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/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
* Copyright by The HDF Group. *
* 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 COPYING file, which can be found at the root of the source code *
* distribution tree, or in https://www.hdfgroup.org/licenses. *
* If you do not have access to either file, you may request a copy from *
* help@hdfgroup.org. *
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
/***********************************************************
*
* Test program: twriteorder
*
* Test to verify that the write order is strictly consistent.
* The SWMR feature requires that the order of write is strictly consistent.
* "Strict consistency in computer science is the most stringent consistency
* model. It says that a read operation has to return the result of the
* latest write operation which occurred on that data item."--
* (http://en.wikipedia.org/wiki/Linearizability#Definition_of_linearizability).
* This is also an alternative form of what POSIX write require that after a
* write operation has returned success, all reads issued afterward should
* get the same data the write has written.
*
* Created: Albert Cheng, 2013/8/28.
*************************************************************/
/***********************************************************
*
* Algorithm
*
* The test simulates what SWMR does by writing chained blocks and see if
* they can be read back correctly.
* There is a writer process and multiple read processes.
* The file is divided into 2KB partitions. Then writer writes 1 chained
* block, each of 1KB big, in each partition after the first partition.
* Each chained block has this structure:
* Byte 0-3: offset address of its child block. The last child uses 0 as NULL.
* Byte 4-1023: some artificial data.
* The child block address of Block 1 is NULL (0).
* The child block address of Block 2 is the offset address of Block 1.
* The child block address of Block n is the offset address of Block n-1.
* After all n blocks are written, the offset address of Block n is written
* to the offset 0 of the first partition.
* Therefore, by the time the offset address of Block n is written to this
* position, all n chain-linked blocks have been written.
*
* The other reader processes will try to read the address value at the
* offset 0. The value is initially NULL(0). When it changes to non-zero,
* it signifies the writer process has written all the chain-link blocks
* and they are ready for the reader processes to access.
*
* If the system, in which the writer and reader processes run, the readers
* will always get all chain-linked blocks correctly. If the order of write
* is not maintained, some reader processes may found unexpect block data.
*
*************************************************************/
#include "h5test.h"
/* This test uses many POSIX things that are not available on
* Windows.
*/
#if defined(H5_HAVE_FORK) && defined(H5_HAVE_WAITPID)
#define DATAFILE "twriteorder.dat"
/* #define READERS_MAX 10 */ /* max number of readers */
#define BLOCKSIZE_DFT 1024 /* 1KB */
#define PARTITION_DFT 2048 /* 2KB */
#define NLINKEDBLOCKS_DFT 512 /* default 512 */
#define SIZE_BLKADDR 4 /* expected sizeof blkaddr */
#define Hgoto_error(val) \
{ \
ret_value = val; \
goto done; \
}
/* type declarations */
typedef enum part_t {
UC_READWRITE = 0, /* both writer and reader */
UC_WRITER, /* writer only */
UC_READER /* reader only */
} part_t;
/* prototypes */
int create_wo_file(void);
int write_wo_file(void);
int read_wo_file(void);
void usage(const char *prog);
int setup_parameters(int argc, char *const argv[]);
int parse_option(int argc, char *const argv[]);
/* Global Variable definitions */
const char *progname_g = "twriteorder"; /* program name */
int write_fd_g;
int blocksize_g, part_size_g, nlinkedblock_g;
part_t launch_g;
/* Function definitions */
/* Show help page */
void
usage(const char *prog)
{
HDfprintf(stderr, "usage: %s [OPTIONS]\n", prog);
HDfprintf(stderr, " OPTIONS\n");
HDfprintf(stderr, " -h Print a usage message and exit\n");
HDfprintf(stderr, " -l w|r launch writer or reader only. [default: launch both]\n");
HDfprintf(stderr, " -b N Block size [default: %d]\n", BLOCKSIZE_DFT);
HDfprintf(stderr, " -p N Partition size [default: %d]\n", PARTITION_DFT);
HDfprintf(stderr, " -n N Number of linked blocks [default: %d]\n", NLINKEDBLOCKS_DFT);
HDfprintf(stderr, " where N is an integer value\n");
HDfprintf(stderr, "\n");
}
/* Setup test parameters by parsing command line options.
* Setup default values if not set by options. */
int
parse_option(int argc, char *const argv[])
{
int ret_value = 0;
int c;
/* command line options: See function usage for a description */
const char *cmd_options = "hb:l:n:p:";
/* suppress getopt from printing error */
opterr = 0;
while (1) {
c = getopt(argc, argv, cmd_options);
if (-1 == c)
break;
switch (c) {
case 'h':
usage(progname_g);
HDexit(EXIT_SUCCESS);
break;
case 'b': /* number of planes to write/read */
if ((blocksize_g = HDatoi(optarg)) <= 0) {
HDfprintf(stderr, "bad blocksize %s, must be a positive integer\n", optarg);
usage(progname_g);
Hgoto_error(-1);
};
break;
case 'n': /* number of planes to write/read */
if ((nlinkedblock_g = HDatoi(optarg)) < 2) {
HDfprintf(stderr, "bad number of linked blocks %s, must be greater than 1.\n", optarg);
usage(progname_g);
Hgoto_error(-1);
};
break;
case 'p': /* number of planes to write/read */
if ((part_size_g = HDatoi(optarg)) <= 0) {
HDfprintf(stderr, "bad partition size %s, must be a positive integer\n", optarg);
usage(progname_g);
Hgoto_error(-1);
};
break;
case 'l': /* launch reader or writer only */
switch (*optarg) {
case 'r': /* reader only */
launch_g = UC_READER;
break;
case 'w': /* writer only */
launch_g = UC_WRITER;
break;
default:
HDfprintf(stderr, "launch value(%c) should be w or r only.\n", *optarg);
usage(progname_g);
Hgoto_error(-1);
break;
} /* end inner switch */
HDprintf("launch = %d\n", launch_g);
break;
case '?':
HDfprintf(stderr, "getopt returned '%c'.\n", c);
usage(progname_g);
Hgoto_error(-1);
default:
HDfprintf(stderr, "getopt returned unexpected value.\n");
HDfprintf(stderr, "Unexpected value is %d\n", c);
Hgoto_error(-1);
} /* end outer switch */
} /* end while */
/* verify partition size must be >= blocksize */
if (part_size_g < blocksize_g) {
HDfprintf(stderr, "Blocksize %d should not be bigger than partition size %d\n", blocksize_g,
part_size_g);
Hgoto_error(-1);
}
done:
/* All done. */
return ret_value;
}
/* Setup parameters for the test case.
* Return: 0 succeed; -1 fail.
*/
int
setup_parameters(int argc, char *const argv[])
{
/* test case defaults */
blocksize_g = BLOCKSIZE_DFT;
part_size_g = PARTITION_DFT;
nlinkedblock_g = NLINKEDBLOCKS_DFT;
launch_g = UC_READWRITE;
/* parse options */
if (parse_option(argc, argv) < 0) {
return -1;
}
/* show parameters and return */
HDprintf("blocksize = %ld\n", (long)blocksize_g);
HDprintf("part_size = %ld\n", (long)part_size_g);
HDprintf("nlinkedblock = %ld\n", (long)nlinkedblock_g);
HDprintf("launch = %d\n", launch_g);
return 0;
}
/* Create the test file with initial "empty" file, that is,
* partition 0 has a null (0) address.
*
* Return: 0 succeed; -1 fail.
*/
int
create_wo_file(void)
{
int blkaddr = 0; /* blkaddress of next linked block */
h5_posix_io_ret_t bytes_wrote = -1; /* # of bytes written */
/* Create the data file */
if ((write_fd_g = HDopen(DATAFILE, O_RDWR | O_TRUNC | O_CREAT, H5_POSIX_CREATE_MODE_RW)) < 0) {
HDprintf("WRITER: error from open\n");
return -1;
}
blkaddr = 0;
/* write it to partition 0 */
if ((bytes_wrote = HDwrite(write_fd_g, &blkaddr, (size_t)SIZE_BLKADDR)) != SIZE_BLKADDR) {
HDprintf("blkaddr write failed\n");
return -1;
}
/* File initialized, return success */
return 0;
}
int
write_wo_file(void)
{
int blkaddr;
int blkaddr_old = 0;
int i;
char buffer[BLOCKSIZE_DFT];
h5_posix_io_ret_t bytes_wrote = -1; /* # of bytes written */
/* write block 1, 2, ... */
for (i = 1; i < nlinkedblock_g; i++) {
/* calculate where to write this block */
blkaddr = i * part_size_g + i;
/* store old block address in byte 0-3 */
HDmemcpy(&buffer[0], &blkaddr_old, sizeof(blkaddr_old));
/* fill the rest with the lowest byte of i */
HDmemset(&buffer[4], i & 0xff, (size_t)(BLOCKSIZE_DFT - 4));
/* write the block */
#ifdef DEBUG
HDprintf("writing block at %d\n", blkaddr);
#endif
HDlseek(write_fd_g, (HDoff_t)blkaddr, SEEK_SET);
if ((bytes_wrote = HDwrite(write_fd_g, buffer, (size_t)blocksize_g)) != blocksize_g) {
HDprintf("blkaddr write failed in partition %d\n", i);
return -1;
}
blkaddr_old = blkaddr;
} /* end for */
/* write the last blkaddr in partition 0 */
HDlseek(write_fd_g, (HDoff_t)0, SEEK_SET);
if ((bytes_wrote = HDwrite(write_fd_g, &blkaddr_old, (size_t)sizeof(blkaddr_old))) !=
sizeof(blkaddr_old)) {
HDprintf("blkaddr write failed in partition %d\n", 0);
return -1;
}
/* all writes done. return succeess. */
#ifdef DEBUG
HDprintf("wrote %d blocks\n", nlinkedblock_g);
#endif
return 0;
}
int
read_wo_file(void)
{
int read_fd;
int blkaddr = 0;
h5_posix_io_ret_t bytes_read = -1; /* # of bytes actually read */
int linkedblocks_read = 0;
char buffer[BLOCKSIZE_DFT];
/* Open the data file */
if ((read_fd = HDopen(DATAFILE, O_RDONLY)) < 0) {
HDprintf("READER: error from open\n");
return -1;
}
/* keep reading the initial block address until it is non-zero before proceeding. */
while (blkaddr == 0) {
HDlseek(read_fd, (HDoff_t)0, SEEK_SET);
if ((bytes_read = HDread(read_fd, &blkaddr, (size_t)sizeof(blkaddr))) != sizeof(blkaddr)) {
HDprintf("blkaddr read failed in partition %d\n", 0);
return -1;
}
}
linkedblocks_read++;
/* got a non-zero blkaddr. Proceed down the linked blocks. */
#ifdef DEBUG
HDprintf("got initial block address=%d\n", blkaddr);
#endif
while (blkaddr != 0) {
HDlseek(read_fd, (HDoff_t)blkaddr, SEEK_SET);
if ((bytes_read = HDread(read_fd, buffer, (size_t)blocksize_g)) != blocksize_g) {
HDprintf("blkaddr read failed in partition %d\n", 0);
return -1;
}
linkedblocks_read++;
/* retrieve the block address in byte 0-3 */
HDmemcpy(&blkaddr, &buffer[0], sizeof(blkaddr));
#ifdef DEBUG
HDprintf("got next block address=%d\n", blkaddr);
#endif
}
#ifdef DEBUG
HDprintf("read %d blocks\n", linkedblocks_read);
#endif
return 0;
}
/* Overall Algorithm:
* Parse options from user;
* Generate/pre-created the test file needed and close it;
* fork: child processes become the reader processes;
* while parent process continues as the writer process;
* both run till ending conditions are met.
*/
int
main(int argc, char *argv[])
{
/*pid_t childpid[READERS_MAX];
int child_ret_value[READERS_MAX];*/
pid_t childpid = 0;
int child_ret_value;
pid_t mypid, tmppid;
int child_status;
int child_wait_option = 0;
int ret_value = 0;
/* initialization */
if (setup_parameters(argc, argv) < 0) {
Hgoto_error(1);
}
/* ==============================================================*/
/* UC_READWRITE: create datafile, launch both reader and writer. */
/* UC_WRITER: create datafile, skip reader, launch writer. */
/* UC_READER: skip create, launch reader, exit. */
/* ==============================================================*/
/* ============*/
/* Create file */
/* ============*/
if (launch_g != UC_READER) {
HDprintf("Creating skeleton data file for test...\n");
if (create_wo_file() < 0) {
HDfprintf(stderr, "***encounter error\n");
Hgoto_error(1);
}
else
HDprintf("File created.\n");
}
/* flush output before possible fork */
HDfflush(stdout);
if (launch_g == UC_READWRITE) {
/* fork process */
if ((childpid = HDfork()) < 0) {
HDperror("fork");
Hgoto_error(1);
};
};
mypid = HDgetpid();
/* ============= */
/* launch reader */
/* ============= */
if (launch_g != UC_WRITER) {
/* child process launch the reader */
if (0 == childpid) {
HDprintf("%d: launch reader process\n", mypid);
if (read_wo_file() < 0) {
HDfprintf(stderr, "read_wo_file encountered error\n");
HDexit(EXIT_FAILURE);
}
/* Reader is done. Clean up by removing the data file */
HDremove(DATAFILE);
HDexit(EXIT_SUCCESS);
}
}
/* ============= */
/* launch writer */
/* ============= */
/* this process continues to launch the writer */
#ifdef DEBUG
HDprintf("%d: continue as the writer process\n", mypid);
#endif
if (write_wo_file() < 0) {
HDfprintf(stderr, "write_wo_file encountered error\n");
Hgoto_error(1);
}
/* ================================================ */
/* If readwrite, collect exit code of child process */
/* ================================================ */
if (launch_g == UC_READWRITE) {
if ((tmppid = HDwaitpid(childpid, &child_status, child_wait_option)) < 0) {
HDperror("waitpid");
Hgoto_error(1);
}
if (WIFEXITED(child_status)) {
if ((child_ret_value = WEXITSTATUS(child_status)) != 0) {
HDprintf("%d: child process exited with non-zero code (%d)\n", mypid, child_ret_value);
Hgoto_error(2);
}
}
else {
HDprintf("%d: child process terminated abnormally\n", mypid);
Hgoto_error(2);
}
}
done:
/* Print result and exit */
if (ret_value != 0) {
HDprintf("Error(s) encountered\n");
}
else {
HDprintf("All passed\n");
}
return ret_value;
}
#else /* defined(H5_HAVE_FORK && defined(H5_HAVE_WAITPID) */
int
main(void)
{
HDfprintf(stderr, "Non-POSIX platform. Skipping.\n");
return EXIT_SUCCESS;
} /* end main() */
#endif /* defined(H5_HAVE_FORK && defined(H5_HAVE_WAITPID) */
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