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Remove trailing whitespace from C/C++ source files, with the following script: foreach f (*.[ch] *.cpp) sed 's/[[:blank:]]*$//' $f > sed.out && mv sed.out $f end Tested on: Mac OS X/32 10.5.5 (amazon) No need for h5committest, just whitespace changes...
935 lines
24 KiB
C
935 lines
24 KiB
C
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/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
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* Copyright by The HDF Group. *
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* Copyright by the Board of Trustees of the University of Illinois. *
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* All rights reserved. *
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* *
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* This file is part of HDF5. The full HDF5 copyright notice, including *
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* terms governing use, modification, and redistribution, is contained in *
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* the files COPYING and Copyright.html. COPYING can be found at the root *
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* of the source code distribution tree; Copyright.html can be found at the *
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* root level of an installed copy of the electronic HDF5 document set and *
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* is linked from the top-level documents page. It can also be found at *
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* http://hdfgroup.org/HDF5/doc/Copyright.html. If you do not have *
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* access to either file, you may request a copy from help@hdfgroup.org. *
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* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
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/*
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This program will test irregular hyperslab selections with collective write and read.
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The way to test whether collective write and read works is to use independent IO
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output to verify the collective output.
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1) We will write two datasets with the same hyperslab selection settings;
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one in independent mode,
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one in collective mode,
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2) We will read two datasets with the same hyperslab selection settings,
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1. independent read to read independent output,
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independent read to read collecive output,
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Compare the result,
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If the result is the same, then collective write succeeds.
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2. collective read to read independent output,
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independent read to read independent output,
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Compare the result,
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If the result is the same, then collective read succeeds.
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*/
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#include "hdf5.h"
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#include "H5private.h"
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#include "testphdf5.h"
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static void coll_write_test(int chunk_factor);
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static void coll_read_test(int chunk_factor);
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/*-------------------------------------------------------------------------
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* Function: coll_irregular_cont_write
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*
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* Purpose: Wrapper to test the collectively irregular hyperslab write in
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contiguous storage
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*
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* Return: Success: 0
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*
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* Failure: -1
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*
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* Programmer: Unknown
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* Dec 2nd, 2004
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*
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* Modifications:
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*
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*-------------------------------------------------------------------------
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*/
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void
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coll_irregular_cont_write(void)
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{
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coll_write_test(0);
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}
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/*-------------------------------------------------------------------------
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* Function: coll_irregular_cont_read
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*
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* Purpose: Wrapper to test the collectively irregular hyperslab read in
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contiguous storage
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*
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* Return: Success: 0
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*
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* Failure: -1
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*
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* Programmer: Unknown
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* Dec 2nd, 2004
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*
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* Modifications:
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*
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*-------------------------------------------------------------------------
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*/
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void
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coll_irregular_cont_read(void)
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{
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coll_read_test(0);
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}
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/*-------------------------------------------------------------------------
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* Function: coll_irregular_simple_chunk_write
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*
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* Purpose: Wrapper to test the collectively irregular hyperslab write in
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chunk storage(1 chunk)
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*
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* Return: Success: 0
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*
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* Failure: -1
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*
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* Programmer: Unknown
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* Dec 2nd, 2004
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*
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* Modifications:
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*
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*-------------------------------------------------------------------------
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*/
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void
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coll_irregular_simple_chunk_write(void)
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{
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coll_write_test(1);
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}
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/*-------------------------------------------------------------------------
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* Function: coll_irregular_simple_chunk_read
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*
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* Purpose: Wrapper to test the collectively irregular hyperslab read in chunk
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storage(1 chunk)
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*
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* Return: Success: 0
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*
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* Failure: -1
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*
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* Programmer: Unknown
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* Dec 2nd, 2004
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*
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* Modifications:
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*
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*-------------------------------------------------------------------------
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*/
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void
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coll_irregular_simple_chunk_read(void)
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{
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coll_read_test(1);
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}
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/*-------------------------------------------------------------------------
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* Function: coll_irregular_complex_chunk_write
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*
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* Purpose: Wrapper to test the collectively irregular hyperslab write in chunk
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storage(4 chunks)
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*
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* Return: Success: 0
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*
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* Failure: -1
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*
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* Programmer: Unknown
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* Dec 2nd, 2004
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*
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* Modifications:
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*
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*-------------------------------------------------------------------------
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*/
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void
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coll_irregular_complex_chunk_write(void)
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{
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coll_write_test(4);
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}
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/*-------------------------------------------------------------------------
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* Function: coll_irregular_complex_chunk_read
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*
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* Purpose: Wrapper to test the collectively irregular hyperslab read in chunk
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storage(1 chunk)
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*
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* Return: Success: 0
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*
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* Failure: -1
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*
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* Programmer: Unknown
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* Dec 2nd, 2004
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*
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* Modifications:
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*
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*-------------------------------------------------------------------------
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*/
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void
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coll_irregular_complex_chunk_read(void)
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{
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coll_read_test(4);
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}
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/*-------------------------------------------------------------------------
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* Function: coll_write_test
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*
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* Purpose: To test the collectively irregular hyperslab write in chunk
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storage
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* Input: number of chunks on each dimension
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if number is equal to 0, contiguous storage
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* Return: Success: 0
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*
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* Failure: -1
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*
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* Programmer: Unknown
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* Dec 2nd, 2004
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*
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* Modifications: Oct 18th, 2005
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*
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*-------------------------------------------------------------------------
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*/
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void coll_write_test(int chunk_factor)
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{
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const char *filename;
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hid_t facc_plist,dxfer_plist,dcrt_plist;
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hid_t file, datasetc,dataseti; /* File and dataset identifiers */
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hid_t mspaceid1, mspaceid, fspaceid,fspaceid1; /* Dataspace identifiers */
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hsize_t mdim1[1],fsdim[2],mdim[2];
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#if 0
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hsize_t mdim1[] = {MSPACE1_DIM}; /* Dimension size of the first dataset
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(in memory) */
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hsize_t fsdim[] = {FSPACE_DIM1, FSPACE_DIM2}; /* Dimension sizes of the dataset
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(on disk) */
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hsize_t mdim[] = {MSPACE_DIM1, MSPACE_DIM2}; /* Dimension sizes of the
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dataset in memory when we
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read selection from the
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dataset on the disk */
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#endif
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hsize_t start[2]; /* Start of hyperslab */
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hsize_t stride[2]; /* Stride of hyperslab */
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hsize_t count[2]; /* Block count */
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hsize_t block[2]; /* Block sizes */
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hsize_t chunk_dims[2];
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herr_t ret;
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unsigned i,j;
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int fillvalue = 0; /* Fill value for the dataset */
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#if 0
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int matrix_out[MSPACE_DIM1][MSPACE_DIM2];
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int matrix_out1[MSPACE_DIM1][MSPACE_DIM2]; /* Buffer to read from the
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dataset */
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int vector[MSPACE1_DIM];
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#endif
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int *matrix_out, *matrix_out1, *vector;
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hbool_t use_gpfs = FALSE;
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int mpi_size,mpi_rank;
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MPI_Comm comm = MPI_COMM_WORLD;
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MPI_Info info = MPI_INFO_NULL;
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/*set up MPI parameters */
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MPI_Comm_size(comm,&mpi_size);
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MPI_Comm_rank(comm,&mpi_rank);
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/* Obtain file name */
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filename = GetTestParameters();
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/*
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* Buffers' initialization.
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*/
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mdim1[0] = MSPACE1_DIM *mpi_size;
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mdim[0] = MSPACE_DIM1;
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mdim[1] = MSPACE_DIM2*mpi_size;
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fsdim[0] = FSPACE_DIM1;
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fsdim[1] = FSPACE_DIM2*mpi_size;
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vector = (int*)HDmalloc(sizeof(int)*mdim1[0]*mpi_size);
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matrix_out = (int*)HDmalloc(sizeof(int)*mdim[0]*mdim[1]*mpi_size);
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matrix_out1 = (int*)HDmalloc(sizeof(int)*mdim[0]*mdim[1]*mpi_size);
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HDmemset(vector,0,sizeof(int)*mdim1[0]*mpi_size);
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vector[0] = vector[MSPACE1_DIM*mpi_size - 1] = -1;
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for (i = 1; i < MSPACE1_DIM*mpi_size - 1; i++) vector[i] = i;
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/* Grab file access property list */
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facc_plist = create_faccess_plist(comm, info, facc_type, use_gpfs);
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VRFY((facc_plist >= 0),"");
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/*
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* Create a file.
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*/
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file = H5Fcreate(filename, H5F_ACC_TRUNC, H5P_DEFAULT, facc_plist);
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VRFY((file >= 0),"H5Fcreate succeeded");
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/*
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* Create property list for a dataset and set up fill values.
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*/
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dcrt_plist = H5Pcreate(H5P_DATASET_CREATE);
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VRFY((dcrt_plist >= 0),"");
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ret = H5Pset_fill_value(dcrt_plist, H5T_NATIVE_INT, &fillvalue);
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VRFY((ret >= 0),"Fill value creation property list succeeded");
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if(chunk_factor != 0) {
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chunk_dims[0] = fsdim[0] / chunk_factor;
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chunk_dims[1] = fsdim[1] / chunk_factor;
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ret = H5Pset_chunk(dcrt_plist, 2, chunk_dims);
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VRFY((ret >= 0),"chunk creation property list succeeded");
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}
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/*
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*
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* Create dataspace for the first dataset in the disk.
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* dim1 = 9
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* dim2 = 3600
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*
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*
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*/
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fspaceid = H5Screate_simple(FSPACE_RANK, fsdim, NULL);
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VRFY((fspaceid >= 0),"file dataspace created succeeded");
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/*
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* Create dataset in the file. Notice that creation
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* property list dcrt_plist is used.
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*/
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datasetc = H5Dcreate2(file, "collect_write", H5T_NATIVE_INT, fspaceid, H5P_DEFAULT, dcrt_plist, H5P_DEFAULT);
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VRFY((datasetc >= 0),"dataset created succeeded");
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dataseti = H5Dcreate2(file, "independ_write", H5T_NATIVE_INT, fspaceid, H5P_DEFAULT, dcrt_plist, H5P_DEFAULT);
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VRFY((dataseti >= 0),"dataset created succeeded");
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/* The First selection for FILE
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*
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* block (3,2)
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* stride(4,3)
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* count (1,768/mpi_size)
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* start (0,1+768*3*mpi_rank/mpi_size)
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*
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*/
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start[0] = FHSTART0;
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start[1] = FHSTART1 + mpi_rank * FHSTRIDE1 * FHCOUNT1;
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stride[0] = FHSTRIDE0;
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stride[1] = FHSTRIDE1;
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count[0] = FHCOUNT0;
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count[1] = FHCOUNT1;
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block[0] = FHBLOCK0;
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block[1] = FHBLOCK1;
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ret = H5Sselect_hyperslab(fspaceid, H5S_SELECT_SET, start, stride, count, block);
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VRFY((ret >= 0),"hyperslab selection succeeded");
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/* The Second selection for FILE
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*
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* block (3,768)
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* stride (1,1)
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* count (1,1)
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* start (4,768*mpi_rank/mpi_size)
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*
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*/
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start[0] = SHSTART0;
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start[1] = SHSTART1+SHCOUNT1*SHBLOCK1*mpi_rank;
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stride[0] = SHSTRIDE0;
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stride[1] = SHSTRIDE1;
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count[0] = SHCOUNT0;
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count[1] = SHCOUNT1;
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block[0] = SHBLOCK0;
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block[1] = SHBLOCK1;
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ret = H5Sselect_hyperslab(fspaceid, H5S_SELECT_OR, start, stride, count, block);
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VRFY((ret >= 0),"hyperslab selection succeeded");
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/*
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* Create dataspace for the first dataset in the memory
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* dim1 = 27000
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*
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*/
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mspaceid1 = H5Screate_simple(MSPACE1_RANK, mdim1, NULL);
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VRFY((mspaceid1 >= 0),"memory dataspace created succeeded");
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/*
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* Memory space is 1-D, this is a good test to check
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* whether a span-tree derived datatype needs to be built.
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* block 1
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* stride 1
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* count 6912/mpi_size
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* start 1
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*
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*/
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start[0] = MHSTART0;
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stride[0] = MHSTRIDE0;
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count[0] = MHCOUNT0;
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block[0] = MHBLOCK0;
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ret = H5Sselect_hyperslab(mspaceid1, H5S_SELECT_SET, start, stride, count, block);
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VRFY((ret >= 0),"hyperslab selection succeeded");
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/* independent write */
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ret = H5Dwrite(dataseti, H5T_NATIVE_INT, mspaceid1, fspaceid, H5P_DEFAULT, vector);
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VRFY((ret >= 0),"dataset independent write succeed");
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dxfer_plist = H5Pcreate(H5P_DATASET_XFER);
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VRFY((dxfer_plist >= 0),"");
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ret = H5Pset_dxpl_mpio(dxfer_plist, H5FD_MPIO_COLLECTIVE);
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VRFY((ret >= 0),"MPIO data transfer property list succeed");
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if(dxfer_coll_type == DXFER_INDEPENDENT_IO) {
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ret = H5Pset_dxpl_mpio_collective_opt(dxfer_plist,H5FD_MPIO_INDIVIDUAL_IO);
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VRFY((ret>= 0),"set independent IO collectively succeeded");
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}
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/* collective write */
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ret = H5Dwrite(datasetc, H5T_NATIVE_INT, mspaceid1, fspaceid, dxfer_plist, vector);
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VRFY((ret >= 0),"dataset collective write succeed");
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ret = H5Sclose(mspaceid1);
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VRFY((ret >= 0),"");
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ret = H5Sclose(fspaceid);
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VRFY((ret >= 0),"");
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/*
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* Close dataset.
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*/
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ret = H5Dclose(datasetc);
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VRFY((ret >= 0),"");
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ret = H5Dclose(dataseti);
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VRFY((ret >= 0),"");
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/*
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* Close the file.
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*/
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ret = H5Fclose(file);
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VRFY((ret >= 0),"");
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/*
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* Close property list
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*/
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ret = H5Pclose(facc_plist);
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VRFY((ret >= 0),"");
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ret = H5Pclose(dxfer_plist);
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VRFY((ret >= 0),"");
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ret = H5Pclose(dcrt_plist);
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VRFY((ret >= 0),"");
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/*
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* Open the file.
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*/
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/***
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For testing collective hyperslab selection write
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In this test, we are using independent read to check
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the correctedness of collective write compared with
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independent write,
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In order to throughly test this feature, we choose
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a different selection set for reading the data out.
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***/
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/* Obtain file access property list with MPI-IO driver */
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facc_plist = create_faccess_plist(comm, info, facc_type, use_gpfs);
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VRFY((facc_plist >= 0),"");
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file = H5Fopen(filename, H5F_ACC_RDONLY, facc_plist);
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VRFY((file >= 0),"H5Fopen succeeded");
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/*
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* Open the dataset.
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*/
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datasetc = H5Dopen2(file,"collect_write", H5P_DEFAULT);
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VRFY((datasetc >= 0),"H5Dopen2 succeeded");
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dataseti = H5Dopen2(file,"independ_write", H5P_DEFAULT);
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VRFY((dataseti >= 0),"H5Dopen2 succeeded");
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/*
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* Get dataspace of the open dataset.
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*/
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fspaceid = H5Dget_space(datasetc);
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VRFY((fspaceid >= 0),"file dataspace obtained succeeded");
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fspaceid1 = H5Dget_space(dataseti);
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VRFY((fspaceid1 >= 0),"file dataspace obtained succeeded");
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/* The First selection for FILE to read
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*
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* block (1,1)
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* stride(1.1)
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* count (3,768/mpi_size)
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* start (1,2+768*mpi_rank/mpi_size)
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*
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*/
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start[0] = RFFHSTART0;
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start[1] = RFFHSTART1+mpi_rank*RFFHCOUNT1;
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block[0] = RFFHBLOCK0;
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block[1] = RFFHBLOCK1;
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stride[0] = RFFHSTRIDE0;
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stride[1] = RFFHSTRIDE1;
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count[0] = RFFHCOUNT0;
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count[1] = RFFHCOUNT1;
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/* The first selection of the dataset generated by collective write */
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ret = H5Sselect_hyperslab(fspaceid, H5S_SELECT_SET, start, stride, count, block);
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VRFY((ret >= 0),"hyperslab selection succeeded");
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/* The first selection of the dataset generated by independent write */
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ret = H5Sselect_hyperslab(fspaceid1, H5S_SELECT_SET, start, stride, count, block);
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VRFY((ret >= 0),"hyperslab selection succeeded");
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/* The Second selection for FILE to read
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*
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* block (1,1)
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* stride(1.1)
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* count (3,1536/mpi_size)
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* start (2,4+1536*mpi_rank/mpi_size)
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*
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*/
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|
|
start[0] = RFSHSTART0;
|
|
start[1] = RFSHSTART1+RFSHCOUNT1*mpi_rank;
|
|
block[0] = RFSHBLOCK0;
|
|
block[1] = RFSHBLOCK1;
|
|
stride[0] = RFSHSTRIDE0;
|
|
stride[1] = RFSHSTRIDE0;
|
|
count[0] = RFSHCOUNT0;
|
|
count[1] = RFSHCOUNT1;
|
|
|
|
/* The second selection of the dataset generated by collective write */
|
|
ret = H5Sselect_hyperslab(fspaceid, H5S_SELECT_OR, start, stride, count, block);
|
|
VRFY((ret >= 0),"hyperslab selection succeeded");
|
|
|
|
/* The second selection of the dataset generated by independent write */
|
|
ret = H5Sselect_hyperslab(fspaceid1, H5S_SELECT_OR, start, stride, count, block);
|
|
VRFY((ret >= 0),"hyperslab selection succeeded");
|
|
|
|
/*
|
|
* Create memory dataspace.
|
|
* rank = 2
|
|
* mdim1 = 9
|
|
* mdim2 = 3600
|
|
*
|
|
*/
|
|
mspaceid = H5Screate_simple(MSPACE_RANK, mdim, NULL);
|
|
|
|
/*
|
|
* Select two hyperslabs in memory. Hyperslabs has the same
|
|
* size and shape as the selected hyperslabs for the file dataspace
|
|
* Only the starting point is different.
|
|
* The first selection
|
|
* block (1,1)
|
|
* stride(1.1)
|
|
* count (3,768/mpi_size)
|
|
* start (0,768*mpi_rank/mpi_size)
|
|
*
|
|
*/
|
|
|
|
|
|
start[0] = RMFHSTART0;
|
|
start[1] = RMFHSTART1+mpi_rank*RMFHCOUNT1;
|
|
block[0] = RMFHBLOCK0;
|
|
block[1] = RMFHBLOCK1;
|
|
stride[0] = RMFHSTRIDE0;
|
|
stride[1] = RMFHSTRIDE1;
|
|
count[0] = RMFHCOUNT0;
|
|
count[1] = RMFHCOUNT1;
|
|
|
|
ret = H5Sselect_hyperslab(mspaceid, H5S_SELECT_SET, start, stride, count, block);
|
|
VRFY((ret >= 0),"hyperslab selection succeeded");
|
|
|
|
/*
|
|
* Select two hyperslabs in memory. Hyperslabs has the same
|
|
* size and shape as the selected hyperslabs for the file dataspace
|
|
* Only the starting point is different.
|
|
* The second selection
|
|
* block (1,1)
|
|
* stride(1,1)
|
|
* count (3,1536/mpi_size)
|
|
* start (1,2+1536*mpi_rank/mpi_size)
|
|
*
|
|
*/
|
|
start[0] = RMSHSTART0;
|
|
start[1] = RMSHSTART1+mpi_rank*RMSHCOUNT1;
|
|
block[0] = RMSHBLOCK0;
|
|
block[1] = RMSHBLOCK1;
|
|
stride[0] = RMSHSTRIDE0;
|
|
stride[1] = RMSHSTRIDE1;
|
|
count[0] = RMSHCOUNT0;
|
|
count[1] = RMSHCOUNT1;
|
|
|
|
ret = H5Sselect_hyperslab(mspaceid, H5S_SELECT_OR, start, stride, count, block);
|
|
VRFY((ret >= 0),"hyperslab selection succeeded");
|
|
|
|
/*
|
|
* Initialize data buffer.
|
|
*/
|
|
|
|
HDmemset(matrix_out,0,sizeof(int)*MSPACE_DIM1*MSPACE_DIM2*mpi_size);
|
|
HDmemset(matrix_out1,0,sizeof(int)*MSPACE_DIM1*MSPACE_DIM2*mpi_size);
|
|
/*
|
|
* Read data back to the buffer matrix_out.
|
|
*/
|
|
|
|
ret = H5Dread(datasetc, H5T_NATIVE_INT, mspaceid, fspaceid,
|
|
H5P_DEFAULT, matrix_out);
|
|
VRFY((ret >= 0),"H5D independent read succeed");
|
|
|
|
|
|
ret = H5Dread(dataseti, H5T_NATIVE_INT, mspaceid, fspaceid,
|
|
H5P_DEFAULT, matrix_out1);
|
|
VRFY((ret >= 0),"H5D independent read succeed");
|
|
|
|
ret = 0;
|
|
|
|
for (i = 0; i < MSPACE_DIM1*MSPACE_DIM2*mpi_size; i++){
|
|
if(matrix_out[i]!=matrix_out1[i]) ret = -1;
|
|
if(ret < 0) break;
|
|
}
|
|
|
|
VRFY((ret >= 0),"H5D irregular collective write succeed");
|
|
|
|
/*
|
|
* Close memory file and memory dataspaces.
|
|
*/
|
|
ret = H5Sclose(mspaceid);
|
|
VRFY((ret >= 0),"");
|
|
ret = H5Sclose(fspaceid);
|
|
VRFY((ret >= 0),"");
|
|
|
|
/*
|
|
* Close dataset.
|
|
*/
|
|
ret = H5Dclose(dataseti);
|
|
VRFY((ret >= 0),"");
|
|
|
|
ret = H5Dclose(datasetc);
|
|
VRFY((ret >= 0),"");
|
|
|
|
/*
|
|
* Close property list
|
|
*/
|
|
|
|
ret = H5Pclose(facc_plist);
|
|
VRFY((ret >= 0),"");
|
|
|
|
|
|
/*
|
|
* Close the file.
|
|
*/
|
|
ret = H5Fclose(file);
|
|
VRFY((ret >= 0),"");
|
|
|
|
return ;
|
|
}
|
|
|
|
/*-------------------------------------------------------------------------
|
|
* Function: coll_read_test
|
|
*
|
|
* Purpose: To test the collectively irregular hyperslab read in chunk
|
|
storage
|
|
* Input: number of chunks on each dimension
|
|
if number is equal to 0, contiguous storage
|
|
* Return: Success: 0
|
|
*
|
|
* Failure: -1
|
|
*
|
|
* Programmer: Unknown
|
|
* Dec 2nd, 2004
|
|
*
|
|
* Modifications: Oct 18th, 2005
|
|
* Note: This test must be used with the correpsonding
|
|
coll_write_test.
|
|
*-------------------------------------------------------------------------
|
|
*/
|
|
void coll_read_test(int chunk_factor)
|
|
{
|
|
|
|
const char *filename;
|
|
hid_t facc_plist,dxfer_plist;
|
|
hid_t file, dataseti; /* File and dataset identifiers */
|
|
hid_t mspaceid, fspaceid1; /* Dataspace identifiers */
|
|
|
|
|
|
/* Dimension sizes of the dataset (on disk) */
|
|
#if 0
|
|
hsize_t mdim[] = {MSPACE_DIM1, MSPACE_DIM2}; /* Dimension sizes of the
|
|
dataset in memory when we
|
|
read selection from the
|
|
dataset on the disk */
|
|
|
|
#endif
|
|
hsize_t mdim[2];
|
|
hsize_t start[2]; /* Start of hyperslab */
|
|
hsize_t stride[2]; /* Stride of hyperslab */
|
|
hsize_t count[2]; /* Block count */
|
|
hsize_t block[2]; /* Block sizes */
|
|
herr_t ret;
|
|
|
|
unsigned i,j;
|
|
|
|
int *matrix_out;
|
|
int *matrix_out1;
|
|
#if 0
|
|
int matrix_out[MSPACE_DIM1][MSPACE_DIM2];
|
|
int matrix_out1[MSPACE_DIM1][MSPACE_DIM2]; /* Buffer to read from the
|
|
dataset */
|
|
|
|
#endif
|
|
hbool_t use_gpfs = FALSE;
|
|
int mpi_size,mpi_rank;
|
|
|
|
MPI_Comm comm = MPI_COMM_WORLD;
|
|
MPI_Info info = MPI_INFO_NULL;
|
|
|
|
/*set up MPI parameters */
|
|
MPI_Comm_size(comm,&mpi_size);
|
|
MPI_Comm_rank(comm,&mpi_rank);
|
|
|
|
|
|
/* Obtain file name */
|
|
filename = GetTestParameters();
|
|
|
|
|
|
/* Initialize the buffer */
|
|
|
|
mdim[0] = MSPACE_DIM1;
|
|
mdim[1] = MSPACE_DIM2*mpi_size;
|
|
matrix_out =(int*)HDmalloc(sizeof(int)*MSPACE_DIM1*MSPACE_DIM2*mpi_size);
|
|
matrix_out1=(int*)HDmalloc(sizeof(int)*MSPACE_DIM1*MSPACE_DIM2*mpi_size);
|
|
|
|
/*** For testing collective hyperslab selection read ***/
|
|
|
|
/* Obtain file access property list */
|
|
facc_plist = create_faccess_plist(comm, info, facc_type, use_gpfs);
|
|
VRFY((facc_plist >= 0),"");
|
|
|
|
/*
|
|
* Open the file.
|
|
*/
|
|
file = H5Fopen(filename, H5F_ACC_RDONLY, facc_plist);
|
|
VRFY((file >= 0),"H5Fopen succeeded");
|
|
|
|
/*
|
|
* Open the dataset.
|
|
*/
|
|
dataseti = H5Dopen2(file,"independ_write", H5P_DEFAULT);
|
|
VRFY((dataseti >= 0),"H5Dopen2 succeeded");
|
|
|
|
/*
|
|
* Get dataspace of the open dataset.
|
|
*/
|
|
fspaceid1 = H5Dget_space(dataseti);
|
|
VRFY((fspaceid1 >= 0),"file dataspace obtained succeeded");
|
|
|
|
/* The First selection for FILE to read
|
|
*
|
|
* block (1,1)
|
|
* stride(1.1)
|
|
* count (3,768/mpi_size)
|
|
* start (1,2+768*mpi_rank/mpi_size)
|
|
*
|
|
*/
|
|
start[0] = RFFHSTART0;
|
|
start[1] = RFFHSTART1+mpi_rank*RFFHCOUNT1;
|
|
block[0] = RFFHBLOCK0;
|
|
block[1] = RFFHBLOCK1;
|
|
stride[0] = RFFHSTRIDE0;
|
|
stride[1] = RFFHSTRIDE1;
|
|
count[0] = RFFHCOUNT0;
|
|
count[1] = RFFHCOUNT1;
|
|
|
|
ret = H5Sselect_hyperslab(fspaceid1, H5S_SELECT_SET, start, stride, count, block);
|
|
VRFY((ret >= 0),"hyperslab selection succeeded");
|
|
|
|
/* The Second selection for FILE to read
|
|
*
|
|
* block (1,1)
|
|
* stride(1.1)
|
|
* count (3,1536/mpi_size)
|
|
* start (2,4+1536*mpi_rank/mpi_size)
|
|
*
|
|
*/
|
|
start[0] = RFSHSTART0;
|
|
start[1] = RFSHSTART1+RFSHCOUNT1*mpi_rank;
|
|
block[0] = RFSHBLOCK0;
|
|
block[1] = RFSHBLOCK1;
|
|
stride[0] = RFSHSTRIDE0;
|
|
stride[1] = RFSHSTRIDE0;
|
|
count[0] = RFSHCOUNT0;
|
|
count[1] = RFSHCOUNT1;
|
|
|
|
ret = H5Sselect_hyperslab(fspaceid1, H5S_SELECT_OR, start, stride, count, block);
|
|
VRFY((ret >= 0),"hyperslab selection succeeded");
|
|
|
|
|
|
/*
|
|
* Create memory dataspace.
|
|
*/
|
|
mspaceid = H5Screate_simple(MSPACE_RANK, mdim, NULL);
|
|
|
|
/*
|
|
* Select two hyperslabs in memory. Hyperslabs has the same
|
|
* size and shape as the selected hyperslabs for the file dataspace.
|
|
* Only the starting point is different.
|
|
* The first selection
|
|
* block (1,1)
|
|
* stride(1.1)
|
|
* count (3,768/mpi_size)
|
|
* start (0,768*mpi_rank/mpi_size)
|
|
*
|
|
*/
|
|
|
|
start[0] = RMFHSTART0;
|
|
start[1] = RMFHSTART1+mpi_rank*RMFHCOUNT1;
|
|
block[0] = RMFHBLOCK0;
|
|
block[1] = RMFHBLOCK1;
|
|
stride[0] = RMFHSTRIDE0;
|
|
stride[1] = RMFHSTRIDE1;
|
|
count[0] = RMFHCOUNT0;
|
|
count[1] = RMFHCOUNT1;
|
|
ret = H5Sselect_hyperslab(mspaceid, H5S_SELECT_SET, start, stride, count, block);
|
|
VRFY((ret >= 0),"hyperslab selection succeeded");
|
|
|
|
/*
|
|
* Select two hyperslabs in memory. Hyperslabs has the same
|
|
* size and shape as the selected hyperslabs for the file dataspace
|
|
* Only the starting point is different.
|
|
* The second selection
|
|
* block (1,1)
|
|
* stride(1,1)
|
|
* count (3,1536/mpi_size)
|
|
* start (1,2+1536*mpi_rank/mpi_size)
|
|
*
|
|
*/
|
|
start[0] = RMSHSTART0;
|
|
start[1] = RMSHSTART1+mpi_rank*RMSHCOUNT1;
|
|
block[0] = RMSHBLOCK0;
|
|
block[1] = RMSHBLOCK1;
|
|
stride[0] = RMSHSTRIDE0;
|
|
stride[1] = RMSHSTRIDE1;
|
|
count[0] = RMSHCOUNT0;
|
|
count[1] = RMSHCOUNT1;
|
|
ret = H5Sselect_hyperslab(mspaceid, H5S_SELECT_OR, start, stride, count, block);
|
|
VRFY((ret >= 0),"hyperslab selection succeeded");
|
|
|
|
|
|
/*
|
|
* Initialize data buffer.
|
|
*/
|
|
|
|
HDmemset(matrix_out,0,sizeof(int)*MSPACE_DIM1*MSPACE_DIM2*mpi_size);
|
|
HDmemset(matrix_out1,0,sizeof(int)*MSPACE_DIM1*MSPACE_DIM2*mpi_size);
|
|
|
|
/*
|
|
* Read data back to the buffer matrix_out.
|
|
*/
|
|
|
|
dxfer_plist = H5Pcreate(H5P_DATASET_XFER);
|
|
VRFY((dxfer_plist >= 0),"");
|
|
|
|
ret = H5Pset_dxpl_mpio(dxfer_plist, H5FD_MPIO_COLLECTIVE);
|
|
VRFY((ret >= 0),"MPIO data transfer property list succeed");
|
|
if(dxfer_coll_type == DXFER_INDEPENDENT_IO) {
|
|
ret = H5Pset_dxpl_mpio_collective_opt(dxfer_plist,H5FD_MPIO_INDIVIDUAL_IO);
|
|
VRFY((ret>= 0),"set independent IO collectively succeeded");
|
|
}
|
|
|
|
|
|
/* Collective read */
|
|
ret = H5Dread(dataseti, H5T_NATIVE_INT, mspaceid, fspaceid1,
|
|
dxfer_plist, matrix_out);
|
|
VRFY((ret >= 0),"H5D collecive read succeed");
|
|
|
|
ret = H5Pclose(dxfer_plist);
|
|
VRFY((ret >= 0),"");
|
|
|
|
/* Independent read */
|
|
ret = H5Dread(dataseti, H5T_NATIVE_INT, mspaceid, fspaceid1,
|
|
H5P_DEFAULT, matrix_out1);
|
|
VRFY((ret >= 0),"H5D independent read succeed");
|
|
|
|
ret = 0;
|
|
for (i = 0; i < MSPACE_DIM1*MSPACE_DIM2*mpi_size; i++){
|
|
if(matrix_out[i]!=matrix_out1[i])ret = -1;
|
|
if(ret < 0) break;
|
|
}
|
|
VRFY((ret >= 0),"H5D contiguous irregular collective read succeed");
|
|
|
|
/*
|
|
* Close memory file and memory dataspaces.
|
|
*/
|
|
ret = H5Sclose(mspaceid);
|
|
VRFY((ret >= 0),"");
|
|
ret = H5Sclose(fspaceid1);
|
|
VRFY((ret >= 0),"");
|
|
|
|
/*
|
|
* Close dataset.
|
|
*/
|
|
ret = H5Dclose(dataseti);
|
|
VRFY((ret >= 0),"");
|
|
|
|
/*
|
|
* Close property list
|
|
*/
|
|
ret = H5Pclose(facc_plist);
|
|
VRFY((ret >= 0),"");
|
|
|
|
|
|
/*
|
|
* Close the file.
|
|
*/
|
|
ret = H5Fclose(file);
|
|
VRFY((ret >= 0),"");
|
|
|
|
return ;
|
|
}
|