/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * 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. * * help@hdfgroup.org. * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */ /* Programmer: Mike McGreevy * October 7, 2010 */ #include "h5test.h" #define H5F_FRIEND /*suppress error about including H5Fpkg */ #define H5FD_FRIEND /*suppress error about including H5FDpkg */ #define H5FD_TESTING #include "H5Fpkg.h" #include "H5FDpkg.h" #include "H5CXprivate.h" /* API Contexts */ #include "H5Iprivate.h" #include "H5VLprivate.h" /* Virtual Object Layer */ /* Filename */ /* (The file names are the same as the define in accum_swmr_reader.c) */ const char *FILENAME[] = {"accum", "accum_swmr_big", NULL}; /* The reader forked by test_swmr_write_big() */ #define SWMR_READER "accum_swmr_reader" /* "big" I/O test values */ #define BIG_BUF_SIZE (6 * 1024 * 1024) /* Random I/O test values */ #define RANDOM_BUF_SIZE (1 * 1024 * 1024) #define MAX_RANDOM_SEGMENTS (5 * 1024) #define RAND_SEG_LEN (1024) #define RANDOM_BASE_OFF (1024 * 1024) /* Function Prototypes */ unsigned test_write_read(H5F_t *f); unsigned test_write_read_nonacc_front(H5F_t *f); unsigned test_write_read_nonacc_end(H5F_t *f); unsigned test_accum_overlap(H5F_t *f); unsigned test_accum_overlap_clean(H5F_t *f); unsigned test_accum_overlap_size(H5F_t *f); unsigned test_accum_non_overlap_size(H5F_t *f); unsigned test_accum_adjust(H5F_t *f); unsigned test_read_after(H5F_t *f); unsigned test_free(H5F_t *f); unsigned test_big(H5F_t *f); unsigned test_random_write(H5F_t *f); unsigned test_swmr_write_big(hbool_t newest_format); /* Helper Function Prototypes */ void accum_printf(const H5F_t *f); /* Private Test H5Faccum Function Wrappers */ #define accum_write(a, s, b) H5F_block_write(f, H5FD_MEM_DEFAULT, (haddr_t)(a), (size_t)(s), (b)) #define accum_read(a, s, b) H5F_block_read(f, H5FD_MEM_DEFAULT, (haddr_t)(a), (size_t)(s), (b)) #define accum_free(f, a, s) H5F__accum_free(f->shared, H5FD_MEM_DEFAULT, (haddr_t)(a), (hsize_t)(s)) #define accum_flush(f) H5F__accum_flush(f->shared) #define accum_reset(f) H5F__accum_reset(f->shared, TRUE) /* ================= */ /* Main Test Routine */ /* ================= */ /*------------------------------------------------------------------------- * Function: main * * Purpose: Test the metadata accumulator code * * Return: Success: SUCCEED * Failure: FAIL * * Programmer: Mike McGreevy * October 7, 2010 * *------------------------------------------------------------------------- */ int main(void) { unsigned nerrors = 0; /* track errors */ hbool_t api_ctx_pushed = FALSE; /* Whether API context pushed */ hid_t fid = -1; hid_t fapl = -1; /* File access property list */ char filename[1024]; H5F_t *f = NULL; /* File for all tests */ /* Test Setup */ HDputs("Testing the metadata accumulator"); /* File access property list */ h5_reset(); if ((fapl = h5_fileaccess()) < 0) FAIL_STACK_ERROR; h5_fixname(FILENAME[0], fapl, filename, sizeof filename); /* Create a test file */ if ((fid = H5Fcreate(filename, H5F_ACC_TRUNC, H5P_DEFAULT, fapl)) < 0) FAIL_STACK_ERROR; /* Push API context */ if (H5CX_push() < 0) FAIL_STACK_ERROR; api_ctx_pushed = TRUE; /* Get H5F_t * to internal file structure */ if (NULL == (f = (H5F_t *)H5VL_object(fid))) FAIL_STACK_ERROR; /* We'll be writing lots of garbage data, so extend the file a ways. 10MB should do. */ if (H5FD_set_eoa(f->shared->lf, H5FD_MEM_DEFAULT, (haddr_t)(1024 * 1024 * 10)) < 0) FAIL_STACK_ERROR; /* Reset metadata accumulator for the file */ if (accum_reset(f) < 0) FAIL_STACK_ERROR; /* Test Functions */ nerrors += test_write_read(f); nerrors += test_write_read_nonacc_front(f); nerrors += test_write_read_nonacc_end(f); nerrors += test_accum_overlap(f); nerrors += test_accum_overlap_clean(f); nerrors += test_accum_overlap_size(f); nerrors += test_accum_non_overlap_size(f); nerrors += test_accum_adjust(f); nerrors += test_read_after(f); nerrors += test_free(f); nerrors += test_big(f); nerrors += test_random_write(f); /* Pop API context */ if (api_ctx_pushed && H5CX_pop(FALSE) < 0) FAIL_STACK_ERROR; api_ctx_pushed = FALSE; /* End of test code, close and delete file */ if (H5Fclose(fid) < 0) TEST_ERROR; /* This test uses a different file */ nerrors += test_swmr_write_big(TRUE); nerrors += test_swmr_write_big(FALSE); if (nerrors) goto error; HDputs("All metadata accumulator tests passed."); h5_cleanup(FILENAME, fapl); return 0; error: if (api_ctx_pushed) H5CX_pop(FALSE); HDputs("*** TESTS FAILED ***"); return 1; } /* end main() */ /* ============================= */ /* Individual Unit Test Routines */ /* ============================= */ /*------------------------------------------------------------------------- * Function: test_write_read * * Purpose: Simple test to write to then read from metadata accumulator. * * Return: Success: SUCCEED * Failure: FAIL * * Programmer: Mike McGreevy * October 7, 2010 * *------------------------------------------------------------------------- */ unsigned test_write_read(H5F_t *f) { int i = 0; int *write_buf, *read_buf; TESTING("simple write/read to/from metadata accumulator"); /* Allocate buffers */ write_buf = (int *)HDmalloc(1024 * sizeof(int)); HDassert(write_buf); read_buf = (int *)HDcalloc((size_t)1024, sizeof(int)); HDassert(read_buf); /* Fill buffer with data, zero out read buffer */ for (i = 0; i < 1024; i++) write_buf[i] = i + 1; /* Do a simple write/read/verify of data */ /* Write 1KB at Address 0 */ if (accum_write(0, 1024, write_buf) < 0) FAIL_STACK_ERROR; if (accum_read(0, 1024, read_buf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(write_buf, read_buf, (size_t)1024) != 0) TEST_ERROR; if (accum_reset(f) < 0) FAIL_STACK_ERROR; PASSED(); /* Release memory */ HDfree(write_buf); HDfree(read_buf); return 0; error: /* Release memory */ HDfree(write_buf); HDfree(read_buf); return 1; } /* test_write_read */ /*------------------------------------------------------------------------- * Function: test_write_read_nonacc_front * * Purpose: Simple test to write to then read from before metadata accumulator. * * Return: Success: SUCCEED * Failure: FAIL * * Programmer: Allen Byrne * October 8, 2010 * *------------------------------------------------------------------------- */ unsigned test_write_read_nonacc_front(H5F_t *f) { int i = 0; int *write_buf, *read_buf; TESTING("simple write/read to/from before metadata accumulator"); /* Allocate buffers */ write_buf = (int *)HDmalloc(2048 * sizeof(int)); HDassert(write_buf); read_buf = (int *)HDcalloc((size_t)2048, sizeof(int)); HDassert(read_buf); /* Fill buffer with data, zero out read buffer */ for (i = 0; i < 2048; i++) write_buf[i] = i + 1; /* Do a simple write/read/verify of data */ /* Write 1KB at Address 0 */ if (accum_write(0, 1024, write_buf) < 0) FAIL_STACK_ERROR; if (accum_flush(f) < 0) FAIL_STACK_ERROR; if (accum_reset(f) < 0) FAIL_STACK_ERROR; if (accum_write(1024, 1024, write_buf) < 0) FAIL_STACK_ERROR; if (accum_read(0, 1024, read_buf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(write_buf, read_buf, (size_t)1024) != 0) TEST_ERROR; if (accum_reset(f) < 0) FAIL_STACK_ERROR; PASSED(); /* Release memory */ HDfree(write_buf); HDfree(read_buf); return 0; error: /* Release memory */ HDfree(write_buf); HDfree(read_buf); return 1; } /* test_write_read */ /*------------------------------------------------------------------------- * Function: test_write_read_nonacc_end * * Purpose: Simple test to write to then read from after metadata accumulator. * * Return: Success: SUCCEED * Failure: FAIL * * Programmer: Allen Byrne * October 8, 2010 * *------------------------------------------------------------------------- */ unsigned test_write_read_nonacc_end(H5F_t *f) { int i = 0; int *write_buf, *read_buf; TESTING("simple write/read to/from after metadata accumulator"); /* Allocate buffers */ write_buf = (int *)HDmalloc(2048 * sizeof(int)); HDassert(write_buf); read_buf = (int *)HDcalloc((size_t)2048, sizeof(int)); HDassert(read_buf); /* Fill buffer with data, zero out read buffer */ for (i = 0; i < 2048; i++) write_buf[i] = i + 1; /* Do a simple write/read/verify of data */ /* Write 1KB at Address 0 */ if (accum_write(1024, 1024, write_buf) < 0) FAIL_STACK_ERROR; if (accum_flush(f) < 0) FAIL_STACK_ERROR; if (accum_reset(f) < 0) FAIL_STACK_ERROR; if (accum_write(0, 1024, write_buf) < 0) FAIL_STACK_ERROR; if (accum_read(1024, 1024, read_buf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(write_buf, read_buf, (size_t)1024) != 0) TEST_ERROR; if (accum_reset(f) < 0) FAIL_STACK_ERROR; PASSED(); /* Release memory */ HDfree(write_buf); HDfree(read_buf); return 0; error: /* Release memory */ HDfree(write_buf); HDfree(read_buf); return 1; } /* test_write_read */ /*------------------------------------------------------------------------- * Function: test_free * * Purpose: Simple test to free metadata accumulator. * * Return: Success: SUCCEED * Failure: FAIL * * Programmer: Raymond Lu * October 8, 2010 * *------------------------------------------------------------------------- */ unsigned test_free(H5F_t *f) { int i = 0; int32_t *wbuf = NULL; int32_t *rbuf = NULL; int32_t *expect = NULL; TESTING("simple freeing metadata accumulator"); /* Write and free the whole accumulator. */ wbuf = (int32_t *)HDmalloc(256 * sizeof(int32_t)); HDassert(wbuf); rbuf = (int32_t *)HDmalloc(256 * sizeof(int32_t)); HDassert(rbuf); expect = (int32_t *)HDmalloc(256 * sizeof(int32_t)); HDassert(expect); /* Fill buffer with data */ for (i = 0; i < 256; i++) wbuf[i] = (int32_t)(i + 1); if (accum_write(0, 256 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; if (accum_free(f, 0, 256 * sizeof(int32_t)) < 0) FAIL_STACK_ERROR; /* Free an empty accumulator */ if (accum_free(f, 0, 256 * 1024 * sizeof(int32_t)) < 0) FAIL_STACK_ERROR; /* Write second quarter of the accumulator */ if (accum_write(64 * sizeof(int32_t), 64 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; /* Free the second quarter of the accumulator, the requested area * is bigger than the data region on the right side. */ if (accum_free(f, 64 * sizeof(int32_t), 65 * sizeof(int32_t)) < 0) FAIL_STACK_ERROR; /* Write half of the accumulator. */ if (accum_write(0, 128 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; /* Free the first block of 4B */ if (accum_free(f, 0, sizeof(int32_t)) < 0) FAIL_STACK_ERROR; /* Check that the accumulator still contains the correct data */ if (accum_read(1 * sizeof(int32_t), 127 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf + 1, rbuf, 127 * sizeof(int32_t)) != 0) TEST_ERROR; /* Free the block of 4B at 127*4B */ if (accum_free(f, 127 * sizeof(int32_t), sizeof(int32_t)) < 0) FAIL_STACK_ERROR; /* Check that the accumulator still contains the correct data */ if (accum_read(1 * sizeof(int32_t), 126 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf + 1, rbuf, 126 * sizeof(int32_t)) != 0) TEST_ERROR; /* Free the block of 4B at 2*4B */ if (accum_free(f, 2 * sizeof(int32_t), sizeof(int32_t)) < 0) FAIL_STACK_ERROR; /* Check that the accumulator still contains the correct data */ if (accum_read(1 * sizeof(int32_t), 1 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf + 1, rbuf, 1 * sizeof(int32_t)) != 0) TEST_ERROR; if (accum_read(3 * sizeof(int32_t), 124 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf + 3, rbuf, 124 * sizeof(int32_t)) != 0) TEST_ERROR; /* Test freeing section that overlaps the start of the accumulator and is * entirely before dirty section */ if (accum_write(64 * sizeof(int32_t), 128 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; HDmemcpy(expect + 64, wbuf, 128 * sizeof(int32_t)); if (accum_flush(f) < 0) FAIL_STACK_ERROR; if (accum_write(68 * sizeof(int32_t), 4 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; HDmemcpy(expect + 68, wbuf, 4 * sizeof(int32_t)); if (accum_free(f, 62 * sizeof(int32_t), 4 * sizeof(int32_t)) < 0) FAIL_STACK_ERROR; /* Check that the accumulator still contains the correct data */ if (accum_read(66 * sizeof(int32_t), 126 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(expect + 66, rbuf, 126 * sizeof(int32_t)) != 0) TEST_ERROR; /* Test freeing section that overlaps the start of the accumulator and * completely contains dirty section */ if (accum_write(64 * sizeof(int32_t), 128 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; HDmemcpy(expect + 64, wbuf, 128 * sizeof(int32_t)); if (accum_flush(f) < 0) FAIL_STACK_ERROR; if (accum_write(68 * sizeof(int32_t), 4 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; HDmemcpy(expect + 68, wbuf, 4 * sizeof(int32_t)); if (accum_free(f, 62 * sizeof(int32_t), 16 * sizeof(int32_t)) < 0) FAIL_STACK_ERROR; /* Check that the accumulator still contains the correct data */ if (accum_read(78 * sizeof(int32_t), 114 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(expect + 78, rbuf, 114 * sizeof(int32_t)) != 0) TEST_ERROR; /* Test freeing section completely contained in accumulator and is entirely * before dirty section */ if (accum_write(64 * sizeof(int32_t), 128 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; HDmemcpy(expect + 64, wbuf, 128 * sizeof(int32_t)); if (accum_flush(f) < 0) FAIL_STACK_ERROR; if (accum_write(72 * sizeof(int32_t), 4 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; HDmemcpy(expect + 72, wbuf, 4 * sizeof(int32_t)); if (accum_free(f, 66 * sizeof(int32_t), 4 * sizeof(int32_t)) < 0) FAIL_STACK_ERROR; /* Check that the accumulator still contains the correct data */ if (accum_read(70 * sizeof(int32_t), 122 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(expect + 70, rbuf, 122 * sizeof(int32_t)) != 0) TEST_ERROR; /* Test freeing section completely contained in accumulator, starts before * dirty section, and ends in dirty section */ if (accum_write(64 * sizeof(int32_t), 128 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; HDmemcpy(expect + 64, wbuf, 128 * sizeof(int32_t)); if (accum_flush(f) < 0) FAIL_STACK_ERROR; if (accum_write(72 * sizeof(int32_t), 4 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; HDmemcpy(expect + 72, wbuf, 4 * sizeof(int32_t)); if (accum_free(f, 70 * sizeof(int32_t), 4 * sizeof(int32_t)) < 0) FAIL_STACK_ERROR; /* Check that the accumulator still contains the correct data */ if (accum_read(74 * sizeof(int32_t), 118 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(expect + 74, rbuf, 118 * sizeof(int32_t)) != 0) TEST_ERROR; /* Test freeing section completely contained in accumulator and completely * contains dirty section */ if (accum_write(64 * sizeof(int32_t), 128 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; HDmemcpy(expect + 64, wbuf, 128 * sizeof(int32_t)); if (accum_flush(f) < 0) FAIL_STACK_ERROR; if (accum_write(72 * sizeof(int32_t), 4 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; HDmemcpy(expect + 72, wbuf, 4 * sizeof(int32_t)); if (accum_free(f, 70 * sizeof(int32_t), 8 * sizeof(int32_t)) < 0) FAIL_STACK_ERROR; /* Check that the accumulator still contains the correct data */ if (accum_read(78 * sizeof(int32_t), 114 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(expect + 78, rbuf, 114 * sizeof(int32_t)) != 0) TEST_ERROR; /* Test freeing section completely contained in accumulator, starts at start * of dirty section, and ends in dirty section */ if (accum_write(64 * sizeof(int32_t), 128 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; HDmemcpy(expect + 64, wbuf, 128 * sizeof(int32_t)); if (accum_flush(f) < 0) FAIL_STACK_ERROR; if (accum_write(72 * sizeof(int32_t), 8 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; HDmemcpy(expect + 72, wbuf, 8 * sizeof(int32_t)); if (accum_free(f, 72 * sizeof(int32_t), 4 * sizeof(int32_t)) < 0) FAIL_STACK_ERROR; /* Check that the accumulator still contains the correct data */ if (accum_read(76 * sizeof(int32_t), 116 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(expect + 76, rbuf, 116 * sizeof(int32_t)) != 0) TEST_ERROR; HDfree(wbuf); wbuf = NULL; HDfree(rbuf); rbuf = NULL; HDfree(expect); expect = NULL; if (accum_reset(f) < 0) FAIL_STACK_ERROR; PASSED(); return 0; error: if (wbuf) HDfree(wbuf); if (rbuf) HDfree(rbuf); if (expect) HDfree(expect); return 1; } /* test_free */ /*------------------------------------------------------------------------- * Function: test_accum_overlap * * Purpose: This test will write a series of pieces of data * to the accumulator with the goal of overlapping * the writes in various different ways. * * Return: Success: SUCCEED * Failure: FAIL * * Programmer: Mike McGreevy * October 7, 2010 * *------------------------------------------------------------------------- */ unsigned test_accum_overlap(H5F_t *f) { int i = 0; int32_t *wbuf, *rbuf; TESTING("overlapping write to metadata accumulator"); /* Allocate buffers */ wbuf = (int32_t *)HDmalloc(4096 * sizeof(int32_t)); HDassert(wbuf); rbuf = (int32_t *)HDcalloc((size_t)4096, sizeof(int32_t)); HDassert(rbuf); /* Case 1: No metadata in accumulator */ /* Write 10 1's at address 40 */ /* @0:| 1111111111| */ /* Put some data in the accumulator initially */ for (i = 0; i < 10; i++) wbuf[i] = 1; if (accum_write(40, 10 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; if (accum_read(40, 10 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, 10 * sizeof(int32_t)) != 0) TEST_ERROR; /* Case 2: End of new piece aligns with start of accumulated data */ /* Write 5 2's at address 20 */ /* @0:| 222221111111111| */ for (i = 0; i < 5; i++) wbuf[i] = 2; if (accum_write(20, 5 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; if (accum_read(20, 5 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, 5 * sizeof(int32_t)) != 0) TEST_ERROR; /* Case 3: Start of new piece aligns with start of accumulated data */ /* Write 3 3's at address 20 */ /* @0:| 333221111111111| */ for (i = 0; i < 3; i++) wbuf[i] = 3; if (accum_write(20, 3 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; if (accum_read(20, 3 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, 3 * sizeof(int32_t)) != 0) TEST_ERROR; /* Case 4: New piece overlaps start of accumulated data */ /* Write 5 4's at address 8 */ /* @0:| 444443221111111111| */ for (i = 0; i < 5; i++) wbuf[i] = 4; if (accum_write(8, 5 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; if (accum_read(8, 5 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, 5 * sizeof(int32_t)) != 0) TEST_ERROR; /* Case 5: New piece completely within accumulated data */ /* Write 4 5's at address 48 */ /* @0:| 444443221155551111| */ for (i = 0; i < 4; i++) wbuf[i] = 5; if (accum_write(48, 4 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; if (accum_read(48, 4 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, 4 * sizeof(int32_t)) != 0) TEST_ERROR; /* Case 6: End of new piece aligns with end of accumulated data */ /* Write 3 6's at address 68 */ /* @0:| 444443221155551666| */ for (i = 0; i < 3; i++) wbuf[i] = 6; if (accum_write(68, 3 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; if (accum_read(68, 3 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, 3 * sizeof(int32_t)) != 0) TEST_ERROR; /* Case 7: New piece overlaps end of accumulated data */ /* Write 5 7's at address 76 */ /* @0:| 4444432211555516677777| */ for (i = 0; i < 5; i++) wbuf[i] = 7; if (accum_write(76, 5 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; if (accum_read(76, 5 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, 5 * sizeof(int32_t)) != 0) TEST_ERROR; /* Case 8: Start of new piece aligns with end of accumulated data */ /* Write 3 8's at address 96 */ /* @0:| 4444432211555516677777888| */ for (i = 0; i < 3; i++) wbuf[i] = 8; if (accum_write(96, 3 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; if (accum_read(96, 3 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, 3 * sizeof(int32_t)) != 0) TEST_ERROR; /* Set up expected data buffer and verify contents of accumulator as constructed by cases 1-8, above */ for (i = 0; i < 5; i++) wbuf[i] = 4; for (i = 5; i < 6; i++) wbuf[i] = 3; for (i = 6; i < 8; i++) wbuf[i] = 2; for (i = 8; i < 10; i++) wbuf[i] = 1; for (i = 10; i < 14; i++) wbuf[i] = 5; for (i = 14; i < 15; i++) wbuf[i] = 1; for (i = 15; i < 17; i++) wbuf[i] = 6; for (i = 17; i < 22; i++) wbuf[i] = 7; for (i = 22; i < 25; i++) wbuf[i] = 8; if (accum_read(8, 25 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, 25 * sizeof(int32_t)) != 0) TEST_ERROR; /* Case 9: New piece completely before accumulated data */ /* Write 1 9 at address 0 */ /* @0:|9 4444432211555516677777888| */ for (i = 0; i < 1; i++) wbuf[i] = 9; if (accum_write(0, 1 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; if (accum_read(0, 1 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, 1 * sizeof(int32_t)) != 0) TEST_ERROR; /* Case 10: New piece completely after accumulated data */ /* Write 4 3's at address 116 */ /* @0:|9 4444432211555516677777888 3333| */ for (i = 0; i < 4; i++) wbuf[i] = 3; if (accum_write(116, 4 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; if (accum_read(116, 4 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, 4 * sizeof(int32_t)) != 0) TEST_ERROR; /* Case 11: New piece completely overlaps accumulated data */ /* Write 6 4's at address 112 */ /* @0:|9 4444432211555516677777888 444444| */ for (i = 0; i < 6; i++) wbuf[i] = 4; if (accum_write(112, 6 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; if (accum_read(112, 6 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, 6 * sizeof(int32_t)) != 0) TEST_ERROR; if (accum_reset(f) < 0) FAIL_STACK_ERROR; PASSED(); /* Release memory */ HDfree(wbuf); HDfree(rbuf); return 0; error: /* Release memory */ HDfree(wbuf); HDfree(rbuf); return 1; } /* test_accum_overlap */ /*------------------------------------------------------------------------- * Function: test_accum_overlap_clean * * Purpose: This test will write a series of pieces of data * to the accumulator with the goal of overlapping * the writes in various different ways, with clean * areas in the accumulator. * * Return: Success: SUCCEED * Failure: FAIL * * Programmer: Neil Fortner * October 8, 2010 * *------------------------------------------------------------------------- */ unsigned test_accum_overlap_clean(H5F_t *f) { int i = 0; int32_t *wbuf, *rbuf; TESTING("overlapping write to partially clean metadata accumulator"); /* Allocate buffers */ wbuf = (int32_t *)HDmalloc(4096 * sizeof(int32_t)); HDassert(wbuf); rbuf = (int32_t *)HDcalloc((size_t)4096, sizeof(int32_t)); HDassert(rbuf); /* Case 1: No metadata in accumulator */ /* Write 10 1's at address 40 */ /* @0:| 1111111111| */ /* Put some data in the accumulator initially */ for (i = 0; i < 10; i++) wbuf[i] = 1; if (accum_write(40, 10 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; if (accum_read(40, 10 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, 10 * sizeof(int32_t)) != 0) TEST_ERROR; /* Case 2: End of new piece aligns with start of clean accumulated data */ /* Write 5 2's at address 20 */ /* @0:| 222221111111111| */ if (accum_flush(f) < 0) FAIL_STACK_ERROR; for (i = 0; i < 5; i++) wbuf[i] = 2; if (accum_write(20, 5 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; if (accum_read(20, 5 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, 5 * sizeof(int32_t)) != 0) TEST_ERROR; /* Case 3: Start of new piece aligns with start of accumulated data, * completely encloses dirty section of accumulator */ /* Write 6 3's at address 20 */ /* @0:| 333333111111111| */ for (i = 0; i < 6; i++) wbuf[i] = 3; if (accum_write(20, 6 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; if (accum_read(20, 6 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, 6 * sizeof(int32_t)) != 0) TEST_ERROR; /* Case 4: New piece completely within accumulated data, overlaps * end of dirty section of accumulator */ /* Write 2 4's at address 40 */ /* @0:| 333334411111111| */ for (i = 0; i < 2; i++) wbuf[i] = 4; if (accum_write(40, 2 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; if (accum_read(40, 2 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, 2 * sizeof(int32_t)) != 0) TEST_ERROR; /* Case 5: New piece completely within accumulated data, completely * after dirty section of accumulator */ /* Write 2 5's at address 52 */ /* @0:| 333334415511111| */ for (i = 0; i < 2; i++) wbuf[i] = 5; if (accum_write(52, 2 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; if (accum_read(52, 2 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, 2 * sizeof(int32_t)) != 0) TEST_ERROR; /* Case 6: New piece completely within clean accumulated data */ /* Write 3 6's at address 44 */ /* @0:| 333334666511111| */ if (accum_flush(f) < 0) FAIL_STACK_ERROR; for (i = 0; i < 3; i++) wbuf[i] = 6; if (accum_write(44, 3 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; if (accum_read(44, 3 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, 3 * sizeof(int32_t)) != 0) TEST_ERROR; /* Case 7: New piece overlaps start of clean accumulated data */ /* Write 2 7's at address 16 */ /* @0:| 7733334666511111| */ if (accum_flush(f) < 0) FAIL_STACK_ERROR; for (i = 0; i < 2; i++) wbuf[i] = 7; if (accum_write(16, 2 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; if (accum_read(16, 2 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, 2 * sizeof(int32_t)) != 0) TEST_ERROR; /* Case 8: New piece overlaps start of accumulated data, completely * encloses dirty section of accumulator */ /* Write 4 8's at address 12 */ /* @0:| 88883334666511111| */ for (i = 0; i < 4; i++) wbuf[i] = 8; if (accum_write(12, 4 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; if (accum_read(12, 4 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, 4 * sizeof(int32_t)) != 0) TEST_ERROR; /* Case 9: Start of new piece aligns with end of clean accumulated data */ /* Write 3 9's at address 80 */ /* @0:| 88883334666511111999| */ if (accum_flush(f) < 0) FAIL_STACK_ERROR; for (i = 0; i < 3; i++) wbuf[i] = 9; if (accum_write(80, 3 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; if (accum_read(80, 3 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, 3 * sizeof(int32_t)) != 0) TEST_ERROR; /* Case 10: New piece overlaps end of clean accumulated data */ /* Write 3 2's at address 88 */ /* @0:| 888833346665111119922| */ if (accum_flush(f) < 0) FAIL_STACK_ERROR; for (i = 0; i < 2; i++) wbuf[i] = 2; if (accum_write(88, 2 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; if (accum_read(88, 2 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, 2 * sizeof(int32_t)) != 0) TEST_ERROR; /* Case 11: New piece overlaps end of accumulated data, completely encloses * dirty section of accumulator */ /* Write 4 7's at address 84 */ /* @0:| 8888333466651111197777| */ for (i = 0; i < 4; i++) wbuf[i] = 7; if (accum_write(84, 4 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; if (accum_read(84, 4 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, 4 * sizeof(int32_t)) != 0) TEST_ERROR; /* Set up expected data buffer and verify contents of accumulator as constructed by cases 1-11, above */ for (i = 0; i < 4; i++) wbuf[i] = 8; for (i = 4; i < 7; i++) wbuf[i] = 3; for (i = 7; i < 8; i++) wbuf[i] = 4; for (i = 8; i < 11; i++) wbuf[i] = 6; for (i = 11; i < 12; i++) wbuf[i] = 5; for (i = 12; i < 17; i++) wbuf[i] = 1; for (i = 17; i < 18; i++) wbuf[i] = 9; for (i = 18; i < 22; i++) wbuf[i] = 7; if (accum_read(12, 22 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, 22 * sizeof(int32_t)) != 0) TEST_ERROR; if (accum_reset(f) < 0) FAIL_STACK_ERROR; PASSED(); /* Release memory */ HDfree(wbuf); HDfree(rbuf); return 0; error: /* Release memory */ HDfree(wbuf); HDfree(rbuf); return 1; } /* test_accum_overlap_clean */ /*------------------------------------------------------------------------- * Function: test_accum_non_overlap_size * * Purpose: This test will write a series of pieces of data * to the accumulator with the goal of not overlapping * the writes with a data size larger then the accum size. * * Return: Success: SUCCEED * Failure: FAIL * * Programmer: Allen Byrne * October 8, 2010 * *------------------------------------------------------------------------- */ unsigned test_accum_non_overlap_size(H5F_t *f) { int i = 0; int32_t *wbuf, *rbuf; TESTING("non-overlapping write to accumulator larger then accum_size"); /* Allocate buffers */ wbuf = (int *)HDmalloc(4096 * sizeof(int32_t)); HDassert(wbuf); rbuf = (int *)HDcalloc((size_t)4096, sizeof(int32_t)); HDassert(rbuf); /* Case 1: No metadata in accumulator */ /* Write 10 1's at address 140 */ /* @0:| 1111111111| */ /* Put some data in the accumulator initially */ for (i = 0; i < 10; i++) wbuf[i] = 1; if (accum_write(140, 10 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; if (accum_read(140, 10 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, 10 * sizeof(int32_t)) != 0) TEST_ERROR; /* Case 9: New piece completely before accumulated data */ /* Write 20 9 at address 0 */ /* @0:|9 1111111111| */ for (i = 0; i < 20; i++) wbuf[i] = 9; if (accum_write(0, 20 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; if (accum_read(0, 20 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, 20 * sizeof(int32_t)) != 0) TEST_ERROR; if (accum_reset(f) < 0) FAIL_STACK_ERROR; PASSED(); /* Release memory */ HDfree(wbuf); HDfree(rbuf); return 0; error: /* Release memory */ HDfree(wbuf); HDfree(rbuf); return 1; } /* test_accum_non_overlap_size */ /*------------------------------------------------------------------------- * Function: test_accum_overlap_size * * Purpose: This test will write a series of pieces of data * to the accumulator with the goal of overlapping * the writes with a data size completely overlapping * the accumulator at both ends. * * Return: Success: SUCCEED * Failure: FAIL * * Programmer: Allen Byrne * October 8, 2010 * *------------------------------------------------------------------------- */ unsigned test_accum_overlap_size(H5F_t *f) { int i = 0; int32_t *wbuf, *rbuf; TESTING("overlapping write to accumulator larger then accum_size"); /* Allocate buffers */ wbuf = (int32_t *)HDmalloc(4096 * sizeof(int32_t)); HDassert(wbuf); rbuf = (int32_t *)HDcalloc((size_t)4096, sizeof(int32_t)); HDassert(rbuf); /* Case 1: No metadata in accumulator */ /* Write 10 1's at address 64 */ /* @0:| 1111111111| */ /* Put some data in the accumulator initially */ for (i = 0; i < 10; i++) wbuf[i] = 1; if (accum_write(64, 10 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; if (accum_read(64, 10 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, 10 * sizeof(int32_t)) != 0) TEST_ERROR; /* Case 9: New piece completely before accumulated data */ /* Write 72 9 at address 60 */ /* @0:|9 1111111111| */ for (i = 0; i < 72; i++) wbuf[i] = 9; if (accum_write(60, 72 * sizeof(int32_t), wbuf) < 0) FAIL_STACK_ERROR; if (accum_read(60, 72 * sizeof(int32_t), rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, 72 * sizeof(int32_t)) != 0) TEST_ERROR; if (accum_reset(f) < 0) FAIL_STACK_ERROR; PASSED(); /* Release memory */ HDfree(wbuf); HDfree(rbuf); return 0; error: /* Release memory */ HDfree(wbuf); HDfree(rbuf); return 1; } /* test_accum_overlap_size */ /*------------------------------------------------------------------------- * Function: test_accum_adjust * * Purpose: This test examines the various ways the accumulator might * adjust itself as a result of data appending or prepending * to it. * * This test program covers all the code in H5F_accum_adjust, * but NOT all possible paths through said code. It only covers * six potential paths through the function. (Again, though, each * piece of code within an if/else statement in H5F_accum_adjust is * covered by one of the paths in this test function). Since there * are a ridiculous number of total possible paths through this * function due to its large number of embedded if/else statements, * that's certainly a lot of different test cases to write by hand. * (Though if someone comes across this code and has some free * time, go for it). * * Return: Success: SUCCEED * Failure: FAIL * * Programmer: Mike McGreevy * October 11, 2010 * *------------------------------------------------------------------------- */ unsigned test_accum_adjust(H5F_t *f) { int i = 0; int s = 1048576; /* size of buffer */ int32_t *wbuf, *rbuf; TESTING("accumulator adjustments after append/prepend of data"); /* Allocate buffers */ wbuf = (int32_t *)HDmalloc((size_t)s * sizeof(int32_t)); HDassert(wbuf); rbuf = (int32_t *)HDcalloc((size_t)s, sizeof(int32_t)); HDassert(rbuf); /* Fill up write buffer */ for (i = 0; i < s; i++) wbuf[i] = i + 1; /* ================================================================ */ /* CASE 1: Prepending small block to large, fully dirty accumulator */ /* ================================================================ */ /* Write data to the accumulator to fill it just under 1MB (max size), * but not quite full. This will force the accumulator to, on subsequent * writes, a) have to adjust since it's nearly full, and b) prevent * an increase in size because it's already at it's maximum size */ if (accum_write((1024 * 1024), (1024 * 1024) - 1, wbuf) < 0) FAIL_STACK_ERROR; /* Write a small (1KB) block that prepends to the front of the accumulator. */ /* ==> Accumulator will need more buffer space */ /* ==> Accumulator will try to resize, but see that it's getting too big */ /* ==> Size of new block is less than half maximum size of accumulator */ /* ==> New block is being prepended to accumulator */ /* ==> Accumulator is dirty, it will be flushed. */ /* ==> Dirty region overlaps region to eliminate from accumulator */ if (accum_write((1024 * 1024) - 1024, 1024, wbuf) < 0) FAIL_STACK_ERROR; /* Read back and verify first write */ if (accum_read((1024 * 1024), (1024 * 1024) - 1, rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, (size_t)((1024 * 1024) - 1)) != 0) TEST_ERROR; /* Read back and verify second write */ if (accum_read((1024 * 1024) - 1024, 1024, rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, (size_t)1024) != 0) TEST_ERROR; /* Reset accumulator for next case */ if (accum_reset(f) < 0) FAIL_STACK_ERROR; /* ================================================================ */ /* Case 2: Prepending large block to large, fully dirty accumulator */ /* ================================================================ */ /* Write data to the accumulator to fill it just under 1MB (max size), * but not quite full. This will force the accumulator to, on subsequent * writes, a) have to adjust since it's nearly full, and b) prevent * an increase in size because it's already at it's maximum size */ if (accum_write((1024 * 1024), (1024 * 1024) - 1, wbuf) < 0) FAIL_STACK_ERROR; /* Write a large (just under 1MB) block to the front of the accumulator. */ /* ==> Accumulator will need more buffer space */ /* ==> Accumulator will try to resize, but see that it's getting too big */ /* ==> Size of new block is larger than half maximum size of accumulator */ /* ==> New block is being prepended to accumulator */ /* ==> Accumulator is dirty, it will be flushed. */ /* ==> Dirty region overlaps region to eliminate from accumulator */ if (accum_write(5, (1024 * 1024) - 5, wbuf) < 0) FAIL_STACK_ERROR; /* Read back and verify both pieces of data */ if (accum_read(1048576, 1048575, rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, (size_t)1048576) != 0) TEST_ERROR; if (accum_read(5, 1048571, rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, (size_t)1048571) != 0) TEST_ERROR; /* Reset accumulator for next case */ if (accum_reset(f) < 0) FAIL_STACK_ERROR; /* ========================================================= */ /* Case 3: Appending small block to large, clean accumulator */ /* ========================================================= */ /* Write data to the accumulator to fill it just under 1MB (max size), * but not quite full. This will force the accumulator to, on subsequent * writes, a) have to adjust since it's nearly full, and b) prevent * an increase in size because it's already at it's maximum size */ if (accum_write(0, (1024 * 1024) - 1, wbuf) < 0) FAIL_STACK_ERROR; /* Flush the accumulator -- we want to test the case when accumulator contains clean data */ if (accum_flush(f) < 0) FAIL_STACK_ERROR; /* Write a small (1KB) block to the end of the accumulator */ /* ==> Accumulator will need more buffer space */ /* ==> Accumulator will try to resize, but see that it's getting too big */ /* ==> Size of new block is larger than half maximum size of accumulator */ /* ==> New block being appended to accumulator */ /* ==> Accumulator is NOT dirty */ /* ==> Since we're appending, need to adjust location of accumulator */ if (accum_write((1024 * 1024) - 1, 1024, wbuf) < 0) FAIL_STACK_ERROR; /* Write a piece of metadata outside current accumulator to force write to disk */ if (accum_write(0, 1, wbuf) < 0) FAIL_STACK_ERROR; /* Read in the piece we wrote to disk above, and then verify that the data is as expected */ if (accum_read((1024 * 1024) - 1, 1024, rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, (size_t)1024) != 0) TEST_ERROR; /* Reset accumulator for next case */ if (accum_reset(f) < 0) FAIL_STACK_ERROR; /* ==================================================================== */ /* Case 4: Appending small block to large, partially dirty accumulator, */ /* with existing dirty region NOT aligning with the new block */ /* ==================================================================== */ /* Write data to the accumulator to fill it just under 1MB (max size), * but not quite full. This will force the accumulator to, on subsequent * writes, a) have to adjust since it's nearly full, and b) prevent * an increase in size because it's already at it's maximum size */ if (accum_write(0, (1024 * 1024) - 5, wbuf) < 0) FAIL_STACK_ERROR; /* Flush the accumulator to clean it */ if (accum_flush(f) < 0) FAIL_STACK_ERROR; /* write to part of the accumulator so just the start of it is dirty */ if (accum_write(0, 5, wbuf) < 0) FAIL_STACK_ERROR; /* Write a small (~340KB) piece of data to the other end of the accumulator */ /* ==> Accumulator will need more buffer space */ /* ==> Accumulator will try to resize, but see that it's getting too big */ /* ==> Size of new block is less than than half maximum size of accumulator */ /* ==> New block being appended to accumulator */ /* ==> We can slide the dirty region down, to accommodate the request */ /* ==> Max Buffer Size - (dirty offset + adjust size) >= 2 * size) */ /* ==> Need to adjust location of accumulator while appending */ /* ==> Accumulator will need to be reallocated */ if (accum_write(1048571, 349523, wbuf) < 0) FAIL_STACK_ERROR; /* Write a piece of metadata outside current accumulator to force write to disk */ if (accum_write(1398900, 1, wbuf) < 0) FAIL_STACK_ERROR; /* Read in the piece we wrote to disk above, and then verify that the data is as expected */ if (accum_read(1048571, 349523, rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, (size_t)349523) != 0) TEST_ERROR; /* Reset accumulator for next case */ if (accum_reset(f) < 0) FAIL_STACK_ERROR; /* ==================================================================== */ /* Case 5: Appending small block to large, partially dirty accumulator, */ /* with existing dirty region aligning with new block */ /* ==================================================================== */ /* Write data to the accumulator to fill it just under max size (but not full) */ if (accum_write(0, (1024 * 1024) - 5, wbuf) < 0) FAIL_STACK_ERROR; /* Flush the accumulator to clean it */ if (accum_flush(f) < 0) FAIL_STACK_ERROR; /* write to part of the accumulator so it's dirty, but not entirely dirty */ /* (just the begging few bytes will be clean) */ if (accum_write(10, (1024 * 1024) - 15, wbuf) < 0) FAIL_STACK_ERROR; /* Write a small piece of data to the dirty end of the accumulator */ /* ==> Accumulator will need more buffer space */ /* ==> Accumulator will try to resize, but see that it's getting too big */ /* ==> Size of new block is less than than half maximum size of accumulator */ /* ==> New block being appended to accumulator */ /* ==> We can slide the dirty region down, to accommodate the request */ /* ==> Max Buffer Size - (dirty offset + adjust size) < 2 * size) */ /* ==> Need to adjust location of accumulator while appending */ if (accum_write((1024 * 1024) - 5, 10, wbuf) < 0) FAIL_STACK_ERROR; /* Write a piece of metadata outside current accumulator to force write to disk */ if (accum_write(0, 1, wbuf) < 0) FAIL_STACK_ERROR; /* Read in the piece we wrote to disk above, and then verify that the data is as expected */ if (accum_read((1024 * 1024) - 5, 10, rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, (size_t)10) != 0) TEST_ERROR; /* Reset accumulator for next case */ if (accum_reset(f) < 0) FAIL_STACK_ERROR; /* ================================================================= */ /* Case 6: Appending small block to large, fully dirty accumulator */ /* ================================================================= */ /* Write data to the accumulator to fill it just under 1MB (max size), * but not quite full. This will force the accumulator to, on subsequent * writes, a) have to adjust since it's nearly full, and b) prevent * an increase in size because it's already at it's maximum size */ if (accum_write(0, (1024 * 1024) - 5, wbuf) < 0) FAIL_STACK_ERROR; /* Write a small (~340KB) piece of data to the end of the accumulator */ /* ==> Accumulator will need more buffer space */ /* ==> Accumulator will try to resize, but see that it's getting too big */ /* ==> Size of new block is less than than half maximum size of accumulator */ /* ==> New block being appended to accumulator */ /* ==> We cannot slide dirty region down, it's all dirty */ /* ==> Dirty region overlaps region to eliminate from accumulator */ /* ==> Need to adjust location of accumulator while appending */ if (accum_write(1048571, 349523, wbuf) < 0) FAIL_STACK_ERROR; /* Write a piece of metadata outside current accumulator to force write to disk */ if (accum_write(1398900, 1, wbuf) < 0) FAIL_STACK_ERROR; /* Read in the piece we wrote to disk above, and then verify that the data is as expected */ if (accum_read(1048571, 349523, rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, (size_t)349523) != 0) TEST_ERROR; if (accum_reset(f) < 0) FAIL_STACK_ERROR; PASSED(); /* Release memory */ HDfree(wbuf); HDfree(rbuf); return 0; error: /* Release memory */ HDfree(wbuf); HDfree(rbuf); return 1; } /* test_accum_adjust */ /*------------------------------------------------------------------------- * Function: test_read_after * * Purpose: This test will verify the case when metadata is read partly * from the accumulator and partly from disk. The test will * write a block of data at address 512, force the data to be * written to disk, write new data partially overlapping the * original block from below, then read data at address 512. * The data read should be partly new and partly original. * * Return: Success: SUCCEED * Failure: FAIL * * Programmer: Larry Knox * October 8, 2010 * *------------------------------------------------------------------------- */ unsigned test_read_after(H5F_t *f) { int i = 0; int s = 128; /* size of buffer */ int32_t *wbuf, *rbuf; TESTING("reading data from both accumulator and disk"); /* Allocate buffers */ wbuf = (int32_t *)HDmalloc((size_t)s * sizeof(int32_t)); HDassert(wbuf); rbuf = (int32_t *)HDcalloc((size_t)s, sizeof(int32_t)); HDassert(rbuf); /* Fill up write buffer with 1s */ for (i = 0; i < s; i++) wbuf[i] = 1; /* Write data to the accumulator to fill it. */ if (accum_write(512, 512, wbuf) < 0) FAIL_STACK_ERROR; /* Write a piece of metadata outside current accumulator to force write to disk */ if (accum_write(0, 1, wbuf) < 0) FAIL_STACK_ERROR; /* Fill up write buffer with 2s */ for (i = 0; i < s; i++) wbuf[i] = 2; /* Write a block of 2s of the original size that will overlap the lower half of the original block */ if (accum_write(256, 512, wbuf) < 0) FAIL_STACK_ERROR; /* Read 128 bytes at the original address, and then */ if (accum_read(512, 512, rbuf) < 0) FAIL_STACK_ERROR; /* Set the second half of wbuf back to 1s */ for (i = 64; i < s; i++) wbuf[i] = 1; /* Read in the piece we wrote to disk above, and then verify that the data is as expected */ if (accum_read(512, 512, rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf, rbuf, (size_t)128) != 0) TEST_ERROR; if (accum_reset(f) < 0) FAIL_STACK_ERROR; PASSED(); /* Release memory */ HDfree(wbuf); HDfree(rbuf); return 0; error: /* Release memory */ HDfree(wbuf); HDfree(rbuf); return 1; } /* end test_read_after */ /*------------------------------------------------------------------------- * Function: test_big * * Purpose: This test exercises writing large pieces of metadata to the * file. * * Return: Success: SUCCEED * Failure: FAIL * * Programmer: Quincey Koziol * October 12, 2010 * *------------------------------------------------------------------------- */ unsigned test_big(H5F_t *f) { uint8_t *wbuf, *wbuf2, *rbuf, *zbuf; /* Buffers for reading & writing, etc */ unsigned u; /* Local index variable */ /* Allocate space for the write & read buffers */ wbuf = (uint8_t *)HDmalloc((size_t)BIG_BUF_SIZE); HDassert(wbuf); wbuf2 = (uint8_t *)HDmalloc((size_t)BIG_BUF_SIZE); HDassert(wbuf2); rbuf = (uint8_t *)HDcalloc((size_t)(BIG_BUF_SIZE + 1536), (size_t)1); HDassert(rbuf); zbuf = (uint8_t *)HDcalloc((size_t)(BIG_BUF_SIZE + 1536), (size_t)1); HDassert(zbuf); /* Initialize write buffers */ for (u = 0; u < BIG_BUF_SIZE; u++) { wbuf[u] = (uint8_t)u; wbuf2[u] = (uint8_t)(u + 1); } /* end for */ TESTING("large metadata I/O operations"); /* Write large data segment to file */ if (accum_write(0, BIG_BUF_SIZE, wbuf) < 0) FAIL_STACK_ERROR; /* Read entire segment back from file */ if (accum_read(0, BIG_BUF_SIZE, rbuf) < 0) FAIL_STACK_ERROR; /* Verify data read */ if (HDmemcmp(wbuf, rbuf, (size_t)BIG_BUF_SIZE) != 0) TEST_ERROR; /* Reset data in file back to zeros & reset the read buffer */ if (accum_write(0, BIG_BUF_SIZE, zbuf) < 0) FAIL_STACK_ERROR; HDmemset(rbuf, 0, (size_t)BIG_BUF_SIZE); if (accum_reset(f) < 0) FAIL_STACK_ERROR; /* Write small section to middle of accumulator */ if (accum_write(1024, 1024, wbuf) < 0) FAIL_STACK_ERROR; /* Read entire segment back from file */ /* (Read covers entire dirty region) */ if (accum_read(0, BIG_BUF_SIZE, rbuf) < 0) FAIL_STACK_ERROR; /* Verify data read */ if (HDmemcmp(zbuf, rbuf, (size_t)1024) != 0) TEST_ERROR; if (HDmemcmp(wbuf, rbuf + 1024, (size_t)1024) != 0) TEST_ERROR; if (HDmemcmp(zbuf, rbuf + 2048, (size_t)(BIG_BUF_SIZE - 2048)) != 0) TEST_ERROR; /* Reset data in file back to zeros & reset the read buffer */ if (accum_write(1024, 1024, zbuf) < 0) FAIL_STACK_ERROR; HDmemset(rbuf, 0, (size_t)BIG_BUF_SIZE); if (accum_reset(f) < 0) FAIL_STACK_ERROR; /* Write small section to overlap with end of "big" region */ if (accum_write(BIG_BUF_SIZE - 512, 1024, wbuf) < 0) FAIL_STACK_ERROR; /* Read entire segment back from file */ /* (Read covers bottom half of dirty region) */ if (accum_read(0, BIG_BUF_SIZE, rbuf) < 0) FAIL_STACK_ERROR; /* Verify data read */ if (HDmemcmp(zbuf, rbuf, (size_t)(BIG_BUF_SIZE - 512)) != 0) TEST_ERROR; if (HDmemcmp(wbuf, rbuf + (BIG_BUF_SIZE - 512), (size_t)512) != 0) TEST_ERROR; /* Reset data in file back to zeros & reset the read buffer */ if (accum_write(BIG_BUF_SIZE - 512, 1024, zbuf) < 0) FAIL_STACK_ERROR; HDmemset(rbuf, 0, (size_t)BIG_BUF_SIZE); if (accum_reset(f) < 0) FAIL_STACK_ERROR; /* Write small section to overlap with beginning of "big" region */ if (accum_write(0, 1024, wbuf) < 0) FAIL_STACK_ERROR; /* Read entire segment back from file */ /* (Read covers bottom half of dirty region) */ if (accum_read(512, BIG_BUF_SIZE, rbuf) < 0) FAIL_STACK_ERROR; /* Verify data read */ if (HDmemcmp(wbuf + 512, rbuf, (size_t)512) != 0) TEST_ERROR; if (HDmemcmp(zbuf, rbuf + 512, (size_t)(BIG_BUF_SIZE - 512)) != 0) TEST_ERROR; /* Reset data in file back to zeros & reset the read buffer */ if (accum_write(0, 1024, zbuf) < 0) FAIL_STACK_ERROR; HDmemset(rbuf, 0, (size_t)BIG_BUF_SIZE); if (accum_reset(f) < 0) FAIL_STACK_ERROR; /* Write small section to middle of accumulator */ /* (With write buffer #1) */ if (accum_write(1024, 1024, wbuf) < 0) FAIL_STACK_ERROR; /* Write entire segment to from file */ /* (With write buffer #2) */ /* (Write covers entire dirty region) */ if (accum_write(0, BIG_BUF_SIZE, wbuf2) < 0) FAIL_STACK_ERROR; /* Read entire segment back from file */ if (accum_read(0, BIG_BUF_SIZE, rbuf) < 0) FAIL_STACK_ERROR; /* Verify data read */ if (HDmemcmp(wbuf2, rbuf, (size_t)BIG_BUF_SIZE) != 0) TEST_ERROR; /* Reset data in file back to zeros & reset the read buffer */ if (accum_write(0, BIG_BUF_SIZE, zbuf) < 0) FAIL_STACK_ERROR; HDmemset(rbuf, 0, (size_t)BIG_BUF_SIZE); if (accum_reset(f) < 0) FAIL_STACK_ERROR; /* Write small section to overlap with end of "big" region */ /* (With write buffer #1) */ if (accum_write(BIG_BUF_SIZE - 512, 1024, wbuf) < 0) FAIL_STACK_ERROR; /* Write entire segment to from file */ /* (With write buffer #2) */ /* (Read covers bottom half of dirty region) */ if (accum_write(0, BIG_BUF_SIZE, wbuf2) < 0) FAIL_STACK_ERROR; /* Read both segments back from file */ if (accum_read(0, BIG_BUF_SIZE + 512, rbuf) < 0) FAIL_STACK_ERROR; /* Verify data read */ if (HDmemcmp(wbuf2, rbuf, (size_t)BIG_BUF_SIZE) != 0) TEST_ERROR; if (HDmemcmp(wbuf + 512, rbuf + BIG_BUF_SIZE, (size_t)512) != 0) TEST_ERROR; /* Reset data in file back to zeros & reset the read buffer */ if (accum_write(0, BIG_BUF_SIZE + 512, zbuf) < 0) FAIL_STACK_ERROR; HDmemset(rbuf, 0, (size_t)(BIG_BUF_SIZE + 512)); if (accum_reset(f) < 0) FAIL_STACK_ERROR; /* Write small section to be past "big" region */ /* (With write buffer #1) */ if (accum_write(BIG_BUF_SIZE + 512, 1024, wbuf) < 0) FAIL_STACK_ERROR; /* Read section before "big" region */ /* (To enlarge accumulator, to it will intersect with big write) */ if (accum_read(BIG_BUF_SIZE - 512, 1024, rbuf) < 0) FAIL_STACK_ERROR; /* Write entire segment to from file */ /* (With write buffer #2) */ /* (Doesn't overlap with small section) */ if (accum_write(0, BIG_BUF_SIZE, wbuf2) < 0) FAIL_STACK_ERROR; /* Read both segments & gap back from file */ if (accum_read(0, BIG_BUF_SIZE + 1024, rbuf) < 0) FAIL_STACK_ERROR; /* Verify data read */ if (HDmemcmp(wbuf2, rbuf, (size_t)BIG_BUF_SIZE) != 0) TEST_ERROR; if (HDmemcmp(zbuf, rbuf + BIG_BUF_SIZE, (size_t)512) != 0) TEST_ERROR; if (HDmemcmp(wbuf, rbuf + BIG_BUF_SIZE + 512, (size_t)512) != 0) TEST_ERROR; /* Reset data in file back to zeros & reset the read buffer */ if (accum_write(0, BIG_BUF_SIZE + 1536, zbuf) < 0) FAIL_STACK_ERROR; HDmemset(rbuf, 0, (size_t)(BIG_BUF_SIZE + 1024)); if (accum_reset(f) < 0) FAIL_STACK_ERROR; /* Write small section to be past "big" region */ /* (With write buffer #1) */ if (accum_write(BIG_BUF_SIZE + 512, 1024, wbuf) < 0) FAIL_STACK_ERROR; /* Read section before "big" region */ /* (To enlarge accumulator, so it will intersect with big write) */ if (accum_read(BIG_BUF_SIZE - 512, 1024, rbuf) < 0) FAIL_STACK_ERROR; if (accum_read(BIG_BUF_SIZE + 1536, 1024, rbuf) < 0) FAIL_STACK_ERROR; /* Write entire segment to from file */ /* (With write buffer #2) */ /* (Overwriting dirty region, but not invalidating entire accumulator) */ if (accum_write(1536, BIG_BUF_SIZE, wbuf2) < 0) FAIL_STACK_ERROR; /* Read both segments & gap back from file */ if (accum_read(0, BIG_BUF_SIZE + 1536, rbuf) < 0) FAIL_STACK_ERROR; /* Verify data read */ if (HDmemcmp(zbuf, rbuf, (size_t)1536) != 0) TEST_ERROR; if (HDmemcmp(wbuf2, rbuf + 1536, (size_t)BIG_BUF_SIZE) != 0) TEST_ERROR; /* Reset data in file back to zeros & reset the read buffer */ if (accum_write(1536, BIG_BUF_SIZE, zbuf) < 0) FAIL_STACK_ERROR; HDmemset(rbuf, 0, (size_t)(BIG_BUF_SIZE + 1536)); if (accum_reset(f) < 0) FAIL_STACK_ERROR; /* Write small section before "big" region */ /* (With write buffer #1) */ if (accum_write(1024, 1024, wbuf) < 0) FAIL_STACK_ERROR; /* Read section before "big" region */ /* (To enlarge accumulator, so it will intersect with big write) */ if (accum_read(0, 1024, rbuf) < 0) FAIL_STACK_ERROR; /* Write entire segment to from file */ /* (With write buffer #2) */ /* (Overwriting dirty region, but not invalidating entire accumulator) */ if (accum_write(512, BIG_BUF_SIZE, wbuf2) < 0) FAIL_STACK_ERROR; /* Read both segments & gap back from file */ if (accum_read(0, BIG_BUF_SIZE + 512, rbuf) < 0) FAIL_STACK_ERROR; /* Verify data read */ if (HDmemcmp(zbuf, rbuf, (size_t)512) != 0) TEST_ERROR; if (HDmemcmp(wbuf2, rbuf + 512, (size_t)BIG_BUF_SIZE) != 0) TEST_ERROR; /* Reset data in file back to zeros & reset the read buffer */ if (accum_write(512, BIG_BUF_SIZE, zbuf) < 0) FAIL_STACK_ERROR; HDmemset(rbuf, 0, (size_t)(BIG_BUF_SIZE + 512)); if (accum_reset(f) < 0) FAIL_STACK_ERROR; /* Write small section before "big" region */ /* (With write buffer #1) */ if (accum_write(0, 1024, wbuf) < 0) FAIL_STACK_ERROR; /* Read section before "big" region */ /* (To enlarge accumulator, so it will intersect with big write) */ if (accum_read(1024, 1024, rbuf) < 0) FAIL_STACK_ERROR; /* Write entire segment to from file */ /* (With write buffer #2) */ /* (Avoiding dirty region, and not invalidating entire accumulator) */ if (accum_write(1536, BIG_BUF_SIZE, wbuf2) < 0) FAIL_STACK_ERROR; /* Read both segments & gap back from file */ if (accum_read(0, BIG_BUF_SIZE + 1536, rbuf) < 0) FAIL_STACK_ERROR; /* Verify data read */ if (HDmemcmp(wbuf, rbuf, (size_t)1024) != 0) TEST_ERROR; if (HDmemcmp(zbuf, rbuf + 1024, (size_t)512) != 0) TEST_ERROR; if (HDmemcmp(wbuf2, rbuf + 1536, (size_t)BIG_BUF_SIZE) != 0) TEST_ERROR; /* Reset data in file back to zeros & reset the read buffer */ if (accum_write(0, BIG_BUF_SIZE + 1536, zbuf) < 0) FAIL_STACK_ERROR; HDmemset(rbuf, 0, (size_t)(BIG_BUF_SIZE + 1536)); if (accum_reset(f) < 0) FAIL_STACK_ERROR; /* Write small section before "big" region */ /* (With write buffer #1) */ if (accum_write(0, 1024, wbuf) < 0) FAIL_STACK_ERROR; /* Read section before "big" region */ /* (To enlarge accumulator, so it will intersect with big write) */ if (accum_read(1024, 1024, rbuf) < 0) FAIL_STACK_ERROR; /* Write entire segment to from file */ /* (With write buffer #2) */ /* (Partially overwriting dirty region, and not invalidating entire accumulator) */ if (accum_write(512, BIG_BUF_SIZE, wbuf2) < 0) FAIL_STACK_ERROR; /* Read both segments back from file */ if (accum_read(0, BIG_BUF_SIZE + 512, rbuf) < 0) FAIL_STACK_ERROR; /* Verify data read */ if (HDmemcmp(wbuf, rbuf, (size_t)512) != 0) TEST_ERROR; if (HDmemcmp(wbuf2, rbuf + 512, (size_t)BIG_BUF_SIZE) != 0) TEST_ERROR; if (accum_reset(f) < 0) FAIL_STACK_ERROR; PASSED(); /* Release memory */ HDfree(wbuf); HDfree(wbuf2); HDfree(rbuf); HDfree(zbuf); return 0; error: HDfree(wbuf); HDfree(wbuf2); HDfree(rbuf); HDfree(zbuf); return 1; } /* end test_big() */ /*------------------------------------------------------------------------- * Function: test_random_write * * Purpose: This test writes random pieces of data to the file and * then reads it all back. * * Return: Success: SUCCEED * Failure: FAIL * * Programmer: Quincey Koziol * October 11, 2010 * *------------------------------------------------------------------------- */ unsigned test_random_write(H5F_t *f) { uint8_t *wbuf, *rbuf; /* Buffers for reading & writing */ unsigned seed = 0; /* Random # seed */ size_t *off; /* Offset of buffer segments to write */ size_t *len; /* Size of buffer segments to write */ size_t cur_off; /* Current offset */ size_t nsegments; /* Number of segments to write */ size_t swap; /* Position to swap with */ unsigned u; /* Local index variable */ /* Allocate space for the write & read buffers */ wbuf = (uint8_t *)HDmalloc((size_t)RANDOM_BUF_SIZE); HDassert(wbuf); rbuf = (uint8_t *)HDcalloc((size_t)RANDOM_BUF_SIZE, (size_t)1); HDassert(rbuf); /* Initialize write buffer */ for (u = 0; u < RANDOM_BUF_SIZE; u++) wbuf[u] = (uint8_t)u; TESTING("random writes to accumulator"); /* Choose random # seed */ seed = (unsigned)HDtime(NULL); #if 0 /* seed = (unsigned)1155438845; */ HDfprintf(stderr, "Random # seed was: %u\n", seed); #endif HDsrandom(seed); /* Allocate space for the segment length buffer */ off = (size_t *)HDmalloc(MAX_RANDOM_SEGMENTS * sizeof(size_t)); HDassert(off); len = (size_t *)HDmalloc(MAX_RANDOM_SEGMENTS * sizeof(size_t)); HDassert(len); /* Randomly choose lengths of segments */ cur_off = 0; for (u = 0; u < MAX_RANDOM_SEGMENTS;) { size_t length = 0; /* Length of current segment */ /* Choose random length of segment, allowing for variance */ do { length += (size_t)(HDrandom() % RAND_SEG_LEN) + 1; } while ((HDrandom() & 256) >= 128); /* end while */ /* Check for going off end of buffer */ if ((cur_off + length) > RANDOM_BUF_SIZE) length = RANDOM_BUF_SIZE - cur_off; /* Set offset & length of segment */ off[u] = cur_off; len[u] = length; /* Advance array offset */ u++; /* Advance current offset */ cur_off += length; /* If we've used up entire buffer before hitting limit of segments, get out */ if (cur_off >= RANDOM_BUF_SIZE) break; } /* end for */ nsegments = u; /* Increase length of last segment, if it doesn't reach end of buffer */ if (nsegments < MAX_RANDOM_SEGMENTS) len[nsegments - 1] = RANDOM_BUF_SIZE - off[nsegments - 1]; /* Shuffle order of segments, to randomize positions to write */ for (u = 0; u < nsegments; u++) { size_t tmp; /* Temporary holder for offset & length values */ /* Choose value within next few elements to to swap with */ swap = ((size_t)HDrandom() % 8) + u; if (swap >= nsegments) swap = nsegments - 1; /* Swap values */ tmp = off[u]; off[u] = off[swap]; off[swap] = tmp; tmp = len[u]; len[u] = len[swap]; len[swap] = tmp; } /* end for */ /* Write data segments to file */ for (u = 0; u < nsegments; u++) { if (accum_write(RANDOM_BASE_OFF + off[u], len[u], wbuf + off[u]) < 0) FAIL_STACK_ERROR; /* Verify individual reads */ if (accum_read(RANDOM_BASE_OFF + off[u], len[u], rbuf) < 0) FAIL_STACK_ERROR; if (HDmemcmp(wbuf + off[u], rbuf, len[u]) != 0) TEST_ERROR; } /* end for */ /* Read entire region back from file */ if (accum_read(RANDOM_BASE_OFF, RANDOM_BUF_SIZE, rbuf) < 0) FAIL_STACK_ERROR; /* Verify data read back in */ if (HDmemcmp(wbuf, rbuf, (size_t)RANDOM_BUF_SIZE) != 0) TEST_ERROR; if (accum_reset(f) < 0) FAIL_STACK_ERROR; PASSED(); /* Release memory */ HDfree(wbuf); HDfree(rbuf); HDfree(off); HDfree(len); return 0; error: /* Release memory */ HDfree(wbuf); HDfree(rbuf); HDfree(off); HDfree(len); HDfprintf(stderr, "Random # seed was: %u\n", seed); return 1; } /* end test_random_write() */ /*------------------------------------------------------------------------- * Function: test_swmr_write_big * * Purpose: A SWMR test: verifies that writing "large" metadata to a file * opened with SWMR_WRITE will flush the existing metadata in the * accumulator to disk first before writing the "large" metadata * to disk. * * This test will fork and exec a reader "accum_swmr_reader" which * opens the same file with SWMR_READ and verifies that the correct * metadata is read from disk. * * Return: Success: 0 * Failure: 1 * * Programmer: Vailin Choi; April 2013 * *------------------------------------------------------------------------- */ unsigned test_swmr_write_big(hbool_t newest_format) { hid_t fid = -1; /* File ID */ hid_t fapl = -1; /* File access property list */ H5F_t *rf = NULL; /* File pointer */ char filename[1024]; uint8_t *wbuf2 = NULL, *rbuf = NULL; /* Buffers for reading & writing */ uint8_t wbuf[1024]; /* Buffer for reading & writing */ unsigned u; /* Local index variable */ hbool_t process_success = FALSE; char *driver = NULL; /* VFD string (from env variable) */ hbool_t api_ctx_pushed = FALSE; /* Whether API context pushed */ if (newest_format) TESTING("SWMR write of large metadata: with latest format"); else TESTING("SWMR write of large metadata: with non-latest-format"); #if !defined(H5_HAVE_UNISTD_H) && !defined(H5_HAVE_WIN32_API) /* Not a Windows or POSIX system */ SKIPPED(); HDputs(" Test skipped: Not a Windows or POSIX system."); return 0; #else /* Skip this test if SWMR I/O is not supported for the VFD specified * by the environment variable. */ driver = HDgetenv(HDF5_DRIVER); if (!H5FD__supports_swmr_test(driver)) { SKIPPED(); HDputs(" Test skipped due to VFD not supporting SWMR I/O."); return 0; } /* File access property list */ if ((fapl = h5_fileaccess()) < 0) FAIL_STACK_ERROR; h5_fixname(FILENAME[1], fapl, filename, sizeof filename); /* Both cases will result in v3 superblock and version 2 object header for SWMR */ if (newest_format) { /* latest format */ if (H5Pset_libver_bounds(fapl, H5F_LIBVER_LATEST, H5F_LIBVER_LATEST) < 0) FAIL_STACK_ERROR; if ((fid = H5Fcreate(filename, H5F_ACC_TRUNC, H5P_DEFAULT, fapl)) < 0) FAIL_STACK_ERROR; } else { /* non-latest-format */ if ((fid = H5Fcreate(filename, H5F_ACC_TRUNC | H5F_ACC_SWMR_WRITE, H5P_DEFAULT, fapl)) < 0) FAIL_STACK_ERROR; } /* end if */ /* Close the file */ if (H5Fclose(fid) < 0) FAIL_STACK_ERROR; /* Open the file with SWMR_WRITE */ if ((fid = H5Fopen(filename, H5F_ACC_RDWR | H5F_ACC_SWMR_WRITE, fapl)) < 0) FAIL_STACK_ERROR; /* Push API context */ if (H5CX_push() < 0) FAIL_STACK_ERROR; api_ctx_pushed = TRUE; /* Get H5F_t * to internal file structure */ if (NULL == (rf = (H5F_t *)H5VL_object(fid))) FAIL_STACK_ERROR; /* We'll be writing lots of garbage data, so extend the file a ways. 10MB should do. */ if (H5FD_set_eoa(rf->shared->lf, H5FD_MEM_DEFAULT, (haddr_t)(1024 * 1024 * 10)) < 0) FAIL_STACK_ERROR; if (H5Fflush(fid, H5F_SCOPE_GLOBAL) < 0) FAIL_STACK_ERROR; /* Reset metadata accumulator for the file */ if (accum_reset(rf) < 0) FAIL_STACK_ERROR; /* Allocate space for the write & read buffers */ if ((wbuf2 = (uint8_t *)HDmalloc((size_t)BIG_BUF_SIZE)) == NULL) FAIL_STACK_ERROR; if ((rbuf = (uint8_t *)HDmalloc((size_t)BIG_BUF_SIZE)) == NULL) FAIL_STACK_ERROR; /* Initialize wbuf with "0, 1, 2...1024"*/ for (u = 0; u < 1024; u++) wbuf[u] = (uint8_t)u; /* Write [1024, 1024] bytes with wbuf */ if (H5F_block_write(rf, H5FD_MEM_DEFAULT, (haddr_t)1024, (size_t)1024, wbuf) < 0) FAIL_STACK_ERROR; /* Read the data */ if (H5F_block_read(rf, H5FD_MEM_DEFAULT, (haddr_t)1024, (size_t)1024, rbuf) < 0) FAIL_STACK_ERROR; /* Verify the data read is correct */ if (HDmemcmp(wbuf, rbuf, (size_t)1024) != 0) TEST_ERROR; /* Flush the data to disk */ if (accum_reset(rf) < 0) FAIL_STACK_ERROR; /* Initialize wbuf with all 1s */ for (u = 0; u < 1024; u++) wbuf[u] = (uint8_t)1; /* Initialize wbuf2 */ for (u = 0; u < BIG_BUF_SIZE; u++) wbuf2[u] = (uint8_t)(u + 1); /* Write [1024,1024] with wbuf--all 1s */ if (H5F_block_write(rf, H5FD_MEM_DEFAULT, (haddr_t)1024, (size_t)1024, wbuf) < 0) FAIL_STACK_ERROR; /* Read the data */ if (H5F_block_read(rf, H5FD_MEM_DEFAULT, (haddr_t)1024, (size_t)1024, rbuf) < 0) FAIL_STACK_ERROR; /* Verify the data read is correct */ if (HDmemcmp(wbuf, rbuf, (size_t)1024) != 0) TEST_ERROR; /* The data stays in the accumulator */ /* Write a large piece of metadata [2048, BIG_BUF_SIZE] with wbuf2 */ if (H5F_block_write(rf, H5FD_MEM_DEFAULT, (haddr_t)2048, (size_t)BIG_BUF_SIZE, wbuf2) < 0) FAIL_STACK_ERROR; /* Read the data */ if (H5F_block_read(rf, H5FD_MEM_DEFAULT, (haddr_t)2048, (size_t)BIG_BUF_SIZE, rbuf) < 0) FAIL_STACK_ERROR; /* Verify the data read is correct */ if (HDmemcmp(wbuf2, rbuf, (size_t)BIG_BUF_SIZE) != 0) TEST_ERROR; #if defined(H5_HAVE_WIN32_API) { STARTUPINFO si; PROCESS_INFORMATION pi; DWORD exit_code = EXIT_FAILURE; ZeroMemory(&si, sizeof(si)); si.cb = sizeof(si); ZeroMemory(&pi, sizeof(pi)); if (0 == CreateProcess(NULL, SWMR_READER, NULL, NULL, FALSE, 0, NULL, NULL, &si, &pi)) { HDprintf("CreateProcess failed (%d).\n", GetLastError()); FAIL_STACK_ERROR; } (void)WaitForSingleObject(pi.hProcess, INFINITE); if (FALSE == GetExitCodeProcess(pi.hProcess, &exit_code) || EXIT_FAILURE == exit_code) process_success = FALSE; else process_success = TRUE; CloseHandle(pi.hProcess); CloseHandle(pi.hThread); } #else /* defined(H5_HAVE_WIN32_API) */ { pid_t pid; /* Process ID */ int status; /* Status returned from child process */ /* Fork child process to verify that the data at [1024, 2014] does get written to disk */ if ((pid = HDfork()) < 0) { HDperror("fork"); FAIL_STACK_ERROR; } else if (0 == pid) { /* Child process */ /* By convention, argv[0] tells the name of program invoked. * * execv on NetBSD 8 will actually return EFAULT if there is a * NULL at argv[0], so we follow the convention unconditionally. */ char swmr_reader[] = SWMR_READER; char *const new_argv[] = {swmr_reader, NULL}; /* Run the reader */ status = HDexecv(SWMR_READER, new_argv); HDprintf("errno from execv = %s\n", HDstrerror(errno)); FAIL_STACK_ERROR; } /* end if */ /* Parent process -- wait for the child process to complete */ while (pid != HDwaitpid(pid, &status, 0)) /*void*/; /* Check if child process terminates normally and its return value */ if (WIFEXITED(status) && !WEXITSTATUS(status)) process_success = TRUE; } #endif /* defined(H5_HAVE_WIN32_API) */ /* Check if the process terminated correctly */ if (!process_success) FAIL_PUTS_ERROR("child process exited abnormally"); /* Flush the accumulator */ if (accum_reset(rf) < 0) FAIL_STACK_ERROR; /* Close and remove the file */ if (H5Fclose(fid) < 0) FAIL_STACK_ERROR; /* Close the property list */ if (H5Pclose(fapl) < 0) FAIL_STACK_ERROR; /* Pop API context */ if (api_ctx_pushed && H5CX_pop(FALSE) < 0) FAIL_STACK_ERROR; api_ctx_pushed = FALSE; /* Release memory */ if (wbuf2) HDfree(wbuf2); if (rbuf) HDfree(rbuf); PASSED(); return 0; error: /* Closing and remove the file */ H5Fclose(fid); if (api_ctx_pushed) H5CX_pop(FALSE); H5Pclose(fapl); /* Release memory */ if (wbuf2) HDfree(wbuf2); if (rbuf) HDfree(rbuf); return 1; #endif /* !defined(H5_HAVE_UNISTD_H) && !defined(H5_HAVE_WIN32_API) */ } /* end test_swmr_write_big() */ /*------------------------------------------------------------------------- * Function: accum_printf * * Purpose: Debug function to print some stats about the accumulator * * Return: Success: SUCCEED * Failure: FAIL * * Programmer: Mike McGreevy * October 7, 2010 * *------------------------------------------------------------------------- */ void accum_printf(const H5F_t *f) { H5F_meta_accum_t *accum = &f->shared->accum; HDprintf("\n"); HDprintf("Current contents of accumulator:\n"); if (accum->alloc_size == 0) { HDprintf("=====================================================\n"); HDprintf(" No accumulator allocated.\n"); HDprintf("=====================================================\n"); } else { HDprintf("=====================================================\n"); HDprintf(" accumulator allocated size == %zu\n", accum->alloc_size); HDprintf(" accumulated data size == %zu\n", accum->size); HDfprintf(stdout, " accumulator dirty? == %s\n", accum->dirty ? "TRUE" : "FALSE"); HDprintf("=====================================================\n"); HDfprintf(stdout, " start of accumulated data, loc = %" PRIuHADDR "\n", accum->loc); if (accum->dirty) { HDfprintf(stdout, " start of dirty region, loc = %" PRIuHADDR "\n", (haddr_t)(accum->loc + accum->dirty_off)); HDfprintf(stdout, " end of dirty region, loc = %" PRIuHADDR "\n", (haddr_t)(accum->loc + accum->dirty_off + accum->dirty_len)); } /* end if */ HDfprintf(stdout, " end of accumulated data, loc = %" PRIuHADDR "\n", (haddr_t)(accum->loc + accum->size)); HDfprintf(stdout, " end of accumulator allocation, loc = %" PRIuHADDR "\n", (haddr_t)(accum->loc + accum->alloc_size)); HDprintf("=====================================================\n"); } HDprintf("\n\n"); } /* accum_printf() */