-bit data" | "cdf5" | "nc5"
Format version numbers (deprecated):
1 (=> classic)
2 (=> 64-bit offset)
3 (=> netCDF-4)
4 (=> netCDF-4 classic model)
5 (=> classic 64 bit data, CDF-5)
*/
{
struct Kvalues* kvalue;
char *kind_name = (char *) emalloc(strlen(optarg)+1);
(void)strcpy(kind_name, optarg);
for(kvalue=legalkinds;kvalue->name;kvalue++) {
if(strcmp(kind_name,kvalue->name) == 0) {
option_kind = kvalue->kind;
break;
}
}
if(kvalue->name == NULL) {
error("invalid output format: %s", kind_name);
}
}
break;
case '3': /* output format is classic (netCDF-3) */
option_kind = NC_FORMAT_CLASSIC;
break;
case '5': /* output format is cdf5 */
option_kind = NC_FORMAT_CDF5;
break;
case '6': /* output format is 64-bit-offset (netCDF-3 version 2) */
option_kind = NC_FORMAT_64BIT_OFFSET;
break;
case '4': /* output format is netCDF-4 (variant of HDF5) */
option_kind = NC_FORMAT_NETCDF4;
break;
case '7': /* output format is netCDF-4 (restricted to classic model)*/
option_kind = NC_FORMAT_NETCDF4_CLASSIC;
break;
case 'd': /* non-default compression level specified */
option_deflate_level = strtol(optarg, NULL, 10);
if(option_deflate_level < 0 || option_deflate_level > 9) {
error("invalid deflation level: %d", option_deflate_level);
}
break;
case 's': /* shuffling, may improve compression */
option_shuffle_vars = NC_SHUFFLE;
break;
case 'u': /* convert unlimited dimensions to fixed size */
option_fix_unlimdims = 1;
break;
case 'm': /* non-default size of data copy buffer */
{
double dval = double_with_suffix(optarg); /* "K" for kilobytes. "M" for megabytes, ... */
if(dval < 0)
error("Suffix used for '-m' option value must be K, M, G, T, or P");
option_copy_buffer_size = dval;
break;
}
case 'h': /* non-default size of chunk cache */
{
double dval = double_with_suffix(optarg); /* "K" for kilobytes. "M" for megabytes, ... */
if(dval < 0)
error("Suffix used for '-h' option value must be K, M, G, T, or P");
option_chunk_cache_size = dval;
break;
}
case 'e': /* number of elements chunk cache can hold */
{
double dval = double_with_suffix(optarg); /* "K" for kilobytes. "M" for megabytes, ... */
if(dval < 0 )
error("Suffix used for '-e' option value must be K, M, G, T, or P");
option_chunk_cache_nelems = (long)dval;
break;
}
case 'r':
option_read_diskless = 1; /* read into memory on open */
break;
case 'w':
option_write_diskless = 1; /* write to memory, persist on close */
break;
case 'x': /* use experimental variable-specific chunk caches */
option_compute_chunkcaches = 1;
break;
case 'c': /* optional chunking spec for each dimension in list */
/* save chunkspec string for parsing later, once we know input ncid */
listpush(option_chunkspecs,strdup(optarg));
break;
case 'g': /* group names */
/* make list of names of groups specified */
make_lgrps (optarg, &option_nlgrps, &option_lgrps, &option_grpids);
option_grpstruct = true;
break;
case 'G': /* group names */
/* make list of names of groups specified */
make_lgrps (optarg, &option_nlgrps, &option_lgrps, &option_grpids);
option_grpstruct = false;
break;
case 'v': /* variable names */
/* make list of names of variables specified */
make_lvars (optarg, &option_nlvars, &option_lvars);
option_varstruct = true;
break;
case 'V': /* variable names */
/* make list of names of variables specified */
make_lvars (optarg, &option_nlvars, &option_lvars);
option_varstruct = false;
break;
case 'L': /* Set logging, if logging support was compiled in. */
#ifdef LOGGING
{
int level = atoi(optarg);
if(level >= 0)
nc_set_log_level(level);
}
#else
error("-L specified, but logging support not enabled");
#endif
break;
case 'F': /* optional filter spec for a specified variable */
#ifdef USE_NETCDF4
/* If the arg is "none" or "*,none" then suppress all filters
on output unless explicit */
if(strcmp(optarg,"none")==0
|| strcasecmp(optarg,"*,none")==0) {
suppressfilters = 1;
} else {
if(filterspecs == NULL)
filterspecs = listnew();
NC_CHECK(parsefilterspec(optarg,filterspecs));
/* Force output to be netcdf-4 */
option_kind = NC_FORMAT_NETCDF4;
}
#else
error("-F requires netcdf-4");
#endif
break;
case 'M': /* set min chunk size */
#ifdef USE_NETCDF4
if(optarg == NULL)
option_min_chunk_bytes = 0;
else
option_min_chunk_bytes = atol(optarg);
if(option_min_chunk_bytes < 0)
error("-M value must be non-negative integer");
break;
#else
error("-M requires netcdf-4");
#endif
default:
usage();
}
}
argc -= optind;
argv += optind;
if (argc != 2) {
error("one input file and one output file required");
}
inputfile = argv[0];
outputfile = argv[1];
if(strcmp(inputfile, outputfile) == 0) {
error("output would overwrite input");
}
#ifdef USE_NETCDF4
#ifdef DEBUGFILTER
{ int i,j;
for(i=0;i<listlength(filterspecs);i++) {
struct FilterSpec *spec = listget(filterspecs,i);
fprintf(stderr,"filterspecs[%d]={fqn=|%s| filterid=%u nparams=%ld params=",
i,spec->fqn,spec->filterid,(unsigned long)spec->nparams);
for(j=0;j<spec->nparams;j++) {
if(j>0) fprintf(stderr,",");
fprintf(stderr,"%u",spec->params[j]);
}
fprintf(stderr,"}\n");
fflush(stderr);
}
}
#endif /*DEBUGFILTER*/
#endif /*USE_NETCDF4*/
if(copy(inputfile, outputfile) != NC_NOERR)
exitcode = EXIT_FAILURE;
#ifdef USE_NETCDF4
{ int i;
/* Clean up */
for(i=0;i<listlength(filterspecs);i++) {
struct FilterSpec* spec = listget(filterspecs,i);
if(spec->fqn) free(spec->fqn);
if(spec->params) free(spec->params);
}
}
#endif /*USE_NETCDF4*/
exit(exitcode);
}
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