mirror of
https://github.com/Unidata/netcdf-c.git
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93e9d92778
* Replace wholevar with more useful wholechunk optimization * Add optimization to read multiple values at one time * Replace NCDEFAULT_get/put_vars with native nczarr versions. * Clarify chunk projection computations * zdebdispatch.h * Add more chunking test cases and re-enable run_chunkcases * If !szip, then suppress deflate interference test * Make H5Znoop(1) filter produce more information * cleanup bzlib.c API
299 lines
9.3 KiB
C
299 lines
9.3 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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*********************************************************************/
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#include "zincludes.h"
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#define MAX(a,b) ((a)>(b)?(a):(b))
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#define MIN(a,b) ((a)<(b)?(a):(b))
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static int pcounter = 0;
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/* Forward */
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static int compute_intersection(const NCZSlice* slice, const size64_t chunklen, NCZChunkRange* range);
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static void skipchunk(const NCZSlice* slice, NCZProjection* projection);
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static int verifyslice(const NCZSlice* slice);
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/**************************************************/
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/* Goal:create a vector of chunk ranges: one for each slice in
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the top-level input. For each slice, compute the index (not
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absolute position) of the first chunk that intersects the slice
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and the index of the last chunk that intersects the slice.
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In practice, the count = last - first + 1 is stored instead of the last index.
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*/
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int
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NCZ_compute_chunk_ranges(
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int rank, /* variable rank */
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const NCZSlice* slices, /* the complete set of slices |slices| == R*/
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const size64_t* chunklen, /* the chunk length corresponding to the dimensions */
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NCZChunkRange* ncr)
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{
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int stat = NC_NOERR;
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int i;
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for(i=0;i<rank;i++) {
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if((stat = compute_intersection(&slices[i],chunklen[i],&ncr[i])))
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goto done;
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}
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done:
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return stat;
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}
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static int
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compute_intersection(
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const NCZSlice* slice,
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const size64_t chunklen,
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NCZChunkRange* range)
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{
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range->start = floordiv(slice->start, chunklen);
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range->stop = ceildiv(slice->stop, chunklen);
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return NC_NOERR;
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}
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/**
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Compute the projection of a slice as applied to n'th chunk.
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This is somewhat complex because:
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1. for the first projection, the start is the slice start,
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but after that, we have to take into account that for
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a non-one stride, the start point in a projection may
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be offset by some value in the range of 0..(slice.stride-1).
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2. The stride might be so large as to completely skip some chunks.
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@return NC_NOERR if ok
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@return NC_ERANGE if chunk skipped
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@return NC_EXXXX if failed
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*/
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int
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NCZ_compute_projections(struct Common* common, int r, size64_t chunkindex, const NCZSlice* slice, size_t n, NCZProjection* projections)
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{
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int stat = NC_NOERR;
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NCZProjection* projection = NULL;
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NCZProjection* prev = NULL;
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size64_t dimlen = common->dimlens[r]; /* the dimension length for r'th dimension */
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size64_t chunklen = common->chunklens[r]; /* the chunk length corresponding to the dimension */
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size64_t abslimit;
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projection = &projections[n];
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if(n > 0) {
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/* Find last non-skipped projection */
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int i;
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for(i=n-1;i>=0;i--) { /* walk backward */
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if(!projections[i].skip) {
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prev = &projections[i];
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break;
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}
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}
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if(prev == NULL) {stat = NC_ENCZARR; goto done;}
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}
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projection->id = ++pcounter;
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projection->chunkindex = chunkindex;
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projection->offset = chunklen * chunkindex; /* with respect to dimension (WRD) */
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/* limit in the n'th touched chunk, taking dimlen and stride->stop into account. */
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abslimit = (chunkindex + 1) * chunklen;
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if(abslimit > slice->stop) abslimit = slice->stop;
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if(abslimit > dimlen) abslimit = dimlen;
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projection->limit = abslimit - projection->offset;
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/* See if the next point after the last one in prev lands in the current projection.
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If not, then we have skipped the current chunk. Also take limit into account.
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Note by definition, n must be greater than zero because we always start in a relevant chunk.
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*/
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if(n == 0) {
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/*initial case: original slice start is in 1st projection */
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projection->first = slice->start - projection->offset;
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projection->iopos = 0;
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} else { /* n > 0 */
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/* Use absolute offsets for these computations to avoid negative values */
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size64_t abslastpoint, absnextpoint, absthislast;
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/* abs last point touched in prev projection */
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abslastpoint = prev->offset + prev->last;
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/* Compute the abs last touchable point in this chunk */
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absthislast = projection->offset + projection->limit;
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/* Compute next point touched after the last point touched in previous projection;
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note that the previous projection might be wrt a chunk other than the immediately preceding
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one (because the intermediate ones were skipped).
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*/
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absnextpoint = abslastpoint + slice->stride; /* abs next point to be touched */
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if(absnextpoint >= absthislast) { /* this chunk is being skipped */
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skipchunk(slice,projection);
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goto done;
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}
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/* Compute start point in this chunk */
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/* basically absnextpoint - abs start of this projection */
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projection->first = absnextpoint - projection->offset;
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/* Compute the memory location of this first point in this chunk */
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projection->iopos = ceildiv((projection->offset - slice->start),slice->stride);
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}
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if(slice->stop > abslimit)
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projection->stop = chunklen;
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else
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projection->stop = slice->stop - projection->offset;
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projection->iocount = ceildiv((projection->stop - projection->first),slice->stride);
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/* Compute the slice relative to this chunk.
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Recall the possibility that start+stride >= projection->limit */
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projection->chunkslice.start = projection->first;
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projection->chunkslice.stop = projection->stop;
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projection->chunkslice.stride = slice->stride;
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projection->chunkslice.len = chunklen;
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/* Last place to be touched */
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projection->last = projection->first + (slice->stride * (projection->iocount - 1));
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projection->memslice.start = projection->iopos;
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projection->memslice.stop = projection->iopos + projection->iocount;
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projection->memslice.stride = 1;
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// projection->memslice.stride = slice->stride;
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// projection->memslice.len = projection->memslice.stop;
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projection->memslice.len = common->memshape[r];
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#ifdef NEVERUSE
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projection->memslice.len = dimlen;
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projection->memslice.len = chunklen;
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#endif
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if(!verifyslice(&projection->memslice) || !verifyslice(&projection->chunkslice))
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{stat = NC_ECONSTRAINT; goto done;}
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done:
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return stat;
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}
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static void
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skipchunk(const NCZSlice* slice, NCZProjection* projection)
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{
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projection->skip = 1;
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projection->first = 0;
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projection->last = 0;
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projection->iopos = ceildiv(projection->offset - slice->start, slice->stride);
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projection->iocount = 0;
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projection->chunkslice.start = 0;
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projection->chunkslice.stop = 0;
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projection->chunkslice.stride = 1;
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projection->chunkslice.len = 0;
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projection->memslice.start = 0;
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projection->memslice.stop = 0;
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projection->memslice.stride = 1;
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projection->memslice.len = 0;
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}
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/* Goal:
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Create a vector of projections wrt a slice and a sequence of chunks.
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*/
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int
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NCZ_compute_per_slice_projections(
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struct Common* common,
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int r, /* which dimension are we projecting? */
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const NCZSlice* slice, /* the slice for which projections are computed */
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const NCZChunkRange* range, /* range */
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NCZSliceProjections* slp)
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{
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int stat = NC_NOERR;
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size64_t index,slicecount;
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size_t n;
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/* Part fill the Slice Projections */
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slp->r = r;
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slp->range = *range;
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slp->count = range->stop - range->start;
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if((slp->projections = calloc(slp->count,sizeof(NCZProjection))) == NULL)
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{stat = NC_ENOMEM; goto done;}
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/* Compute the total number of output items defined by this slice
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(equivalent to count as used by nc_get_vars) */
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slicecount = ceildiv((slice->stop - slice->start), slice->stride);
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if(slicecount < 0) slicecount = 0;
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/* Iterate over each chunk that intersects slice to produce projection */
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for(n=0,index=range->start;index<range->stop;index++,n++) {
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if((stat = NCZ_compute_projections(common, r, index, slice, n, slp->projections)))
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goto done; /* something went wrong */
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}
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done:
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return stat;
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}
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/* Goal:create a vector of SliceProjection instances: one for each
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slice in the top-level input. For each slice, compute a set
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of projections from it wrt a dimension and a chunk size
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associated with that dimension.
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*/
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int
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NCZ_compute_all_slice_projections(
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struct Common* common,
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const NCZSlice* slices, /* the complete set of slices |slices| == R*/
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const NCZChunkRange* ranges,
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NCZSliceProjections* results)
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{
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int stat = NC_NOERR;
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size64_t r;
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for(r=0;r<common->rank;r++) {
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/* Compute each of the rank SliceProjections instances */
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NCZSliceProjections* slp = &results[r];
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if((stat=NCZ_compute_per_slice_projections(
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common,
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r,
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&slices[r],
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&ranges[r],
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slp))) goto done;
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}
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done:
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return stat;
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}
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/**************************************************/
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/* Utilities */
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/* return 0 if slice is malformed; 1 otherwise */
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static int
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verifyslice(const NCZSlice* slice)
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{
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if(slice->stop < slice->start) return 0;
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if(slice->stride <= 0) return 0;
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if((slice->stop - slice->start) > slice->len) return 0;
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return 1;
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}
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void
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NCZ_clearsliceprojections(int count, NCZSliceProjections* slpv)
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{
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if(slpv != NULL) {
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int i;
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for(i=0;i<count;i++) {
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NCZSliceProjections* slp = &slpv[i];
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nullfree(slp->projections);
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}
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}
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}
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#if 0
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static void
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clearallprojections(NCZAllProjections* nap)
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{
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if(nap != NULL) {
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int i;
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for(i=0;i<nap->rank;i++)
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nclistfreeall(&nap->allprojections[i].projections);
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}
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}
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#endif
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