hdf5/testpar/testphdf5.h
MuQun Yang 00b54cf131 [svn-r12554] New tests have been added to test the correctness of independent IO with file setview.
To activite this test,
add the command option -i.
For example, at IBM AIX, type "poe testphdf5 -i" will test the library with independent IO with file setview. It simply replaces all the collective IO tests with independent IO with file setview.
2006-08-08 22:16:07 -05:00

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12 KiB
C

/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
* Copyright by the Board of Trustees of the University of Illinois. *
* All rights reserved. *
* *
* This file is part of HDF5. The full HDF5 copyright notice, including *
* terms governing use, modification, and redistribution, is contained in *
* the files COPYING and Copyright.html. COPYING can be found at the root *
* of the source code distribution tree; Copyright.html can be found at the *
* root level of an installed copy of the electronic HDF5 document set and *
* is linked from the top-level documents page. It can also be found at *
* http://hdf.ncsa.uiuc.edu/HDF5/doc/Copyright.html. If you do not have *
* access to either file, you may request a copy from hdfhelp@ncsa.uiuc.edu. *
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
/* common definitions used by all parallel hdf5 test programs. */
#ifndef PHDF5TEST_H
#define PHDF5TEST_H
#include "testpar.h"
enum H5TEST_COLL_CHUNK_API {API_NONE=0,API_LINK_HARD,
API_MULTI_HARD,API_LINK_TRUE,API_LINK_FALSE,
API_MULTI_COLL,API_MULTI_IND};
#ifndef FALSE
#define FALSE 0
#endif
#ifndef TRUE
#define TRUE 1
#endif
/* Constants definitions */
#define DIM0 600 /* Default dataset sizes. */
#define DIM1 1200 /* Values are from a monitor pixel sizes */
#define RANK 2
#define DATASETNAME1 "Data1"
#define DATASETNAME2 "Data2"
#define DATASETNAME3 "Data3"
#define DATASETNAME4 "Data4"
/* Hyperslab layout styles */
#define BYROW 1 /* divide into slabs of rows */
#define BYCOL 2 /* divide into blocks of columns */
#define ZROW 3 /* same as BYCOL except process 0 gets 0 rows */
#define ZCOL 4 /* same as BYCOL except process 0 gets 0 columns */
/* File_Access_type bits */
#define FACC_DEFAULT 0x0 /* default */
#define FACC_MPIO 0x1 /* MPIO */
#define FACC_SPLIT 0x2 /* Split File */
#define FACC_MULTI 0x4 /* Multi File */
#define FACC_MPIPOSIX 0x8 /* MPIPOSIX */
#define DXFER_COLLECTIVE_IO 0x1 /* Collective IO*/
#define DXFER_INDEPENDENT_IO 0x2 /* Independent IO collectively */
/*Constants for collective chunk definitions */
#define SPACE_DIM1 24
#define SPACE_DIM2 4
#define BYROW_CONT 1
#define BYROW_DISCONT 2
#define BYROW_SELECTNONE 3
#define BYROW_SELECTUNBALANCE 4
#define BYROW_SELECTINCHUNK 5
#define DIMO_NUM_CHUNK 4
#define DIM1_NUM_CHUNK 2
#define LINK_TRUE_NUM_CHUNK 2
#define LINK_FALSE_NUM_CHUNK 6
#define MULTI_TRUE_PERCENT 50
#define LINK_TRUE_CHUNK_NAME "h5_link_chunk_true"
#define LINK_FALSE_CHUNK_NAME "h5_link_chunk_false"
#define LINK_HARD_CHUNK_NAME "h5_link_chunk_hard"
#define MULTI_HARD_CHUNK_NAME "h5_multi_chunk_hard"
#define MULTI_COLL_CHUNK_NAME "h5_multi_chunk_coll"
#define MULTI_INDP_CHUNK_NAME "h5_multi_chunk_indp"
#define DSET_COLLECTIVE_CHUNK_NAME "coll_chunk_name"
/*Constants for MPI derived data type generated from span tree */
#define MSPACE1_RANK 1 /* Rank of the first dataset in memory */
#define MSPACE1_DIM 27000 /* Dataset size in memory */
#define FSPACE_RANK 2 /* Dataset rank as it is stored in the file */
#define FSPACE_DIM1 9 /* Dimension sizes of the dataset as it is stored in the file */
#define FSPACE_DIM2 3600 /* We will read dataset back from the file to the dataset in memory with these dataspace parameters. */
#define MSPACE_RANK 2
#define MSPACE_DIM1 9
#define MSPACE_DIM2 3600
#define FHCOUNT0 1 /* Count of the first dimension of the first hyperslab selection*/
#define FHCOUNT1 768 /* Count of the second dimension of the first hyperslab selection*/
#define FHSTRIDE0 4 /* Stride of the first dimension of the first hyperslab selection*/
#define FHSTRIDE1 3 /* Stride of the second dimension of the first hyperslab selection*/
#define FHBLOCK0 3 /* Block of the first dimension of the first hyperslab selection*/
#define FHBLOCK1 2 /* Block of the second dimension of the first hyperslab selection*/
#define FHSTART0 0 /* start of the first dimension of the first hyperslab selection*/
#define FHSTART1 1 /* start of the second dimension of the first hyperslab selection*/
#define SHCOUNT0 1 /* Count of the first dimension of the first hyperslab selection*/
#define SHCOUNT1 1 /* Count of the second dimension of the first hyperslab selection*/
#define SHSTRIDE0 1 /* Stride of the first dimension of the first hyperslab selection*/
#define SHSTRIDE1 1 /* Stride of the second dimension of the first hyperslab selection*/
#define SHBLOCK0 3 /* Block of the first dimension of the first hyperslab selection*/
#define SHBLOCK1 768 /* Block of the second dimension of the first hyperslab selection*/
#define SHSTART0 4 /* start of the first dimension of the first hyperslab selection*/
#define SHSTART1 0 /* start of the second dimension of the first hyperslab selection*/
#define MHCOUNT0 6912 /* Count of the first dimension of the first hyperslab selection*/
#define MHSTRIDE0 1 /* Stride of the first dimension of the first hyperslab selection*/
#define MHBLOCK0 1 /* Block of the first dimension of the first hyperslab selection*/
#define MHSTART0 1 /* start of the first dimension of the first hyperslab selection*/
#define RFFHCOUNT0 3 /* Count of the first dimension of the first hyperslab selection*/
#define RFFHCOUNT1 768 /* Count of the second dimension of the first hyperslab selection*/
#define RFFHSTRIDE0 1 /* Stride of the first dimension of the first hyperslab selection*/
#define RFFHSTRIDE1 1 /* Stride of the second dimension of the first hyperslab selection*/
#define RFFHBLOCK0 1 /* Block of the first dimension of the first hyperslab selection*/
#define RFFHBLOCK1 1 /* Block of the second dimension of the first hyperslab selection*/
#define RFFHSTART0 1 /* start of the first dimension of the first hyperslab selection*/
#define RFFHSTART1 2 /* start of the second dimension of the first hyperslab selection*/
#define RFSHCOUNT0 3 /* Count of the first dimension of the first hyperslab selection*/
#define RFSHCOUNT1 1536 /* Count of the second dimension of the first hyperslab selection*/
#define RFSHSTRIDE0 1 /* Stride of the first dimension of the first hyperslab selection*/
#define RFSHSTRIDE1 1 /* Stride of the second dimension of the first hyperslab selection*/
#define RFSHBLOCK0 1 /* Block of the first dimension of the first hyperslab selection*/
#define RFSHBLOCK1 1 /* Block of the second dimension of the first hyperslab selection*/
#define RFSHSTART0 2 /* start of the first dimension of the first hyperslab selection*/
#define RFSHSTART1 4 /* start of the second dimension of the first hyperslab selection*/
#define RMFHCOUNT0 3 /* Count of the first dimension of the first hyperslab selection*/
#define RMFHCOUNT1 768 /* Count of the second dimension of the first hyperslab selection*/
#define RMFHSTRIDE0 1 /* Stride of the first dimension of the first hyperslab selection*/
#define RMFHSTRIDE1 1 /* Stride of the second dimension of the first hyperslab selection*/
#define RMFHBLOCK0 1 /* Block of the first dimension of the first hyperslab selection*/
#define RMFHBLOCK1 1 /* Block of the second dimension of the first hyperslab selection*/
#define RMFHSTART0 0 /* start of the first dimension of the first hyperslab selection*/
#define RMFHSTART1 0 /* start of the second dimension of the first hyperslab selection*/
#define RMSHCOUNT0 3 /* Count of the first dimension of the first hyperslab selection*/
#define RMSHCOUNT1 1536 /* Count of the second dimension of the first hyperslab selection*/
#define RMSHSTRIDE0 1 /* Stride of the first dimension of the first hyperslab selection*/
#define RMSHSTRIDE1 1 /* Stride of the second dimension of the first hyperslab selection*/
#define RMSHBLOCK0 1 /* Block of the first dimension of the first hyperslab selection*/
#define RMSHBLOCK1 1 /* Block of the second dimension of the first hyperslab selection*/
#define RMSHSTART0 1 /* start of the first dimension of the first hyperslab selection*/
#define RMSHSTART1 2 /* start of the second dimension of the first hyperslab selection*/
#define NPOINTS 4 /* Number of points that will be selected
and overwritten */
/* Don't erase these lines, they are put here for debugging purposes */
/*
#define MSPACE1_RANK 1
#define MSPACE1_DIM 50
#define MSPACE2_RANK 1
#define MSPACE2_DIM 4
#define FSPACE_RANK 2
#define FSPACE_DIM1 8
#define FSPACE_DIM2 12
#define MSPACE_RANK 2
#define MSPACE_DIM1 8
#define MSPACE_DIM2 9
#define NPOINTS 4
*/ /* end of debugging macro */
/* type definitions */
typedef struct H5Ptest_param_t /* holds extra test parameters */
{
char *name;
int count;
} H5Ptest_param_t;
/* Dataset data type. Int's can be easily octo dumped. */
typedef int DATATYPE;
/* Shared global variables */
extern int dim0, dim1; /*Dataset dimensions */
extern int chunkdim0, chunkdim1; /*Chunk dimensions */
extern int nerrors; /*errors count */
extern H5E_auto_t old_func; /* previous error handler */
extern void *old_client_data; /*previous error handler arg.*/
extern int facc_type; /*Test file access type */
extern int dxfer_coll_type;
/* Test program prototypes */
void multiple_dset_write(void);
void multiple_group_write(void);
void multiple_group_read(void);
void collective_group_write(void);
void independent_group_read(void);
void test_fapl_mpio_dup(void);
void test_fapl_mpiposix_dup(void);
void test_split_comm_access(void);
void dataset_writeInd(void);
void dataset_writeAll(void);
void extend_writeInd(void);
void extend_writeInd2(void);
void extend_writeAll(void);
void dataset_readInd(void);
void dataset_readAll(void);
void extend_readInd(void);
void extend_readAll(void);
void test_chunk_alloc(void);
void compact_dataset(void);
void null_dataset(void);
void big_dataset(void);
void dataset_fillvalue(void);
void coll_chunk1(void);
void coll_chunk2(void);
void coll_chunk3(void);
void coll_chunk4(void);
void coll_chunk5(void);
void coll_chunk6(void);
void coll_chunk7(void);
void coll_chunk8(void);
void coll_chunk9(void);
void coll_chunk10(void);
void coll_irregular_cont_read(void);
void coll_irregular_cont_write(void);
void coll_irregular_simple_chunk_read(void);
void coll_irregular_simple_chunk_write(void);
void coll_irregular_complex_chunk_read(void);
void coll_irregular_complex_chunk_write(void);
void io_mode_confusion(void);
#ifdef H5_HAVE_FILTER_DEFLATE
void compress_readAll(void);
#endif /* H5_HAVE_FILTER_DEFLATE */
/* commonly used prototypes */
hid_t create_faccess_plist(MPI_Comm comm, MPI_Info info, int l_facc_type, hbool_t use_gpfs);
MPI_Offset h5_mpi_get_file_size(const char *filename, MPI_Comm comm, MPI_Info info);
int dataset_vrfy(hsize_t start[], hsize_t count[], hsize_t stride[],
hsize_t block[], DATATYPE *dataset, DATATYPE *original);
#endif /* PHDF5TEST_H */