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29784f35cd
Spdk/examples/bdev/bdevperf/bdevperf.c
Krzysztof Karas 29784f35cd bdevperf: promote bdevperf from test to example application 
bdevperf application is utilized in multiple test scenarios
and most prominently in SPDK performance reports.
Similar to perf and fio_plugins, it is used to measure performance.
It is intended to represent the expected behavior of users
application that use SPDK bdev layer.

Applications under --enable-tests are intended for specific test
scenarios and user interaction is usually via a test scripts.
Meanwhile --enable-examples are used more broadly to teach and
show usage of SPDK libraries.

As an added benefit with this patch, its possible to compile
bdevperf without need to satisfy additional requirements to
compile all the test applications.

Change-Id: I9aaec1f9d729a1cdee89b5fdc365d61c19b03f82
Signed-off-by: Krzysztof Karas <krzysztof.karas@intel.com>
Reviewed-on: https://review.spdk.io/gerrit/c/spdk/spdk/+/14558
Reviewed-by: Tomasz Zawadzki <tomasz.zawadzki@intel.com>
Reviewed-by: Aleksey Marchuk <alexeymar@nvidia.com>
Reviewed-by: Paul Luse <paul.e.luse@intel.com>
Tested-by: SPDK CI Jenkins <sys_sgci@intel.com>
Community-CI: Mellanox Build Bot
2022-11-16 09:52:41 +00:00

2231 lines
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/* SPDX-License-Identifier: BSD-3-Clause
* Copyright (C) 2016 Intel Corporation.
* Copyright (c) 2022 NVIDIA CORPORATION & AFFILIATES.
* All rights reserved.
*/
#include "spdk/stdinc.h"
#include "spdk/bdev.h"
#include "spdk/accel.h"
#include "spdk/endian.h"
#include "spdk/env.h"
#include "spdk/event.h"
#include "spdk/log.h"
#include "spdk/util.h"
#include "spdk/thread.h"
#include "spdk/string.h"
#include "spdk/rpc.h"
#include "spdk/bit_array.h"
#include "spdk/conf.h"
#include "spdk/zipf.h"
#define BDEVPERF_CONFIG_MAX_FILENAME 1024
#define BDEVPERF_CONFIG_UNDEFINED -1
#define BDEVPERF_CONFIG_ERROR -2
struct bdevperf_task {
struct iovec iov;
struct bdevperf_job *job;
struct spdk_bdev_io *bdev_io;
void *buf;
void *md_buf;
uint64_t offset_blocks;
struct bdevperf_task *task_to_abort;
enum spdk_bdev_io_type io_type;
TAILQ_ENTRY(bdevperf_task) link;
struct spdk_bdev_io_wait_entry bdev_io_wait;
};
static const char *g_workload_type = NULL;
static int g_io_size = 0;
/* initialize to invalid value so we can detect if user overrides it. */
static int g_rw_percentage = -1;
static bool g_verify = false;
static bool g_reset = false;
static bool g_continue_on_failure = false;
static bool g_abort = false;
static bool g_error_to_exit = false;
static int g_queue_depth = 0;
static uint64_t g_time_in_usec;
static int g_show_performance_real_time = 0;
static uint64_t g_show_performance_period_in_usec = 1000000;
static uint64_t g_show_performance_period_num = 0;
static uint64_t g_show_performance_ema_period = 0;
static int g_run_rc = 0;
static bool g_shutdown = false;
static uint64_t g_start_tsc;
static uint64_t g_shutdown_tsc;
static bool g_zcopy = false;
static struct spdk_thread *g_main_thread;
static int g_time_in_sec = 0;
static bool g_mix_specified = false;
static const char *g_job_bdev_name;
static bool g_wait_for_tests = false;
static struct spdk_jsonrpc_request *g_request = NULL;
static bool g_multithread_mode = false;
static int g_timeout_in_sec;
static struct spdk_conf *g_bdevperf_conf = NULL;
static const char *g_bdevperf_conf_file = NULL;
static double g_zipf_theta;
static struct spdk_cpuset g_all_cpuset;
static struct spdk_poller *g_perf_timer = NULL;
static void bdevperf_submit_single(struct bdevperf_job *job, struct bdevperf_task *task);
static void rpc_perform_tests_cb(void);
struct bdevperf_job {
char *name;
struct spdk_bdev *bdev;
struct spdk_bdev_desc *bdev_desc;
struct spdk_io_channel *ch;
TAILQ_ENTRY(bdevperf_job) link;
struct spdk_thread *thread;
const char *workload_type;
int io_size;
int rw_percentage;
bool is_random;
bool verify;
bool reset;
bool continue_on_failure;
bool unmap;
bool write_zeroes;
bool flush;
bool abort;
int queue_depth;
unsigned int seed;
uint64_t io_completed;
uint64_t io_failed;
uint64_t io_timeout;
uint64_t prev_io_completed;
double ema_io_per_second;
int current_queue_depth;
uint64_t size_in_ios;
uint64_t ios_base;
uint64_t offset_in_ios;
uint64_t io_size_blocks;
uint64_t buf_size;
uint32_t dif_check_flags;
bool is_draining;
struct spdk_poller *run_timer;
struct spdk_poller *reset_timer;
struct spdk_bit_array *outstanding;
struct spdk_zipf *zipf;
TAILQ_HEAD(, bdevperf_task) task_list;
uint64_t run_time_in_usec;
};
struct spdk_bdevperf {
TAILQ_HEAD(, bdevperf_job) jobs;
uint32_t running_jobs;
};
static struct spdk_bdevperf g_bdevperf = {
.jobs = TAILQ_HEAD_INITIALIZER(g_bdevperf.jobs),
.running_jobs = 0,
};
enum job_config_rw {
JOB_CONFIG_RW_READ = 0,
JOB_CONFIG_RW_WRITE,
JOB_CONFIG_RW_RANDREAD,
JOB_CONFIG_RW_RANDWRITE,
JOB_CONFIG_RW_RW,
JOB_CONFIG_RW_RANDRW,
JOB_CONFIG_RW_VERIFY,
JOB_CONFIG_RW_RESET,
JOB_CONFIG_RW_UNMAP,
JOB_CONFIG_RW_FLUSH,
JOB_CONFIG_RW_WRITE_ZEROES,
};
/* Storing values from a section of job config file */
struct job_config {
const char *name;
const char *filename;
struct spdk_cpuset cpumask;
int bs;
int iodepth;
int rwmixread;
int64_t offset;
uint64_t length;
enum job_config_rw rw;
TAILQ_ENTRY(job_config) link;
};
TAILQ_HEAD(, job_config) job_config_list
= TAILQ_HEAD_INITIALIZER(job_config_list);
static bool g_performance_dump_active = false;
struct bdevperf_aggregate_stats {
struct bdevperf_job *current_job;
uint64_t io_time_in_usec;
uint64_t ema_period;
double total_io_per_second;
double total_mb_per_second;
double total_failed_per_second;
double total_timeout_per_second;
};
static struct bdevperf_aggregate_stats g_stats = {};
/*
* Cumulative Moving Average (CMA): average of all data up to current
* Exponential Moving Average (EMA): weighted mean of the previous n data and more weight is given to recent
* Simple Moving Average (SMA): unweighted mean of the previous n data
*
* Bdevperf supports CMA and EMA.
*/
static double
get_cma_io_per_second(struct bdevperf_job *job, uint64_t io_time_in_usec)
{
return (double)job->io_completed * 1000000 / io_time_in_usec;
}
static double
get_ema_io_per_second(struct bdevperf_job *job, uint64_t ema_period)
{
double io_completed, io_per_second;
io_completed = job->io_completed;
io_per_second = (double)(io_completed - job->prev_io_completed) * 1000000
/ g_show_performance_period_in_usec;
job->prev_io_completed = io_completed;
job->ema_io_per_second += (io_per_second - job->ema_io_per_second) * 2
/ (ema_period + 1);
return job->ema_io_per_second;
}
static void
performance_dump_job(struct bdevperf_aggregate_stats *stats, struct bdevperf_job *job)
{
double io_per_second, mb_per_second, failed_per_second, timeout_per_second;
uint64_t time_in_usec;
printf("\r Job: %s (Core Mask 0x%s)\n", spdk_thread_get_name(job->thread),
spdk_cpuset_fmt(spdk_thread_get_cpumask(job->thread)));
if (job->io_failed > 0 && !job->reset && !job->continue_on_failure) {
printf("\r Job: %s ended in about %.2f seconds with error\n",
spdk_thread_get_name(job->thread), (double)job->run_time_in_usec / 1000000);
}
if (job->verify) {
printf("\t Verification LBA range: start 0x%" PRIx64 " length 0x%" PRIx64 "\n",
job->ios_base, job->size_in_ios);
}
if (g_performance_dump_active == true) {
/* Use job's actual run time as Job has ended */
if (job->io_failed > 0 && !job->continue_on_failure) {
time_in_usec = job->run_time_in_usec;
} else {
time_in_usec = stats->io_time_in_usec;
}
} else {
time_in_usec = job->run_time_in_usec;
}
if (stats->ema_period == 0) {
io_per_second = get_cma_io_per_second(job, time_in_usec);
} else {
io_per_second = get_ema_io_per_second(job, stats->ema_period);
}
mb_per_second = io_per_second * job->io_size / (1024 * 1024);
failed_per_second = (double)job->io_failed * 1000000 / time_in_usec;
timeout_per_second = (double)job->io_timeout * 1000000 / time_in_usec;
printf("\t %-20s: %10.2f %10.2f %10.2f",
job->name, (float)time_in_usec / 1000000, io_per_second, mb_per_second);
printf(" %10.2f %8.2f\n",
failed_per_second, timeout_per_second);
stats->total_io_per_second += io_per_second;
stats->total_mb_per_second += mb_per_second;
stats->total_failed_per_second += failed_per_second;
stats->total_timeout_per_second += timeout_per_second;
}
static void
generate_data(void *buf, int buf_len, int block_size, void *md_buf, int md_size,
int num_blocks)
{
int offset_blocks = 0, md_offset, data_block_size, inner_offset;
if (buf_len < num_blocks * block_size) {
return;
}
if (md_buf == NULL) {
data_block_size = block_size - md_size;
md_buf = (char *)buf + data_block_size;
md_offset = block_size;
} else {
data_block_size = block_size;
md_offset = md_size;
}
while (offset_blocks < num_blocks) {
inner_offset = 0;
while (inner_offset < data_block_size) {
*(uint32_t *)buf = offset_blocks + inner_offset;
inner_offset += sizeof(uint32_t);
buf += sizeof(uint32_t);
}
memset(md_buf, offset_blocks, md_size);
md_buf += md_offset;
offset_blocks++;
}
}
static bool
copy_data(void *wr_buf, int wr_buf_len, void *rd_buf, int rd_buf_len, int block_size,
void *wr_md_buf, void *rd_md_buf, int md_size, int num_blocks)
{
if (wr_buf_len < num_blocks * block_size || rd_buf_len < num_blocks * block_size) {
return false;
}
assert((wr_md_buf != NULL) == (rd_md_buf != NULL));
memcpy(wr_buf, rd_buf, block_size * num_blocks);
if (wr_md_buf != NULL) {
memcpy(wr_md_buf, rd_md_buf, md_size * num_blocks);
}
return true;
}
static bool
verify_data(void *wr_buf, int wr_buf_len, void *rd_buf, int rd_buf_len, int block_size,
void *wr_md_buf, void *rd_md_buf, int md_size, int num_blocks, bool md_check)
{
int offset_blocks = 0, md_offset, data_block_size;
if (wr_buf_len < num_blocks * block_size || rd_buf_len < num_blocks * block_size) {
return false;
}
assert((wr_md_buf != NULL) == (rd_md_buf != NULL));
if (wr_md_buf == NULL) {
data_block_size = block_size - md_size;
wr_md_buf = (char *)wr_buf + data_block_size;
rd_md_buf = (char *)rd_buf + data_block_size;
md_offset = block_size;
} else {
data_block_size = block_size;
md_offset = md_size;
}
while (offset_blocks < num_blocks) {
if (memcmp(wr_buf, rd_buf, data_block_size) != 0) {
return false;
}
wr_buf += block_size;
rd_buf += block_size;
if (md_check) {
if (memcmp(wr_md_buf, rd_md_buf, md_size) != 0) {
return false;
}
wr_md_buf += md_offset;
rd_md_buf += md_offset;
}
offset_blocks++;
}
return true;
}
static void
free_job_config(void)
{
struct job_config *config, *tmp;
spdk_conf_free(g_bdevperf_conf);
g_bdevperf_conf = NULL;
TAILQ_FOREACH_SAFE(config, &job_config_list, link, tmp) {
TAILQ_REMOVE(&job_config_list, config, link);
free(config);
}
}
static void
bdevperf_test_done(void *ctx)
{
struct bdevperf_job *job, *jtmp;
struct bdevperf_task *task, *ttmp;
int rc;
uint64_t time_in_usec;
if (g_time_in_usec) {
g_stats.io_time_in_usec = g_time_in_usec;
if (!g_run_rc && g_performance_dump_active) {
spdk_thread_send_msg(spdk_get_thread(), bdevperf_test_done, NULL);
return;
}
}
if (g_show_performance_real_time) {
spdk_poller_unregister(&g_perf_timer);
}
if (g_shutdown) {
g_shutdown_tsc = spdk_get_ticks() - g_start_tsc;
time_in_usec = g_shutdown_tsc * 1000000 / spdk_get_ticks_hz();
g_time_in_usec = (g_time_in_usec > time_in_usec) ? time_in_usec : g_time_in_usec;
printf("Received shutdown signal, test time was about %.6f seconds\n",
(double)g_time_in_usec / 1000000);
}
printf("\n\r %-*s: %10s %10s %10s %10s %8s\n",
28, "Device Information", "runtime(s)", "IOPS", "MiB/s", "Fail/s", "TO/s");
TAILQ_FOREACH_SAFE(job, &g_bdevperf.jobs, link, jtmp) {
TAILQ_REMOVE(&g_bdevperf.jobs, job, link);
performance_dump_job(&g_stats, job);
TAILQ_FOREACH_SAFE(task, &job->task_list, link, ttmp) {
TAILQ_REMOVE(&job->task_list, task, link);
spdk_free(task->buf);
spdk_free(task->md_buf);
free(task);
}
if (job->verify) {
spdk_bit_array_free(&job->outstanding);
}
spdk_zipf_free(&job->zipf);
free(job->name);
free(job);
}
printf("\r ==================================================================================\n");
printf("\r %-28s: %10s %10.2f %10.2f",
"Total", "", g_stats.total_io_per_second, g_stats.total_mb_per_second);
printf(" %10.2f %8.2f\n",
g_stats.total_failed_per_second, g_stats.total_timeout_per_second);
fflush(stdout);
rc = g_run_rc;
if (g_request && !g_shutdown) {
rpc_perform_tests_cb();
if (rc != 0) {
spdk_app_stop(rc);
}
} else {
spdk_app_stop(rc);
}
}
static void
bdevperf_job_end(void *ctx)
{
assert(g_main_thread == spdk_get_thread());
if (--g_bdevperf.running_jobs == 0) {
bdevperf_test_done(NULL);
}
}
static void
bdevperf_end_task(struct bdevperf_task *task)
{
struct bdevperf_job *job = task->job;
uint64_t end_tsc = 0;
TAILQ_INSERT_TAIL(&job->task_list, task, link);
if (job->is_draining) {
if (job->current_queue_depth == 0) {
end_tsc = spdk_get_ticks() - g_start_tsc;
job->run_time_in_usec = end_tsc * 1000000 / spdk_get_ticks_hz();
spdk_put_io_channel(job->ch);
spdk_bdev_close(job->bdev_desc);
spdk_thread_send_msg(g_main_thread, bdevperf_job_end, NULL);
}
}
}
static void
bdevperf_queue_io_wait_with_cb(struct bdevperf_task *task, spdk_bdev_io_wait_cb cb_fn)
{
struct bdevperf_job *job = task->job;
task->bdev_io_wait.bdev = job->bdev;
task->bdev_io_wait.cb_fn = cb_fn;
task->bdev_io_wait.cb_arg = task;
spdk_bdev_queue_io_wait(job->bdev, job->ch, &task->bdev_io_wait);
}
static int
bdevperf_job_drain(void *ctx)
{
struct bdevperf_job *job = ctx;
spdk_poller_unregister(&job->run_timer);
if (job->reset) {
spdk_poller_unregister(&job->reset_timer);
}
job->is_draining = true;
return -1;
}
static void
bdevperf_abort_complete(struct spdk_bdev_io *bdev_io, bool success, void *cb_arg)
{
struct bdevperf_task *task = cb_arg;
struct bdevperf_job *job = task->job;
job->current_queue_depth--;
if (success) {
job->io_completed++;
} else {
job->io_failed++;
if (!job->continue_on_failure) {
bdevperf_job_drain(job);
g_run_rc = -1;
}
}
spdk_bdev_free_io(bdev_io);
bdevperf_end_task(task);
}
static int
bdevperf_verify_dif(struct bdevperf_task *task, struct iovec *iovs, int iovcnt)
{
struct bdevperf_job *job = task->job;
struct spdk_bdev *bdev = job->bdev;
struct spdk_dif_ctx dif_ctx;
struct spdk_dif_error err_blk = {};
int rc;
rc = spdk_dif_ctx_init(&dif_ctx,
spdk_bdev_get_block_size(bdev),
spdk_bdev_get_md_size(bdev),
spdk_bdev_is_md_interleaved(bdev),
spdk_bdev_is_dif_head_of_md(bdev),
spdk_bdev_get_dif_type(bdev),
job->dif_check_flags,
task->offset_blocks, 0, 0, 0, 0);
if (rc != 0) {
fprintf(stderr, "Initialization of DIF context failed\n");
return rc;
}
if (spdk_bdev_is_md_interleaved(bdev)) {
rc = spdk_dif_verify(iovs, iovcnt, job->io_size_blocks, &dif_ctx, &err_blk);
} else {
struct iovec md_iov = {
.iov_base = task->md_buf,
.iov_len = spdk_bdev_get_md_size(bdev) * job->io_size_blocks,
};
rc = spdk_dix_verify(iovs, iovcnt, &md_iov, job->io_size_blocks, &dif_ctx, &err_blk);
}
if (rc != 0) {
fprintf(stderr, "DIF/DIX error detected. type=%d, offset=%" PRIu32 "\n",
err_blk.err_type, err_blk.err_offset);
}
return rc;
}
static void
bdevperf_complete(struct spdk_bdev_io *bdev_io, bool success, void *cb_arg)
{
struct bdevperf_job *job;
struct bdevperf_task *task = cb_arg;
struct iovec *iovs;
int iovcnt;
bool md_check;
uint64_t offset_in_ios;
int rc;
job = task->job;
md_check = spdk_bdev_get_dif_type(job->bdev) == SPDK_DIF_DISABLE;
if (g_error_to_exit == true) {
bdevperf_job_drain(job);
} else if (!success) {
if (!job->reset && !job->continue_on_failure) {
bdevperf_job_drain(job);
g_run_rc = -1;
g_error_to_exit = true;
printf("task offset: %" PRIu64 " on job bdev=%s fails\n",
task->offset_blocks, job->name);
}
} else if (job->verify || job->reset) {
spdk_bdev_io_get_iovec(bdev_io, &iovs, &iovcnt);
assert(iovcnt == 1);
assert(iovs != NULL);
if (!verify_data(task->buf, job->buf_size, iovs[0].iov_base, iovs[0].iov_len,
spdk_bdev_get_block_size(job->bdev),
task->md_buf, spdk_bdev_io_get_md_buf(bdev_io),
spdk_bdev_get_md_size(job->bdev),
job->io_size_blocks, md_check)) {
printf("Buffer mismatch! Target: %s Disk Offset: %" PRIu64 "\n", job->name, task->offset_blocks);
printf(" First dword expected 0x%x got 0x%x\n", *(int *)task->buf, *(int *)iovs[0].iov_base);
bdevperf_job_drain(job);
g_run_rc = -1;
}
} else if (job->dif_check_flags != 0) {
if (task->io_type == SPDK_BDEV_IO_TYPE_READ && spdk_bdev_get_md_size(job->bdev) != 0) {
spdk_bdev_io_get_iovec(bdev_io, &iovs, &iovcnt);
assert(iovcnt == 1);
assert(iovs != NULL);
rc = bdevperf_verify_dif(task, iovs, iovcnt);
if (rc != 0) {
printf("DIF error detected. task offset: %" PRIu64 " on job bdev=%s\n",
task->offset_blocks, job->name);
success = false;
if (!job->reset && !job->continue_on_failure) {
bdevperf_job_drain(job);
g_run_rc = -1;
g_error_to_exit = true;
}
}
}
}
job->current_queue_depth--;
if (success) {
job->io_completed++;
} else {
job->io_failed++;
}
if (job->verify) {
assert(task->offset_blocks / job->io_size_blocks >= job->ios_base);
offset_in_ios = task->offset_blocks / job->io_size_blocks - job->ios_base;
assert(spdk_bit_array_get(job->outstanding, offset_in_ios) == true);
spdk_bit_array_clear(job->outstanding, offset_in_ios);
}
spdk_bdev_free_io(bdev_io);
/*
* is_draining indicates when time has expired for the test run
* and we are just waiting for the previously submitted I/O
* to complete. In this case, do not submit a new I/O to replace
* the one just completed.
*/
if (!job->is_draining) {
bdevperf_submit_single(job, task);
} else {
bdevperf_end_task(task);
}
}
static void
bdevperf_verify_submit_read(void *cb_arg)
{
struct bdevperf_job *job;
struct bdevperf_task *task = cb_arg;
int rc;
job = task->job;
/* Read the data back in */
rc = spdk_bdev_read_blocks_with_md(job->bdev_desc, job->ch, NULL, NULL,
task->offset_blocks, job->io_size_blocks,
bdevperf_complete, task);
if (rc == -ENOMEM) {
bdevperf_queue_io_wait_with_cb(task, bdevperf_verify_submit_read);
} else if (rc != 0) {
printf("Failed to submit read: %d\n", rc);
bdevperf_job_drain(job);
g_run_rc = rc;
}
}
static void
bdevperf_verify_write_complete(struct spdk_bdev_io *bdev_io, bool success,
void *cb_arg)
{
if (success) {
spdk_bdev_free_io(bdev_io);
bdevperf_verify_submit_read(cb_arg);
} else {
bdevperf_complete(bdev_io, success, cb_arg);
}
}
static void
bdevperf_zcopy_populate_complete(struct spdk_bdev_io *bdev_io, bool success, void *cb_arg)
{
if (!success) {
bdevperf_complete(bdev_io, success, cb_arg);
return;
}
spdk_bdev_zcopy_end(bdev_io, false, bdevperf_complete, cb_arg);
}
static int
bdevperf_generate_dif(struct bdevperf_task *task)
{
struct bdevperf_job *job = task->job;
struct spdk_bdev *bdev = job->bdev;
struct spdk_dif_ctx dif_ctx;
int rc;
rc = spdk_dif_ctx_init(&dif_ctx,
spdk_bdev_get_block_size(bdev),
spdk_bdev_get_md_size(bdev),
spdk_bdev_is_md_interleaved(bdev),
spdk_bdev_is_dif_head_of_md(bdev),
spdk_bdev_get_dif_type(bdev),
job->dif_check_flags,
task->offset_blocks, 0, 0, 0, 0);
if (rc != 0) {
fprintf(stderr, "Initialization of DIF context failed\n");
return rc;
}
if (spdk_bdev_is_md_interleaved(bdev)) {
rc = spdk_dif_generate(&task->iov, 1, job->io_size_blocks, &dif_ctx);
} else {
struct iovec md_iov = {
.iov_base = task->md_buf,
.iov_len = spdk_bdev_get_md_size(bdev) * job->io_size_blocks,
};
rc = spdk_dix_generate(&task->iov, 1, &md_iov, job->io_size_blocks, &dif_ctx);
}
if (rc != 0) {
fprintf(stderr, "Generation of DIF/DIX failed\n");
}
return rc;
}
static void
bdevperf_submit_task(void *arg)
{
struct bdevperf_task *task = arg;
struct bdevperf_job *job = task->job;
struct spdk_bdev_desc *desc;
struct spdk_io_channel *ch;
spdk_bdev_io_completion_cb cb_fn;
uint64_t offset_in_ios;
int rc = 0;
desc = job->bdev_desc;
ch = job->ch;
switch (task->io_type) {
case SPDK_BDEV_IO_TYPE_WRITE:
if (spdk_bdev_get_md_size(job->bdev) != 0 && job->dif_check_flags != 0) {
rc = bdevperf_generate_dif(task);
}
if (rc == 0) {
cb_fn = (job->verify || job->reset) ? bdevperf_verify_write_complete : bdevperf_complete;
if (g_zcopy) {
spdk_bdev_zcopy_end(task->bdev_io, true, cb_fn, task);
return;
} else {
rc = spdk_bdev_writev_blocks_with_md(desc, ch, &task->iov, 1,
task->md_buf,
task->offset_blocks,
job->io_size_blocks,
cb_fn, task);
}
}
break;
case SPDK_BDEV_IO_TYPE_FLUSH:
rc = spdk_bdev_flush_blocks(desc, ch, task->offset_blocks,
job->io_size_blocks, bdevperf_complete, task);
break;
case SPDK_BDEV_IO_TYPE_UNMAP:
rc = spdk_bdev_unmap_blocks(desc, ch, task->offset_blocks,
job->io_size_blocks, bdevperf_complete, task);
break;
case SPDK_BDEV_IO_TYPE_WRITE_ZEROES:
rc = spdk_bdev_write_zeroes_blocks(desc, ch, task->offset_blocks,
job->io_size_blocks, bdevperf_complete, task);
break;
case SPDK_BDEV_IO_TYPE_READ:
if (g_zcopy) {
rc = spdk_bdev_zcopy_start(desc, ch, NULL, 0, task->offset_blocks, job->io_size_blocks,
true, bdevperf_zcopy_populate_complete, task);
} else {
rc = spdk_bdev_read_blocks_with_md(desc, ch, task->buf, task->md_buf,
task->offset_blocks,
job->io_size_blocks,
bdevperf_complete, task);
}
break;
case SPDK_BDEV_IO_TYPE_ABORT:
rc = spdk_bdev_abort(desc, ch, task->task_to_abort, bdevperf_abort_complete, task);
break;
default:
assert(false);
rc = -EINVAL;
break;
}
if (rc == -ENOMEM) {
bdevperf_queue_io_wait_with_cb(task, bdevperf_submit_task);
return;
} else if (rc != 0) {
printf("Failed to submit bdev_io: %d\n", rc);
if (job->verify) {
assert(task->offset_blocks / job->io_size_blocks >= job->ios_base);
offset_in_ios = task->offset_blocks / job->io_size_blocks - job->ios_base;
assert(spdk_bit_array_get(job->outstanding, offset_in_ios) == true);
spdk_bit_array_clear(job->outstanding, offset_in_ios);
}
bdevperf_job_drain(job);
g_run_rc = rc;
return;
}
job->current_queue_depth++;
}
static void
bdevperf_zcopy_get_buf_complete(struct spdk_bdev_io *bdev_io, bool success, void *cb_arg)
{
struct bdevperf_task *task = cb_arg;
struct bdevperf_job *job = task->job;
struct iovec *iovs;
int iovcnt;
if (!success) {
bdevperf_job_drain(job);
g_run_rc = -1;
return;
}
task->bdev_io = bdev_io;
task->io_type = SPDK_BDEV_IO_TYPE_WRITE;
if (job->verify || job->reset) {
/* When job->verify or job->reset is enabled, task->buf is used for
* verification of read after write. For write I/O, when zcopy APIs
* are used, task->buf cannot be used, and data must be written to
* the data buffer allocated underneath bdev layer instead.
* Hence we copy task->buf to the allocated data buffer here.
*/
spdk_bdev_io_get_iovec(bdev_io, &iovs, &iovcnt);
assert(iovcnt == 1);
assert(iovs != NULL);
copy_data(iovs[0].iov_base, iovs[0].iov_len, task->buf, job->buf_size,
spdk_bdev_get_block_size(job->bdev),
spdk_bdev_io_get_md_buf(bdev_io), task->md_buf,
spdk_bdev_get_md_size(job->bdev), job->io_size_blocks);
}
bdevperf_submit_task(task);
}
static void
bdevperf_prep_zcopy_write_task(void *arg)
{
struct bdevperf_task *task = arg;
struct bdevperf_job *job = task->job;
int rc;
rc = spdk_bdev_zcopy_start(job->bdev_desc, job->ch, NULL, 0,
task->offset_blocks, job->io_size_blocks,
false, bdevperf_zcopy_get_buf_complete, task);
if (rc != 0) {
assert(rc == -ENOMEM);
bdevperf_queue_io_wait_with_cb(task, bdevperf_prep_zcopy_write_task);
return;
}
job->current_queue_depth++;
}
static struct bdevperf_task *
bdevperf_job_get_task(struct bdevperf_job *job)
{
struct bdevperf_task *task;
task = TAILQ_FIRST(&job->task_list);
if (!task) {
printf("Task allocation failed\n");
abort();
}
TAILQ_REMOVE(&job->task_list, task, link);
return task;
}
static void
bdevperf_submit_single(struct bdevperf_job *job, struct bdevperf_task *task)
{
uint64_t offset_in_ios;
if (job->zipf) {
offset_in_ios = spdk_zipf_generate(job->zipf);
} else if (job->is_random) {
offset_in_ios = rand_r(&job->seed) % job->size_in_ios;
} else {
offset_in_ios = job->offset_in_ios++;
if (job->offset_in_ios == job->size_in_ios) {
job->offset_in_ios = 0;
}
/* Increment of offset_in_ios if there's already an outstanding IO
* to that location. We only need this with job->verify as random
* offsets are not supported with job->verify at this time.
*/
if (job->verify) {
assert(spdk_bit_array_find_first_clear(job->outstanding, 0) != UINT32_MAX);
while (spdk_bit_array_get(job->outstanding, offset_in_ios)) {
offset_in_ios = job->offset_in_ios++;
if (job->offset_in_ios == job->size_in_ios) {
job->offset_in_ios = 0;
}
}
spdk_bit_array_set(job->outstanding, offset_in_ios);
}
}
/* For multi-thread to same job, offset_in_ios is relative
* to the LBA range assigned for that job. job->offset_blocks
* is absolute (entire bdev LBA range).
*/
task->offset_blocks = (offset_in_ios + job->ios_base) * job->io_size_blocks;
if (job->verify || job->reset) {
generate_data(task->buf, job->buf_size,
spdk_bdev_get_block_size(job->bdev),
task->md_buf, spdk_bdev_get_md_size(job->bdev),
job->io_size_blocks);
if (g_zcopy) {
bdevperf_prep_zcopy_write_task(task);
return;
} else {
task->iov.iov_base = task->buf;
task->iov.iov_len = job->buf_size;
task->io_type = SPDK_BDEV_IO_TYPE_WRITE;
}
} else if (job->flush) {
task->io_type = SPDK_BDEV_IO_TYPE_FLUSH;
} else if (job->unmap) {
task->io_type = SPDK_BDEV_IO_TYPE_UNMAP;
} else if (job->write_zeroes) {
task->io_type = SPDK_BDEV_IO_TYPE_WRITE_ZEROES;
} else if ((job->rw_percentage == 100) ||
(job->rw_percentage != 0 && ((rand_r(&job->seed) % 100) < job->rw_percentage))) {
task->io_type = SPDK_BDEV_IO_TYPE_READ;
} else {
if (g_zcopy) {
bdevperf_prep_zcopy_write_task(task);
return;
} else {
task->iov.iov_base = task->buf;
task->iov.iov_len = job->buf_size;
task->io_type = SPDK_BDEV_IO_TYPE_WRITE;
}
}
bdevperf_submit_task(task);
}
static int reset_job(void *arg);
static void
reset_cb(struct spdk_bdev_io *bdev_io, bool success, void *cb_arg)
{
struct bdevperf_task *task = cb_arg;
struct bdevperf_job *job = task->job;
if (!success) {
printf("Reset blockdev=%s failed\n", spdk_bdev_get_name(job->bdev));
bdevperf_job_drain(job);
g_run_rc = -1;
}
TAILQ_INSERT_TAIL(&job->task_list, task, link);
spdk_bdev_free_io(bdev_io);
job->reset_timer = SPDK_POLLER_REGISTER(reset_job, job,
10 * 1000000);
}
static int
reset_job(void *arg)
{
struct bdevperf_job *job = arg;
struct bdevperf_task *task;
int rc;
spdk_poller_unregister(&job->reset_timer);
/* Do reset. */
task = bdevperf_job_get_task(job);
rc = spdk_bdev_reset(job->bdev_desc, job->ch,
reset_cb, task);
if (rc) {
printf("Reset failed: %d\n", rc);
bdevperf_job_drain(job);
g_run_rc = -1;
}
return -1;
}
static void
bdevperf_timeout_cb(void *cb_arg, struct spdk_bdev_io *bdev_io)
{
struct bdevperf_job *job = cb_arg;
struct bdevperf_task *task;
job->io_timeout++;
if (job->is_draining || !job->abort ||
!spdk_bdev_io_type_supported(job->bdev, SPDK_BDEV_IO_TYPE_ABORT)) {
return;
}
task = bdevperf_job_get_task(job);
if (task == NULL) {
return;
}
task->task_to_abort = spdk_bdev_io_get_cb_arg(bdev_io);
task->io_type = SPDK_BDEV_IO_TYPE_ABORT;
bdevperf_submit_task(task);
}
static void
bdevperf_job_run(void *ctx)
{
struct bdevperf_job *job = ctx;
struct bdevperf_task *task;
int i;
/* Submit initial I/O for this job. Each time one
* completes, another will be submitted. */
/* Start a timer to stop this I/O chain when the run is over */
job->run_timer = SPDK_POLLER_REGISTER(bdevperf_job_drain, job, g_time_in_usec);
if (job->reset) {
job->reset_timer = SPDK_POLLER_REGISTER(reset_job, job,
10 * 1000000);
}
spdk_bdev_set_timeout(job->bdev_desc, g_timeout_in_sec, bdevperf_timeout_cb, job);
for (i = 0; i < job->queue_depth; i++) {
task = bdevperf_job_get_task(job);
bdevperf_submit_single(job, task);
}
}
static void
_performance_dump_done(void *ctx)
{
struct bdevperf_aggregate_stats *stats = ctx;
printf("\r ==================================================================================\n");
printf("\r %-28s: %10s %10.2f %10.2f",
"Total", "", stats->total_io_per_second, stats->total_mb_per_second);
printf(" %10.2f %8.2f\n",
stats->total_failed_per_second, stats->total_timeout_per_second);
fflush(stdout);
g_performance_dump_active = false;
free(stats);
}
static void
_performance_dump(void *ctx)
{
struct bdevperf_aggregate_stats *stats = ctx;
performance_dump_job(stats, stats->current_job);
/* This assumes the jobs list is static after start up time.
* That's true right now, but if that ever changed this would need a lock. */
stats->current_job = TAILQ_NEXT(stats->current_job, link);
if (stats->current_job == NULL) {
spdk_thread_send_msg(g_main_thread, _performance_dump_done, stats);
} else {
spdk_thread_send_msg(stats->current_job->thread, _performance_dump, stats);
}
}
static int
performance_statistics_thread(void *arg)
{
struct bdevperf_aggregate_stats *stats;
if (g_performance_dump_active) {
return -1;
}
g_performance_dump_active = true;
stats = calloc(1, sizeof(*stats));
if (stats == NULL) {
return -1;
}
g_show_performance_period_num++;
stats->io_time_in_usec = g_show_performance_period_num * g_show_performance_period_in_usec;
stats->ema_period = g_show_performance_ema_period;
/* Iterate all of the jobs to gather stats
* These jobs will not get removed here until a final performance dump is run,
* so this should be safe without locking.
*/
stats->current_job = TAILQ_FIRST(&g_bdevperf.jobs);
if (stats->current_job == NULL) {
spdk_thread_send_msg(g_main_thread, _performance_dump_done, stats);
} else {
spdk_thread_send_msg(stats->current_job->thread, _performance_dump, stats);
}
return -1;
}
static void
bdevperf_test(void)
{
struct bdevperf_job *job;
printf("Running I/O for %" PRIu64 " seconds...\n", g_time_in_usec / 1000000);
fflush(stdout);
/* Start a timer to dump performance numbers */
g_start_tsc = spdk_get_ticks();
if (g_show_performance_real_time && !g_perf_timer) {
printf("\r %-*s: %10s %10s %10s %10s %8s\n",
28, "Device Information", "runtime(s)", "IOPS", "MiB/s", "Fail/s", "TO/s");
g_perf_timer = SPDK_POLLER_REGISTER(performance_statistics_thread, NULL,
g_show_performance_period_in_usec);
}
/* Iterate jobs to start all I/O */
TAILQ_FOREACH(job, &g_bdevperf.jobs, link) {
g_bdevperf.running_jobs++;
spdk_thread_send_msg(job->thread, bdevperf_job_run, job);
}
}
static void
bdevperf_bdev_removed(enum spdk_bdev_event_type type, struct spdk_bdev *bdev, void *event_ctx)
{
struct bdevperf_job *job = event_ctx;
if (SPDK_BDEV_EVENT_REMOVE == type) {
bdevperf_job_drain(job);
}
}
static uint32_t g_construct_job_count = 0;
static void
_bdevperf_construct_job_done(void *ctx)
{
if (--g_construct_job_count == 0) {
if (g_run_rc != 0) {
/* Something failed. */
bdevperf_test_done(NULL);
return;
}
/* Ready to run the test */
bdevperf_test();
} else if (g_run_rc != 0) {
/* Reset error as some jobs constructed right */
g_run_rc = 0;
if (g_continue_on_failure == false) {
g_error_to_exit = true;
}
}
}
/* Checkformat will not allow to use inlined type,
this is a workaround */
typedef struct spdk_thread *spdk_thread_t;
static spdk_thread_t
construct_job_thread(struct spdk_cpuset *cpumask, const char *tag)
{
struct spdk_cpuset tmp;
/* This function runs on the main thread. */
assert(g_main_thread == spdk_get_thread());
/* Handle default mask */
if (spdk_cpuset_count(cpumask) == 0) {
cpumask = &g_all_cpuset;
}
/* Warn user that mask might need to be changed */
spdk_cpuset_copy(&tmp, cpumask);
spdk_cpuset_or(&tmp, &g_all_cpuset);
if (!spdk_cpuset_equal(&tmp, &g_all_cpuset)) {
fprintf(stderr, "cpumask for '%s' is too big\n", tag);
}
return spdk_thread_create(tag, cpumask);
}
static uint32_t
_get_next_core(void)
{
static uint32_t current_core = SPDK_ENV_LCORE_ID_ANY;
if (current_core == SPDK_ENV_LCORE_ID_ANY) {
current_core = spdk_env_get_first_core();
return current_core;
}
current_core = spdk_env_get_next_core(current_core);
if (current_core == SPDK_ENV_LCORE_ID_ANY) {
current_core = spdk_env_get_first_core();
}
return current_core;
}
static void
_bdevperf_construct_job(void *ctx)
{
struct bdevperf_job *job = ctx;
int rc;
rc = spdk_bdev_open_ext(spdk_bdev_get_name(job->bdev), true, bdevperf_bdev_removed, job,
&job->bdev_desc);
if (rc != 0) {
SPDK_ERRLOG("Could not open leaf bdev %s, error=%d\n", spdk_bdev_get_name(job->bdev), rc);
g_run_rc = -EINVAL;
goto end;
}
if (g_zcopy) {
if (!spdk_bdev_io_type_supported(job->bdev, SPDK_BDEV_IO_TYPE_ZCOPY)) {
printf("Test requires ZCOPY but bdev module does not support ZCOPY\n");
g_run_rc = -ENOTSUP;
goto end;
}
}
job->ch = spdk_bdev_get_io_channel(job->bdev_desc);
if (!job->ch) {
SPDK_ERRLOG("Could not get io_channel for device %s, error=%d\n", spdk_bdev_get_name(job->bdev),
rc);
spdk_bdev_close(job->bdev_desc);
TAILQ_REMOVE(&g_bdevperf.jobs, job, link);
g_run_rc = -ENOMEM;
goto end;
}
end:
spdk_thread_send_msg(g_main_thread, _bdevperf_construct_job_done, NULL);
}
static void
job_init_rw(struct bdevperf_job *job, enum job_config_rw rw)
{
switch (rw) {
case JOB_CONFIG_RW_READ:
job->rw_percentage = 100;
break;
case JOB_CONFIG_RW_WRITE:
job->rw_percentage = 0;
break;
case JOB_CONFIG_RW_RANDREAD:
job->is_random = true;
job->rw_percentage = 100;
job->seed = rand();
break;
case JOB_CONFIG_RW_RANDWRITE:
job->is_random = true;
job->rw_percentage = 0;
job->seed = rand();
break;
case JOB_CONFIG_RW_RW:
job->is_random = false;
break;
case JOB_CONFIG_RW_RANDRW:
job->is_random = true;
job->seed = rand();
break;
case JOB_CONFIG_RW_VERIFY:
job->verify = true;
job->rw_percentage = 50;
break;
case JOB_CONFIG_RW_RESET:
job->reset = true;
job->verify = true;
job->rw_percentage = 50;
break;
case JOB_CONFIG_RW_UNMAP:
job->unmap = true;
break;
case JOB_CONFIG_RW_FLUSH:
job->flush = true;
break;
case JOB_CONFIG_RW_WRITE_ZEROES:
job->write_zeroes = true;
break;
}
}
static int
bdevperf_construct_job(struct spdk_bdev *bdev, struct job_config *config,
struct spdk_thread *thread)
{
struct bdevperf_job *job;
struct bdevperf_task *task;
int block_size, data_block_size;
int rc;
int task_num, n;
block_size = spdk_bdev_get_block_size(bdev);
data_block_size = spdk_bdev_get_data_block_size(bdev);
job = calloc(1, sizeof(struct bdevperf_job));
if (!job) {
fprintf(stderr, "Unable to allocate memory for new job.\n");
return -ENOMEM;
}
job->name = strdup(spdk_bdev_get_name(bdev));
if (!job->name) {
fprintf(stderr, "Unable to allocate memory for job name.\n");
free(job);
return -ENOMEM;
}
job->workload_type = g_workload_type;
job->io_size = config->bs;
job->rw_percentage = config->rwmixread;
job->continue_on_failure = g_continue_on_failure;
job->queue_depth = config->iodepth;
job->bdev = bdev;
job->io_size_blocks = job->io_size / data_block_size;
job->buf_size = job->io_size_blocks * block_size;
job->abort = g_abort;
job_init_rw(job, config->rw);
if ((job->io_size % data_block_size) != 0) {
SPDK_ERRLOG("IO size (%d) is not multiples of data block size of bdev %s (%"PRIu32")\n",
job->io_size, spdk_bdev_get_name(bdev), data_block_size);
free(job->name);
free(job);
return -ENOTSUP;
}
if (job->unmap && !spdk_bdev_io_type_supported(bdev, SPDK_BDEV_IO_TYPE_UNMAP)) {
printf("Skipping %s because it does not support unmap\n", spdk_bdev_get_name(bdev));
free(job->name);
free(job);
return -ENOTSUP;
}
if (spdk_bdev_is_dif_check_enabled(bdev, SPDK_DIF_CHECK_TYPE_REFTAG)) {
job->dif_check_flags |= SPDK_DIF_FLAGS_REFTAG_CHECK;
}
if (spdk_bdev_is_dif_check_enabled(bdev, SPDK_DIF_CHECK_TYPE_GUARD)) {
job->dif_check_flags |= SPDK_DIF_FLAGS_GUARD_CHECK;
}
job->offset_in_ios = 0;
if (config->length != 0) {
/* Use subset of disk */
job->size_in_ios = config->length / job->io_size_blocks;
job->ios_base = config->offset / job->io_size_blocks;
} else {
/* Use whole disk */
job->size_in_ios = spdk_bdev_get_num_blocks(bdev) / job->io_size_blocks;
job->ios_base = 0;
}
if (job->is_random && g_zipf_theta > 0) {
job->zipf = spdk_zipf_create(job->size_in_ios, g_zipf_theta, 0);
}
if (job->verify) {
job->outstanding = spdk_bit_array_create(job->size_in_ios);
if (job->outstanding == NULL) {
SPDK_ERRLOG("Could not create outstanding array bitmap for bdev %s\n",
spdk_bdev_get_name(bdev));
free(job->name);
free(job);
return -ENOMEM;
}
}
TAILQ_INIT(&job->task_list);
task_num = job->queue_depth;
if (job->reset) {
task_num += 1;
}
if (job->abort) {
task_num += job->queue_depth;
}
TAILQ_INSERT_TAIL(&g_bdevperf.jobs, job, link);
for (n = 0; n < task_num; n++) {
task = calloc(1, sizeof(struct bdevperf_task));
if (!task) {
fprintf(stderr, "Failed to allocate task from memory\n");
return -ENOMEM;
}
task->buf = spdk_zmalloc(job->buf_size, spdk_bdev_get_buf_align(job->bdev), NULL,
SPDK_ENV_LCORE_ID_ANY, SPDK_MALLOC_DMA);
if (!task->buf) {
fprintf(stderr, "Cannot allocate buf for task=%p\n", task);
free(task);
return -ENOMEM;
}
if (spdk_bdev_is_md_separate(job->bdev)) {
task->md_buf = spdk_zmalloc(job->io_size_blocks *
spdk_bdev_get_md_size(job->bdev), 0, NULL,
SPDK_ENV_LCORE_ID_ANY, SPDK_MALLOC_DMA);
if (!task->md_buf) {
fprintf(stderr, "Cannot allocate md buf for task=%p\n", task);
spdk_free(task->buf);
free(task);
return -ENOMEM;
}
}
task->job = job;
TAILQ_INSERT_TAIL(&job->task_list, task, link);
}
job->thread = thread;
g_construct_job_count++;
rc = spdk_thread_send_msg(thread, _bdevperf_construct_job, job);
assert(rc == 0);
return rc;
}
static int
parse_rw(const char *str, enum job_config_rw ret)
{
if (str == NULL) {
return ret;
}
if (!strcmp(str, "read")) {
ret = JOB_CONFIG_RW_READ;
} else if (!strcmp(str, "randread")) {
ret = JOB_CONFIG_RW_RANDREAD;
} else if (!strcmp(str, "write")) {
ret = JOB_CONFIG_RW_WRITE;
} else if (!strcmp(str, "randwrite")) {
ret = JOB_CONFIG_RW_RANDWRITE;
} else if (!strcmp(str, "verify")) {
ret = JOB_CONFIG_RW_VERIFY;
} else if (!strcmp(str, "reset")) {
ret = JOB_CONFIG_RW_RESET;
} else if (!strcmp(str, "unmap")) {
ret = JOB_CONFIG_RW_UNMAP;
} else if (!strcmp(str, "write_zeroes")) {
ret = JOB_CONFIG_RW_WRITE_ZEROES;
} else if (!strcmp(str, "flush")) {
ret = JOB_CONFIG_RW_FLUSH;
} else if (!strcmp(str, "rw")) {
ret = JOB_CONFIG_RW_RW;
} else if (!strcmp(str, "randrw")) {
ret = JOB_CONFIG_RW_RANDRW;
} else {
fprintf(stderr, "rw must be one of\n"
"(read, write, randread, randwrite, rw, randrw, verify, reset, unmap, flush)\n");
ret = BDEVPERF_CONFIG_ERROR;
}
return ret;
}
static const char *
config_filename_next(const char *filename, char *out)
{
int i, k;
if (filename == NULL) {
out[0] = '\0';
return NULL;
}
if (filename[0] == ':') {
filename++;
}
for (i = 0, k = 0;
filename[i] != '\0' &&
filename[i] != ':' &&
i < BDEVPERF_CONFIG_MAX_FILENAME;
i++) {
if (filename[i] == ' ' || filename[i] == '\t') {
continue;
}
out[k++] = filename[i];
}
out[k] = 0;
return filename + i;
}
static void
bdevperf_construct_jobs(void)
{
char filename[BDEVPERF_CONFIG_MAX_FILENAME];
struct spdk_thread *thread;
struct job_config *config;
struct spdk_bdev *bdev;
const char *filenames;
int rc;
TAILQ_FOREACH(config, &job_config_list, link) {
filenames = config->filename;
thread = construct_job_thread(&config->cpumask, config->name);
assert(thread);
while (filenames) {
filenames = config_filename_next(filenames, filename);
if (strlen(filename) == 0) {
break;
}
bdev = spdk_bdev_get_by_name(filename);
if (!bdev) {
fprintf(stderr, "Unable to find bdev '%s'\n", filename);
g_run_rc = -EINVAL;
return;
}
rc = bdevperf_construct_job(bdev, config, thread);
if (rc < 0) {
g_run_rc = rc;
return;
}
}
}
}
static int
make_cli_job_config(const char *filename, int64_t offset, uint64_t range)
{
struct job_config *config = calloc(1, sizeof(*config));
if (config == NULL) {
fprintf(stderr, "Unable to allocate memory for job config\n");
return -ENOMEM;
}
config->name = filename;
config->filename = filename;
spdk_cpuset_zero(&config->cpumask);
spdk_cpuset_set_cpu(&config->cpumask, _get_next_core(), true);
config->bs = g_io_size;
config->iodepth = g_queue_depth;
config->rwmixread = g_rw_percentage;
config->offset = offset;
config->length = range;
config->rw = parse_rw(g_workload_type, BDEVPERF_CONFIG_ERROR);
if ((int)config->rw == BDEVPERF_CONFIG_ERROR) {
return -EINVAL;
}
TAILQ_INSERT_TAIL(&job_config_list, config, link);
return 0;
}
static void
bdevperf_construct_multithread_job_configs(void)
{
struct spdk_bdev *bdev;
uint32_t i;
uint32_t num_cores;
uint64_t blocks_per_job;
int64_t offset;
num_cores = 0;
SPDK_ENV_FOREACH_CORE(i) {
num_cores++;
}
if (num_cores == 0) {
g_run_rc = -EINVAL;
return;
}
if (g_job_bdev_name != NULL) {
bdev = spdk_bdev_get_by_name(g_job_bdev_name);
if (!bdev) {
fprintf(stderr, "Unable to find bdev '%s'\n", g_job_bdev_name);
return;
}
blocks_per_job = spdk_bdev_get_num_blocks(bdev) / num_cores;
offset = 0;
SPDK_ENV_FOREACH_CORE(i) {
g_run_rc = make_cli_job_config(g_job_bdev_name, offset, blocks_per_job);
if (g_run_rc) {
return;
}
offset += blocks_per_job;
}
} else {
bdev = spdk_bdev_first_leaf();
while (bdev != NULL) {
blocks_per_job = spdk_bdev_get_num_blocks(bdev) / num_cores;
offset = 0;
SPDK_ENV_FOREACH_CORE(i) {
g_run_rc = make_cli_job_config(spdk_bdev_get_name(bdev),
offset, blocks_per_job);
if (g_run_rc) {
return;
}
offset += blocks_per_job;
}
bdev = spdk_bdev_next_leaf(bdev);
}
}
}
static void
bdevperf_construct_job_configs(void)
{
struct spdk_bdev *bdev;
/* There are three different modes for allocating jobs. Standard mode
* (the default) creates one spdk_thread per bdev and runs the I/O job there.
*
* The -C flag places bdevperf into "multithread" mode, meaning it creates
* one spdk_thread per bdev PER CORE, and runs a copy of the job on each.
* This runs multiple threads per bdev, effectively.
*
* The -j flag implies "FIO" mode which tries to mimic semantic of FIO jobs.
* In "FIO" mode, threads are spawned per-job instead of per-bdev.
* Each FIO job can be individually parameterized by filename, cpu mask, etc,
* which is different from other modes in that they only support global options.
*/
if (g_bdevperf_conf) {
goto end;
} else if (g_multithread_mode) {
bdevperf_construct_multithread_job_configs();
goto end;
}
if (g_job_bdev_name != NULL) {
bdev = spdk_bdev_get_by_name(g_job_bdev_name);
if (bdev) {
/* Construct the job */
g_run_rc = make_cli_job_config(g_job_bdev_name, 0, 0);
} else {
fprintf(stderr, "Unable to find bdev '%s'\n", g_job_bdev_name);
}
} else {
bdev = spdk_bdev_first_leaf();
while (bdev != NULL) {
/* Construct the job */
g_run_rc = make_cli_job_config(spdk_bdev_get_name(bdev), 0, 0);
if (g_run_rc) {
break;
}
bdev = spdk_bdev_next_leaf(bdev);
}
}
end:
/* Increment initial construct_jobs count so that it will never reach 0 in the middle
* of iteration.
*/
g_construct_job_count = 1;
if (g_run_rc == 0) {
bdevperf_construct_jobs();
}
_bdevperf_construct_job_done(NULL);
}
static int
parse_uint_option(struct spdk_conf_section *s, const char *name, int def)
{
const char *job_name;
int tmp;
tmp = spdk_conf_section_get_intval(s, name);
if (tmp == -1) {
/* Field was not found. Check default value
* In [global] section it is ok to have undefined values
* but for other sections it is not ok */
if (def == BDEVPERF_CONFIG_UNDEFINED) {
job_name = spdk_conf_section_get_name(s);
if (strcmp(job_name, "global") == 0) {
return def;
}
fprintf(stderr,
"Job '%s' has no '%s' assigned\n",
job_name, name);
return BDEVPERF_CONFIG_ERROR;
}
return def;
}
/* NOTE: get_intval returns nonnegative on success */
if (tmp < 0) {
fprintf(stderr, "Job '%s' has bad '%s' value.\n",
spdk_conf_section_get_name(s), name);
return BDEVPERF_CONFIG_ERROR;
}
return tmp;
}
/* CLI arguments override parameters for global sections */
static void
config_set_cli_args(struct job_config *config)
{
if (g_job_bdev_name) {
config->filename = g_job_bdev_name;
}
if (g_io_size > 0) {
config->bs = g_io_size;
}
if (g_queue_depth > 0) {
config->iodepth = g_queue_depth;
}
if (g_rw_percentage > 0) {
config->rwmixread = g_rw_percentage;
}
if (g_workload_type) {
config->rw = parse_rw(g_workload_type, config->rw);
}
}
static int
read_job_config(void)
{
struct job_config global_default_config;
struct job_config global_config;
struct spdk_conf_section *s;
struct job_config *config;
const char *cpumask;
const char *rw;
bool is_global;
int n = 0;
int val;
if (g_bdevperf_conf_file == NULL) {
return 0;
}
g_bdevperf_conf = spdk_conf_allocate();
if (g_bdevperf_conf == NULL) {
fprintf(stderr, "Could not allocate job config structure\n");
return 1;
}
spdk_conf_disable_sections_merge(g_bdevperf_conf);
if (spdk_conf_read(g_bdevperf_conf, g_bdevperf_conf_file)) {
fprintf(stderr, "Invalid job config");
return 1;
}
/* Initialize global defaults */
global_default_config.filename = NULL;
/* Zero mask is the same as g_all_cpuset
* The g_all_cpuset is not initialized yet,
* so use zero mask as the default instead */
spdk_cpuset_zero(&global_default_config.cpumask);
global_default_config.bs = BDEVPERF_CONFIG_UNDEFINED;
global_default_config.iodepth = BDEVPERF_CONFIG_UNDEFINED;
/* bdevperf has no default for -M option but in FIO the default is 50 */
global_default_config.rwmixread = 50;
global_default_config.offset = 0;
/* length 0 means 100% */
global_default_config.length = 0;
global_default_config.rw = BDEVPERF_CONFIG_UNDEFINED;
config_set_cli_args(&global_default_config);
if ((int)global_default_config.rw == BDEVPERF_CONFIG_ERROR) {
return 1;
}
/* There is only a single instance of global job_config
* We just reset its value when we encounter new [global] section */
global_config = global_default_config;
for (s = spdk_conf_first_section(g_bdevperf_conf);
s != NULL;
s = spdk_conf_next_section(s)) {
config = calloc(1, sizeof(*config));
if (config == NULL) {
fprintf(stderr, "Unable to allocate memory for job config\n");
return 1;
}
config->name = spdk_conf_section_get_name(s);
is_global = strcmp(config->name, "global") == 0;
if (is_global) {
global_config = global_default_config;
}
config->filename = spdk_conf_section_get_val(s, "filename");
if (config->filename == NULL) {
config->filename = global_config.filename;
}
if (!is_global) {
if (config->filename == NULL) {
fprintf(stderr, "Job '%s' expects 'filename' parameter\n", config->name);
goto error;
} else if (strnlen(config->filename, BDEVPERF_CONFIG_MAX_FILENAME)
>= BDEVPERF_CONFIG_MAX_FILENAME) {
fprintf(stderr,
"filename for '%s' job is too long. Max length is %d\n",
config->name, BDEVPERF_CONFIG_MAX_FILENAME);
goto error;
}
}
cpumask = spdk_conf_section_get_val(s, "cpumask");
if (cpumask == NULL) {
config->cpumask = global_config.cpumask;
} else if (spdk_cpuset_parse(&config->cpumask, cpumask)) {
fprintf(stderr, "Job '%s' has bad 'cpumask' value\n", config->name);
goto error;
}
config->bs = parse_uint_option(s, "bs", global_config.bs);
if (config->bs == BDEVPERF_CONFIG_ERROR) {
goto error;
} else if (config->bs == 0) {
fprintf(stderr, "'bs' of job '%s' must be greater than 0\n", config->name);
goto error;
}
config->iodepth = parse_uint_option(s, "iodepth", global_config.iodepth);
if (config->iodepth == BDEVPERF_CONFIG_ERROR) {
goto error;
} else if (config->iodepth == 0) {
fprintf(stderr,
"'iodepth' of job '%s' must be greater than 0\n",
config->name);
goto error;
}
config->rwmixread = parse_uint_option(s, "rwmixread", global_config.rwmixread);
if (config->rwmixread == BDEVPERF_CONFIG_ERROR) {
goto error;
} else if (config->rwmixread > 100) {
fprintf(stderr,
"'rwmixread' value of '%s' job is not in 0-100 range\n",
config->name);
goto error;
}
config->offset = parse_uint_option(s, "offset", global_config.offset);
if (config->offset == BDEVPERF_CONFIG_ERROR) {
goto error;
}
val = parse_uint_option(s, "length", global_config.length);
if (val == BDEVPERF_CONFIG_ERROR) {
goto error;
}
config->length = val;
rw = spdk_conf_section_get_val(s, "rw");
config->rw = parse_rw(rw, global_config.rw);
if ((int)config->rw == BDEVPERF_CONFIG_ERROR) {
fprintf(stderr, "Job '%s' has bad 'rw' value\n", config->name);
goto error;
} else if (!is_global && (int)config->rw == BDEVPERF_CONFIG_UNDEFINED) {
fprintf(stderr, "Job '%s' has no 'rw' assigned\n", config->name);
goto error;
}
if (is_global) {
config_set_cli_args(config);
global_config = *config;
free(config);
} else {
TAILQ_INSERT_TAIL(&job_config_list, config, link);
n++;
}
}
printf("Using job config with %d jobs\n", n);
return 0;
error:
free(config);
return 1;
}
static void
bdevperf_run(void *arg1)
{
uint32_t i;
g_main_thread = spdk_get_thread();
spdk_cpuset_zero(&g_all_cpuset);
SPDK_ENV_FOREACH_CORE(i) {
spdk_cpuset_set_cpu(&g_all_cpuset, i, true);
}
if (g_wait_for_tests) {
/* Do not perform any tests until RPC is received */
return;
}
bdevperf_construct_job_configs();
}
static void
rpc_perform_tests_cb(void)
{
struct spdk_json_write_ctx *w;
struct spdk_jsonrpc_request *request = g_request;
g_request = NULL;
if (g_run_rc == 0) {
w = spdk_jsonrpc_begin_result(request);
spdk_json_write_uint32(w, g_run_rc);
spdk_jsonrpc_end_result(request, w);
} else {
spdk_jsonrpc_send_error_response_fmt(request, SPDK_JSONRPC_ERROR_INTERNAL_ERROR,
"bdevperf failed with error %s", spdk_strerror(-g_run_rc));
}
/* Reset g_run_rc to 0 for the next test run. */
g_run_rc = 0;
/* Reset g_stats to 0 for the next test run. */
memset(&g_stats, 0, sizeof(g_stats));
}
static void
rpc_perform_tests(struct spdk_jsonrpc_request *request, const struct spdk_json_val *params)
{
if (params != NULL) {
spdk_jsonrpc_send_error_response(request, SPDK_JSONRPC_ERROR_INVALID_PARAMS,
"perform_tests method requires no parameters");
return;
}
if (g_request != NULL) {
fprintf(stderr, "Another test is already in progress.\n");
spdk_jsonrpc_send_error_response(request, SPDK_JSONRPC_ERROR_INTERNAL_ERROR,
spdk_strerror(-EINPROGRESS));
return;
}
g_request = request;
/* Only construct job configs at the first test run. */
if (TAILQ_EMPTY(&job_config_list)) {
bdevperf_construct_job_configs();
} else {
bdevperf_construct_jobs();
}
}
SPDK_RPC_REGISTER("perform_tests", rpc_perform_tests, SPDK_RPC_RUNTIME)
static void
_bdevperf_job_drain(void *ctx)
{
bdevperf_job_drain(ctx);
}
static void
spdk_bdevperf_shutdown_cb(void)
{
g_shutdown = true;
struct bdevperf_job *job, *tmp;
if (g_bdevperf.running_jobs == 0) {
bdevperf_test_done(NULL);
return;
}
/* Iterate jobs to stop all I/O */
TAILQ_FOREACH_SAFE(job, &g_bdevperf.jobs, link, tmp) {
spdk_thread_send_msg(job->thread, _bdevperf_job_drain, job);
}
}
static int
bdevperf_parse_arg(int ch, char *arg)
{
long long tmp;
if (ch == 'w') {
g_workload_type = optarg;
} else if (ch == 'T') {
g_job_bdev_name = optarg;
} else if (ch == 'z') {
g_wait_for_tests = true;
} else if (ch == 'Z') {
g_zcopy = true;
} else if (ch == 'X') {
g_abort = true;
} else if (ch == 'C') {
g_multithread_mode = true;
} else if (ch == 'f') {
g_continue_on_failure = true;
} else if (ch == 'j') {
g_bdevperf_conf_file = optarg;
} else if (ch == 'F') {
char *endptr;
errno = 0;
g_zipf_theta = strtod(optarg, &endptr);
if (errno || optarg == endptr || g_zipf_theta < 0) {
fprintf(stderr, "Illegal zipf theta value %s\n", optarg);
return -EINVAL;
}
} else {
tmp = spdk_strtoll(optarg, 10);
if (tmp < 0) {
fprintf(stderr, "Parse failed for the option %c.\n", ch);
return tmp;
} else if (tmp >= INT_MAX) {
fprintf(stderr, "Parsed option was too large %c.\n", ch);
return -ERANGE;
}
switch (ch) {
case 'q':
g_queue_depth = tmp;
break;
case 'o':
g_io_size = tmp;
break;
case 't':
g_time_in_sec = tmp;
break;
case 'k':
g_timeout_in_sec = tmp;
break;
case 'M':
g_rw_percentage = tmp;
g_mix_specified = true;
break;
case 'P':
g_show_performance_ema_period = tmp;
break;
case 'S':
g_show_performance_real_time = 1;
g_show_performance_period_in_usec = tmp * 1000000;
break;
default:
return -EINVAL;
}
}
return 0;
}
static void
bdevperf_usage(void)
{
printf(" -q <depth> io depth\n");
printf(" -o <size> io size in bytes\n");
printf(" -w <type> io pattern type, must be one of (read, write, randread, randwrite, rw, randrw, verify, reset, unmap, flush)\n");
printf(" -t <time> time in seconds\n");
printf(" -k <timeout> timeout in seconds to detect starved I/O (default is 0 and disabled)\n");
printf(" -M <percent> rwmixread (100 for reads, 0 for writes)\n");
printf(" -P <num> number of moving average period\n");
printf("\t\t(If set to n, show weighted mean of the previous n IO/s in real time)\n");
printf("\t\t(Formula: M = 2 / (n + 1), EMA[i+1] = IO/s * M + (1 - M) * EMA[i])\n");
printf("\t\t(only valid with -S)\n");
printf(" -S <period> show performance result in real time every <period> seconds\n");
printf(" -T <bdev> bdev to run against. Default: all available bdevs.\n");
printf(" -f continue processing I/O even after failures\n");
printf(" -F <zipf theta> use zipf distribution for random I/O\n");
printf(" -Z enable using zcopy bdev API for read or write I/O\n");
printf(" -z start bdevperf, but wait for RPC to start tests\n");
printf(" -X abort timed out I/O\n");
printf(" -C enable every core to send I/Os to each bdev\n");
printf(" -j <filename> use job config file\n");
}
static int
verify_test_params(struct spdk_app_opts *opts)
{
/* When RPC is used for starting tests and
* no rpc_addr was configured for the app,
* use the default address. */
if (g_wait_for_tests && opts->rpc_addr == NULL) {
opts->rpc_addr = SPDK_DEFAULT_RPC_ADDR;
}
if (!g_bdevperf_conf_file && g_queue_depth <= 0) {
goto out;
}
if (!g_bdevperf_conf_file && g_io_size <= 0) {
goto out;
}
if (!g_bdevperf_conf_file && !g_workload_type) {
goto out;
}
if (g_time_in_sec <= 0) {
goto out;
}
g_time_in_usec = g_time_in_sec * 1000000LL;
if (g_timeout_in_sec < 0) {
goto out;
}
if (g_abort && !g_timeout_in_sec) {
printf("Timeout must be set for abort option, Ignoring g_abort\n");
}
if (g_show_performance_ema_period > 0 &&
g_show_performance_real_time == 0) {
fprintf(stderr, "-P option must be specified with -S option\n");
return 1;
}
if (g_io_size > SPDK_BDEV_LARGE_BUF_MAX_SIZE) {
printf("I/O size of %d is greater than zero copy threshold (%d).\n",
g_io_size, SPDK_BDEV_LARGE_BUF_MAX_SIZE);
printf("Zero copy mechanism will not be used.\n");
g_zcopy = false;
}
if (g_bdevperf_conf_file) {
/* workload_type verification happens during config file parsing */
return 0;
}
if (!strcmp(g_workload_type, "verify") ||
!strcmp(g_workload_type, "reset")) {
g_rw_percentage = 50;
if (g_io_size > SPDK_BDEV_LARGE_BUF_MAX_SIZE) {
fprintf(stderr, "Unable to exceed max I/O size of %d for verify. (%d provided).\n",
SPDK_BDEV_LARGE_BUF_MAX_SIZE, g_io_size);
return 1;
}
g_verify = true;
if (!strcmp(g_workload_type, "reset")) {
g_reset = true;
}
}
if (!strcmp(g_workload_type, "read") ||
!strcmp(g_workload_type, "randread") ||
!strcmp(g_workload_type, "write") ||
!strcmp(g_workload_type, "randwrite") ||
!strcmp(g_workload_type, "verify") ||
!strcmp(g_workload_type, "reset") ||
!strcmp(g_workload_type, "unmap") ||
!strcmp(g_workload_type, "write_zeroes") ||
!strcmp(g_workload_type, "flush")) {
if (g_mix_specified) {
fprintf(stderr, "Ignoring -M option... Please use -M option"
" only when using rw or randrw.\n");
}
}
if (!strcmp(g_workload_type, "rw") ||
!strcmp(g_workload_type, "randrw")) {
if (g_rw_percentage < 0 || g_rw_percentage > 100) {
fprintf(stderr,
"-M must be specified to value from 0 to 100 "
"for rw or randrw.\n");
return 1;
}
}
return 0;
out:
spdk_app_usage();
bdevperf_usage();
return 1;
}
int
main(int argc, char **argv)
{
struct spdk_app_opts opts = {};
int rc;
/* Use the runtime PID to set the random seed */
srand(getpid());
spdk_app_opts_init(&opts, sizeof(opts));
opts.name = "bdevperf";
opts.rpc_addr = NULL;
opts.shutdown_cb = spdk_bdevperf_shutdown_cb;
if ((rc = spdk_app_parse_args(argc, argv, &opts, "Zzfq:o:t:w:k:CF:M:P:S:T:Xj:", NULL,
bdevperf_parse_arg, bdevperf_usage)) !=
SPDK_APP_PARSE_ARGS_SUCCESS) {
return rc;
}
if (read_job_config()) {
free_job_config();
return 1;
}
if (verify_test_params(&opts) != 0) {
free_job_config();
exit(1);
}
rc = spdk_app_start(&opts, bdevperf_run, NULL);
spdk_app_fini();
free_job_config();
return rc;
}
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