/*- * BSD LICENSE * * Copyright (c) Intel Corporation. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * * Neither the name of Intel Corporation nor the names of its * contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include "spdk_cunit.h" #include "common/lib/ut_multithread.c" #include "unit/lib/json_mock.c" #include "spdk/config.h" /* HACK: disable VTune integration so the unit test doesn't need VTune headers and libs to build */ #undef SPDK_CONFIG_VTUNE #include "bdev/bdev.c" #define BDEV_UT_NUM_THREADS 3 DEFINE_STUB(spdk_conf_find_section, struct spdk_conf_section *, (struct spdk_conf *cp, const char *name), NULL); DEFINE_STUB(spdk_conf_section_get_nmval, char *, (struct spdk_conf_section *sp, const char *key, int idx1, int idx2), NULL); DEFINE_STUB(spdk_conf_section_get_intval, int, (struct spdk_conf_section *sp, const char *key), -1); struct spdk_trace_histories *g_trace_histories; DEFINE_STUB_V(spdk_trace_add_register_fn, (struct spdk_trace_register_fn *reg_fn)); DEFINE_STUB_V(spdk_trace_register_owner, (uint8_t type, char id_prefix)); DEFINE_STUB_V(spdk_trace_register_object, (uint8_t type, char id_prefix)); DEFINE_STUB_V(spdk_trace_register_description, (const char *name, uint16_t tpoint_id, uint8_t owner_type, uint8_t object_type, uint8_t new_object, uint8_t arg1_type, const char *arg1_name)); DEFINE_STUB_V(_spdk_trace_record, (uint64_t tsc, uint16_t tpoint_id, uint16_t poller_id, uint32_t size, uint64_t object_id, uint64_t arg1)); DEFINE_STUB(spdk_notify_send, uint64_t, (const char *type, const char *ctx), 0); DEFINE_STUB(spdk_notify_type_register, struct spdk_notify_type *, (const char *type), NULL); struct ut_bdev { struct spdk_bdev bdev; void *io_target; }; struct ut_bdev_channel { TAILQ_HEAD(, spdk_bdev_io) outstanding_io; uint32_t outstanding_cnt; uint32_t avail_cnt; }; int g_io_device; struct ut_bdev g_bdev; struct spdk_bdev_desc *g_desc; bool g_teardown_done = false; bool g_get_io_channel = true; bool g_create_ch = true; bool g_init_complete_called = false; bool g_fini_start_called = true; int g_status = 0; int g_count = 0; struct spdk_histogram_data *g_histogram = NULL; static int stub_create_ch(void *io_device, void *ctx_buf) { struct ut_bdev_channel *ch = ctx_buf; if (g_create_ch == false) { return -1; } TAILQ_INIT(&ch->outstanding_io); ch->outstanding_cnt = 0; /* * When avail gets to 0, the submit_request function will return ENOMEM. * Most tests to not want ENOMEM to occur, so by default set this to a * big value that won't get hit. The ENOMEM tests can then override this * value to something much smaller to induce ENOMEM conditions. */ ch->avail_cnt = 2048; return 0; } static void stub_destroy_ch(void *io_device, void *ctx_buf) { } static struct spdk_io_channel * stub_get_io_channel(void *ctx) { struct ut_bdev *ut_bdev = ctx; if (g_get_io_channel == true) { return spdk_get_io_channel(ut_bdev->io_target); } else { return NULL; } } static int stub_destruct(void *ctx) { return 0; } static void stub_submit_request(struct spdk_io_channel *_ch, struct spdk_bdev_io *bdev_io) { struct ut_bdev_channel *ch = spdk_io_channel_get_ctx(_ch); struct spdk_bdev_io *io; if (bdev_io->type == SPDK_BDEV_IO_TYPE_RESET) { while (!TAILQ_EMPTY(&ch->outstanding_io)) { io = TAILQ_FIRST(&ch->outstanding_io); TAILQ_REMOVE(&ch->outstanding_io, io, module_link); ch->outstanding_cnt--; spdk_bdev_io_complete(io, SPDK_BDEV_IO_STATUS_ABORTED); ch->avail_cnt++; } } else if (bdev_io->type == SPDK_BDEV_IO_TYPE_ABORT) { TAILQ_FOREACH(io, &ch->outstanding_io, module_link) { if (io == bdev_io->u.abort.bio_to_abort) { TAILQ_REMOVE(&ch->outstanding_io, io, module_link); ch->outstanding_cnt--; spdk_bdev_io_complete(io, SPDK_BDEV_IO_STATUS_ABORTED); ch->avail_cnt++; spdk_bdev_io_complete(bdev_io, SPDK_BDEV_IO_STATUS_SUCCESS); return; } } spdk_bdev_io_complete(bdev_io, SPDK_BDEV_IO_STATUS_FAILED); return; } if (ch->avail_cnt > 0) { TAILQ_INSERT_TAIL(&ch->outstanding_io, bdev_io, module_link); ch->outstanding_cnt++; ch->avail_cnt--; } else { spdk_bdev_io_complete(bdev_io, SPDK_BDEV_IO_STATUS_NOMEM); } } static uint32_t stub_complete_io(void *io_target, uint32_t num_to_complete) { struct spdk_io_channel *_ch = spdk_get_io_channel(io_target); struct ut_bdev_channel *ch = spdk_io_channel_get_ctx(_ch); struct spdk_bdev_io *io; bool complete_all = (num_to_complete == 0); uint32_t num_completed = 0; while (complete_all || num_completed < num_to_complete) { if (TAILQ_EMPTY(&ch->outstanding_io)) { break; } io = TAILQ_FIRST(&ch->outstanding_io); TAILQ_REMOVE(&ch->outstanding_io, io, module_link); ch->outstanding_cnt--; spdk_bdev_io_complete(io, SPDK_BDEV_IO_STATUS_SUCCESS); ch->avail_cnt++; num_completed++; } spdk_put_io_channel(_ch); return num_completed; } static bool stub_io_type_supported(void *ctx, enum spdk_bdev_io_type type) { return true; } static struct spdk_bdev_fn_table fn_table = { .get_io_channel = stub_get_io_channel, .destruct = stub_destruct, .submit_request = stub_submit_request, .io_type_supported = stub_io_type_supported, }; struct spdk_bdev_module bdev_ut_if; static int module_init(void) { spdk_bdev_module_init_done(&bdev_ut_if); return 0; } static void module_fini(void) { } static void init_complete(void) { g_init_complete_called = true; } static void fini_start(void) { g_fini_start_called = true; } struct spdk_bdev_module bdev_ut_if = { .name = "bdev_ut", .module_init = module_init, .module_fini = module_fini, .async_init = true, .init_complete = init_complete, .fini_start = fini_start, }; SPDK_BDEV_MODULE_REGISTER(bdev_ut, &bdev_ut_if) static void register_bdev(struct ut_bdev *ut_bdev, char *name, void *io_target) { memset(ut_bdev, 0, sizeof(*ut_bdev)); ut_bdev->io_target = io_target; ut_bdev->bdev.ctxt = ut_bdev; ut_bdev->bdev.name = name; ut_bdev->bdev.fn_table = &fn_table; ut_bdev->bdev.module = &bdev_ut_if; ut_bdev->bdev.blocklen = 4096; ut_bdev->bdev.blockcnt = 1024; spdk_bdev_register(&ut_bdev->bdev); } static void unregister_bdev(struct ut_bdev *ut_bdev) { /* Handle any deferred messages. */ poll_threads(); spdk_bdev_unregister(&ut_bdev->bdev, NULL, NULL); } static void bdev_init_cb(void *done, int rc) { CU_ASSERT(rc == 0); *(bool *)done = true; } static void setup_test(void) { bool done = false; allocate_cores(BDEV_UT_NUM_THREADS); allocate_threads(BDEV_UT_NUM_THREADS); set_thread(0); spdk_bdev_initialize(bdev_init_cb, &done); spdk_io_device_register(&g_io_device, stub_create_ch, stub_destroy_ch, sizeof(struct ut_bdev_channel), NULL); register_bdev(&g_bdev, "ut_bdev", &g_io_device); spdk_bdev_open(&g_bdev.bdev, true, NULL, NULL, &g_desc); } static void finish_cb(void *cb_arg) { g_teardown_done = true; } static void teardown_test(void) { set_thread(0); g_teardown_done = false; spdk_bdev_close(g_desc); g_desc = NULL; unregister_bdev(&g_bdev); spdk_io_device_unregister(&g_io_device, NULL); spdk_bdev_finish(finish_cb, NULL); poll_threads(); memset(&g_bdev, 0, sizeof(g_bdev)); CU_ASSERT(g_teardown_done == true); g_teardown_done = false; free_threads(); free_cores(); } static uint32_t bdev_io_tailq_cnt(bdev_io_tailq_t *tailq) { struct spdk_bdev_io *io; uint32_t cnt = 0; TAILQ_FOREACH(io, tailq, internal.link) { cnt++; } return cnt; } static void basic(void) { g_init_complete_called = false; setup_test(); CU_ASSERT(g_init_complete_called == true); set_thread(0); g_get_io_channel = false; g_ut_threads[0].ch = spdk_bdev_get_io_channel(g_desc); CU_ASSERT(g_ut_threads[0].ch == NULL); g_get_io_channel = true; g_create_ch = false; g_ut_threads[0].ch = spdk_bdev_get_io_channel(g_desc); CU_ASSERT(g_ut_threads[0].ch == NULL); g_get_io_channel = true; g_create_ch = true; g_ut_threads[0].ch = spdk_bdev_get_io_channel(g_desc); CU_ASSERT(g_ut_threads[0].ch != NULL); spdk_put_io_channel(g_ut_threads[0].ch); g_fini_start_called = false; teardown_test(); CU_ASSERT(g_fini_start_called == true); } static void _bdev_removed(void *done) { *(bool *)done = true; } static void _bdev_unregistered(void *done, int rc) { CU_ASSERT(rc == 0); *(bool *)done = true; } static void unregister_and_close(void) { bool done, remove_notify; struct spdk_bdev_desc *desc = NULL; setup_test(); set_thread(0); /* setup_test() automatically opens the bdev, * but this test needs to do that in a different * way. */ spdk_bdev_close(g_desc); poll_threads(); /* Try hotremoving a bdev with descriptors which don't provide * the notification callback */ spdk_bdev_open(&g_bdev.bdev, true, NULL, NULL, &desc); SPDK_CU_ASSERT_FATAL(desc != NULL); /* There is an open descriptor on the device. Unregister it, * which can't proceed until the descriptor is closed. */ done = false; spdk_bdev_unregister(&g_bdev.bdev, _bdev_unregistered, &done); /* Poll the threads to allow all events to be processed */ poll_threads(); /* Make sure the bdev was not unregistered. We still have a * descriptor open */ CU_ASSERT(done == false); spdk_bdev_close(desc); poll_threads(); desc = NULL; /* The unregister should have completed */ CU_ASSERT(done == true); /* Register the bdev again */ register_bdev(&g_bdev, "ut_bdev", &g_io_device); remove_notify = false; spdk_bdev_open(&g_bdev.bdev, true, _bdev_removed, &remove_notify, &desc); SPDK_CU_ASSERT_FATAL(desc != NULL); CU_ASSERT(remove_notify == false); /* There is an open descriptor on the device. Unregister it, * which can't proceed until the descriptor is closed. */ done = false; spdk_bdev_unregister(&g_bdev.bdev, _bdev_unregistered, &done); /* No polling has occurred, so neither of these should execute */ CU_ASSERT(remove_notify == false); CU_ASSERT(done == false); /* Prior to the unregister completing, close the descriptor */ spdk_bdev_close(desc); /* Poll the threads to allow all events to be processed */ poll_threads(); /* Remove notify should not have been called because the * descriptor is already closed. */ CU_ASSERT(remove_notify == false); /* The unregister should have completed */ CU_ASSERT(done == true); /* Restore the original g_bdev so that we can use teardown_test(). */ register_bdev(&g_bdev, "ut_bdev", &g_io_device); spdk_bdev_open(&g_bdev.bdev, true, NULL, NULL, &g_desc); teardown_test(); } static void reset_done(struct spdk_bdev_io *bdev_io, bool success, void *cb_arg) { bool *done = cb_arg; CU_ASSERT(success == true); *done = true; spdk_bdev_free_io(bdev_io); } static void put_channel_during_reset(void) { struct spdk_io_channel *io_ch; bool done = false; setup_test(); set_thread(0); io_ch = spdk_bdev_get_io_channel(g_desc); CU_ASSERT(io_ch != NULL); /* * Start a reset, but then put the I/O channel before * the deferred messages for the reset get a chance to * execute. */ spdk_bdev_reset(g_desc, io_ch, reset_done, &done); spdk_put_io_channel(io_ch); poll_threads(); stub_complete_io(g_bdev.io_target, 0); teardown_test(); } static void aborted_reset_done(struct spdk_bdev_io *bdev_io, bool success, void *cb_arg) { enum spdk_bdev_io_status *status = cb_arg; *status = success ? SPDK_BDEV_IO_STATUS_SUCCESS : SPDK_BDEV_IO_STATUS_FAILED; spdk_bdev_free_io(bdev_io); } static void aborted_reset(void) { struct spdk_io_channel *io_ch[2]; enum spdk_bdev_io_status status1 = SPDK_BDEV_IO_STATUS_PENDING, status2 = SPDK_BDEV_IO_STATUS_PENDING; setup_test(); set_thread(0); io_ch[0] = spdk_bdev_get_io_channel(g_desc); CU_ASSERT(io_ch[0] != NULL); spdk_bdev_reset(g_desc, io_ch[0], aborted_reset_done, &status1); poll_threads(); CU_ASSERT(g_bdev.bdev.internal.reset_in_progress != NULL); /* * First reset has been submitted on ch0. Now submit a second * reset on ch1 which will get queued since there is already a * reset in progress. */ set_thread(1); io_ch[1] = spdk_bdev_get_io_channel(g_desc); CU_ASSERT(io_ch[1] != NULL); spdk_bdev_reset(g_desc, io_ch[1], aborted_reset_done, &status2); poll_threads(); CU_ASSERT(g_bdev.bdev.internal.reset_in_progress != NULL); /* * Now destroy ch1. This will abort the queued reset. Check that * the second reset was completed with failed status. Also check * that bdev->internal.reset_in_progress != NULL, since the * original reset has not been completed yet. This ensures that * the bdev code is correctly noticing that the failed reset is * *not* the one that had been submitted to the bdev module. */ set_thread(1); spdk_put_io_channel(io_ch[1]); poll_threads(); CU_ASSERT(status2 == SPDK_BDEV_IO_STATUS_FAILED); CU_ASSERT(g_bdev.bdev.internal.reset_in_progress != NULL); /* * Now complete the first reset, verify that it completed with SUCCESS * status and that bdev->internal.reset_in_progress is also set back to NULL. */ set_thread(0); spdk_put_io_channel(io_ch[0]); stub_complete_io(g_bdev.io_target, 0); poll_threads(); CU_ASSERT(status1 == SPDK_BDEV_IO_STATUS_SUCCESS); CU_ASSERT(g_bdev.bdev.internal.reset_in_progress == NULL); teardown_test(); } static void io_during_io_done(struct spdk_bdev_io *bdev_io, bool success, void *cb_arg) { enum spdk_bdev_io_status *status = cb_arg; *status = bdev_io->internal.status; spdk_bdev_free_io(bdev_io); } static void io_during_reset(void) { struct spdk_io_channel *io_ch[2]; struct spdk_bdev_channel *bdev_ch[2]; enum spdk_bdev_io_status status0, status1, status_reset; int rc; setup_test(); /* * First test normal case - submit an I/O on each of two channels (with no resets) * and verify they complete successfully. */ set_thread(0); io_ch[0] = spdk_bdev_get_io_channel(g_desc); bdev_ch[0] = spdk_io_channel_get_ctx(io_ch[0]); CU_ASSERT(bdev_ch[0]->flags == 0); status0 = SPDK_BDEV_IO_STATUS_PENDING; rc = spdk_bdev_read_blocks(g_desc, io_ch[0], NULL, 0, 1, io_during_io_done, &status0); CU_ASSERT(rc == 0); set_thread(1); io_ch[1] = spdk_bdev_get_io_channel(g_desc); bdev_ch[1] = spdk_io_channel_get_ctx(io_ch[1]); CU_ASSERT(bdev_ch[1]->flags == 0); status1 = SPDK_BDEV_IO_STATUS_PENDING; rc = spdk_bdev_read_blocks(g_desc, io_ch[1], NULL, 0, 1, io_during_io_done, &status1); CU_ASSERT(rc == 0); poll_threads(); CU_ASSERT(status0 == SPDK_BDEV_IO_STATUS_PENDING); CU_ASSERT(status1 == SPDK_BDEV_IO_STATUS_PENDING); set_thread(0); stub_complete_io(g_bdev.io_target, 0); CU_ASSERT(status0 == SPDK_BDEV_IO_STATUS_SUCCESS); set_thread(1); stub_complete_io(g_bdev.io_target, 0); CU_ASSERT(status1 == SPDK_BDEV_IO_STATUS_SUCCESS); /* * Now submit a reset, and leave it pending while we submit I/O on two different * channels. These I/O should be failed by the bdev layer since the reset is in * progress. */ set_thread(0); status_reset = SPDK_BDEV_IO_STATUS_PENDING; rc = spdk_bdev_reset(g_desc, io_ch[0], io_during_io_done, &status_reset); CU_ASSERT(rc == 0); CU_ASSERT(bdev_ch[0]->flags == 0); CU_ASSERT(bdev_ch[1]->flags == 0); poll_threads(); CU_ASSERT(bdev_ch[0]->flags == BDEV_CH_RESET_IN_PROGRESS); CU_ASSERT(bdev_ch[1]->flags == BDEV_CH_RESET_IN_PROGRESS); set_thread(0); status0 = SPDK_BDEV_IO_STATUS_PENDING; rc = spdk_bdev_read_blocks(g_desc, io_ch[0], NULL, 0, 1, io_during_io_done, &status0); CU_ASSERT(rc == 0); set_thread(1); status1 = SPDK_BDEV_IO_STATUS_PENDING; rc = spdk_bdev_read_blocks(g_desc, io_ch[1], NULL, 0, 1, io_during_io_done, &status1); CU_ASSERT(rc == 0); /* * A reset is in progress so these read I/O should complete with aborted. Note that we * need to poll_threads() since I/O completed inline have their completion deferred. */ poll_threads(); CU_ASSERT(status_reset == SPDK_BDEV_IO_STATUS_PENDING); CU_ASSERT(status0 == SPDK_BDEV_IO_STATUS_ABORTED); CU_ASSERT(status1 == SPDK_BDEV_IO_STATUS_ABORTED); /* * Complete the reset */ set_thread(0); stub_complete_io(g_bdev.io_target, 0); /* * Only poll thread 0. We should not get a completion. */ poll_thread(0); CU_ASSERT(status_reset == SPDK_BDEV_IO_STATUS_PENDING); /* * Poll both thread 0 and 1 so the messages can propagate and we * get a completion. */ poll_threads(); CU_ASSERT(status_reset == SPDK_BDEV_IO_STATUS_SUCCESS); spdk_put_io_channel(io_ch[0]); set_thread(1); spdk_put_io_channel(io_ch[1]); poll_threads(); teardown_test(); } static void basic_qos(void) { struct spdk_io_channel *io_ch[2]; struct spdk_bdev_channel *bdev_ch[2]; struct spdk_bdev *bdev; enum spdk_bdev_io_status status, abort_status; int rc; setup_test(); /* Enable QoS */ bdev = &g_bdev.bdev; bdev->internal.qos = calloc(1, sizeof(*bdev->internal.qos)); SPDK_CU_ASSERT_FATAL(bdev->internal.qos != NULL); TAILQ_INIT(&bdev->internal.qos->queued); /* * Enable read/write IOPS, read only byte per second and * read/write byte per second rate limits. * In this case, all rate limits will take equal effect. */ /* 2000 read/write I/O per second, or 2 per millisecond */ bdev->internal.qos->rate_limits[SPDK_BDEV_QOS_RW_IOPS_RATE_LIMIT].limit = 2000; /* 8K read/write byte per millisecond with 4K block size */ bdev->internal.qos->rate_limits[SPDK_BDEV_QOS_RW_BPS_RATE_LIMIT].limit = 8192000; /* 8K read only byte per millisecond with 4K block size */ bdev->internal.qos->rate_limits[SPDK_BDEV_QOS_R_BPS_RATE_LIMIT].limit = 8192000; g_get_io_channel = true; set_thread(0); io_ch[0] = spdk_bdev_get_io_channel(g_desc); bdev_ch[0] = spdk_io_channel_get_ctx(io_ch[0]); CU_ASSERT(bdev_ch[0]->flags == BDEV_CH_QOS_ENABLED); set_thread(1); io_ch[1] = spdk_bdev_get_io_channel(g_desc); bdev_ch[1] = spdk_io_channel_get_ctx(io_ch[1]); CU_ASSERT(bdev_ch[1]->flags == BDEV_CH_QOS_ENABLED); /* * Send an I/O on thread 0, which is where the QoS thread is running. */ set_thread(0); status = SPDK_BDEV_IO_STATUS_PENDING; rc = spdk_bdev_read_blocks(g_desc, io_ch[0], NULL, 0, 1, io_during_io_done, &status); CU_ASSERT(rc == 0); CU_ASSERT(status == SPDK_BDEV_IO_STATUS_PENDING); poll_threads(); stub_complete_io(g_bdev.io_target, 0); poll_threads(); CU_ASSERT(status == SPDK_BDEV_IO_STATUS_SUCCESS); /* Send an I/O on thread 1. The QoS thread is not running here. */ status = SPDK_BDEV_IO_STATUS_PENDING; set_thread(1); rc = spdk_bdev_read_blocks(g_desc, io_ch[1], NULL, 0, 1, io_during_io_done, &status); CU_ASSERT(rc == 0); CU_ASSERT(status == SPDK_BDEV_IO_STATUS_PENDING); poll_threads(); /* Complete I/O on thread 1. This should not complete the I/O we submitted */ stub_complete_io(g_bdev.io_target, 0); poll_threads(); CU_ASSERT(status == SPDK_BDEV_IO_STATUS_PENDING); /* Now complete I/O on thread 0 */ set_thread(0); poll_threads(); stub_complete_io(g_bdev.io_target, 0); poll_threads(); CU_ASSERT(status == SPDK_BDEV_IO_STATUS_SUCCESS); /* Reset rate limit for the next test cases. */ spdk_delay_us(SPDK_BDEV_QOS_TIMESLICE_IN_USEC); poll_threads(); /* * Test abort request when QoS is enabled. */ /* Send an I/O on thread 0, which is where the QoS thread is running. */ set_thread(0); status = SPDK_BDEV_IO_STATUS_PENDING; rc = spdk_bdev_read_blocks(g_desc, io_ch[0], NULL, 0, 1, io_during_io_done, &status); CU_ASSERT(rc == 0); CU_ASSERT(status == SPDK_BDEV_IO_STATUS_PENDING); /* Send an abort to the I/O on the same thread. */ abort_status = SPDK_BDEV_IO_STATUS_PENDING; rc = spdk_bdev_abort(g_desc, io_ch[0], &status, io_during_io_done, &abort_status); CU_ASSERT(rc == 0); CU_ASSERT(abort_status == SPDK_BDEV_IO_STATUS_PENDING); poll_threads(); CU_ASSERT(abort_status == SPDK_BDEV_IO_STATUS_SUCCESS); CU_ASSERT(status == SPDK_BDEV_IO_STATUS_ABORTED); /* Send an I/O on thread 1. The QoS thread is not running here. */ status = SPDK_BDEV_IO_STATUS_PENDING; set_thread(1); rc = spdk_bdev_read_blocks(g_desc, io_ch[1], NULL, 0, 1, io_during_io_done, &status); CU_ASSERT(rc == 0); CU_ASSERT(status == SPDK_BDEV_IO_STATUS_PENDING); poll_threads(); /* Send an abort to the I/O on the same thread. */ abort_status = SPDK_BDEV_IO_STATUS_PENDING; rc = spdk_bdev_abort(g_desc, io_ch[1], &status, io_during_io_done, &abort_status); CU_ASSERT(rc == 0); CU_ASSERT(abort_status == SPDK_BDEV_IO_STATUS_PENDING); poll_threads(); /* Complete the I/O with failure and the abort with success on thread 1. */ CU_ASSERT(abort_status == SPDK_BDEV_IO_STATUS_SUCCESS); CU_ASSERT(status == SPDK_BDEV_IO_STATUS_ABORTED); set_thread(0); /* * Close the descriptor only, which should stop the qos channel as * the last descriptor removed. */ spdk_bdev_close(g_desc); poll_threads(); CU_ASSERT(bdev->internal.qos->ch == NULL); /* * Open the bdev again which shall setup the qos channel as the * channels are valid. */ spdk_bdev_open(bdev, true, NULL, NULL, &g_desc); poll_threads(); CU_ASSERT(bdev->internal.qos->ch != NULL); /* Tear down the channels */ set_thread(0); spdk_put_io_channel(io_ch[0]); set_thread(1); spdk_put_io_channel(io_ch[1]); poll_threads(); set_thread(0); /* Close the descriptor, which should stop the qos channel */ spdk_bdev_close(g_desc); poll_threads(); CU_ASSERT(bdev->internal.qos->ch == NULL); /* Open the bdev again, no qos channel setup without valid channels. */ spdk_bdev_open(bdev, true, NULL, NULL, &g_desc); poll_threads(); CU_ASSERT(bdev->internal.qos->ch == NULL); /* Create the channels in reverse order. */ set_thread(1); io_ch[1] = spdk_bdev_get_io_channel(g_desc); bdev_ch[1] = spdk_io_channel_get_ctx(io_ch[1]); CU_ASSERT(bdev_ch[1]->flags == BDEV_CH_QOS_ENABLED); set_thread(0); io_ch[0] = spdk_bdev_get_io_channel(g_desc); bdev_ch[0] = spdk_io_channel_get_ctx(io_ch[0]); CU_ASSERT(bdev_ch[0]->flags == BDEV_CH_QOS_ENABLED); /* Confirm that the qos thread is now thread 1 */ CU_ASSERT(bdev->internal.qos->ch == bdev_ch[1]); /* Tear down the channels */ set_thread(0); spdk_put_io_channel(io_ch[0]); set_thread(1); spdk_put_io_channel(io_ch[1]); poll_threads(); set_thread(0); teardown_test(); } static void io_during_qos_queue(void) { struct spdk_io_channel *io_ch[2]; struct spdk_bdev_channel *bdev_ch[2]; struct spdk_bdev *bdev; enum spdk_bdev_io_status status0, status1, status2; int rc; setup_test(); MOCK_SET(spdk_get_ticks, 0); /* Enable QoS */ bdev = &g_bdev.bdev; bdev->internal.qos = calloc(1, sizeof(*bdev->internal.qos)); SPDK_CU_ASSERT_FATAL(bdev->internal.qos != NULL); TAILQ_INIT(&bdev->internal.qos->queued); /* * Enable read/write IOPS, read only byte per sec, write only * byte per sec and read/write byte per sec rate limits. * In this case, both read only and write only byte per sec * rate limit will take effect. */ /* 4000 read/write I/O per second, or 4 per millisecond */ bdev->internal.qos->rate_limits[SPDK_BDEV_QOS_RW_IOPS_RATE_LIMIT].limit = 4000; /* 8K byte per millisecond with 4K block size */ bdev->internal.qos->rate_limits[SPDK_BDEV_QOS_RW_BPS_RATE_LIMIT].limit = 8192000; /* 4K byte per millisecond with 4K block size */ bdev->internal.qos->rate_limits[SPDK_BDEV_QOS_R_BPS_RATE_LIMIT].limit = 4096000; /* 4K byte per millisecond with 4K block size */ bdev->internal.qos->rate_limits[SPDK_BDEV_QOS_W_BPS_RATE_LIMIT].limit = 4096000; g_get_io_channel = true; /* Create channels */ set_thread(0); io_ch[0] = spdk_bdev_get_io_channel(g_desc); bdev_ch[0] = spdk_io_channel_get_ctx(io_ch[0]); CU_ASSERT(bdev_ch[0]->flags == BDEV_CH_QOS_ENABLED); set_thread(1); io_ch[1] = spdk_bdev_get_io_channel(g_desc); bdev_ch[1] = spdk_io_channel_get_ctx(io_ch[1]); CU_ASSERT(bdev_ch[1]->flags == BDEV_CH_QOS_ENABLED); /* Send two read I/Os */ status1 = SPDK_BDEV_IO_STATUS_PENDING; rc = spdk_bdev_read_blocks(g_desc, io_ch[1], NULL, 0, 1, io_during_io_done, &status1); CU_ASSERT(rc == 0); CU_ASSERT(status1 == SPDK_BDEV_IO_STATUS_PENDING); set_thread(0); status0 = SPDK_BDEV_IO_STATUS_PENDING; rc = spdk_bdev_read_blocks(g_desc, io_ch[0], NULL, 0, 1, io_during_io_done, &status0); CU_ASSERT(rc == 0); CU_ASSERT(status0 == SPDK_BDEV_IO_STATUS_PENDING); /* Send one write I/O */ status2 = SPDK_BDEV_IO_STATUS_PENDING; rc = spdk_bdev_write_blocks(g_desc, io_ch[0], NULL, 0, 1, io_during_io_done, &status2); CU_ASSERT(rc == 0); CU_ASSERT(status2 == SPDK_BDEV_IO_STATUS_PENDING); /* Complete any I/O that arrived at the disk */ poll_threads(); set_thread(1); stub_complete_io(g_bdev.io_target, 0); set_thread(0); stub_complete_io(g_bdev.io_target, 0); poll_threads(); /* Only one of the two read I/Os should complete. (logical XOR) */ if (status0 == SPDK_BDEV_IO_STATUS_SUCCESS) { CU_ASSERT(status1 == SPDK_BDEV_IO_STATUS_PENDING); } else { CU_ASSERT(status1 == SPDK_BDEV_IO_STATUS_SUCCESS); } /* The write I/O should complete. */ CU_ASSERT(status2 == SPDK_BDEV_IO_STATUS_SUCCESS); /* Advance in time by a millisecond */ spdk_delay_us(1000); /* Complete more I/O */ poll_threads(); set_thread(1); stub_complete_io(g_bdev.io_target, 0); set_thread(0); stub_complete_io(g_bdev.io_target, 0); poll_threads(); /* Now the second read I/O should be done */ CU_ASSERT(status0 == SPDK_BDEV_IO_STATUS_SUCCESS); CU_ASSERT(status1 == SPDK_BDEV_IO_STATUS_SUCCESS); /* Tear down the channels */ set_thread(1); spdk_put_io_channel(io_ch[1]); set_thread(0); spdk_put_io_channel(io_ch[0]); poll_threads(); teardown_test(); } static void io_during_qos_reset(void) { struct spdk_io_channel *io_ch[2]; struct spdk_bdev_channel *bdev_ch[2]; struct spdk_bdev *bdev; enum spdk_bdev_io_status status0, status1, reset_status; int rc; setup_test(); MOCK_SET(spdk_get_ticks, 0); /* Enable QoS */ bdev = &g_bdev.bdev; bdev->internal.qos = calloc(1, sizeof(*bdev->internal.qos)); SPDK_CU_ASSERT_FATAL(bdev->internal.qos != NULL); TAILQ_INIT(&bdev->internal.qos->queued); /* * Enable read/write IOPS, write only byte per sec and * read/write byte per second rate limits. * In this case, read/write byte per second rate limit will * take effect first. */ /* 2000 read/write I/O per second, or 2 per millisecond */ bdev->internal.qos->rate_limits[SPDK_BDEV_QOS_RW_IOPS_RATE_LIMIT].limit = 2000; /* 4K byte per millisecond with 4K block size */ bdev->internal.qos->rate_limits[SPDK_BDEV_QOS_RW_BPS_RATE_LIMIT].limit = 4096000; /* 8K byte per millisecond with 4K block size */ bdev->internal.qos->rate_limits[SPDK_BDEV_QOS_W_BPS_RATE_LIMIT].limit = 8192000; g_get_io_channel = true; /* Create channels */ set_thread(0); io_ch[0] = spdk_bdev_get_io_channel(g_desc); bdev_ch[0] = spdk_io_channel_get_ctx(io_ch[0]); CU_ASSERT(bdev_ch[0]->flags == BDEV_CH_QOS_ENABLED); set_thread(1); io_ch[1] = spdk_bdev_get_io_channel(g_desc); bdev_ch[1] = spdk_io_channel_get_ctx(io_ch[1]); CU_ASSERT(bdev_ch[1]->flags == BDEV_CH_QOS_ENABLED); /* Send two I/O. One of these gets queued by QoS. The other is sitting at the disk. */ status1 = SPDK_BDEV_IO_STATUS_PENDING; rc = spdk_bdev_write_blocks(g_desc, io_ch[1], NULL, 0, 1, io_during_io_done, &status1); CU_ASSERT(rc == 0); set_thread(0); status0 = SPDK_BDEV_IO_STATUS_PENDING; rc = spdk_bdev_write_blocks(g_desc, io_ch[0], NULL, 0, 1, io_during_io_done, &status0); CU_ASSERT(rc == 0); poll_threads(); CU_ASSERT(status1 == SPDK_BDEV_IO_STATUS_PENDING); CU_ASSERT(status0 == SPDK_BDEV_IO_STATUS_PENDING); /* Reset the bdev. */ reset_status = SPDK_BDEV_IO_STATUS_PENDING; rc = spdk_bdev_reset(g_desc, io_ch[0], io_during_io_done, &reset_status); CU_ASSERT(rc == 0); /* Complete any I/O that arrived at the disk */ poll_threads(); set_thread(1); stub_complete_io(g_bdev.io_target, 0); set_thread(0); stub_complete_io(g_bdev.io_target, 0); poll_threads(); CU_ASSERT(reset_status == SPDK_BDEV_IO_STATUS_SUCCESS); CU_ASSERT(status0 == SPDK_BDEV_IO_STATUS_ABORTED); CU_ASSERT(status1 == SPDK_BDEV_IO_STATUS_ABORTED); /* Tear down the channels */ set_thread(1); spdk_put_io_channel(io_ch[1]); set_thread(0); spdk_put_io_channel(io_ch[0]); poll_threads(); teardown_test(); } static void enomem_done(struct spdk_bdev_io *bdev_io, bool success, void *cb_arg) { enum spdk_bdev_io_status *status = cb_arg; *status = success ? SPDK_BDEV_IO_STATUS_SUCCESS : SPDK_BDEV_IO_STATUS_FAILED; spdk_bdev_free_io(bdev_io); } static void enomem(void) { struct spdk_io_channel *io_ch; struct spdk_bdev_channel *bdev_ch; struct spdk_bdev_shared_resource *shared_resource; struct ut_bdev_channel *ut_ch; const uint32_t IO_ARRAY_SIZE = 64; const uint32_t AVAIL = 20; enum spdk_bdev_io_status status[IO_ARRAY_SIZE], status_reset; uint32_t nomem_cnt, i; struct spdk_bdev_io *first_io; int rc; setup_test(); set_thread(0); io_ch = spdk_bdev_get_io_channel(g_desc); bdev_ch = spdk_io_channel_get_ctx(io_ch); shared_resource = bdev_ch->shared_resource; ut_ch = spdk_io_channel_get_ctx(bdev_ch->channel); ut_ch->avail_cnt = AVAIL; /* First submit a number of IOs equal to what the channel can support. */ for (i = 0; i < AVAIL; i++) { status[i] = SPDK_BDEV_IO_STATUS_PENDING; rc = spdk_bdev_read_blocks(g_desc, io_ch, NULL, 0, 1, enomem_done, &status[i]); CU_ASSERT(rc == 0); } CU_ASSERT(TAILQ_EMPTY(&shared_resource->nomem_io)); /* * Next, submit one additional I/O. This one should fail with ENOMEM and then go onto * the enomem_io list. */ status[AVAIL] = SPDK_BDEV_IO_STATUS_PENDING; rc = spdk_bdev_read_blocks(g_desc, io_ch, NULL, 0, 1, enomem_done, &status[AVAIL]); CU_ASSERT(rc == 0); SPDK_CU_ASSERT_FATAL(!TAILQ_EMPTY(&shared_resource->nomem_io)); first_io = TAILQ_FIRST(&shared_resource->nomem_io); /* * Now submit a bunch more I/O. These should all fail with ENOMEM and get queued behind * the first_io above. */ for (i = AVAIL + 1; i < IO_ARRAY_SIZE; i++) { status[i] = SPDK_BDEV_IO_STATUS_PENDING; rc = spdk_bdev_read_blocks(g_desc, io_ch, NULL, 0, 1, enomem_done, &status[i]); CU_ASSERT(rc == 0); } /* Assert that first_io is still at the head of the list. */ CU_ASSERT(TAILQ_FIRST(&shared_resource->nomem_io) == first_io); CU_ASSERT(bdev_io_tailq_cnt(&shared_resource->nomem_io) == (IO_ARRAY_SIZE - AVAIL)); nomem_cnt = bdev_io_tailq_cnt(&shared_resource->nomem_io); CU_ASSERT(shared_resource->nomem_threshold == (AVAIL - NOMEM_THRESHOLD_COUNT)); /* * Complete 1 I/O only. The key check here is bdev_io_tailq_cnt - this should not have * changed since completing just 1 I/O should not trigger retrying the queued nomem_io * list. */ stub_complete_io(g_bdev.io_target, 1); CU_ASSERT(bdev_io_tailq_cnt(&shared_resource->nomem_io) == nomem_cnt); /* * Complete enough I/O to hit the nomem_theshold. This should trigger retrying nomem_io, * and we should see I/O get resubmitted to the test bdev module. */ stub_complete_io(g_bdev.io_target, NOMEM_THRESHOLD_COUNT - 1); CU_ASSERT(bdev_io_tailq_cnt(&shared_resource->nomem_io) < nomem_cnt); nomem_cnt = bdev_io_tailq_cnt(&shared_resource->nomem_io); /* Complete 1 I/O only. This should not trigger retrying the queued nomem_io. */ stub_complete_io(g_bdev.io_target, 1); CU_ASSERT(bdev_io_tailq_cnt(&shared_resource->nomem_io) == nomem_cnt); /* * Send a reset and confirm that all I/O are completed, including the ones that * were queued on the nomem_io list. */ status_reset = SPDK_BDEV_IO_STATUS_PENDING; rc = spdk_bdev_reset(g_desc, io_ch, enomem_done, &status_reset); poll_threads(); CU_ASSERT(rc == 0); /* This will complete the reset. */ stub_complete_io(g_bdev.io_target, 0); CU_ASSERT(bdev_io_tailq_cnt(&shared_resource->nomem_io) == 0); CU_ASSERT(shared_resource->io_outstanding == 0); spdk_put_io_channel(io_ch); poll_threads(); teardown_test(); } static void enomem_multi_bdev(void) { struct spdk_io_channel *io_ch; struct spdk_bdev_channel *bdev_ch; struct spdk_bdev_shared_resource *shared_resource; struct ut_bdev_channel *ut_ch; const uint32_t IO_ARRAY_SIZE = 64; const uint32_t AVAIL = 20; enum spdk_bdev_io_status status[IO_ARRAY_SIZE]; uint32_t i; struct ut_bdev *second_bdev; struct spdk_bdev_desc *second_desc = NULL; struct spdk_bdev_channel *second_bdev_ch; struct spdk_io_channel *second_ch; int rc; setup_test(); /* Register second bdev with the same io_target */ second_bdev = calloc(1, sizeof(*second_bdev)); SPDK_CU_ASSERT_FATAL(second_bdev != NULL); register_bdev(second_bdev, "ut_bdev2", g_bdev.io_target); spdk_bdev_open(&second_bdev->bdev, true, NULL, NULL, &second_desc); SPDK_CU_ASSERT_FATAL(second_desc != NULL); set_thread(0); io_ch = spdk_bdev_get_io_channel(g_desc); bdev_ch = spdk_io_channel_get_ctx(io_ch); shared_resource = bdev_ch->shared_resource; ut_ch = spdk_io_channel_get_ctx(bdev_ch->channel); ut_ch->avail_cnt = AVAIL; second_ch = spdk_bdev_get_io_channel(second_desc); second_bdev_ch = spdk_io_channel_get_ctx(second_ch); SPDK_CU_ASSERT_FATAL(shared_resource == second_bdev_ch->shared_resource); /* Saturate io_target through bdev A. */ for (i = 0; i < AVAIL; i++) { status[i] = SPDK_BDEV_IO_STATUS_PENDING; rc = spdk_bdev_read_blocks(g_desc, io_ch, NULL, 0, 1, enomem_done, &status[i]); CU_ASSERT(rc == 0); } CU_ASSERT(TAILQ_EMPTY(&shared_resource->nomem_io)); /* * Now submit I/O through the second bdev. This should fail with ENOMEM * and then go onto the nomem_io list. */ status[AVAIL] = SPDK_BDEV_IO_STATUS_PENDING; rc = spdk_bdev_read_blocks(second_desc, second_ch, NULL, 0, 1, enomem_done, &status[AVAIL]); CU_ASSERT(rc == 0); SPDK_CU_ASSERT_FATAL(!TAILQ_EMPTY(&shared_resource->nomem_io)); /* Complete first bdev's I/O. This should retry sending second bdev's nomem_io */ stub_complete_io(g_bdev.io_target, AVAIL); SPDK_CU_ASSERT_FATAL(TAILQ_EMPTY(&shared_resource->nomem_io)); CU_ASSERT(shared_resource->io_outstanding == 1); /* Now complete our retried I/O */ stub_complete_io(g_bdev.io_target, 1); SPDK_CU_ASSERT_FATAL(shared_resource->io_outstanding == 0); spdk_put_io_channel(io_ch); spdk_put_io_channel(second_ch); spdk_bdev_close(second_desc); unregister_bdev(second_bdev); poll_threads(); free(second_bdev); teardown_test(); } static void enomem_multi_io_target(void) { struct spdk_io_channel *io_ch; struct spdk_bdev_channel *bdev_ch; struct ut_bdev_channel *ut_ch; const uint32_t IO_ARRAY_SIZE = 64; const uint32_t AVAIL = 20; enum spdk_bdev_io_status status[IO_ARRAY_SIZE]; uint32_t i; int new_io_device; struct ut_bdev *second_bdev; struct spdk_bdev_desc *second_desc = NULL; struct spdk_bdev_channel *second_bdev_ch; struct spdk_io_channel *second_ch; int rc; setup_test(); /* Create new io_target and a second bdev using it */ spdk_io_device_register(&new_io_device, stub_create_ch, stub_destroy_ch, sizeof(struct ut_bdev_channel), NULL); second_bdev = calloc(1, sizeof(*second_bdev)); SPDK_CU_ASSERT_FATAL(second_bdev != NULL); register_bdev(second_bdev, "ut_bdev2", &new_io_device); spdk_bdev_open(&second_bdev->bdev, true, NULL, NULL, &second_desc); SPDK_CU_ASSERT_FATAL(second_desc != NULL); set_thread(0); io_ch = spdk_bdev_get_io_channel(g_desc); bdev_ch = spdk_io_channel_get_ctx(io_ch); ut_ch = spdk_io_channel_get_ctx(bdev_ch->channel); ut_ch->avail_cnt = AVAIL; /* Different io_target should imply a different shared_resource */ second_ch = spdk_bdev_get_io_channel(second_desc); second_bdev_ch = spdk_io_channel_get_ctx(second_ch); SPDK_CU_ASSERT_FATAL(bdev_ch->shared_resource != second_bdev_ch->shared_resource); /* Saturate io_target through bdev A. */ for (i = 0; i < AVAIL; i++) { status[i] = SPDK_BDEV_IO_STATUS_PENDING; rc = spdk_bdev_read_blocks(g_desc, io_ch, NULL, 0, 1, enomem_done, &status[i]); CU_ASSERT(rc == 0); } CU_ASSERT(TAILQ_EMPTY(&bdev_ch->shared_resource->nomem_io)); /* Issue one more I/O to fill ENOMEM list. */ status[AVAIL] = SPDK_BDEV_IO_STATUS_PENDING; rc = spdk_bdev_read_blocks(g_desc, io_ch, NULL, 0, 1, enomem_done, &status[AVAIL]); CU_ASSERT(rc == 0); SPDK_CU_ASSERT_FATAL(!TAILQ_EMPTY(&bdev_ch->shared_resource->nomem_io)); /* * Now submit I/O through the second bdev. This should go through and complete * successfully because we're using a different io_device underneath. */ status[AVAIL] = SPDK_BDEV_IO_STATUS_PENDING; rc = spdk_bdev_read_blocks(second_desc, second_ch, NULL, 0, 1, enomem_done, &status[AVAIL]); CU_ASSERT(rc == 0); SPDK_CU_ASSERT_FATAL(TAILQ_EMPTY(&second_bdev_ch->shared_resource->nomem_io)); stub_complete_io(second_bdev->io_target, 1); /* Cleanup; Complete outstanding I/O. */ stub_complete_io(g_bdev.io_target, AVAIL); SPDK_CU_ASSERT_FATAL(TAILQ_EMPTY(&bdev_ch->shared_resource->nomem_io)); /* Complete the ENOMEM I/O */ stub_complete_io(g_bdev.io_target, 1); CU_ASSERT(bdev_ch->shared_resource->io_outstanding == 0); SPDK_CU_ASSERT_FATAL(TAILQ_EMPTY(&bdev_ch->shared_resource->nomem_io)); CU_ASSERT(bdev_ch->shared_resource->io_outstanding == 0); spdk_put_io_channel(io_ch); spdk_put_io_channel(second_ch); spdk_bdev_close(second_desc); unregister_bdev(second_bdev); spdk_io_device_unregister(&new_io_device, NULL); poll_threads(); free(second_bdev); teardown_test(); } static void qos_dynamic_enable_done(void *cb_arg, int status) { int *rc = cb_arg; *rc = status; } static void qos_dynamic_enable(void) { struct spdk_io_channel *io_ch[2]; struct spdk_bdev_channel *bdev_ch[2]; struct spdk_bdev *bdev; enum spdk_bdev_io_status bdev_io_status[2]; uint64_t limits[SPDK_BDEV_QOS_NUM_RATE_LIMIT_TYPES] = {}; int status, second_status, rc, i; setup_test(); MOCK_SET(spdk_get_ticks, 0); for (i = 0; i < SPDK_BDEV_QOS_NUM_RATE_LIMIT_TYPES; i++) { limits[i] = UINT64_MAX; } bdev = &g_bdev.bdev; g_get_io_channel = true; /* Create channels */ set_thread(0); io_ch[0] = spdk_bdev_get_io_channel(g_desc); bdev_ch[0] = spdk_io_channel_get_ctx(io_ch[0]); CU_ASSERT(bdev_ch[0]->flags == 0); set_thread(1); io_ch[1] = spdk_bdev_get_io_channel(g_desc); bdev_ch[1] = spdk_io_channel_get_ctx(io_ch[1]); CU_ASSERT(bdev_ch[1]->flags == 0); set_thread(0); /* * Enable QoS: Read/Write IOPS, Read/Write byte, * Read only byte and Write only byte per second * rate limits. * More than 10 I/Os allowed per timeslice. */ status = -1; limits[SPDK_BDEV_QOS_RW_IOPS_RATE_LIMIT] = 10000; limits[SPDK_BDEV_QOS_RW_BPS_RATE_LIMIT] = 100; limits[SPDK_BDEV_QOS_R_BPS_RATE_LIMIT] = 100; limits[SPDK_BDEV_QOS_W_BPS_RATE_LIMIT] = 10; spdk_bdev_set_qos_rate_limits(bdev, limits, qos_dynamic_enable_done, &status); poll_threads(); CU_ASSERT(status == 0); CU_ASSERT((bdev_ch[0]->flags & BDEV_CH_QOS_ENABLED) != 0); CU_ASSERT((bdev_ch[1]->flags & BDEV_CH_QOS_ENABLED) != 0); /* * Submit and complete 10 I/O to fill the QoS allotment for this timeslice. * Additional I/O will then be queued. */ set_thread(0); for (i = 0; i < 10; i++) { bdev_io_status[0] = SPDK_BDEV_IO_STATUS_PENDING; rc = spdk_bdev_read_blocks(g_desc, io_ch[0], NULL, 0, 1, io_during_io_done, &bdev_io_status[0]); CU_ASSERT(rc == 0); CU_ASSERT(bdev_io_status[0] == SPDK_BDEV_IO_STATUS_PENDING); poll_thread(0); stub_complete_io(g_bdev.io_target, 0); CU_ASSERT(bdev_io_status[0] == SPDK_BDEV_IO_STATUS_SUCCESS); } /* * Send two more I/O. These I/O will be queued since the current timeslice allotment has been * filled already. We want to test that when QoS is disabled that these two I/O: * 1) are not aborted * 2) are sent back to their original thread for resubmission */ bdev_io_status[0] = SPDK_BDEV_IO_STATUS_PENDING; rc = spdk_bdev_read_blocks(g_desc, io_ch[0], NULL, 0, 1, io_during_io_done, &bdev_io_status[0]); CU_ASSERT(rc == 0); CU_ASSERT(bdev_io_status[0] == SPDK_BDEV_IO_STATUS_PENDING); set_thread(1); bdev_io_status[1] = SPDK_BDEV_IO_STATUS_PENDING; rc = spdk_bdev_read_blocks(g_desc, io_ch[1], NULL, 0, 1, io_during_io_done, &bdev_io_status[1]); CU_ASSERT(rc == 0); CU_ASSERT(bdev_io_status[1] == SPDK_BDEV_IO_STATUS_PENDING); poll_threads(); /* * Disable QoS: Read/Write IOPS, Read/Write byte, * Read only byte rate limits */ status = -1; limits[SPDK_BDEV_QOS_RW_IOPS_RATE_LIMIT] = 0; limits[SPDK_BDEV_QOS_RW_BPS_RATE_LIMIT] = 0; limits[SPDK_BDEV_QOS_R_BPS_RATE_LIMIT] = 0; spdk_bdev_set_qos_rate_limits(bdev, limits, qos_dynamic_enable_done, &status); poll_threads(); CU_ASSERT(status == 0); CU_ASSERT((bdev_ch[0]->flags & BDEV_CH_QOS_ENABLED) != 0); CU_ASSERT((bdev_ch[1]->flags & BDEV_CH_QOS_ENABLED) != 0); /* Disable QoS: Write only Byte per second rate limit */ status = -1; limits[SPDK_BDEV_QOS_W_BPS_RATE_LIMIT] = 0; spdk_bdev_set_qos_rate_limits(bdev, limits, qos_dynamic_enable_done, &status); poll_threads(); CU_ASSERT(status == 0); CU_ASSERT((bdev_ch[0]->flags & BDEV_CH_QOS_ENABLED) == 0); CU_ASSERT((bdev_ch[1]->flags & BDEV_CH_QOS_ENABLED) == 0); /* * All I/O should have been resubmitted back on their original thread. Complete * all I/O on thread 0, and ensure that only the thread 0 I/O was completed. */ set_thread(0); stub_complete_io(g_bdev.io_target, 0); poll_threads(); CU_ASSERT(bdev_io_status[0] == SPDK_BDEV_IO_STATUS_SUCCESS); CU_ASSERT(bdev_io_status[1] == SPDK_BDEV_IO_STATUS_PENDING); /* Now complete all I/O on thread 1 and ensure the thread 1 I/O was completed. */ set_thread(1); stub_complete_io(g_bdev.io_target, 0); poll_threads(); CU_ASSERT(bdev_io_status[1] == SPDK_BDEV_IO_STATUS_SUCCESS); /* Disable QoS again */ status = -1; limits[SPDK_BDEV_QOS_RW_IOPS_RATE_LIMIT] = 0; spdk_bdev_set_qos_rate_limits(bdev, limits, qos_dynamic_enable_done, &status); poll_threads(); CU_ASSERT(status == 0); /* This should succeed */ CU_ASSERT((bdev_ch[0]->flags & BDEV_CH_QOS_ENABLED) == 0); CU_ASSERT((bdev_ch[1]->flags & BDEV_CH_QOS_ENABLED) == 0); /* Enable QoS on thread 0 */ status = -1; limits[SPDK_BDEV_QOS_RW_IOPS_RATE_LIMIT] = 10000; spdk_bdev_set_qos_rate_limits(bdev, limits, qos_dynamic_enable_done, &status); poll_threads(); CU_ASSERT(status == 0); CU_ASSERT((bdev_ch[0]->flags & BDEV_CH_QOS_ENABLED) != 0); CU_ASSERT((bdev_ch[1]->flags & BDEV_CH_QOS_ENABLED) != 0); /* Disable QoS on thread 1 */ set_thread(1); status = -1; limits[SPDK_BDEV_QOS_RW_IOPS_RATE_LIMIT] = 0; spdk_bdev_set_qos_rate_limits(bdev, limits, qos_dynamic_enable_done, &status); /* Don't poll yet. This should leave the channels with QoS enabled */ CU_ASSERT(status == -1); CU_ASSERT((bdev_ch[0]->flags & BDEV_CH_QOS_ENABLED) != 0); CU_ASSERT((bdev_ch[1]->flags & BDEV_CH_QOS_ENABLED) != 0); /* Enable QoS. This should immediately fail because the previous disable QoS hasn't completed. */ second_status = 0; limits[SPDK_BDEV_QOS_RW_BPS_RATE_LIMIT] = 10; spdk_bdev_set_qos_rate_limits(bdev, limits, qos_dynamic_enable_done, &second_status); poll_threads(); CU_ASSERT(status == 0); /* The disable should succeed */ CU_ASSERT(second_status < 0); /* The enable should fail */ CU_ASSERT((bdev_ch[0]->flags & BDEV_CH_QOS_ENABLED) == 0); CU_ASSERT((bdev_ch[1]->flags & BDEV_CH_QOS_ENABLED) == 0); /* Enable QoS on thread 1. This should succeed now that the disable has completed. */ status = -1; limits[SPDK_BDEV_QOS_RW_IOPS_RATE_LIMIT] = 10000; spdk_bdev_set_qos_rate_limits(bdev, limits, qos_dynamic_enable_done, &status); poll_threads(); CU_ASSERT(status == 0); CU_ASSERT((bdev_ch[0]->flags & BDEV_CH_QOS_ENABLED) != 0); CU_ASSERT((bdev_ch[1]->flags & BDEV_CH_QOS_ENABLED) != 0); /* Tear down the channels */ set_thread(0); spdk_put_io_channel(io_ch[0]); set_thread(1); spdk_put_io_channel(io_ch[1]); poll_threads(); set_thread(0); teardown_test(); } static void histogram_status_cb(void *cb_arg, int status) { g_status = status; } static void histogram_data_cb(void *cb_arg, int status, struct spdk_histogram_data *histogram) { g_status = status; g_histogram = histogram; } static void histogram_io_count(void *ctx, uint64_t start, uint64_t end, uint64_t count, uint64_t total, uint64_t so_far) { g_count += count; } static void bdev_histograms_mt(void) { struct spdk_io_channel *ch[2]; struct spdk_histogram_data *histogram; uint8_t buf[4096]; int status = false; int rc; setup_test(); set_thread(0); ch[0] = spdk_bdev_get_io_channel(g_desc); CU_ASSERT(ch[0] != NULL); set_thread(1); ch[1] = spdk_bdev_get_io_channel(g_desc); CU_ASSERT(ch[1] != NULL); /* Enable histogram */ spdk_bdev_histogram_enable(&g_bdev.bdev, histogram_status_cb, NULL, true); poll_threads(); CU_ASSERT(g_status == 0); CU_ASSERT(g_bdev.bdev.internal.histogram_enabled == true); /* Allocate histogram */ histogram = spdk_histogram_data_alloc(); /* Check if histogram is zeroed */ spdk_bdev_histogram_get(&g_bdev.bdev, histogram, histogram_data_cb, NULL); poll_threads(); CU_ASSERT(g_status == 0); SPDK_CU_ASSERT_FATAL(g_histogram != NULL); g_count = 0; spdk_histogram_data_iterate(g_histogram, histogram_io_count, NULL); CU_ASSERT(g_count == 0); set_thread(0); rc = spdk_bdev_write_blocks(g_desc, ch[0], &buf, 0, 1, io_during_io_done, &status); CU_ASSERT(rc == 0); spdk_delay_us(10); stub_complete_io(g_bdev.io_target, 1); poll_threads(); CU_ASSERT(status == true); set_thread(1); rc = spdk_bdev_read_blocks(g_desc, ch[1], &buf, 0, 1, io_during_io_done, &status); CU_ASSERT(rc == 0); spdk_delay_us(10); stub_complete_io(g_bdev.io_target, 1); poll_threads(); CU_ASSERT(status == true); set_thread(0); /* Check if histogram gathered data from all I/O channels */ spdk_bdev_histogram_get(&g_bdev.bdev, histogram, histogram_data_cb, NULL); poll_threads(); CU_ASSERT(g_status == 0); CU_ASSERT(g_bdev.bdev.internal.histogram_enabled == true); SPDK_CU_ASSERT_FATAL(g_histogram != NULL); g_count = 0; spdk_histogram_data_iterate(g_histogram, histogram_io_count, NULL); CU_ASSERT(g_count == 2); /* Disable histogram */ spdk_bdev_histogram_enable(&g_bdev.bdev, histogram_status_cb, NULL, false); poll_threads(); CU_ASSERT(g_status == 0); CU_ASSERT(g_bdev.bdev.internal.histogram_enabled == false); spdk_histogram_data_free(histogram); /* Tear down the channels */ set_thread(0); spdk_put_io_channel(ch[0]); set_thread(1); spdk_put_io_channel(ch[1]); poll_threads(); set_thread(0); teardown_test(); } struct timeout_io_cb_arg { struct iovec iov; uint8_t type; }; static int bdev_channel_count_submitted_io(struct spdk_bdev_channel *ch) { struct spdk_bdev_io *bdev_io; int n = 0; if (!ch) { return -1; } TAILQ_FOREACH(bdev_io, &ch->io_submitted, internal.ch_link) { n++; } return n; } static void bdev_channel_io_timeout_cb(void *cb_arg, struct spdk_bdev_io *bdev_io) { struct timeout_io_cb_arg *ctx = cb_arg; ctx->type = bdev_io->type; ctx->iov.iov_base = bdev_io->iov.iov_base; ctx->iov.iov_len = bdev_io->iov.iov_len; } static bool g_io_done; static void io_done(struct spdk_bdev_io *bdev_io, bool success, void *cb_arg) { g_io_done = true; spdk_bdev_free_io(bdev_io); } static void bdev_set_io_timeout_mt(void) { struct spdk_io_channel *ch[3]; struct spdk_bdev_channel *bdev_ch[3]; struct timeout_io_cb_arg cb_arg; setup_test(); g_bdev.bdev.optimal_io_boundary = 16; g_bdev.bdev.split_on_optimal_io_boundary = true; set_thread(0); ch[0] = spdk_bdev_get_io_channel(g_desc); CU_ASSERT(ch[0] != NULL); set_thread(1); ch[1] = spdk_bdev_get_io_channel(g_desc); CU_ASSERT(ch[1] != NULL); set_thread(2); ch[2] = spdk_bdev_get_io_channel(g_desc); CU_ASSERT(ch[2] != NULL); /* Multi-thread mode * 1, Check the poller was registered successfully * 2, Check the timeout IO and ensure the IO was the submitted by user * 3, Check the link int the bdev_ch works right. * 4, Close desc and put io channel during the timeout poller is polling */ /* In desc thread set the timeout */ set_thread(0); CU_ASSERT(spdk_bdev_set_timeout(g_desc, 5, bdev_channel_io_timeout_cb, &cb_arg) == 0); CU_ASSERT(g_desc->io_timeout_poller != NULL); CU_ASSERT(g_desc->cb_fn == bdev_channel_io_timeout_cb); CU_ASSERT(g_desc->cb_arg == &cb_arg); /* check the IO submitted list and timeout handler */ CU_ASSERT(spdk_bdev_read_blocks(g_desc, ch[0], (void *)0x2000, 0, 1, io_done, NULL) == 0); bdev_ch[0] = spdk_io_channel_get_ctx(ch[0]); CU_ASSERT(bdev_channel_count_submitted_io(bdev_ch[0]) == 1); set_thread(1); CU_ASSERT(spdk_bdev_write_blocks(g_desc, ch[1], (void *)0x1000, 0, 1, io_done, NULL) == 0); bdev_ch[1] = spdk_io_channel_get_ctx(ch[1]); CU_ASSERT(bdev_channel_count_submitted_io(bdev_ch[1]) == 1); /* Now test that a single-vector command is split correctly. * Offset 14, length 8, payload 0xF000 * Child - Offset 14, length 2, payload 0xF000 * Child - Offset 16, length 6, payload 0xF000 + 2 * 512 * * Set up the expected values before calling spdk_bdev_read_blocks */ set_thread(2); CU_ASSERT(spdk_bdev_read_blocks(g_desc, ch[2], (void *)0xF000, 14, 8, io_done, NULL) == 0); bdev_ch[2] = spdk_io_channel_get_ctx(ch[2]); CU_ASSERT(bdev_channel_count_submitted_io(bdev_ch[2]) == 3); set_thread(0); memset(&cb_arg, 0, sizeof(cb_arg)); spdk_delay_us(3 * spdk_get_ticks_hz()); poll_threads(); CU_ASSERT(cb_arg.type == 0); CU_ASSERT(cb_arg.iov.iov_base == (void *)0x0); CU_ASSERT(cb_arg.iov.iov_len == 0); /* Now the time reach the limit */ spdk_delay_us(3 * spdk_get_ticks_hz()); poll_thread(0); CU_ASSERT(cb_arg.type == SPDK_BDEV_IO_TYPE_READ); CU_ASSERT(cb_arg.iov.iov_base == (void *)0x2000); CU_ASSERT(cb_arg.iov.iov_len == 1 * g_bdev.bdev.blocklen); stub_complete_io(g_bdev.io_target, 1); CU_ASSERT(bdev_channel_count_submitted_io(bdev_ch[0]) == 0); memset(&cb_arg, 0, sizeof(cb_arg)); set_thread(1); poll_thread(1); CU_ASSERT(cb_arg.type == SPDK_BDEV_IO_TYPE_WRITE); CU_ASSERT(cb_arg.iov.iov_base == (void *)0x1000); CU_ASSERT(cb_arg.iov.iov_len == 1 * g_bdev.bdev.blocklen); stub_complete_io(g_bdev.io_target, 1); CU_ASSERT(bdev_channel_count_submitted_io(bdev_ch[1]) == 0); memset(&cb_arg, 0, sizeof(cb_arg)); set_thread(2); poll_thread(2); CU_ASSERT(cb_arg.type == SPDK_BDEV_IO_TYPE_READ); CU_ASSERT(cb_arg.iov.iov_base == (void *)0xF000); CU_ASSERT(cb_arg.iov.iov_len == 8 * g_bdev.bdev.blocklen); stub_complete_io(g_bdev.io_target, 1); CU_ASSERT(bdev_channel_count_submitted_io(bdev_ch[2]) == 2); stub_complete_io(g_bdev.io_target, 1); CU_ASSERT(bdev_channel_count_submitted_io(bdev_ch[2]) == 0); /* Run poll_timeout_done() it means complete the timeout poller */ set_thread(0); poll_thread(0); CU_ASSERT(g_desc->refs == 0); CU_ASSERT(spdk_bdev_read_blocks(g_desc, ch[0], (void *)0x1000, 0, 1, io_done, NULL) == 0); set_thread(1); CU_ASSERT(spdk_bdev_write_blocks(g_desc, ch[1], (void *)0x2000, 0, 2, io_done, NULL) == 0); set_thread(2); CU_ASSERT(spdk_bdev_read_blocks(g_desc, ch[2], (void *)0x3000, 0, 3, io_done, NULL) == 0); /* Trigger timeout poller to run again, desc->refs is incremented. * In thread 0 we destroy the io channel before timeout poller runs. * Timeout callback is not called on thread 0. */ spdk_delay_us(6 * spdk_get_ticks_hz()); memset(&cb_arg, 0, sizeof(cb_arg)); set_thread(0); stub_complete_io(g_bdev.io_target, 1); spdk_put_io_channel(ch[0]); poll_thread(0); CU_ASSERT(g_desc->refs == 1) CU_ASSERT(cb_arg.type == 0); CU_ASSERT(cb_arg.iov.iov_base == (void *)0x0); CU_ASSERT(cb_arg.iov.iov_len == 0); /* In thread 1 timeout poller runs then we destroy the io channel * Timeout callback is called on thread 1. */ memset(&cb_arg, 0, sizeof(cb_arg)); set_thread(1); poll_thread(1); stub_complete_io(g_bdev.io_target, 1); spdk_put_io_channel(ch[1]); poll_thread(1); CU_ASSERT(cb_arg.type == SPDK_BDEV_IO_TYPE_WRITE); CU_ASSERT(cb_arg.iov.iov_base == (void *)0x2000); CU_ASSERT(cb_arg.iov.iov_len == 2 * g_bdev.bdev.blocklen); /* Close the desc. * Unregister the timeout poller first. * Then decrement desc->refs but it's not zero yet so desc is not freed. */ set_thread(0); spdk_bdev_close(g_desc); CU_ASSERT(g_desc->refs == 1); CU_ASSERT(g_desc->io_timeout_poller == NULL); /* Timeout poller runs on thread 2 then we destroy the io channel. * Desc is closed so we would exit the timeout poller directly. * timeout callback is not called on thread 2. */ memset(&cb_arg, 0, sizeof(cb_arg)); set_thread(2); poll_thread(2); stub_complete_io(g_bdev.io_target, 1); spdk_put_io_channel(ch[2]); poll_thread(2); CU_ASSERT(cb_arg.type == 0); CU_ASSERT(cb_arg.iov.iov_base == (void *)0x0); CU_ASSERT(cb_arg.iov.iov_len == 0); set_thread(0); poll_thread(0); g_teardown_done = false; unregister_bdev(&g_bdev); spdk_io_device_unregister(&g_io_device, NULL); spdk_bdev_finish(finish_cb, NULL); poll_threads(); memset(&g_bdev, 0, sizeof(g_bdev)); CU_ASSERT(g_teardown_done == true); g_teardown_done = false; free_threads(); free_cores(); } static bool g_io_done2; static bool g_lock_lba_range_done; static bool g_unlock_lba_range_done; static void io_done2(struct spdk_bdev_io *bdev_io, bool success, void *cb_arg) { g_io_done2 = true; spdk_bdev_free_io(bdev_io); } static void lock_lba_range_done(void *ctx, int status) { g_lock_lba_range_done = true; } static void unlock_lba_range_done(void *ctx, int status) { g_unlock_lba_range_done = true; } static uint32_t stub_channel_outstanding_cnt(void *io_target) { struct spdk_io_channel *_ch = spdk_get_io_channel(io_target); struct ut_bdev_channel *ch = spdk_io_channel_get_ctx(_ch); uint32_t outstanding_cnt; outstanding_cnt = ch->outstanding_cnt; spdk_put_io_channel(_ch); return outstanding_cnt; } static void lock_lba_range_then_submit_io(void) { struct spdk_bdev_desc *desc = NULL; void *io_target; struct spdk_io_channel *io_ch[3]; struct spdk_bdev_channel *bdev_ch[3]; struct lba_range *range; char buf[4096]; int ctx0, ctx1, ctx2; int rc; setup_test(); io_target = g_bdev.io_target; desc = g_desc; set_thread(0); io_ch[0] = spdk_bdev_get_io_channel(desc); bdev_ch[0] = spdk_io_channel_get_ctx(io_ch[0]); CU_ASSERT(io_ch[0] != NULL); set_thread(1); io_ch[1] = spdk_bdev_get_io_channel(desc); bdev_ch[1] = spdk_io_channel_get_ctx(io_ch[1]); CU_ASSERT(io_ch[1] != NULL); set_thread(0); g_lock_lba_range_done = false; rc = bdev_lock_lba_range(desc, io_ch[0], 20, 10, lock_lba_range_done, &ctx0); CU_ASSERT(rc == 0); poll_threads(); /* The lock should immediately become valid, since there are no outstanding * write I/O. */ CU_ASSERT(g_lock_lba_range_done == true); range = TAILQ_FIRST(&bdev_ch[0]->locked_ranges); SPDK_CU_ASSERT_FATAL(range != NULL); CU_ASSERT(range->offset == 20); CU_ASSERT(range->length == 10); CU_ASSERT(range->owner_ch == bdev_ch[0]); g_io_done = false; CU_ASSERT(TAILQ_EMPTY(&bdev_ch[0]->io_locked)); rc = spdk_bdev_read_blocks(desc, io_ch[0], buf, 20, 1, io_done, &ctx0); CU_ASSERT(rc == 0); CU_ASSERT(stub_channel_outstanding_cnt(io_target) == 1); stub_complete_io(io_target, 1); poll_threads(); CU_ASSERT(g_io_done == true); CU_ASSERT(TAILQ_EMPTY(&bdev_ch[0]->io_locked)); /* Try a write I/O. This should actually be allowed to execute, since the channel * holding the lock is submitting the write I/O. */ g_io_done = false; CU_ASSERT(TAILQ_EMPTY(&bdev_ch[0]->io_locked)); rc = spdk_bdev_write_blocks(desc, io_ch[0], buf, 20, 1, io_done, &ctx0); CU_ASSERT(rc == 0); CU_ASSERT(stub_channel_outstanding_cnt(io_target) == 1); stub_complete_io(io_target, 1); poll_threads(); CU_ASSERT(g_io_done == true); CU_ASSERT(TAILQ_EMPTY(&bdev_ch[0]->io_locked)); /* Try a write I/O. This should get queued in the io_locked tailq. */ set_thread(1); g_io_done = false; CU_ASSERT(TAILQ_EMPTY(&bdev_ch[1]->io_locked)); rc = spdk_bdev_write_blocks(desc, io_ch[1], buf, 20, 1, io_done, &ctx1); CU_ASSERT(rc == 0); poll_threads(); CU_ASSERT(stub_channel_outstanding_cnt(io_target) == 0); CU_ASSERT(!TAILQ_EMPTY(&bdev_ch[1]->io_locked)); CU_ASSERT(g_io_done == false); /* Try to unlock the lba range using thread 1's io_ch. This should fail. */ rc = bdev_unlock_lba_range(desc, io_ch[1], 20, 10, unlock_lba_range_done, &ctx1); CU_ASSERT(rc == -EINVAL); /* Now create a new channel and submit a write I/O with it. This should also be queued. * The new channel should inherit the active locks from the bdev's internal list. */ set_thread(2); io_ch[2] = spdk_bdev_get_io_channel(desc); bdev_ch[2] = spdk_io_channel_get_ctx(io_ch[2]); CU_ASSERT(io_ch[2] != NULL); g_io_done2 = false; CU_ASSERT(TAILQ_EMPTY(&bdev_ch[2]->io_locked)); rc = spdk_bdev_write_blocks(desc, io_ch[2], buf, 22, 2, io_done2, &ctx2); CU_ASSERT(rc == 0); poll_threads(); CU_ASSERT(stub_channel_outstanding_cnt(io_target) == 0); CU_ASSERT(!TAILQ_EMPTY(&bdev_ch[2]->io_locked)); CU_ASSERT(g_io_done2 == false); set_thread(0); rc = bdev_unlock_lba_range(desc, io_ch[0], 20, 10, unlock_lba_range_done, &ctx0); CU_ASSERT(rc == 0); poll_threads(); CU_ASSERT(TAILQ_EMPTY(&bdev_ch[0]->locked_ranges)); /* The LBA range is unlocked, so the write IOs should now have started execution. */ CU_ASSERT(TAILQ_EMPTY(&bdev_ch[1]->io_locked)); CU_ASSERT(TAILQ_EMPTY(&bdev_ch[2]->io_locked)); set_thread(1); CU_ASSERT(stub_channel_outstanding_cnt(io_target) == 1); stub_complete_io(io_target, 1); set_thread(2); CU_ASSERT(stub_channel_outstanding_cnt(io_target) == 1); stub_complete_io(io_target, 1); poll_threads(); CU_ASSERT(g_io_done == true); CU_ASSERT(g_io_done2 == true); /* Tear down the channels */ set_thread(0); spdk_put_io_channel(io_ch[0]); set_thread(1); spdk_put_io_channel(io_ch[1]); set_thread(2); spdk_put_io_channel(io_ch[2]); poll_threads(); set_thread(0); teardown_test(); } int main(int argc, char **argv) { CU_pSuite suite = NULL; unsigned int num_failures; CU_set_error_action(CUEA_ABORT); CU_initialize_registry(); suite = CU_add_suite("bdev", NULL, NULL); CU_ADD_TEST(suite, basic); CU_ADD_TEST(suite, unregister_and_close); CU_ADD_TEST(suite, basic_qos); CU_ADD_TEST(suite, put_channel_during_reset); CU_ADD_TEST(suite, aborted_reset); CU_ADD_TEST(suite, io_during_reset); CU_ADD_TEST(suite, io_during_qos_queue); CU_ADD_TEST(suite, io_during_qos_reset); CU_ADD_TEST(suite, enomem); CU_ADD_TEST(suite, enomem_multi_bdev); CU_ADD_TEST(suite, enomem_multi_io_target); CU_ADD_TEST(suite, qos_dynamic_enable); CU_ADD_TEST(suite, bdev_histograms_mt); CU_ADD_TEST(suite, bdev_set_io_timeout_mt); CU_ADD_TEST(suite, lock_lba_range_then_submit_io); CU_basic_set_mode(CU_BRM_VERBOSE); CU_basic_run_tests(); num_failures = CU_get_number_of_failures(); CU_cleanup_registry(); return num_failures; }