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925cc3b8a9
Spdk/test/unit/lib/ftl/ftl_io.c/ftl_io_ut.c
Konrad Sztyber 925cc3b8a9 lib/ftl: pending batches queue 
Added queue responsible for keeping track of full, ready to be written
batches.  A batch might be put on this queue in case it'd already been
filled, but could not be written out due to lack of resources or it was
written out, but failed and needs to be resent.

Change-Id: Iba49cd359425300d21b8100f13f17189e99d4c7c
Signed-off-by: Konrad Sztyber <konrad.sztyber@intel.com>
Reviewed-on: https://review.spdk.io/gerrit/c/spdk/spdk/+/908
Tested-by: SPDK CI Jenkins <sys_sgci@intel.com>
Reviewed-by: Jim Harris <james.r.harris@intel.com>
Reviewed-by: Shuhei Matsumoto <shuhei.matsumoto.xt@hitachi.com>
Reviewed-by: Maciej Szczepaniak <maciej.szczepaniak@intel.com>
Reviewed-by: Wojciech Malikowski <wojciech.malikowski@intel.com>
2020-03-02 10:27:06 +00:00

1084 lines
31 KiB
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/*-
* 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/stdinc.h"
#include "spdk_cunit.h"
#include "common/lib/ut_multithread.c"
#include "ftl/ftl_io.c"
#include "ftl/ftl_init.c"
#include "ftl/ftl_core.c"
#include "ftl/ftl_band.c"
#include "ftl/ftl_rwb.c"
DEFINE_STUB(ftl_trace_alloc_id, uint64_t, (struct spdk_ftl_dev *dev), 0);
DEFINE_STUB_V(ftl_trace_completion, (struct spdk_ftl_dev *dev, const struct ftl_io *io,
enum ftl_trace_completion type));
DEFINE_STUB(spdk_bdev_io_get_append_location, uint64_t, (struct spdk_bdev_io *bdev_io), 0);
DEFINE_STUB(spdk_bdev_desc_get_bdev, struct spdk_bdev *, (struct spdk_bdev_desc *desc), NULL);
DEFINE_STUB(spdk_bdev_get_optimal_open_zones, uint32_t, (const struct spdk_bdev *b), 1);
DEFINE_STUB(spdk_bdev_zone_appendv, int, (struct spdk_bdev_desc *desc, struct spdk_io_channel *ch,
struct iovec *iov, int iovcnt, uint64_t zone_id, uint64_t num_blocks,
spdk_bdev_io_completion_cb cb, void *cb_arg), 0);
DEFINE_STUB(spdk_bdev_get_zone_size, uint64_t, (const struct spdk_bdev *b), 1024);
DEFINE_STUB(spdk_bdev_zone_management, int, (struct spdk_bdev_desc *desc,
struct spdk_io_channel *ch, uint64_t zone_id, enum spdk_bdev_zone_action action,
spdk_bdev_io_completion_cb cb, void *cb_arg), 0);
DEFINE_STUB_V(spdk_bdev_free_io, (struct spdk_bdev_io *bdev_io));
DEFINE_STUB_V(ftl_trace_submission, (struct spdk_ftl_dev *dev, const struct ftl_io *io,
struct ftl_addr addr, size_t addr_cnt));
DEFINE_STUB_V(ftl_trace_limits, (struct spdk_ftl_dev *dev, const size_t *limits, size_t num_free));
DEFINE_STUB(spdk_bdev_read_blocks, int, (struct spdk_bdev_desc *desc, struct spdk_io_channel *ch,
void *buf, uint64_t offset_blocks, uint64_t num_blocks,
spdk_bdev_io_completion_cb cb, void *cb_arg), 0);
DEFINE_STUB(spdk_bdev_write_blocks, int, (struct spdk_bdev_desc *desc, struct spdk_io_channel *ch,
void *buf, uint64_t offset_blocks, uint64_t num_blocks, spdk_bdev_io_completion_cb cb,
void *cb_arg), 0);
DEFINE_STUB(spdk_bdev_write_blocks_with_md, int, (struct spdk_bdev_desc *desc,
struct spdk_io_channel *ch, void *buf, void *md, uint64_t offset_blocks,
uint64_t num_blocks, spdk_bdev_io_completion_cb cb, void *cb_arg), 0);
DEFINE_STUB(spdk_bdev_writev_blocks, int, (struct spdk_bdev_desc *desc, struct spdk_io_channel *ch,
struct iovec *iov, int iovcnt, uint64_t offset_blocks, uint64_t num_blocks,
spdk_bdev_io_completion_cb cb, void *cb_arg), 0);
DEFINE_STUB(spdk_bdev_get_num_blocks, uint64_t, (const struct spdk_bdev *bdev), 1024);
DEFINE_STUB(spdk_bdev_get_md_size, uint32_t, (const struct spdk_bdev *bdev), 0);
DEFINE_STUB(spdk_bdev_get_block_size, uint32_t, (const struct spdk_bdev *bdev), 4096);
DEFINE_STUB(ftl_band_validate_md, bool, (struct ftl_band *band), true);
DEFINE_STUB_V(ftl_trace_rwb_fill, (struct spdk_ftl_dev *dev, const struct ftl_io *io));
struct spdk_io_channel *
spdk_bdev_get_io_channel(struct spdk_bdev_desc *bdev_desc)
{
return spdk_get_io_channel(bdev_desc);
}
static int
channel_create_cb(void *io_device, void *ctx)
{
return 0;
}
static void
channel_destroy_cb(void *io_device, void *ctx)
{}
static struct spdk_ftl_dev *
setup_device(uint32_t num_threads, uint32_t xfer_size)
{
struct spdk_ftl_dev *dev;
struct _ftl_io_channel *_ioch;
struct ftl_io_channel *ioch;
int rc;
allocate_threads(num_threads);
set_thread(0);
dev = calloc(1, sizeof(*dev));
SPDK_CU_ASSERT_FATAL(dev != NULL);
dev->core_thread = spdk_get_thread();
dev->ioch = calloc(1, sizeof(*_ioch) + sizeof(struct spdk_io_channel));
SPDK_CU_ASSERT_FATAL(dev->ioch != NULL);
_ioch = (struct _ftl_io_channel *)(dev->ioch + 1);
ioch = _ioch->ioch = calloc(1, sizeof(*ioch));
SPDK_CU_ASSERT_FATAL(ioch != NULL);
ioch->elem_size = sizeof(struct ftl_md_io);
ioch->io_pool = spdk_mempool_create("io-pool", 4096, ioch->elem_size, 0, 0);
SPDK_CU_ASSERT_FATAL(ioch->io_pool != NULL);
dev->conf = g_default_conf;
dev->xfer_size = xfer_size;
dev->base_bdev_desc = (struct spdk_bdev_desc *)0xdeadbeef;
spdk_io_device_register(dev->base_bdev_desc, channel_create_cb, channel_destroy_cb, 0, NULL);
rc = ftl_dev_init_io_channel(dev);
CU_ASSERT_EQUAL(rc, 0);
return dev;
}
static void
free_device(struct spdk_ftl_dev *dev)
{
struct ftl_io_channel *ioch;
ioch = ftl_io_channel_get_ctx(dev->ioch);
spdk_mempool_free(ioch->io_pool);
free(ioch);
spdk_io_device_unregister(dev, NULL);
spdk_io_device_unregister(dev->base_bdev_desc, NULL);
free_threads();
free(dev->ioch_array);
free(dev->iov_buf);
free(dev->ioch);
free(dev);
}
static void
setup_io(struct ftl_io *io, struct spdk_ftl_dev *dev, ftl_io_fn cb, void *ctx)
{
io->dev = dev;
io->cb_fn = cb;
io->cb_ctx = ctx;
}
static struct ftl_io *
alloc_io(struct spdk_ftl_dev *dev, ftl_io_fn cb, void *ctx)
{
struct ftl_io *io;
io = ftl_io_alloc(dev->ioch);
SPDK_CU_ASSERT_FATAL(io != NULL);
setup_io(io, dev, cb, ctx);
return io;
}
static void
io_complete_cb(struct ftl_io *io, void *ctx, int status)
{
*(int *)ctx = status;
}
static void
test_completion(void)
{
struct spdk_ftl_dev *dev;
struct ftl_io_channel *ioch;
struct ftl_io *io;
int req, status = 0;
size_t pool_size;
dev = setup_device(1, 16);
ioch = ftl_io_channel_get_ctx(dev->ioch);
pool_size = spdk_mempool_count(ioch->io_pool);
io = alloc_io(dev, io_complete_cb, &status);
io->status = -EIO;
#define NUM_REQUESTS 16
for (req = 0; req < NUM_REQUESTS; ++req) {
ftl_io_inc_req(io);
CU_ASSERT_FALSE(ftl_io_done(io));
}
CU_ASSERT_EQUAL(io->req_cnt, NUM_REQUESTS);
for (req = 0; req < (NUM_REQUESTS - 1); ++req) {
ftl_io_dec_req(io);
CU_ASSERT_FALSE(ftl_io_done(io));
}
CU_ASSERT_EQUAL(io->req_cnt, 1);
ftl_io_dec_req(io);
CU_ASSERT_TRUE(ftl_io_done(io));
ftl_io_complete(io);
CU_ASSERT_EQUAL(status, -EIO);
CU_ASSERT_EQUAL(spdk_mempool_count(ioch->io_pool), pool_size);
free_device(dev);
}
static void
test_alloc_free(void)
{
struct spdk_ftl_dev *dev;
struct ftl_io_channel *ioch;
struct ftl_io *parent, *child;
int parent_status = -1;
size_t pool_size;
dev = setup_device(1, 16);
ioch = ftl_io_channel_get_ctx(dev->ioch);
pool_size = spdk_mempool_count(ioch->io_pool);
parent = alloc_io(dev, io_complete_cb, &parent_status);
SPDK_CU_ASSERT_FATAL(parent != NULL);
child = ftl_io_alloc_child(parent);
SPDK_CU_ASSERT_FATAL(child != NULL);
ftl_io_free(child);
CU_ASSERT_EQUAL(spdk_mempool_count(ioch->io_pool), pool_size - 1);
child = ftl_io_alloc_child(parent);
SPDK_CU_ASSERT_FATAL(child != NULL);
ftl_io_complete(child);
CU_ASSERT_EQUAL(parent_status, -1);
ftl_io_complete(parent);
CU_ASSERT_EQUAL(parent_status, 0);
CU_ASSERT_EQUAL(spdk_mempool_count(ioch->io_pool), pool_size);
parent_status = -1;
parent = alloc_io(dev, io_complete_cb, &parent_status);
SPDK_CU_ASSERT_FATAL(parent != NULL);
child = ftl_io_alloc_child(parent);
SPDK_CU_ASSERT_FATAL(child != NULL);
ftl_io_free(child);
CU_ASSERT_EQUAL(parent_status, -1);
CU_ASSERT_EQUAL(spdk_mempool_count(ioch->io_pool), pool_size - 1);
ftl_io_complete(parent);
CU_ASSERT_EQUAL(parent_status, 0);
CU_ASSERT_EQUAL(spdk_mempool_count(ioch->io_pool), pool_size);
free_device(dev);
}
static void
test_child_requests(void)
{
struct spdk_ftl_dev *dev;
struct ftl_io_channel *ioch;
#define MAX_CHILDREN 16
struct ftl_io *parent, *child[MAX_CHILDREN];
int status[MAX_CHILDREN + 1], i;
size_t pool_size;
dev = setup_device(1, 16);
ioch = ftl_io_channel_get_ctx(dev->ioch);
pool_size = spdk_mempool_count(ioch->io_pool);
/* Verify correct behaviour when children finish first */
parent = alloc_io(dev, io_complete_cb, &status[0]);
parent->status = 0;
ftl_io_inc_req(parent);
status[0] = -1;
for (i = 0; i < MAX_CHILDREN; ++i) {
status[i + 1] = -1;
child[i] = ftl_io_alloc_child(parent);
SPDK_CU_ASSERT_FATAL(child[i] != NULL);
setup_io(child[i], dev, io_complete_cb, &status[i + 1]);
child[i]->status = 0;
ftl_io_inc_req(child[i]);
}
CU_ASSERT_FALSE(ftl_io_done(parent));
CU_ASSERT_EQUAL(spdk_mempool_count(ioch->io_pool), pool_size - MAX_CHILDREN - 1);
for (i = 0; i < MAX_CHILDREN; ++i) {
CU_ASSERT_FALSE(ftl_io_done(child[i]));
ftl_io_dec_req(child[i]);
CU_ASSERT_TRUE(ftl_io_done(child[i]));
CU_ASSERT_FALSE(ftl_io_done(parent));
ftl_io_complete(child[i]);
CU_ASSERT_FALSE(ftl_io_done(parent));
CU_ASSERT_EQUAL(status[i + 1], 0);
}
CU_ASSERT_EQUAL(status[0], -1);
ftl_io_dec_req(parent);
CU_ASSERT_EQUAL(parent->req_cnt, 0);
CU_ASSERT_TRUE(ftl_io_done(parent));
ftl_io_complete(parent);
CU_ASSERT_EQUAL(status[0], 0);
CU_ASSERT_EQUAL(spdk_mempool_count(ioch->io_pool), pool_size);
/* Verify correct behaviour when parent finishes first */
parent = alloc_io(dev, io_complete_cb, &status[0]);
parent->status = 0;
ftl_io_inc_req(parent);
status[0] = -1;
for (i = 0; i < MAX_CHILDREN; ++i) {
status[i + 1] = -1;
child[i] = ftl_io_alloc_child(parent);
SPDK_CU_ASSERT_FATAL(child[i] != NULL);
setup_io(child[i], dev, io_complete_cb, &status[i + 1]);
child[i]->status = 0;
ftl_io_inc_req(child[i]);
}
CU_ASSERT_FALSE(ftl_io_done(parent));
CU_ASSERT_EQUAL(spdk_mempool_count(ioch->io_pool), pool_size - MAX_CHILDREN - 1);
ftl_io_dec_req(parent);
CU_ASSERT_TRUE(ftl_io_done(parent));
CU_ASSERT_EQUAL(parent->req_cnt, 0);
ftl_io_complete(parent);
CU_ASSERT_EQUAL(status[0], -1);
CU_ASSERT_EQUAL(spdk_mempool_count(ioch->io_pool), pool_size - MAX_CHILDREN - 1);
for (i = 0; i < MAX_CHILDREN; ++i) {
CU_ASSERT_FALSE(ftl_io_done(child[i]));
ftl_io_dec_req(child[i]);
CU_ASSERT_TRUE(ftl_io_done(child[i]));
ftl_io_complete(child[i]);
CU_ASSERT_EQUAL(status[i + 1], 0);
}
CU_ASSERT_EQUAL(status[0], 0);
CU_ASSERT_EQUAL(spdk_mempool_count(ioch->io_pool), pool_size);
free_device(dev);
}
static void
test_child_status(void)
{
struct spdk_ftl_dev *dev;
struct ftl_io_channel *ioch;
struct ftl_io *parent, *child[2];
int parent_status, child_status[2];
size_t pool_size, i;
dev = setup_device(1, 16);
ioch = ftl_io_channel_get_ctx(dev->ioch);
pool_size = spdk_mempool_count(ioch->io_pool);
/* Verify the first error is returned by the parent */
parent = alloc_io(dev, io_complete_cb, &parent_status);
parent->status = 0;
for (i = 0; i < 2; ++i) {
child[i] = ftl_io_alloc_child(parent);
SPDK_CU_ASSERT_FATAL(child[i] != NULL);
setup_io(child[i], dev, io_complete_cb, &child_status[i]);
}
child[0]->status = -3;
child[1]->status = -4;
ftl_io_complete(child[1]);
ftl_io_complete(child[0]);
ftl_io_complete(parent);
CU_ASSERT_EQUAL(child_status[0], -3);
CU_ASSERT_EQUAL(child_status[1], -4);
CU_ASSERT_EQUAL(parent_status, -4);
CU_ASSERT_EQUAL(spdk_mempool_count(ioch->io_pool), pool_size);
/* Verify parent's status is kept if children finish successfully */
parent = alloc_io(dev, io_complete_cb, &parent_status);
parent->status = -1;
for (i = 0; i < 2; ++i) {
child[i] = ftl_io_alloc_child(parent);
SPDK_CU_ASSERT_FATAL(child[i] != NULL);
setup_io(child[i], dev, io_complete_cb, &child_status[i]);
}
child[0]->status = 0;
child[1]->status = 0;
ftl_io_complete(parent);
ftl_io_complete(child[1]);
ftl_io_complete(child[0]);
CU_ASSERT_EQUAL(child_status[0], 0);
CU_ASSERT_EQUAL(child_status[1], 0);
CU_ASSERT_EQUAL(parent_status, -1);
CU_ASSERT_EQUAL(spdk_mempool_count(ioch->io_pool), pool_size);
/* Verify parent's status is kept if children fail too */
parent = alloc_io(dev, io_complete_cb, &parent_status);
parent->status = -1;
for (i = 0; i < 2; ++i) {
child[i] = ftl_io_alloc_child(parent);
SPDK_CU_ASSERT_FATAL(child[i] != NULL);
setup_io(child[i], dev, io_complete_cb, &child_status[i]);
}
child[0]->status = -3;
child[1]->status = -4;
ftl_io_complete(parent);
ftl_io_complete(child[1]);
ftl_io_complete(child[0]);
CU_ASSERT_EQUAL(child_status[0], -3);
CU_ASSERT_EQUAL(child_status[1], -4);
CU_ASSERT_EQUAL(parent_status, -1);
CU_ASSERT_EQUAL(spdk_mempool_count(ioch->io_pool), pool_size);
free_device(dev);
}
static void
test_multi_generation(void)
{
struct spdk_ftl_dev *dev;
struct ftl_io_channel *ioch;
#define MAX_GRAND_CHILDREN 32
struct ftl_io *parent, *child[MAX_CHILDREN], *gchild[MAX_CHILDREN * MAX_GRAND_CHILDREN];
int parent_status, child_status[MAX_CHILDREN], gchild_status[MAX_CHILDREN * MAX_GRAND_CHILDREN];
size_t pool_size;
int i, j;
dev = setup_device(1, 16);
ioch = ftl_io_channel_get_ctx(dev->ioch);
pool_size = spdk_mempool_count(ioch->io_pool);
/* Verify correct behaviour when children finish first */
parent = alloc_io(dev, io_complete_cb, &parent_status);
parent->status = 0;
ftl_io_inc_req(parent);
parent_status = -1;
for (i = 0; i < MAX_CHILDREN; ++i) {
child_status[i] = -1;
child[i] = ftl_io_alloc_child(parent);
SPDK_CU_ASSERT_FATAL(child[i] != NULL);
setup_io(child[i], dev, io_complete_cb, &child_status[i]);
child[i]->status = 0;
for (j = 0; j < MAX_GRAND_CHILDREN; ++j) {
struct ftl_io *io = ftl_io_alloc_child(child[i]);
SPDK_CU_ASSERT_FATAL(io != NULL);
gchild[i * MAX_GRAND_CHILDREN + j] = io;
gchild_status[i * MAX_GRAND_CHILDREN + j] = -1;
setup_io(io, dev, io_complete_cb, &gchild_status[i * MAX_GRAND_CHILDREN + j]);
io->status = 0;
ftl_io_inc_req(io);
}
ftl_io_inc_req(child[i]);
}
for (i = 0; i < MAX_CHILDREN; ++i) {
CU_ASSERT_FALSE(ftl_io_done(child[i]));
ftl_io_dec_req(child[i]);
CU_ASSERT_TRUE(ftl_io_done(child[i]));
ftl_io_complete(child[i]);
CU_ASSERT_FALSE(ftl_io_done(parent));
CU_ASSERT_EQUAL(child_status[i], -1);
for (j = 0; j < MAX_GRAND_CHILDREN; ++j) {
struct ftl_io *io = gchild[i * MAX_GRAND_CHILDREN + j];
CU_ASSERT_FALSE(ftl_io_done(io));
ftl_io_dec_req(io);
CU_ASSERT_TRUE(ftl_io_done(io));
ftl_io_complete(io);
CU_ASSERT_EQUAL(gchild_status[i * MAX_GRAND_CHILDREN + j], 0);
}
CU_ASSERT_EQUAL(child_status[i], 0);
}
ftl_io_dec_req(parent);
CU_ASSERT_TRUE(ftl_io_done(parent));
ftl_io_complete(parent);
CU_ASSERT_EQUAL(parent_status, 0);
CU_ASSERT_EQUAL(spdk_mempool_count(ioch->io_pool), pool_size);
/* Verify correct behaviour when parents finish first */
parent = alloc_io(dev, io_complete_cb, &parent_status);
parent->status = 0;
parent_status = -1;
for (i = 0; i < MAX_CHILDREN; ++i) {
child_status[i] = -1;
child[i] = ftl_io_alloc_child(parent);
SPDK_CU_ASSERT_FATAL(child[i] != NULL);
setup_io(child[i], dev, io_complete_cb, &child_status[i]);
child[i]->status = 0;
for (j = 0; j < MAX_GRAND_CHILDREN; ++j) {
struct ftl_io *io = ftl_io_alloc_child(child[i]);
SPDK_CU_ASSERT_FATAL(io != NULL);
gchild[i * MAX_GRAND_CHILDREN + j] = io;
gchild_status[i * MAX_GRAND_CHILDREN + j] = -1;
setup_io(io, dev, io_complete_cb, &gchild_status[i * MAX_GRAND_CHILDREN + j]);
io->status = 0;
ftl_io_inc_req(io);
}
CU_ASSERT_TRUE(ftl_io_done(child[i]));
ftl_io_complete(child[i]);
CU_ASSERT_EQUAL(child_status[i], -1);
}
CU_ASSERT_TRUE(ftl_io_done(parent));
ftl_io_complete(parent);
CU_ASSERT_EQUAL(parent_status, -1);
for (i = 0; i < MAX_CHILDREN; ++i) {
for (j = 0; j < MAX_GRAND_CHILDREN; ++j) {
struct ftl_io *io = gchild[i * MAX_GRAND_CHILDREN + j];
CU_ASSERT_FALSE(ftl_io_done(io));
ftl_io_dec_req(io);
CU_ASSERT_TRUE(ftl_io_done(io));
ftl_io_complete(io);
CU_ASSERT_EQUAL(gchild_status[i * MAX_GRAND_CHILDREN + j], 0);
}
CU_ASSERT_EQUAL(child_status[i], 0);
}
CU_ASSERT_EQUAL(parent_status, 0);
CU_ASSERT_EQUAL(spdk_mempool_count(ioch->io_pool), pool_size);
free_device(dev);
}
static void
test_io_channel_create(void)
{
struct spdk_ftl_dev *dev;
struct spdk_io_channel *ioch, **ioch_array;
struct ftl_io_channel *ftl_ioch;
uint32_t ioch_idx;
dev = setup_device(g_default_conf.max_io_channels + 1, 16);
ioch = spdk_get_io_channel(dev);
CU_ASSERT(ioch != NULL);
CU_ASSERT_EQUAL(dev->num_io_channels, 1);
spdk_put_io_channel(ioch);
poll_threads();
CU_ASSERT_EQUAL(dev->num_io_channels, 0);
ioch_array = calloc(dev->conf.max_io_channels, sizeof(*ioch_array));
SPDK_CU_ASSERT_FATAL(ioch != NULL);
for (ioch_idx = 0; ioch_idx < dev->conf.max_io_channels; ++ioch_idx) {
set_thread(ioch_idx);
ioch = ioch_array[ioch_idx] = spdk_get_io_channel(dev);
SPDK_CU_ASSERT_FATAL(ioch != NULL);
poll_threads();
ftl_ioch = ftl_io_channel_get_ctx(ioch);
CU_ASSERT_EQUAL(ftl_ioch->index, ioch_idx);
}
CU_ASSERT_EQUAL(dev->num_io_channels, dev->conf.max_io_channels);
set_thread(dev->conf.max_io_channels);
ioch = spdk_get_io_channel(dev);
CU_ASSERT_EQUAL(dev->num_io_channels, dev->conf.max_io_channels);
CU_ASSERT_EQUAL(ioch, NULL);
for (ioch_idx = 0; ioch_idx < dev->conf.max_io_channels; ioch_idx += 2) {
set_thread(ioch_idx);
spdk_put_io_channel(ioch_array[ioch_idx]);
ioch_array[ioch_idx] = NULL;
poll_threads();
}
poll_threads();
CU_ASSERT_EQUAL(dev->num_io_channels, dev->conf.max_io_channels / 2);
for (ioch_idx = 0; ioch_idx < dev->conf.max_io_channels; ioch_idx++) {
set_thread(ioch_idx);
if (ioch_array[ioch_idx] == NULL) {
ioch = ioch_array[ioch_idx] = spdk_get_io_channel(dev);
SPDK_CU_ASSERT_FATAL(ioch != NULL);
poll_threads();
ftl_ioch = ftl_io_channel_get_ctx(ioch);
CU_ASSERT_EQUAL(ftl_ioch->index, ioch_idx);
}
}
for (ioch_idx = 0; ioch_idx < dev->conf.max_io_channels; ioch_idx++) {
set_thread(ioch_idx);
spdk_put_io_channel(ioch_array[ioch_idx]);
}
poll_threads();
CU_ASSERT_EQUAL(dev->num_io_channels, 0);
free(ioch_array);
free_device(dev);
}
static void
test_acquire_entry(void)
{
struct spdk_ftl_dev *dev;
struct spdk_io_channel *ioch, **ioch_array;
struct ftl_io_channel *ftl_ioch;
struct ftl_wbuf_entry *entry, **entries;
uint32_t num_entries, num_io_channels = 2;
uint32_t ioch_idx, entry_idx, tmp_idx;
dev = setup_device(num_io_channels, 16);
num_entries = dev->conf.rwb_size / FTL_BLOCK_SIZE;
entries = calloc(num_entries * num_io_channels, sizeof(*entries));
SPDK_CU_ASSERT_FATAL(entries != NULL);
ioch_array = calloc(num_io_channels, sizeof(*ioch_array));
SPDK_CU_ASSERT_FATAL(ioch_array != NULL);
/* Acquire whole buffer of internal entries */
entry_idx = 0;
for (ioch_idx = 0; ioch_idx < num_io_channels; ++ioch_idx) {
set_thread(ioch_idx);
ioch_array[ioch_idx] = spdk_get_io_channel(dev);
SPDK_CU_ASSERT_FATAL(ioch_array[ioch_idx] != NULL);
ftl_ioch = ftl_io_channel_get_ctx(ioch_array[ioch_idx]);
poll_threads();
for (tmp_idx = 0; tmp_idx < num_entries; ++tmp_idx) {
entries[entry_idx++] = ftl_acquire_wbuf_entry(ftl_ioch, FTL_IO_INTERNAL);
CU_ASSERT(entries[entry_idx - 1] != NULL);
}
entry = ftl_acquire_wbuf_entry(ftl_ioch, FTL_IO_INTERNAL);
CU_ASSERT(entry == NULL);
}
for (ioch_idx = 0; ioch_idx < num_io_channels; ++ioch_idx) {
set_thread(ioch_idx);
for (tmp_idx = 0; tmp_idx < num_entries; ++tmp_idx) {
ftl_release_wbuf_entry(entries[ioch_idx * num_entries + tmp_idx]);
entries[ioch_idx * num_entries + tmp_idx] = NULL;
}
spdk_put_io_channel(ioch_array[ioch_idx]);
}
poll_threads();
/* Do the same for user entries */
entry_idx = 0;
for (ioch_idx = 0; ioch_idx < num_io_channels; ++ioch_idx) {
set_thread(ioch_idx);
ioch_array[ioch_idx] = spdk_get_io_channel(dev);
SPDK_CU_ASSERT_FATAL(ioch_array[ioch_idx] != NULL);
ftl_ioch = ftl_io_channel_get_ctx(ioch_array[ioch_idx]);
poll_threads();
for (tmp_idx = 0; tmp_idx < num_entries; ++tmp_idx) {
entries[entry_idx++] = ftl_acquire_wbuf_entry(ftl_ioch, 0);
CU_ASSERT(entries[entry_idx - 1] != NULL);
}
entry = ftl_acquire_wbuf_entry(ftl_ioch, 0);
CU_ASSERT(entry == NULL);
}
for (ioch_idx = 0; ioch_idx < num_io_channels; ++ioch_idx) {
set_thread(ioch_idx);
for (tmp_idx = 0; tmp_idx < num_entries; ++tmp_idx) {
ftl_release_wbuf_entry(entries[ioch_idx * num_entries + tmp_idx]);
entries[ioch_idx * num_entries + tmp_idx] = NULL;
}
spdk_put_io_channel(ioch_array[ioch_idx]);
}
poll_threads();
/* Verify limits */
entry_idx = 0;
for (ioch_idx = 0; ioch_idx < num_io_channels; ++ioch_idx) {
set_thread(ioch_idx);
ioch_array[ioch_idx] = spdk_get_io_channel(dev);
SPDK_CU_ASSERT_FATAL(ioch_array[ioch_idx] != NULL);
ftl_ioch = ftl_io_channel_get_ctx(ioch_array[ioch_idx]);
poll_threads();
ftl_ioch->qdepth_limit = num_entries / 2;
for (tmp_idx = 0; tmp_idx < num_entries / 2; ++tmp_idx) {
entries[entry_idx++] = ftl_acquire_wbuf_entry(ftl_ioch, 0);
CU_ASSERT(entries[entry_idx - 1] != NULL);
}
entry = ftl_acquire_wbuf_entry(ftl_ioch, 0);
CU_ASSERT(entry == NULL);
for (; tmp_idx < num_entries; ++tmp_idx) {
entries[entry_idx++] = ftl_acquire_wbuf_entry(ftl_ioch, FTL_IO_INTERNAL);
CU_ASSERT(entries[entry_idx - 1] != NULL);
}
}
for (ioch_idx = 0; ioch_idx < num_io_channels; ++ioch_idx) {
set_thread(ioch_idx);
for (tmp_idx = 0; tmp_idx < num_entries; ++tmp_idx) {
ftl_release_wbuf_entry(entries[ioch_idx * num_entries + tmp_idx]);
entries[ioch_idx * num_entries + tmp_idx] = NULL;
}
spdk_put_io_channel(ioch_array[ioch_idx]);
}
poll_threads();
/* Verify acquire/release */
set_thread(0);
ioch = spdk_get_io_channel(dev);
SPDK_CU_ASSERT_FATAL(ioch != NULL);
ftl_ioch = ftl_io_channel_get_ctx(ioch);
poll_threads();
for (entry_idx = 0; entry_idx < num_entries; ++entry_idx) {
entries[entry_idx] = ftl_acquire_wbuf_entry(ftl_ioch, 0);
CU_ASSERT(entries[entry_idx] != NULL);
}
entry = ftl_acquire_wbuf_entry(ftl_ioch, 0);
CU_ASSERT(entry == NULL);
for (entry_idx = 0; entry_idx < num_entries / 2; ++entry_idx) {
ftl_release_wbuf_entry(entries[entry_idx]);
entries[entry_idx] = NULL;
}
for (; entry_idx < num_entries; ++entry_idx) {
entries[entry_idx - num_entries / 2] = ftl_acquire_wbuf_entry(ftl_ioch, 0);
CU_ASSERT(entries[entry_idx - num_entries / 2] != NULL);
}
for (entry_idx = 0; entry_idx < num_entries; ++entry_idx) {
ftl_release_wbuf_entry(entries[entry_idx]);
entries[entry_idx] = NULL;
}
spdk_put_io_channel(ioch);
poll_threads();
free(ioch_array);
free(entries);
free_device(dev);
}
static void
test_submit_batch(void)
{
struct spdk_ftl_dev *dev;
struct spdk_io_channel **_ioch_array;
struct ftl_io_channel **ioch_array;
struct ftl_wbuf_entry *entry;
struct ftl_batch *batch, *batch2;
uint32_t num_io_channels = 16;
uint32_t ioch_idx, tmp_idx, entry_idx;
uint64_t ioch_bitmap;
size_t num_entries;
dev = setup_device(num_io_channels, num_io_channels);
_ioch_array = calloc(num_io_channels, sizeof(*_ioch_array));
SPDK_CU_ASSERT_FATAL(_ioch_array != NULL);
ioch_array = calloc(num_io_channels, sizeof(*ioch_array));
SPDK_CU_ASSERT_FATAL(ioch_array != NULL);
for (ioch_idx = 0; ioch_idx < num_io_channels; ++ioch_idx) {
set_thread(ioch_idx);
_ioch_array[ioch_idx] = spdk_get_io_channel(dev);
SPDK_CU_ASSERT_FATAL(_ioch_array[ioch_idx] != NULL);
ioch_array[ioch_idx] = ftl_io_channel_get_ctx(_ioch_array[ioch_idx]);
poll_threads();
}
/* Make sure the IO channels are not starved and entries are popped in RR fashion */
for (ioch_idx = 0; ioch_idx < num_io_channels; ++ioch_idx) {
set_thread(ioch_idx);
for (entry_idx = 0; entry_idx < dev->xfer_size; ++entry_idx) {
entry = ftl_acquire_wbuf_entry(ioch_array[ioch_idx], 0);
SPDK_CU_ASSERT_FATAL(entry != NULL);
num_entries = spdk_ring_enqueue(ioch_array[ioch_idx]->submit_queue,
(void **)&entry, 1, NULL);
CU_ASSERT(num_entries == 1);
}
}
for (ioch_idx = 0; ioch_idx < num_io_channels; ++ioch_idx) {
for (tmp_idx = 0; tmp_idx < ioch_idx; ++tmp_idx) {
set_thread(tmp_idx);
while (spdk_ring_count(ioch_array[tmp_idx]->submit_queue) < dev->xfer_size) {
entry = ftl_acquire_wbuf_entry(ioch_array[tmp_idx], 0);
SPDK_CU_ASSERT_FATAL(entry != NULL);
num_entries = spdk_ring_enqueue(ioch_array[tmp_idx]->submit_queue,
(void **)&entry, 1, NULL);
CU_ASSERT(num_entries == 1);
}
}
set_thread(ioch_idx);
batch = ftl_get_next_batch(dev);
SPDK_CU_ASSERT_FATAL(batch != NULL);
TAILQ_FOREACH(entry, &batch->entries, tailq) {
CU_ASSERT(entry->ioch == ioch_array[ioch_idx]);
}
ftl_release_batch(dev, batch);
CU_ASSERT(spdk_ring_count(ioch_array[ioch_idx]->free_queue) ==
ioch_array[ioch_idx]->num_entries);
}
for (ioch_idx = 0; ioch_idx < num_io_channels - 1; ++ioch_idx) {
batch = ftl_get_next_batch(dev);
SPDK_CU_ASSERT_FATAL(batch != NULL);
ftl_release_batch(dev, batch);
}
/* Make sure the batch can be built from entries from any IO channel */
for (ioch_idx = 0; ioch_idx < num_io_channels; ++ioch_idx) {
set_thread(ioch_idx);
entry = ftl_acquire_wbuf_entry(ioch_array[ioch_idx], 0);
SPDK_CU_ASSERT_FATAL(entry != NULL);
num_entries = spdk_ring_enqueue(ioch_array[ioch_idx]->submit_queue,
(void **)&entry, 1, NULL);
CU_ASSERT(num_entries == 1);
}
batch = ftl_get_next_batch(dev);
SPDK_CU_ASSERT_FATAL(batch != NULL);
ioch_bitmap = 0;
TAILQ_FOREACH(entry, &batch->entries, tailq) {
ioch_bitmap |= 1 << entry->ioch->index;
}
for (ioch_idx = 0; ioch_idx < num_io_channels; ++ioch_idx) {
CU_ASSERT((ioch_bitmap & (1 << ioch_array[ioch_idx]->index)) != 0);
}
ftl_release_batch(dev, batch);
for (ioch_idx = 0; ioch_idx < num_io_channels; ++ioch_idx) {
CU_ASSERT(spdk_ring_count(ioch_array[ioch_idx]->free_queue) ==
ioch_array[ioch_idx]->num_entries);
}
/* Make sure pending batches are prioritized */
for (ioch_idx = 0; ioch_idx < num_io_channels; ++ioch_idx) {
set_thread(ioch_idx);
while (spdk_ring_count(ioch_array[ioch_idx]->submit_queue) < dev->xfer_size) {
entry = ftl_acquire_wbuf_entry(ioch_array[ioch_idx], 0);
SPDK_CU_ASSERT_FATAL(entry != NULL);
num_entries = spdk_ring_enqueue(ioch_array[ioch_idx]->submit_queue,
(void **)&entry, 1, NULL);
CU_ASSERT(num_entries == 1);
}
}
batch = ftl_get_next_batch(dev);
SPDK_CU_ASSERT_FATAL(batch != NULL);
TAILQ_INSERT_TAIL(&dev->pending_batches, batch, tailq);
batch2 = ftl_get_next_batch(dev);
SPDK_CU_ASSERT_FATAL(batch2 != NULL);
CU_ASSERT(TAILQ_EMPTY(&dev->pending_batches));
CU_ASSERT(batch == batch2);
batch = ftl_get_next_batch(dev);
SPDK_CU_ASSERT_FATAL(batch != NULL);
ftl_release_batch(dev, batch);
ftl_release_batch(dev, batch2);
for (ioch_idx = 2; ioch_idx < num_io_channels; ++ioch_idx) {
batch = ftl_get_next_batch(dev);
SPDK_CU_ASSERT_FATAL(batch != NULL);
ftl_release_batch(dev, batch);
}
for (ioch_idx = 0; ioch_idx < num_io_channels; ++ioch_idx) {
set_thread(ioch_idx);
spdk_put_io_channel(_ioch_array[ioch_idx]);
}
poll_threads();
free(_ioch_array);
free(ioch_array);
free_device(dev);
}
static void
test_entry_address(void)
{
struct spdk_ftl_dev *dev;
struct spdk_io_channel **ioch_array;
struct ftl_io_channel *ftl_ioch;
struct ftl_wbuf_entry **entry_array;
struct ftl_addr addr;
uint32_t num_entries, num_io_channels = 7;
uint32_t ioch_idx, entry_idx;
dev = setup_device(num_io_channels, num_io_channels);
ioch_array = calloc(num_io_channels, sizeof(*ioch_array));
SPDK_CU_ASSERT_FATAL(ioch_array != NULL);
num_entries = dev->conf.rwb_size / FTL_BLOCK_SIZE;
entry_array = calloc(num_entries, sizeof(*entry_array));
SPDK_CU_ASSERT_FATAL(entry_array != NULL);
for (ioch_idx = 0; ioch_idx < num_io_channels; ++ioch_idx) {
set_thread(ioch_idx);
ioch_array[ioch_idx] = spdk_get_io_channel(dev);
SPDK_CU_ASSERT_FATAL(ioch_array[ioch_idx] != NULL);
poll_threads();
}
for (ioch_idx = 0; ioch_idx < num_io_channels; ++ioch_idx) {
set_thread(ioch_idx);
ftl_ioch = ftl_io_channel_get_ctx(ioch_array[ioch_idx]);
for (entry_idx = 0; entry_idx < num_entries; ++entry_idx) {
entry_array[entry_idx] = ftl_acquire_wbuf_entry(ftl_ioch, 0);
SPDK_CU_ASSERT_FATAL(entry_array[entry_idx] != NULL);
addr = ftl_get_addr_from_entry(entry_array[entry_idx]);
CU_ASSERT(addr.cached == 1);
CU_ASSERT((addr.cache_offset >> dev->ioch_shift) == entry_idx);
CU_ASSERT((addr.cache_offset & ((1 << dev->ioch_shift) - 1)) == ioch_idx);
CU_ASSERT(entry_array[entry_idx] == ftl_get_entry_from_addr(dev, addr));
}
for (entry_idx = 0; entry_idx < num_entries; ++entry_idx) {
ftl_release_wbuf_entry(entry_array[entry_idx]);
}
}
for (ioch_idx = 0; ioch_idx < num_io_channels; ioch_idx += 2) {
set_thread(ioch_idx);
spdk_put_io_channel(ioch_array[ioch_idx]);
ioch_array[ioch_idx] = NULL;
}
poll_threads();
for (ioch_idx = 1; ioch_idx < num_io_channels; ioch_idx += 2) {
set_thread(ioch_idx);
ftl_ioch = ftl_io_channel_get_ctx(ioch_array[ioch_idx]);
for (entry_idx = 0; entry_idx < num_entries; ++entry_idx) {
entry_array[entry_idx] = ftl_acquire_wbuf_entry(ftl_ioch, 0);
SPDK_CU_ASSERT_FATAL(entry_array[entry_idx] != NULL);
addr = ftl_get_addr_from_entry(entry_array[entry_idx]);
CU_ASSERT(addr.cached == 1);
CU_ASSERT(entry_array[entry_idx] == ftl_get_entry_from_addr(dev, addr));
}
for (entry_idx = 0; entry_idx < num_entries; ++entry_idx) {
ftl_release_wbuf_entry(entry_array[entry_idx]);
}
}
for (ioch_idx = 1; ioch_idx < num_io_channels; ioch_idx += 2) {
set_thread(ioch_idx);
spdk_put_io_channel(ioch_array[ioch_idx]);
}
poll_threads();
free(entry_array);
free(ioch_array);
free_device(dev);
}
int
main(int argc, char **argv)
{
CU_pSuite suite;
unsigned int num_failures;
if (CU_initialize_registry() != CUE_SUCCESS) {
return CU_get_error();
}
suite = CU_add_suite("ftl_io_suite", NULL, NULL);
if (!suite) {
CU_cleanup_registry();
return CU_get_error();
}
if (
CU_add_test(suite, "test_completion",
test_completion) == NULL
|| CU_add_test(suite, "test_alloc_free",
test_alloc_free) == NULL
|| CU_add_test(suite, "test_child_requests",
test_child_requests) == NULL
|| CU_add_test(suite, "test_child_status",
test_child_status) == NULL
|| CU_add_test(suite, "test_multi_generation",
test_multi_generation) == NULL
|| CU_add_test(suite, "test_io_channel_create",
test_io_channel_create) == NULL
|| CU_add_test(suite, "test_acquire_entry",
test_acquire_entry) == NULL
|| CU_add_test(suite, "test_submit_batch",
test_submit_batch) == NULL
|| CU_add_test(suite, "test_entry_address",
test_entry_address) == NULL
) {
CU_cleanup_registry();
return CU_get_error();
}
CU_basic_set_mode(CU_BRM_VERBOSE);
CU_basic_run_tests();
num_failures = CU_get_number_of_failures();
CU_cleanup_registry();
return num_failures;
}
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