/*--- This software is copyrighted by the Regents of the University of California, and other parties. The following terms apply to all files associated with the software unless explicitly disclaimed in individual files. The authors hereby grant permission to use, copy, modify, distribute, and license this software and its documentation for any purpose, provided that existing copyright notices are retained in all copies and that this notice is included verbatim in any distributions. No written agreement, license, or royalty fee is required for any of the authorized uses. Modifications to this software may be copyrighted by their authors and need not follow the licensing terms described here, provided that the new terms are clearly indicated on the first page of each file where they apply. IN NO EVENT SHALL THE AUTHORS OR DISTRIBUTORS BE LIABLE TO ANY PARTY FOR DIRECT, INDIRECT, SPECIAL, INCIDENTAL, OR CONSEQUENTIAL DAMAGES ARISING OUT OF THE USE OF THIS SOFTWARE, ITS DOCUMENTATION, OR ANY DERIVATIVES THEREOF, EVEN IF THE AUTHORS HAVE BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. THE AUTHORS AND DISTRIBUTORS SPECIFICALLY DISCLAIM ANY WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE, AND NON-INFRINGEMENT. THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, AND THE AUTHORS AND DISTRIBUTORS HAVE NO OBLIGATION TO PROVIDE MAINTENANCE, SUPPORT, UPDATES, ENHANCEMENTS, OR MODIFICATIONS. GOVERNMENT USE: If you are acquiring this software on behalf of the U.S. government, the Government shall have only "Restricted Rights" in the software and related documentation as defined in the Federal Acquisition Regulations (FARs) in Clause 52.227.19 (c) (2). If you are acquiring the software on behalf of the Department of Defense, the software shall be classified as "Commercial Computer Software" and the Government shall have only "Restricted Rights" as defined in Clause 252.227-7013 (c) (1) of DFARs. Notwithstanding the foregoing, the authors grant the U.S. Government and others acting in its behalf permission to use and distribute the software in accordance with the terms specified in this license. ---*/ #include "../check_includes.h" #include #include #include #include #include #include #include #define LOG_NAME "check_io.log" int handle_truncate_is_supported = 1; void handle_smoketest(stasis_handle_t * h) { const int one = 0x11111111; const int two = 0x22222222; const int three = 0x33333333; const int four = 0x44444444; lsn_t off; h->append(h, &off, 0, 0); assert(off == 0); assert((!h->num_copies(h)) || (!h->num_copies_buffer(h))); assert(0 == h->start_position(h) || 0 == h->end_position(h)); assert(! h->write(h, 0, (byte*)&one, sizeof(int))); int one_read = 0; int ret = h->read(h, 0, (byte*)&one_read, sizeof(int)); assert(!ret); assert(one_read == one); stasis_write_buffer_t * w = h->write_buffer(h, sizeof(int), sizeof(int)); *((int*)(w->buf)) = two; w->h->release_write_buffer(w); one_read = 0; stasis_read_buffer_t * r = h->read_buffer(h, 0, sizeof(int)); one_read = *((int*)(r->buf)); r->h->release_read_buffer(r); assert(one == one_read); int two_read = 0; assert(! h->read(h, sizeof(int), (byte*)&two_read, sizeof(int))); assert(two == two_read); assert(! h->append(h, &off, (byte*)&three, sizeof(int))); w = h->append_buffer(h, sizeof(int)); memcpy(w->buf, &four, sizeof(int)); w->h->release_write_buffer(w); if(handle_truncate_is_supported) { h->truncate_start(h, 2 * sizeof(int)); } int three_read = 0; int four_read = 0; ret = h->read(h, 2*sizeof(int), (byte*)&three_read, sizeof(int)); assert(!ret); r = h->read_buffer(h, 3*sizeof(int), sizeof(int)); memcpy(&four_read, r->buf, sizeof(int)); r->h->release_read_buffer(r); assert(three == three_read); assert(four == four_read); } typedef struct { int * values; int count; stasis_handle_t * h; } thread_arg; #define VALUE_COUNT 100000 #define THREAD_COUNT 100 #define OPS_PER_THREAD 500000 lsn_t trunc_val; pthread_mutex_t trunc_mut = PTHREAD_MUTEX_INITIALIZER; void load_handle(thread_arg* t) { lsn_t * offsets = malloc(t->count * sizeof(lsn_t)); stasis_handle_t * h = t->h; for(int i = 0; i < t->count; i++) { offsets[i] = -1; } for(int i = 0; i < OPS_PER_THREAD; i++) { int val = myrandom(t->count); if(offsets[val] == -1) { // Need to write it somewhere. long choice = myrandom(4); switch(choice) { case 0: { // overwrite old entry with write() long val2 = myrandom(t->count); offsets[val] = offsets[val2]; offsets[val2] = -1; if(offsets[val] != -1) { int ret = h->write(h, offsets[val], (const byte*)&(t->values[val]), sizeof(int)); if(ret) { assert(ret == EDOM); offsets[val] = -1; i--; } } else { i--; } } break; case 1: { // overwrite old entry with write_buffer() long val2 = myrandom(t->count); offsets[val] = offsets[val2]; offsets[val2] = -1; if(offsets[val] != -1) { stasis_write_buffer_t * w = h->write_buffer(h, offsets[val], sizeof(int)); if(!w->error) { *((int*)w->buf) = t->values[val]; assert(w->len == sizeof(int)); assert(w->off == offsets[val]); } else { assert(w->error == EDOM); offsets[val] = -1; i--; } w->h->release_write_buffer(w); } else { i--; } } break; case 2: { // append lsn_t oldend = h->end_position(h); int ret = h->append(h, &(offsets[val]), (const byte*)&(t->values[val]), sizeof(int)); assert(!ret || oldend < h->start_position(h)); } break; case 3: { // append_buffer lsn_t oldend = h->end_position(h); stasis_write_buffer_t * w = h->append_buffer(h, sizeof(int)); if(!w->error) { *((int*)w->buf) = t->values[val]; assert(w->len == sizeof(int)); offsets[val] = w->off; } else { assert(oldend < h->start_position(h)); } w->h->release_write_buffer(w); } break; default: { abort(); } } int check; int ret = h->read(h, offsets[val], (byte*)&check, sizeof(int)); if(!ret) { assert(check == t->values[val]); } } else { // Read the value. long choice = myrandom(2); switch(choice) { case 0: { // read int j = -1; int ret = h->read(h, offsets[val], (byte*)&j, sizeof(int)); if(!ret) { assert(j == t->values[val]); } else { assert(ret == EDOM); assert(h->start_position(h) > offsets[val]); } } break; case 1: { // read_buffer stasis_read_buffer_t * r = h->read_buffer(h, offsets[val], sizeof(int)); if(!r->error) { assert(*(int*)(r->buf) == t->values[val]); assert(r->len == sizeof(int)); r->h->release_read_buffer(r); } else { assert(r->error == EDOM); r->h->release_read_buffer(r); assert(h->start_position(h) > offsets[val]); } } break; default: abort(); }; } // Force 1% of the time. if(!myrandom(100)) { h->force(h); } // Truncate 1% of the time. if(!myrandom(100) && handle_truncate_is_supported) { lsn_t pre_start = h->start_position(h); pthread_mutex_lock(&trunc_mut); lsn_t start = trunc_val; lsn_t stop = start - 100 + myrandom(200); if(stop > trunc_val) { trunc_val = stop; } pthread_mutex_unlock(&trunc_mut); assert(pre_start <= start); int ret = h->truncate_start(h, stop); if(!ret) { lsn_t post_stop = h->start_position(h); assert(stop <= post_stop); } } } free(offsets); } void handle_sequentialtest(stasis_handle_t * h) { time_t seed = time(0); printf("Seed = %ld\n", seed); srandom(seed); int * values = malloc(VALUE_COUNT * sizeof(int)); for(int i = 0; i < VALUE_COUNT; i++) { values[i] = i; } trunc_val = 0; thread_arg arg = { values, VALUE_COUNT, h}; load_handle(&arg); free(values); } void handle_concurrencytest(stasis_handle_t * h) { int vc = myrandom(VALUE_COUNT) + 10; printf("Running concurrency test with %d values", vc); fflush(stdout); int * values = malloc(vc * sizeof(int)); for(int i = 0; i < vc; i++) { values[i] = i; } thread_arg * args = malloc(THREAD_COUNT * sizeof(thread_arg)); pthread_t * threads = malloc(THREAD_COUNT * sizeof(pthread_t)); int val_per_thread = vc / THREAD_COUNT; trunc_val = 0; for(int i = 0; i < THREAD_COUNT; i++) { args[i].values = &(values[i * val_per_thread]); args[i].count = val_per_thread; args[i].h = h; pthread_create(&threads[i], 0, (void*(*)(void*))load_handle, &args[i]); } for(int i = 0; i < THREAD_COUNT; i++) { pthread_join(threads[i], 0); } free(values); free(args); free(threads); } /** @test Check the memory I/O handle. */ START_TEST(io_memoryTest) { printf("io_memoryTest\n"); fflush(stdout); stasis_handle_t * h; h = stasis_handle(open_memory)(0); // h = stasis_handle(open_debug)(h); handle_smoketest(h); h->close(h); h = stasis_handle(open_memory)(0); // h = stasis_handle(open_debug)(h); handle_sequentialtest(h); h->close(h); h = stasis_handle(open_memory)(0); // h = stasis_handle(open_debug)(h); handle_concurrencytest(h); h->close(h); } END_TEST START_TEST(io_fileTest) { printf("io_fileTest\n"); fflush(stdout); stasis_handle_t * h; h = stasis_handle(open_file)(0, "logfile.txt", O_CREAT | O_RDWR, FILE_PERM); // h = stasis_handle(open_debug)(h); handle_smoketest(h); h->close(h); unlink("logfile.txt"); h = stasis_handle(open_file)(0, "logfile.txt", O_CREAT | O_RDWR, FILE_PERM); //h = stasis_handle(open_debug)(h); handle_sequentialtest(h); h->close(h); unlink("logfile.txt"); h = stasis_handle(open_file)(0, "logfile.txt", O_CREAT | O_RDWR, FILE_PERM); //handle_concurrencytest(h); h->close(h); unlink("logfile.txt"); } END_TEST static stasis_handle_t * fast_factory(lsn_t off, lsn_t len, void * ignored) { stasis_handle_t * h = stasis_handle(open_memory)(off); // h = stasis_handle(open_debug)(h); stasis_write_buffer_t * w = h->append_buffer(h, len); w->h->release_write_buffer(w); return h; } START_TEST(io_pfileTest) { printf("io_pfileTest\n"); fflush(stdout); handle_truncate_is_supported = 0; stasis_handle_t * h; h = stasis_handle(open_pfile)(0, "logfile.txt", O_CREAT | O_RDWR, FILE_PERM); // h = stasis_handle(open_debug)(h); handle_smoketest(h); h->close(h); unlink("logfile.txt"); h = stasis_handle(open_pfile)(0, "logfile.txt", O_CREAT | O_RDWR, FILE_PERM); //h = stasis_handle(open_debug)(h); handle_sequentialtest(h); h->close(h); unlink("logfile.txt"); h = stasis_handle(open_pfile)(0, "logfile.txt", O_CREAT | O_RDWR, FILE_PERM); //handle_concurrencytest(h); h->close(h); unlink("logfile.txt"); handle_truncate_is_supported = 1; } END_TEST typedef struct sf_args { char * filename; int openMode; int filePerm; } sf_args; static stasis_handle_t * slow_factory(void * argsP) { sf_args * args = (sf_args*) argsP; return stasis_handle(open_file)(0, args->filename, args->openMode, args->filePerm); } START_TEST(io_nonBlockingTest) { printf("io_nonBlockingTest\n"); fflush(stdout); stasis_handle_t * h; sf_args slow_args = { "logfile.txt", O_CREAT | O_RDWR, FILE_PERM }; h = stasis_handle(open_non_blocking)(slow_factory, 0, &slow_args, 0, fast_factory, 0, 5, 1024*1024, 100); // h = stasis_handle(open_debug)(h); handle_smoketest(h); h->close(h); unlink("logfile.txt"); h = stasis_handle(open_non_blocking)(slow_factory, 0, &slow_args, 0, fast_factory, 0, 5, 1024*1024, 100); //h = stasis_handle(open_debug)(h); handle_sequentialtest(h); h->close(h); unlink("logfile.txt"); h = stasis_handle(open_non_blocking)(slow_factory, 0, &slow_args, 0, fast_factory, 0, 5, 1024 * 1024, 100); handle_concurrencytest(h); h->close(h); unlink("logfile.txt"); } END_TEST /** Add suite declarations here */ Suite * check_suite(void) { Suite *s = suite_create("io"); /* Begin a new test */ TCase *tc = tcase_create("io_test"); tcase_set_timeout(tc, 600); // ten minute timeout /* Sub tests are added, one per line, here */ tcase_add_test(tc, io_memoryTest); tcase_add_test(tc, io_fileTest); tcase_add_test(tc, io_pfileTest); tcase_add_test(tc, io_nonBlockingTest); /* --------------------------------------------- */ tcase_add_checked_fixture(tc, setup, teardown); suite_add_tcase(s, tc); return s; } #include "../check_setup.h"