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git/reftable/stack_test.c
Patrick Steinhardt f234df07f6 reftable/stack: handle locked tables during auto-compaction 
When compacting tables, it may happen that we want to compact a set of
tables which are already locked by a concurrent process that compacts
them. In the case where we wanted to perform a full compaction of all
tables it is sensible to bail out in this case, as we cannot fulfill the
requested action.

But when performing auto-compaction it isn't necessarily in our best
interest of us to abort the whole operation. For example, due to the
geometric compacting schema that we use, it may be that process A takes
a lot of time to compact the bulk of all tables whereas process B
appends a bunch of new tables to the stack. B would in this case also
notice that it has to compact the tables that process A is compacting
already and thus also try to compact the same range, probably including
the new tables it has appended. But because those tables are locked
already, it will fail and thus abort the complete auto-compaction. The
consequence is that the stack will grow longer and longer while A isn't
yet done with compaction, which will lead to a growing performance
impact.

Instead of aborting auto-compaction altogether, let's gracefully handle
this situation by instead compacting tables which aren't locked. To do
so, instead of locking from the beginning of the slice-to-be-compacted,
we start locking tables from the end of the slice. Once we hit the first
table that is locked already, we abort. If we succeeded to lock two or
more tables, then we simply reduce the slice of tables that we're about
to compact to those which we managed to lock.

This ensures that we can at least make some progress for compaction in
said scenario. It also helps in other scenarios, like for example when a
process died and left a stale lockfile behind. In such a case we can at
least ensure some compaction on a best-effort basis.

Signed-off-by: Patrick Steinhardt <ps@pks.im>
Signed-off-by: Junio C Hamano <gitster@pobox.com>
2024-08-08 10:14:43 -07:00

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/*
Copyright 2020 Google LLC
Use of this source code is governed by a BSD-style
license that can be found in the LICENSE file or at
https://developers.google.com/open-source/licenses/bsd
*/
#include "stack.h"
#include "system.h"
#include "reftable-reader.h"
#include "merged.h"
#include "basics.h"
#include "record.h"
#include "test_framework.h"
#include "reftable-tests.h"
#include "reader.h"
#include <sys/types.h>
#include <dirent.h>
static void clear_dir(const char *dirname)
{
struct strbuf path = STRBUF_INIT;
strbuf_addstr(&path, dirname);
remove_dir_recursively(&path, 0);
strbuf_release(&path);
}
static int count_dir_entries(const char *dirname)
{
DIR *dir = opendir(dirname);
int len = 0;
struct dirent *d;
if (!dir)
return 0;
while ((d = readdir(dir))) {
/*
* Besides skipping over "." and "..", we also need to
* skip over other files that have a leading ".". This
* is due to behaviour of NFS, which will rename files
* to ".nfs*" to emulate delete-on-last-close.
*
* In any case this should be fine as the reftable
* library will never write files with leading dots
* anyway.
*/
if (starts_with(d->d_name, "."))
continue;
len++;
}
closedir(dir);
return len;
}
/*
* Work linenumber into the tempdir, so we can see which tests forget to
* cleanup.
*/
static char *get_tmp_template(int linenumber)
{
const char *tmp = getenv("TMPDIR");
static char template[1024];
snprintf(template, sizeof(template) - 1, "%s/stack_test-%d.XXXXXX",
tmp ? tmp : "/tmp", linenumber);
return template;
}
static char *get_tmp_dir(int linenumber)
{
char *dir = get_tmp_template(linenumber);
EXPECT(mkdtemp(dir));
return dir;
}
static void test_read_file(void)
{
char *fn = get_tmp_template(__LINE__);
int fd = mkstemp(fn);
char out[1024] = "line1\n\nline2\nline3";
int n, err;
char **names = NULL;
const char *want[] = { "line1", "line2", "line3" };
int i = 0;
EXPECT(fd > 0);
n = write_in_full(fd, out, strlen(out));
EXPECT(n == strlen(out));
err = close(fd);
EXPECT(err >= 0);
err = read_lines(fn, &names);
EXPECT_ERR(err);
for (i = 0; names[i]; i++) {
EXPECT(0 == strcmp(want[i], names[i]));
}
free_names(names);
(void) remove(fn);
}
static int write_test_ref(struct reftable_writer *wr, void *arg)
{
struct reftable_ref_record *ref = arg;
reftable_writer_set_limits(wr, ref->update_index, ref->update_index);
return reftable_writer_add_ref(wr, ref);
}
static void write_n_ref_tables(struct reftable_stack *st,
size_t n)
{
struct strbuf buf = STRBUF_INIT;
int disable_auto_compact;
int err;
disable_auto_compact = st->opts.disable_auto_compact;
st->opts.disable_auto_compact = 1;
for (size_t i = 0; i < n; i++) {
struct reftable_ref_record ref = {
.update_index = reftable_stack_next_update_index(st),
.value_type = REFTABLE_REF_VAL1,
};
strbuf_addf(&buf, "refs/heads/branch-%04u", (unsigned) i);
ref.refname = buf.buf;
set_test_hash(ref.value.val1, i);
err = reftable_stack_add(st, &write_test_ref, &ref);
EXPECT_ERR(err);
}
st->opts.disable_auto_compact = disable_auto_compact;
strbuf_release(&buf);
}
struct write_log_arg {
struct reftable_log_record *log;
uint64_t update_index;
};
static int write_test_log(struct reftable_writer *wr, void *arg)
{
struct write_log_arg *wla = arg;
reftable_writer_set_limits(wr, wla->update_index, wla->update_index);
return reftable_writer_add_log(wr, wla->log);
}
static void test_reftable_stack_add_one(void)
{
char *dir = get_tmp_dir(__LINE__);
struct strbuf scratch = STRBUF_INIT;
int mask = umask(002);
struct reftable_write_options opts = {
.default_permissions = 0660,
};
struct reftable_stack *st = NULL;
int err;
struct reftable_ref_record ref = {
.refname = (char *) "HEAD",
.update_index = 1,
.value_type = REFTABLE_REF_SYMREF,
.value.symref = (char *) "master",
};
struct reftable_ref_record dest = { NULL };
struct stat stat_result = { 0 };
err = reftable_new_stack(&st, dir, &opts);
EXPECT_ERR(err);
err = reftable_stack_add(st, &write_test_ref, &ref);
EXPECT_ERR(err);
err = reftable_stack_read_ref(st, ref.refname, &dest);
EXPECT_ERR(err);
EXPECT(0 == strcmp("master", dest.value.symref));
EXPECT(st->readers_len > 0);
printf("testing print functionality:\n");
err = reftable_stack_print_directory(dir, GIT_SHA1_FORMAT_ID);
EXPECT_ERR(err);
err = reftable_stack_print_directory(dir, GIT_SHA256_FORMAT_ID);
EXPECT(err == REFTABLE_FORMAT_ERROR);
#ifndef GIT_WINDOWS_NATIVE
strbuf_addstr(&scratch, dir);
strbuf_addstr(&scratch, "/tables.list");
err = stat(scratch.buf, &stat_result);
EXPECT(!err);
EXPECT((stat_result.st_mode & 0777) == opts.default_permissions);
strbuf_reset(&scratch);
strbuf_addstr(&scratch, dir);
strbuf_addstr(&scratch, "/");
/* do not try at home; not an external API for reftable. */
strbuf_addstr(&scratch, st->readers[0]->name);
err = stat(scratch.buf, &stat_result);
EXPECT(!err);
EXPECT((stat_result.st_mode & 0777) == opts.default_permissions);
#else
(void) stat_result;
#endif
reftable_ref_record_release(&dest);
reftable_stack_destroy(st);
strbuf_release(&scratch);
clear_dir(dir);
umask(mask);
}
static void test_reftable_stack_uptodate(void)
{
struct reftable_write_options opts = { 0 };
struct reftable_stack *st1 = NULL;
struct reftable_stack *st2 = NULL;
char *dir = get_tmp_dir(__LINE__);
int err;
struct reftable_ref_record ref1 = {
.refname = (char *) "HEAD",
.update_index = 1,
.value_type = REFTABLE_REF_SYMREF,
.value.symref = (char *) "master",
};
struct reftable_ref_record ref2 = {
.refname = (char *) "branch2",
.update_index = 2,
.value_type = REFTABLE_REF_SYMREF,
.value.symref = (char *) "master",
};
/* simulate multi-process access to the same stack
by creating two stacks for the same directory.
*/
err = reftable_new_stack(&st1, dir, &opts);
EXPECT_ERR(err);
err = reftable_new_stack(&st2, dir, &opts);
EXPECT_ERR(err);
err = reftable_stack_add(st1, &write_test_ref, &ref1);
EXPECT_ERR(err);
err = reftable_stack_add(st2, &write_test_ref, &ref2);
EXPECT(err == REFTABLE_OUTDATED_ERROR);
err = reftable_stack_reload(st2);
EXPECT_ERR(err);
err = reftable_stack_add(st2, &write_test_ref, &ref2);
EXPECT_ERR(err);
reftable_stack_destroy(st1);
reftable_stack_destroy(st2);
clear_dir(dir);
}
static void test_reftable_stack_transaction_api(void)
{
char *dir = get_tmp_dir(__LINE__);
struct reftable_write_options opts = { 0 };
struct reftable_stack *st = NULL;
int err;
struct reftable_addition *add = NULL;
struct reftable_ref_record ref = {
.refname = (char *) "HEAD",
.update_index = 1,
.value_type = REFTABLE_REF_SYMREF,
.value.symref = (char *) "master",
};
struct reftable_ref_record dest = { NULL };
err = reftable_new_stack(&st, dir, &opts);
EXPECT_ERR(err);
reftable_addition_destroy(add);
err = reftable_stack_new_addition(&add, st);
EXPECT_ERR(err);
err = reftable_addition_add(add, &write_test_ref, &ref);
EXPECT_ERR(err);
err = reftable_addition_commit(add);
EXPECT_ERR(err);
reftable_addition_destroy(add);
err = reftable_stack_read_ref(st, ref.refname, &dest);
EXPECT_ERR(err);
EXPECT(REFTABLE_REF_SYMREF == dest.value_type);
EXPECT(0 == strcmp("master", dest.value.symref));
reftable_ref_record_release(&dest);
reftable_stack_destroy(st);
clear_dir(dir);
}
static void test_reftable_stack_transaction_api_performs_auto_compaction(void)
{
char *dir = get_tmp_dir(__LINE__);
struct reftable_write_options opts = {0};
struct reftable_addition *add = NULL;
struct reftable_stack *st = NULL;
int i, n = 20, err;
err = reftable_new_stack(&st, dir, &opts);
EXPECT_ERR(err);
for (i = 0; i <= n; i++) {
struct reftable_ref_record ref = {
.update_index = reftable_stack_next_update_index(st),
.value_type = REFTABLE_REF_SYMREF,
.value.symref = (char *) "master",
};
char name[100];
snprintf(name, sizeof(name), "branch%04d", i);
ref.refname = name;
/*
* Disable auto-compaction for all but the last runs. Like this
* we can ensure that we indeed honor this setting and have
* better control over when exactly auto compaction runs.
*/
st->opts.disable_auto_compact = i != n;
err = reftable_stack_new_addition(&add, st);
EXPECT_ERR(err);
err = reftable_addition_add(add, &write_test_ref, &ref);
EXPECT_ERR(err);
err = reftable_addition_commit(add);
EXPECT_ERR(err);
reftable_addition_destroy(add);
/*
* The stack length should grow continuously for all runs where
* auto compaction is disabled. When enabled, we should merge
* all tables in the stack.
*/
if (i != n)
EXPECT(st->merged->stack_len == i + 1);
else
EXPECT(st->merged->stack_len == 1);
}
reftable_stack_destroy(st);
clear_dir(dir);
}
static void test_reftable_stack_auto_compaction_fails_gracefully(void)
{
struct reftable_ref_record ref = {
.refname = (char *) "refs/heads/master",
.update_index = 1,
.value_type = REFTABLE_REF_VAL1,
.value.val1 = {0x01},
};
struct reftable_write_options opts = {0};
struct reftable_stack *st;
struct strbuf table_path = STRBUF_INIT;
char *dir = get_tmp_dir(__LINE__);
int err;
err = reftable_new_stack(&st, dir, &opts);
EXPECT_ERR(err);
err = reftable_stack_add(st, write_test_ref, &ref);
EXPECT_ERR(err);
EXPECT(st->merged->stack_len == 1);
EXPECT(st->stats.attempts == 0);
EXPECT(st->stats.failures == 0);
/*
* Lock the newly written table such that it cannot be compacted.
* Adding a new table to the stack should not be impacted by this, even
* though auto-compaction will now fail.
*/
strbuf_addf(&table_path, "%s/%s.lock", dir, st->readers[0]->name);
write_file_buf(table_path.buf, "", 0);
ref.update_index = 2;
err = reftable_stack_add(st, write_test_ref, &ref);
EXPECT_ERR(err);
EXPECT(st->merged->stack_len == 2);
EXPECT(st->stats.attempts == 1);
EXPECT(st->stats.failures == 1);
reftable_stack_destroy(st);
strbuf_release(&table_path);
clear_dir(dir);
}
static int write_error(struct reftable_writer *wr, void *arg)
{
return *((int *)arg);
}
static void test_reftable_stack_update_index_check(void)
{
char *dir = get_tmp_dir(__LINE__);
struct reftable_write_options opts = { 0 };
struct reftable_stack *st = NULL;
int err;
struct reftable_ref_record ref1 = {
.refname = (char *) "name1",
.update_index = 1,
.value_type = REFTABLE_REF_SYMREF,
.value.symref = (char *) "master",
};
struct reftable_ref_record ref2 = {
.refname = (char *) "name2",
.update_index = 1,
.value_type = REFTABLE_REF_SYMREF,
.value.symref = (char *) "master",
};
err = reftable_new_stack(&st, dir, &opts);
EXPECT_ERR(err);
err = reftable_stack_add(st, &write_test_ref, &ref1);
EXPECT_ERR(err);
err = reftable_stack_add(st, &write_test_ref, &ref2);
EXPECT(err == REFTABLE_API_ERROR);
reftable_stack_destroy(st);
clear_dir(dir);
}
static void test_reftable_stack_lock_failure(void)
{
char *dir = get_tmp_dir(__LINE__);
struct reftable_write_options opts = { 0 };
struct reftable_stack *st = NULL;
int err, i;
err = reftable_new_stack(&st, dir, &opts);
EXPECT_ERR(err);
for (i = -1; i != REFTABLE_EMPTY_TABLE_ERROR; i--) {
err = reftable_stack_add(st, &write_error, &i);
EXPECT(err == i);
}
reftable_stack_destroy(st);
clear_dir(dir);
}
static void test_reftable_stack_add(void)
{
int i = 0;
int err = 0;
struct reftable_write_options opts = {
.exact_log_message = 1,
.default_permissions = 0660,
.disable_auto_compact = 1,
};
struct reftable_stack *st = NULL;
char *dir = get_tmp_dir(__LINE__);
struct reftable_ref_record refs[2] = { { NULL } };
struct reftable_log_record logs[2] = { { NULL } };
struct strbuf path = STRBUF_INIT;
struct stat stat_result;
int N = ARRAY_SIZE(refs);
err = reftable_new_stack(&st, dir, &opts);
EXPECT_ERR(err);
for (i = 0; i < N; i++) {
char buf[256];
snprintf(buf, sizeof(buf), "branch%02d", i);
refs[i].refname = xstrdup(buf);
refs[i].update_index = i + 1;
refs[i].value_type = REFTABLE_REF_VAL1;
set_test_hash(refs[i].value.val1, i);
logs[i].refname = xstrdup(buf);
logs[i].update_index = N + i + 1;
logs[i].value_type = REFTABLE_LOG_UPDATE;
logs[i].value.update.email = xstrdup("identity@invalid");
set_test_hash(logs[i].value.update.new_hash, i);
}
for (i = 0; i < N; i++) {
int err = reftable_stack_add(st, &write_test_ref, &refs[i]);
EXPECT_ERR(err);
}
for (i = 0; i < N; i++) {
struct write_log_arg arg = {
.log = &logs[i],
.update_index = reftable_stack_next_update_index(st),
};
int err = reftable_stack_add(st, &write_test_log, &arg);
EXPECT_ERR(err);
}
err = reftable_stack_compact_all(st, NULL);
EXPECT_ERR(err);
for (i = 0; i < N; i++) {
struct reftable_ref_record dest = { NULL };
int err = reftable_stack_read_ref(st, refs[i].refname, &dest);
EXPECT_ERR(err);
EXPECT(reftable_ref_record_equal(&dest, refs + i,
GIT_SHA1_RAWSZ));
reftable_ref_record_release(&dest);
}
for (i = 0; i < N; i++) {
struct reftable_log_record dest = { NULL };
int err = reftable_stack_read_log(st, refs[i].refname, &dest);
EXPECT_ERR(err);
EXPECT(reftable_log_record_equal(&dest, logs + i,
GIT_SHA1_RAWSZ));
reftable_log_record_release(&dest);
}
#ifndef GIT_WINDOWS_NATIVE
strbuf_addstr(&path, dir);
strbuf_addstr(&path, "/tables.list");
err = stat(path.buf, &stat_result);
EXPECT(!err);
EXPECT((stat_result.st_mode & 0777) == opts.default_permissions);
strbuf_reset(&path);
strbuf_addstr(&path, dir);
strbuf_addstr(&path, "/");
/* do not try at home; not an external API for reftable. */
strbuf_addstr(&path, st->readers[0]->name);
err = stat(path.buf, &stat_result);
EXPECT(!err);
EXPECT((stat_result.st_mode & 0777) == opts.default_permissions);
#else
(void) stat_result;
#endif
/* cleanup */
reftable_stack_destroy(st);
for (i = 0; i < N; i++) {
reftable_ref_record_release(&refs[i]);
reftable_log_record_release(&logs[i]);
}
strbuf_release(&path);
clear_dir(dir);
}
static void test_reftable_stack_log_normalize(void)
{
int err = 0;
struct reftable_write_options opts = {
0,
};
struct reftable_stack *st = NULL;
char *dir = get_tmp_dir(__LINE__);
struct reftable_log_record input = {
.refname = (char *) "branch",
.update_index = 1,
.value_type = REFTABLE_LOG_UPDATE,
.value = {
.update = {
.new_hash = { 1 },
.old_hash = { 2 },
},
},
};
struct reftable_log_record dest = {
.update_index = 0,
};
struct write_log_arg arg = {
.log = &input,
.update_index = 1,
};
err = reftable_new_stack(&st, dir, &opts);
EXPECT_ERR(err);
input.value.update.message = (char *) "one\ntwo";
err = reftable_stack_add(st, &write_test_log, &arg);
EXPECT(err == REFTABLE_API_ERROR);
input.value.update.message = (char *) "one";
err = reftable_stack_add(st, &write_test_log, &arg);
EXPECT_ERR(err);
err = reftable_stack_read_log(st, input.refname, &dest);
EXPECT_ERR(err);
EXPECT(0 == strcmp(dest.value.update.message, "one\n"));
input.value.update.message = (char *) "two\n";
arg.update_index = 2;
err = reftable_stack_add(st, &write_test_log, &arg);
EXPECT_ERR(err);
err = reftable_stack_read_log(st, input.refname, &dest);
EXPECT_ERR(err);
EXPECT(0 == strcmp(dest.value.update.message, "two\n"));
/* cleanup */
reftable_stack_destroy(st);
reftable_log_record_release(&dest);
clear_dir(dir);
}
static void test_reftable_stack_tombstone(void)
{
int i = 0;
char *dir = get_tmp_dir(__LINE__);
struct reftable_write_options opts = { 0 };
struct reftable_stack *st = NULL;
int err;
struct reftable_ref_record refs[2] = { { NULL } };
struct reftable_log_record logs[2] = { { NULL } };
int N = ARRAY_SIZE(refs);
struct reftable_ref_record dest = { NULL };
struct reftable_log_record log_dest = { NULL };
err = reftable_new_stack(&st, dir, &opts);
EXPECT_ERR(err);
/* even entries add the refs, odd entries delete them. */
for (i = 0; i < N; i++) {
const char *buf = "branch";
refs[i].refname = xstrdup(buf);
refs[i].update_index = i + 1;
if (i % 2 == 0) {
refs[i].value_type = REFTABLE_REF_VAL1;
set_test_hash(refs[i].value.val1, i);
}
logs[i].refname = xstrdup(buf);
/* update_index is part of the key. */
logs[i].update_index = 42;
if (i % 2 == 0) {
logs[i].value_type = REFTABLE_LOG_UPDATE;
set_test_hash(logs[i].value.update.new_hash, i);
logs[i].value.update.email =
xstrdup("identity@invalid");
}
}
for (i = 0; i < N; i++) {
int err = reftable_stack_add(st, &write_test_ref, &refs[i]);
EXPECT_ERR(err);
}
for (i = 0; i < N; i++) {
struct write_log_arg arg = {
.log = &logs[i],
.update_index = reftable_stack_next_update_index(st),
};
int err = reftable_stack_add(st, &write_test_log, &arg);
EXPECT_ERR(err);
}
err = reftable_stack_read_ref(st, "branch", &dest);
EXPECT(err == 1);
reftable_ref_record_release(&dest);
err = reftable_stack_read_log(st, "branch", &log_dest);
EXPECT(err == 1);
reftable_log_record_release(&log_dest);
err = reftable_stack_compact_all(st, NULL);
EXPECT_ERR(err);
err = reftable_stack_read_ref(st, "branch", &dest);
EXPECT(err == 1);
err = reftable_stack_read_log(st, "branch", &log_dest);
EXPECT(err == 1);
reftable_ref_record_release(&dest);
reftable_log_record_release(&log_dest);
/* cleanup */
reftable_stack_destroy(st);
for (i = 0; i < N; i++) {
reftable_ref_record_release(&refs[i]);
reftable_log_record_release(&logs[i]);
}
clear_dir(dir);
}
static void test_reftable_stack_hash_id(void)
{
char *dir = get_tmp_dir(__LINE__);
struct reftable_write_options opts = { 0 };
struct reftable_stack *st = NULL;
int err;
struct reftable_ref_record ref = {
.refname = (char *) "master",
.value_type = REFTABLE_REF_SYMREF,
.value.symref = (char *) "target",
.update_index = 1,
};
struct reftable_write_options opts32 = { .hash_id = GIT_SHA256_FORMAT_ID };
struct reftable_stack *st32 = NULL;
struct reftable_write_options opts_default = { 0 };
struct reftable_stack *st_default = NULL;
struct reftable_ref_record dest = { NULL };
err = reftable_new_stack(&st, dir, &opts);
EXPECT_ERR(err);
err = reftable_stack_add(st, &write_test_ref, &ref);
EXPECT_ERR(err);
/* can't read it with the wrong hash ID. */
err = reftable_new_stack(&st32, dir, &opts32);
EXPECT(err == REFTABLE_FORMAT_ERROR);
/* check that we can read it back with default opts too. */
err = reftable_new_stack(&st_default, dir, &opts_default);
EXPECT_ERR(err);
err = reftable_stack_read_ref(st_default, "master", &dest);
EXPECT_ERR(err);
EXPECT(reftable_ref_record_equal(&ref, &dest, GIT_SHA1_RAWSZ));
reftable_ref_record_release(&dest);
reftable_stack_destroy(st);
reftable_stack_destroy(st_default);
clear_dir(dir);
}
static void test_suggest_compaction_segment(void)
{
uint64_t sizes[] = { 512, 64, 17, 16, 9, 9, 9, 16, 2, 16 };
struct segment min =
suggest_compaction_segment(sizes, ARRAY_SIZE(sizes), 2);
EXPECT(min.start == 1);
EXPECT(min.end == 10);
}
static void test_suggest_compaction_segment_nothing(void)
{
uint64_t sizes[] = { 64, 32, 16, 8, 4, 2 };
struct segment result =
suggest_compaction_segment(sizes, ARRAY_SIZE(sizes), 2);
EXPECT(result.start == result.end);
}
static void test_reflog_expire(void)
{
char *dir = get_tmp_dir(__LINE__);
struct reftable_write_options opts = { 0 };
struct reftable_stack *st = NULL;
struct reftable_log_record logs[20] = { { NULL } };
int N = ARRAY_SIZE(logs) - 1;
int i = 0;
int err;
struct reftable_log_expiry_config expiry = {
.time = 10,
};
struct reftable_log_record log = { NULL };
err = reftable_new_stack(&st, dir, &opts);
EXPECT_ERR(err);
for (i = 1; i <= N; i++) {
char buf[256];
snprintf(buf, sizeof(buf), "branch%02d", i);
logs[i].refname = xstrdup(buf);
logs[i].update_index = i;
logs[i].value_type = REFTABLE_LOG_UPDATE;
logs[i].value.update.time = i;
logs[i].value.update.email = xstrdup("identity@invalid");
set_test_hash(logs[i].value.update.new_hash, i);
}
for (i = 1; i <= N; i++) {
struct write_log_arg arg = {
.log = &logs[i],
.update_index = reftable_stack_next_update_index(st),
};
int err = reftable_stack_add(st, &write_test_log, &arg);
EXPECT_ERR(err);
}
err = reftable_stack_compact_all(st, NULL);
EXPECT_ERR(err);
err = reftable_stack_compact_all(st, &expiry);
EXPECT_ERR(err);
err = reftable_stack_read_log(st, logs[9].refname, &log);
EXPECT(err == 1);
err = reftable_stack_read_log(st, logs[11].refname, &log);
EXPECT_ERR(err);
expiry.min_update_index = 15;
err = reftable_stack_compact_all(st, &expiry);
EXPECT_ERR(err);
err = reftable_stack_read_log(st, logs[14].refname, &log);
EXPECT(err == 1);
err = reftable_stack_read_log(st, logs[16].refname, &log);
EXPECT_ERR(err);
/* cleanup */
reftable_stack_destroy(st);
for (i = 0; i <= N; i++) {
reftable_log_record_release(&logs[i]);
}
clear_dir(dir);
reftable_log_record_release(&log);
}
static int write_nothing(struct reftable_writer *wr, void *arg)
{
reftable_writer_set_limits(wr, 1, 1);
return 0;
}
static void test_empty_add(void)
{
struct reftable_write_options opts = { 0 };
struct reftable_stack *st = NULL;
int err;
char *dir = get_tmp_dir(__LINE__);
struct reftable_stack *st2 = NULL;
err = reftable_new_stack(&st, dir, &opts);
EXPECT_ERR(err);
err = reftable_stack_add(st, &write_nothing, NULL);
EXPECT_ERR(err);
err = reftable_new_stack(&st2, dir, &opts);
EXPECT_ERR(err);
clear_dir(dir);
reftable_stack_destroy(st);
reftable_stack_destroy(st2);
}
static int fastlog2(uint64_t sz)
{
int l = 0;
if (sz == 0)
return 0;
for (; sz; sz /= 2)
l++;
return l - 1;
}
static void test_reftable_stack_auto_compaction(void)
{
struct reftable_write_options opts = {
.disable_auto_compact = 1,
};
struct reftable_stack *st = NULL;
char *dir = get_tmp_dir(__LINE__);
int err, i;
int N = 100;
err = reftable_new_stack(&st, dir, &opts);
EXPECT_ERR(err);
for (i = 0; i < N; i++) {
char name[100];
struct reftable_ref_record ref = {
.refname = name,
.update_index = reftable_stack_next_update_index(st),
.value_type = REFTABLE_REF_SYMREF,
.value.symref = (char *) "master",
};
snprintf(name, sizeof(name), "branch%04d", i);
err = reftable_stack_add(st, &write_test_ref, &ref);
EXPECT_ERR(err);
err = reftable_stack_auto_compact(st);
EXPECT_ERR(err);
EXPECT(i < 3 || st->merged->stack_len < 2 * fastlog2(i));
}
EXPECT(reftable_stack_compaction_stats(st)->entries_written <
(uint64_t)(N * fastlog2(N)));
reftable_stack_destroy(st);
clear_dir(dir);
}
static void test_reftable_stack_auto_compaction_with_locked_tables(void)
{
struct reftable_write_options opts = {
.disable_auto_compact = 1,
};
struct reftable_stack *st = NULL;
struct strbuf buf = STRBUF_INIT;
char *dir = get_tmp_dir(__LINE__);
int err;
err = reftable_new_stack(&st, dir, &opts);
EXPECT_ERR(err);
write_n_ref_tables(st, 5);
EXPECT(st->merged->stack_len == 5);
/*
* Given that all tables we have written should be roughly the same
* size, we expect that auto-compaction will want to compact all of the
* tables. Locking any of the tables will keep it from doing so.
*/
strbuf_reset(&buf);
strbuf_addf(&buf, "%s/%s.lock", dir, st->readers[2]->name);
write_file_buf(buf.buf, "", 0);
/*
* When parts of the stack are locked, then auto-compaction does a best
* effort compaction of those tables which aren't locked. So while this
* would in theory compact all tables, due to the preexisting lock we
* only compact the newest two tables.
*/
err = reftable_stack_auto_compact(st);
EXPECT_ERR(err);
EXPECT(st->stats.failures == 0);
EXPECT(st->merged->stack_len == 4);
reftable_stack_destroy(st);
strbuf_release(&buf);
clear_dir(dir);
}
static void test_reftable_stack_add_performs_auto_compaction(void)
{
struct reftable_write_options opts = { 0 };
struct reftable_stack *st = NULL;
struct strbuf refname = STRBUF_INIT;
char *dir = get_tmp_dir(__LINE__);
int err, i, n = 20;
err = reftable_new_stack(&st, dir, &opts);
EXPECT_ERR(err);
for (i = 0; i <= n; i++) {
struct reftable_ref_record ref = {
.update_index = reftable_stack_next_update_index(st),
.value_type = REFTABLE_REF_SYMREF,
.value.symref = (char *) "master",
};
/*
* Disable auto-compaction for all but the last runs. Like this
* we can ensure that we indeed honor this setting and have
* better control over when exactly auto compaction runs.
*/
st->opts.disable_auto_compact = i != n;
strbuf_reset(&refname);
strbuf_addf(&refname, "branch-%04d", i);
ref.refname = refname.buf;
err = reftable_stack_add(st, &write_test_ref, &ref);
EXPECT_ERR(err);
/*
* The stack length should grow continuously for all runs where
* auto compaction is disabled. When enabled, we should merge
* all tables in the stack.
*/
if (i != n)
EXPECT(st->merged->stack_len == i + 1);
else
EXPECT(st->merged->stack_len == 1);
}
reftable_stack_destroy(st);
strbuf_release(&refname);
clear_dir(dir);
}
static void test_reftable_stack_compaction_with_locked_tables(void)
{
struct reftable_write_options opts = {
.disable_auto_compact = 1,
};
struct reftable_stack *st = NULL;
struct strbuf buf = STRBUF_INIT;
char *dir = get_tmp_dir(__LINE__);
int err;
err = reftable_new_stack(&st, dir, &opts);
EXPECT_ERR(err);
write_n_ref_tables(st, 3);
EXPECT(st->merged->stack_len == 3);
/* Lock one of the tables that we're about to compact. */
strbuf_reset(&buf);
strbuf_addf(&buf, "%s/%s.lock", dir, st->readers[1]->name);
write_file_buf(buf.buf, "", 0);
/*
* Compaction is expected to fail given that we were not able to
* compact all tables.
*/
err = reftable_stack_compact_all(st, NULL);
EXPECT(err == REFTABLE_LOCK_ERROR);
EXPECT(st->stats.failures == 1);
EXPECT(st->merged->stack_len == 3);
reftable_stack_destroy(st);
strbuf_release(&buf);
clear_dir(dir);
}
static void test_reftable_stack_compaction_concurrent(void)
{
struct reftable_write_options opts = { 0 };
struct reftable_stack *st1 = NULL, *st2 = NULL;
char *dir = get_tmp_dir(__LINE__);
int err;
err = reftable_new_stack(&st1, dir, &opts);
EXPECT_ERR(err);
write_n_ref_tables(st1, 3);
err = reftable_new_stack(&st2, dir, &opts);
EXPECT_ERR(err);
err = reftable_stack_compact_all(st1, NULL);
EXPECT_ERR(err);
reftable_stack_destroy(st1);
reftable_stack_destroy(st2);
EXPECT(count_dir_entries(dir) == 2);
clear_dir(dir);
}
static void unclean_stack_close(struct reftable_stack *st)
{
/* break abstraction boundary to simulate unclean shutdown. */
int i = 0;
for (; i < st->readers_len; i++) {
reftable_reader_free(st->readers[i]);
}
st->readers_len = 0;
FREE_AND_NULL(st->readers);
}
static void test_reftable_stack_compaction_concurrent_clean(void)
{
struct reftable_write_options opts = { 0 };
struct reftable_stack *st1 = NULL, *st2 = NULL, *st3 = NULL;
char *dir = get_tmp_dir(__LINE__);
int err;
err = reftable_new_stack(&st1, dir, &opts);
EXPECT_ERR(err);
write_n_ref_tables(st1, 3);
err = reftable_new_stack(&st2, dir, &opts);
EXPECT_ERR(err);
err = reftable_stack_compact_all(st1, NULL);
EXPECT_ERR(err);
unclean_stack_close(st1);
unclean_stack_close(st2);
err = reftable_new_stack(&st3, dir, &opts);
EXPECT_ERR(err);
err = reftable_stack_clean(st3);
EXPECT_ERR(err);
EXPECT(count_dir_entries(dir) == 2);
reftable_stack_destroy(st1);
reftable_stack_destroy(st2);
reftable_stack_destroy(st3);
clear_dir(dir);
}
int stack_test_main(int argc, const char *argv[])
{
RUN_TEST(test_empty_add);
RUN_TEST(test_read_file);
RUN_TEST(test_reflog_expire);
RUN_TEST(test_reftable_stack_add);
RUN_TEST(test_reftable_stack_add_one);
RUN_TEST(test_reftable_stack_auto_compaction);
RUN_TEST(test_reftable_stack_auto_compaction_with_locked_tables);
RUN_TEST(test_reftable_stack_add_performs_auto_compaction);
RUN_TEST(test_reftable_stack_compaction_concurrent);
RUN_TEST(test_reftable_stack_compaction_concurrent_clean);
RUN_TEST(test_reftable_stack_compaction_with_locked_tables);
RUN_TEST(test_reftable_stack_hash_id);
RUN_TEST(test_reftable_stack_lock_failure);
RUN_TEST(test_reftable_stack_log_normalize);
RUN_TEST(test_reftable_stack_tombstone);
RUN_TEST(test_reftable_stack_transaction_api);
RUN_TEST(test_reftable_stack_transaction_api_performs_auto_compaction);
RUN_TEST(test_reftable_stack_auto_compaction_fails_gracefully);
RUN_TEST(test_reftable_stack_update_index_check);
RUN_TEST(test_reftable_stack_uptodate);
RUN_TEST(test_suggest_compaction_segment);
RUN_TEST(test_suggest_compaction_segment_nothing);
return 0;
}
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