git/reftable/readwrite_test.c
Patrick Steinhardt 87ff723018 reftable/record: convert old and new object IDs to arrays
In 7af607c58d (reftable/record: store "val1" hashes as static arrays,
2024-01-03) and b31e3cc620 (reftable/record: store "val2" hashes as
static arrays, 2024-01-03) we have converted ref records to store their
object IDs in a static array. Convert log records to do the same so that
their old and new object IDs are arrays, too.

This change results in two allocations less per log record that we're
iterating over. Before:

    HEAP SUMMARY:
        in use at exit: 13,473 bytes in 122 blocks
      total heap usage: 8,068,495 allocs, 8,068,373 frees, 401,011,862 bytes allocated

After:

    HEAP SUMMARY:
        in use at exit: 13,473 bytes in 122 blocks
      total heap usage: 6,068,489 allocs, 6,068,367 frees, 361,011,822 bytes allocated

Signed-off-by: Patrick Steinhardt <ps@pks.im>
Signed-off-by: Junio C Hamano <gitster@pobox.com>
2024-03-05 09:10:06 -08:00

966 lines
23 KiB
C

/*
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 "system.h"
#include "basics.h"
#include "block.h"
#include "blocksource.h"
#include "reader.h"
#include "record.h"
#include "test_framework.h"
#include "reftable-tests.h"
#include "reftable-writer.h"
static const int update_index = 5;
static void test_buffer(void)
{
struct strbuf buf = STRBUF_INIT;
struct reftable_block_source source = { NULL };
struct reftable_block out = { NULL };
int n;
uint8_t in[] = "hello";
strbuf_add(&buf, in, sizeof(in));
block_source_from_strbuf(&source, &buf);
EXPECT(block_source_size(&source) == 6);
n = block_source_read_block(&source, &out, 0, sizeof(in));
EXPECT(n == sizeof(in));
EXPECT(!memcmp(in, out.data, n));
reftable_block_done(&out);
n = block_source_read_block(&source, &out, 1, 2);
EXPECT(n == 2);
EXPECT(!memcmp(out.data, "el", 2));
reftable_block_done(&out);
block_source_close(&source);
strbuf_release(&buf);
}
static void write_table(char ***names, struct strbuf *buf, int N,
int block_size, uint32_t hash_id)
{
struct reftable_write_options opts = {
.block_size = block_size,
.hash_id = hash_id,
};
struct reftable_writer *w =
reftable_new_writer(&strbuf_add_void, &noop_flush, buf, &opts);
struct reftable_ref_record ref = { NULL };
int i = 0, n;
struct reftable_log_record log = { NULL };
const struct reftable_stats *stats = NULL;
REFTABLE_CALLOC_ARRAY(*names, N + 1);
reftable_writer_set_limits(w, update_index, update_index);
for (i = 0; i < N; i++) {
char name[100];
int n;
snprintf(name, sizeof(name), "refs/heads/branch%02d", i);
ref.refname = name;
ref.update_index = update_index;
ref.value_type = REFTABLE_REF_VAL1;
set_test_hash(ref.value.val1, i);
(*names)[i] = xstrdup(name);
n = reftable_writer_add_ref(w, &ref);
EXPECT(n == 0);
}
for (i = 0; i < N; i++) {
char name[100];
int n;
snprintf(name, sizeof(name), "refs/heads/branch%02d", i);
log.refname = name;
log.update_index = update_index;
log.value_type = REFTABLE_LOG_UPDATE;
set_test_hash(log.value.update.new_hash, i);
log.value.update.message = "message";
n = reftable_writer_add_log(w, &log);
EXPECT(n == 0);
}
n = reftable_writer_close(w);
EXPECT(n == 0);
stats = reftable_writer_stats(w);
for (i = 0; i < stats->ref_stats.blocks; i++) {
int off = i * opts.block_size;
if (off == 0) {
off = header_size(
(hash_id == GIT_SHA256_FORMAT_ID) ? 2 : 1);
}
EXPECT(buf->buf[off] == 'r');
}
EXPECT(stats->log_stats.blocks > 0);
reftable_writer_free(w);
}
static void test_log_buffer_size(void)
{
struct strbuf buf = STRBUF_INIT;
struct reftable_write_options opts = {
.block_size = 4096,
};
int err;
int i;
struct reftable_log_record
log = { .refname = "refs/heads/master",
.update_index = 0xa,
.value_type = REFTABLE_LOG_UPDATE,
.value = { .update = {
.name = "Han-Wen Nienhuys",
.email = "hanwen@google.com",
.tz_offset = 100,
.time = 0x5e430672,
.message = "commit: 9\n",
} } };
struct reftable_writer *w =
reftable_new_writer(&strbuf_add_void, &noop_flush, &buf, &opts);
/* This tests buffer extension for log compression. Must use a random
hash, to ensure that the compressed part is larger than the original.
*/
for (i = 0; i < GIT_SHA1_RAWSZ; i++) {
log.value.update.old_hash[i] = (uint8_t)(git_rand() % 256);
log.value.update.new_hash[i] = (uint8_t)(git_rand() % 256);
}
reftable_writer_set_limits(w, update_index, update_index);
err = reftable_writer_add_log(w, &log);
EXPECT_ERR(err);
err = reftable_writer_close(w);
EXPECT_ERR(err);
reftable_writer_free(w);
strbuf_release(&buf);
}
static void test_log_overflow(void)
{
struct strbuf buf = STRBUF_INIT;
char msg[256] = { 0 };
struct reftable_write_options opts = {
.block_size = ARRAY_SIZE(msg),
};
int err;
struct reftable_log_record log = {
.refname = "refs/heads/master",
.update_index = 0xa,
.value_type = REFTABLE_LOG_UPDATE,
.value = {
.update = {
.old_hash = { 1 },
.new_hash = { 2 },
.name = "Han-Wen Nienhuys",
.email = "hanwen@google.com",
.tz_offset = 100,
.time = 0x5e430672,
.message = msg,
},
},
};
struct reftable_writer *w =
reftable_new_writer(&strbuf_add_void, &noop_flush, &buf, &opts);
memset(msg, 'x', sizeof(msg) - 1);
reftable_writer_set_limits(w, update_index, update_index);
err = reftable_writer_add_log(w, &log);
EXPECT(err == REFTABLE_ENTRY_TOO_BIG_ERROR);
reftable_writer_free(w);
strbuf_release(&buf);
}
static void test_log_write_read(void)
{
int N = 2;
char **names = reftable_calloc(N + 1, sizeof(*names));
int err;
struct reftable_write_options opts = {
.block_size = 256,
};
struct reftable_ref_record ref = { NULL };
int i = 0;
struct reftable_log_record log = { NULL };
int n;
struct reftable_iterator it = { NULL };
struct reftable_reader rd = { NULL };
struct reftable_block_source source = { NULL };
struct strbuf buf = STRBUF_INIT;
struct reftable_writer *w =
reftable_new_writer(&strbuf_add_void, &noop_flush, &buf, &opts);
const struct reftable_stats *stats = NULL;
reftable_writer_set_limits(w, 0, N);
for (i = 0; i < N; i++) {
char name[256];
struct reftable_ref_record ref = { NULL };
snprintf(name, sizeof(name), "b%02d%0*d", i, 130, 7);
names[i] = xstrdup(name);
ref.refname = name;
ref.update_index = i;
err = reftable_writer_add_ref(w, &ref);
EXPECT_ERR(err);
}
for (i = 0; i < N; i++) {
struct reftable_log_record log = { NULL };
log.refname = names[i];
log.update_index = i;
log.value_type = REFTABLE_LOG_UPDATE;
set_test_hash(log.value.update.old_hash, i);
set_test_hash(log.value.update.new_hash, i + 1);
err = reftable_writer_add_log(w, &log);
EXPECT_ERR(err);
}
n = reftable_writer_close(w);
EXPECT(n == 0);
stats = reftable_writer_stats(w);
EXPECT(stats->log_stats.blocks > 0);
reftable_writer_free(w);
w = NULL;
block_source_from_strbuf(&source, &buf);
err = init_reader(&rd, &source, "file.log");
EXPECT_ERR(err);
err = reftable_reader_seek_ref(&rd, &it, names[N - 1]);
EXPECT_ERR(err);
err = reftable_iterator_next_ref(&it, &ref);
EXPECT_ERR(err);
/* end of iteration. */
err = reftable_iterator_next_ref(&it, &ref);
EXPECT(0 < err);
reftable_iterator_destroy(&it);
reftable_ref_record_release(&ref);
err = reftable_reader_seek_log(&rd, &it, "");
EXPECT_ERR(err);
i = 0;
while (1) {
int err = reftable_iterator_next_log(&it, &log);
if (err > 0) {
break;
}
EXPECT_ERR(err);
EXPECT_STREQ(names[i], log.refname);
EXPECT(i == log.update_index);
i++;
reftable_log_record_release(&log);
}
EXPECT(i == N);
reftable_iterator_destroy(&it);
/* cleanup. */
strbuf_release(&buf);
free_names(names);
reader_close(&rd);
}
static void test_log_zlib_corruption(void)
{
struct reftable_write_options opts = {
.block_size = 256,
};
struct reftable_iterator it = { 0 };
struct reftable_reader rd = { 0 };
struct reftable_block_source source = { 0 };
struct strbuf buf = STRBUF_INIT;
struct reftable_writer *w =
reftable_new_writer(&strbuf_add_void, &noop_flush, &buf, &opts);
const struct reftable_stats *stats = NULL;
char message[100] = { 0 };
int err, i, n;
struct reftable_log_record log = {
.refname = "refname",
.value_type = REFTABLE_LOG_UPDATE,
.value = {
.update = {
.new_hash = { 1 },
.old_hash = { 2 },
.name = "My Name",
.email = "myname@invalid",
.message = message,
},
},
};
for (i = 0; i < sizeof(message) - 1; i++)
message[i] = (uint8_t)(git_rand() % 64 + ' ');
reftable_writer_set_limits(w, 1, 1);
err = reftable_writer_add_log(w, &log);
EXPECT_ERR(err);
n = reftable_writer_close(w);
EXPECT(n == 0);
stats = reftable_writer_stats(w);
EXPECT(stats->log_stats.blocks > 0);
reftable_writer_free(w);
w = NULL;
/* corrupt the data. */
buf.buf[50] ^= 0x99;
block_source_from_strbuf(&source, &buf);
err = init_reader(&rd, &source, "file.log");
EXPECT_ERR(err);
err = reftable_reader_seek_log(&rd, &it, "refname");
EXPECT(err == REFTABLE_ZLIB_ERROR);
reftable_iterator_destroy(&it);
/* cleanup. */
strbuf_release(&buf);
reader_close(&rd);
}
static void test_table_read_write_sequential(void)
{
char **names;
struct strbuf buf = STRBUF_INIT;
int N = 50;
struct reftable_iterator it = { NULL };
struct reftable_block_source source = { NULL };
struct reftable_reader rd = { NULL };
int err = 0;
int j = 0;
write_table(&names, &buf, N, 256, GIT_SHA1_FORMAT_ID);
block_source_from_strbuf(&source, &buf);
err = init_reader(&rd, &source, "file.ref");
EXPECT_ERR(err);
err = reftable_reader_seek_ref(&rd, &it, "");
EXPECT_ERR(err);
while (1) {
struct reftable_ref_record ref = { NULL };
int r = reftable_iterator_next_ref(&it, &ref);
EXPECT(r >= 0);
if (r > 0) {
break;
}
EXPECT(0 == strcmp(names[j], ref.refname));
EXPECT(update_index == ref.update_index);
j++;
reftable_ref_record_release(&ref);
}
EXPECT(j == N);
reftable_iterator_destroy(&it);
strbuf_release(&buf);
free_names(names);
reader_close(&rd);
}
static void test_table_write_small_table(void)
{
char **names;
struct strbuf buf = STRBUF_INIT;
int N = 1;
write_table(&names, &buf, N, 4096, GIT_SHA1_FORMAT_ID);
EXPECT(buf.len < 200);
strbuf_release(&buf);
free_names(names);
}
static void test_table_read_api(void)
{
char **names;
struct strbuf buf = STRBUF_INIT;
int N = 50;
struct reftable_reader rd = { NULL };
struct reftable_block_source source = { NULL };
int err;
int i;
struct reftable_log_record log = { NULL };
struct reftable_iterator it = { NULL };
write_table(&names, &buf, N, 256, GIT_SHA1_FORMAT_ID);
block_source_from_strbuf(&source, &buf);
err = init_reader(&rd, &source, "file.ref");
EXPECT_ERR(err);
err = reftable_reader_seek_ref(&rd, &it, names[0]);
EXPECT_ERR(err);
err = reftable_iterator_next_log(&it, &log);
EXPECT(err == REFTABLE_API_ERROR);
strbuf_release(&buf);
for (i = 0; i < N; i++) {
reftable_free(names[i]);
}
reftable_iterator_destroy(&it);
reftable_free(names);
reader_close(&rd);
strbuf_release(&buf);
}
static void test_table_read_write_seek(int index, int hash_id)
{
char **names;
struct strbuf buf = STRBUF_INIT;
int N = 50;
struct reftable_reader rd = { NULL };
struct reftable_block_source source = { NULL };
int err;
int i = 0;
struct reftable_iterator it = { NULL };
struct strbuf pastLast = STRBUF_INIT;
struct reftable_ref_record ref = { NULL };
write_table(&names, &buf, N, 256, hash_id);
block_source_from_strbuf(&source, &buf);
err = init_reader(&rd, &source, "file.ref");
EXPECT_ERR(err);
EXPECT(hash_id == reftable_reader_hash_id(&rd));
if (!index) {
rd.ref_offsets.index_offset = 0;
} else {
EXPECT(rd.ref_offsets.index_offset > 0);
}
for (i = 1; i < N; i++) {
int err = reftable_reader_seek_ref(&rd, &it, names[i]);
EXPECT_ERR(err);
err = reftable_iterator_next_ref(&it, &ref);
EXPECT_ERR(err);
EXPECT(0 == strcmp(names[i], ref.refname));
EXPECT(REFTABLE_REF_VAL1 == ref.value_type);
EXPECT(i == ref.value.val1[0]);
reftable_ref_record_release(&ref);
reftable_iterator_destroy(&it);
}
strbuf_addstr(&pastLast, names[N - 1]);
strbuf_addstr(&pastLast, "/");
err = reftable_reader_seek_ref(&rd, &it, pastLast.buf);
if (err == 0) {
struct reftable_ref_record ref = { NULL };
int err = reftable_iterator_next_ref(&it, &ref);
EXPECT(err > 0);
} else {
EXPECT(err > 0);
}
strbuf_release(&pastLast);
reftable_iterator_destroy(&it);
strbuf_release(&buf);
for (i = 0; i < N; i++) {
reftable_free(names[i]);
}
reftable_free(names);
reader_close(&rd);
}
static void test_table_read_write_seek_linear(void)
{
test_table_read_write_seek(0, GIT_SHA1_FORMAT_ID);
}
static void test_table_read_write_seek_linear_sha256(void)
{
test_table_read_write_seek(0, GIT_SHA256_FORMAT_ID);
}
static void test_table_read_write_seek_index(void)
{
test_table_read_write_seek(1, GIT_SHA1_FORMAT_ID);
}
static void test_table_refs_for(int indexed)
{
int N = 50;
char **want_names = reftable_calloc(N + 1, sizeof(*want_names));
int want_names_len = 0;
uint8_t want_hash[GIT_SHA1_RAWSZ];
struct reftable_write_options opts = {
.block_size = 256,
};
struct reftable_ref_record ref = { NULL };
int i = 0;
int n;
int err;
struct reftable_reader rd;
struct reftable_block_source source = { NULL };
struct strbuf buf = STRBUF_INIT;
struct reftable_writer *w =
reftable_new_writer(&strbuf_add_void, &noop_flush, &buf, &opts);
struct reftable_iterator it = { NULL };
int j;
set_test_hash(want_hash, 4);
for (i = 0; i < N; i++) {
uint8_t hash[GIT_SHA1_RAWSZ];
char fill[51] = { 0 };
char name[100];
struct reftable_ref_record ref = { NULL };
memset(hash, i, sizeof(hash));
memset(fill, 'x', 50);
/* Put the variable part in the start */
snprintf(name, sizeof(name), "br%02d%s", i, fill);
name[40] = 0;
ref.refname = name;
ref.value_type = REFTABLE_REF_VAL2;
set_test_hash(ref.value.val2.value, i / 4);
set_test_hash(ref.value.val2.target_value, 3 + i / 4);
/* 80 bytes / entry, so 3 entries per block. Yields 17
*/
/* blocks. */
n = reftable_writer_add_ref(w, &ref);
EXPECT(n == 0);
if (!memcmp(ref.value.val2.value, want_hash, GIT_SHA1_RAWSZ) ||
!memcmp(ref.value.val2.target_value, want_hash, GIT_SHA1_RAWSZ)) {
want_names[want_names_len++] = xstrdup(name);
}
}
n = reftable_writer_close(w);
EXPECT(n == 0);
reftable_writer_free(w);
w = NULL;
block_source_from_strbuf(&source, &buf);
err = init_reader(&rd, &source, "file.ref");
EXPECT_ERR(err);
if (!indexed) {
rd.obj_offsets.is_present = 0;
}
err = reftable_reader_seek_ref(&rd, &it, "");
EXPECT_ERR(err);
reftable_iterator_destroy(&it);
err = reftable_reader_refs_for(&rd, &it, want_hash);
EXPECT_ERR(err);
j = 0;
while (1) {
int err = reftable_iterator_next_ref(&it, &ref);
EXPECT(err >= 0);
if (err > 0) {
break;
}
EXPECT(j < want_names_len);
EXPECT(0 == strcmp(ref.refname, want_names[j]));
j++;
reftable_ref_record_release(&ref);
}
EXPECT(j == want_names_len);
strbuf_release(&buf);
free_names(want_names);
reftable_iterator_destroy(&it);
reader_close(&rd);
}
static void test_table_refs_for_no_index(void)
{
test_table_refs_for(0);
}
static void test_table_refs_for_obj_index(void)
{
test_table_refs_for(1);
}
static void test_write_empty_table(void)
{
struct reftable_write_options opts = { 0 };
struct strbuf buf = STRBUF_INIT;
struct reftable_writer *w =
reftable_new_writer(&strbuf_add_void, &noop_flush, &buf, &opts);
struct reftable_block_source source = { NULL };
struct reftable_reader *rd = NULL;
struct reftable_ref_record rec = { NULL };
struct reftable_iterator it = { NULL };
int err;
reftable_writer_set_limits(w, 1, 1);
err = reftable_writer_close(w);
EXPECT(err == REFTABLE_EMPTY_TABLE_ERROR);
reftable_writer_free(w);
EXPECT(buf.len == header_size(1) + footer_size(1));
block_source_from_strbuf(&source, &buf);
err = reftable_new_reader(&rd, &source, "filename");
EXPECT_ERR(err);
err = reftable_reader_seek_ref(rd, &it, "");
EXPECT_ERR(err);
err = reftable_iterator_next_ref(&it, &rec);
EXPECT(err > 0);
reftable_iterator_destroy(&it);
reftable_reader_free(rd);
strbuf_release(&buf);
}
static void test_write_object_id_min_length(void)
{
struct reftable_write_options opts = {
.block_size = 75,
};
struct strbuf buf = STRBUF_INIT;
struct reftable_writer *w =
reftable_new_writer(&strbuf_add_void, &noop_flush, &buf, &opts);
struct reftable_ref_record ref = {
.update_index = 1,
.value_type = REFTABLE_REF_VAL1,
.value.val1 = {42},
};
int err;
int i;
reftable_writer_set_limits(w, 1, 1);
/* Write the same hash in many refs. If there is only 1 hash, the
* disambiguating prefix is length 0 */
for (i = 0; i < 256; i++) {
char name[256];
snprintf(name, sizeof(name), "ref%05d", i);
ref.refname = name;
err = reftable_writer_add_ref(w, &ref);
EXPECT_ERR(err);
}
err = reftable_writer_close(w);
EXPECT_ERR(err);
EXPECT(reftable_writer_stats(w)->object_id_len == 2);
reftable_writer_free(w);
strbuf_release(&buf);
}
static void test_write_object_id_length(void)
{
struct reftable_write_options opts = {
.block_size = 75,
};
struct strbuf buf = STRBUF_INIT;
struct reftable_writer *w =
reftable_new_writer(&strbuf_add_void, &noop_flush, &buf, &opts);
struct reftable_ref_record ref = {
.update_index = 1,
.value_type = REFTABLE_REF_VAL1,
.value.val1 = {42},
};
int err;
int i;
reftable_writer_set_limits(w, 1, 1);
/* Write the same hash in many refs. If there is only 1 hash, the
* disambiguating prefix is length 0 */
for (i = 0; i < 256; i++) {
char name[256];
snprintf(name, sizeof(name), "ref%05d", i);
ref.refname = name;
ref.value.val1[15] = i;
err = reftable_writer_add_ref(w, &ref);
EXPECT_ERR(err);
}
err = reftable_writer_close(w);
EXPECT_ERR(err);
EXPECT(reftable_writer_stats(w)->object_id_len == 16);
reftable_writer_free(w);
strbuf_release(&buf);
}
static void test_write_empty_key(void)
{
struct reftable_write_options opts = { 0 };
struct strbuf buf = STRBUF_INIT;
struct reftable_writer *w =
reftable_new_writer(&strbuf_add_void, &noop_flush, &buf, &opts);
struct reftable_ref_record ref = {
.refname = "",
.update_index = 1,
.value_type = REFTABLE_REF_DELETION,
};
int err;
reftable_writer_set_limits(w, 1, 1);
err = reftable_writer_add_ref(w, &ref);
EXPECT(err == REFTABLE_API_ERROR);
err = reftable_writer_close(w);
EXPECT(err == REFTABLE_EMPTY_TABLE_ERROR);
reftable_writer_free(w);
strbuf_release(&buf);
}
static void test_write_key_order(void)
{
struct reftable_write_options opts = { 0 };
struct strbuf buf = STRBUF_INIT;
struct reftable_writer *w =
reftable_new_writer(&strbuf_add_void, &noop_flush, &buf, &opts);
struct reftable_ref_record refs[2] = {
{
.refname = "b",
.update_index = 1,
.value_type = REFTABLE_REF_SYMREF,
.value = {
.symref = "target",
},
}, {
.refname = "a",
.update_index = 1,
.value_type = REFTABLE_REF_SYMREF,
.value = {
.symref = "target",
},
}
};
int err;
reftable_writer_set_limits(w, 1, 1);
err = reftable_writer_add_ref(w, &refs[0]);
EXPECT_ERR(err);
err = reftable_writer_add_ref(w, &refs[1]);
EXPECT(err == REFTABLE_API_ERROR);
reftable_writer_close(w);
reftable_writer_free(w);
strbuf_release(&buf);
}
static void test_write_multiple_indices(void)
{
struct reftable_write_options opts = {
.block_size = 100,
};
struct strbuf writer_buf = STRBUF_INIT, buf = STRBUF_INIT;
struct reftable_block_source source = { 0 };
struct reftable_iterator it = { 0 };
const struct reftable_stats *stats;
struct reftable_writer *writer;
struct reftable_reader *reader;
int err, i;
writer = reftable_new_writer(&strbuf_add_void, &noop_flush, &writer_buf, &opts);
reftable_writer_set_limits(writer, 1, 1);
for (i = 0; i < 100; i++) {
struct reftable_ref_record ref = {
.update_index = 1,
.value_type = REFTABLE_REF_VAL1,
.value.val1 = {i},
};
strbuf_reset(&buf);
strbuf_addf(&buf, "refs/heads/%04d", i);
ref.refname = buf.buf,
err = reftable_writer_add_ref(writer, &ref);
EXPECT_ERR(err);
}
for (i = 0; i < 100; i++) {
struct reftable_log_record log = {
.update_index = 1,
.value_type = REFTABLE_LOG_UPDATE,
.value.update = {
.old_hash = { i },
.new_hash = { i },
},
};
strbuf_reset(&buf);
strbuf_addf(&buf, "refs/heads/%04d", i);
log.refname = buf.buf,
err = reftable_writer_add_log(writer, &log);
EXPECT_ERR(err);
}
reftable_writer_close(writer);
/*
* The written data should be sufficiently large to result in indices
* for each of the block types.
*/
stats = reftable_writer_stats(writer);
EXPECT(stats->ref_stats.index_offset > 0);
EXPECT(stats->obj_stats.index_offset > 0);
EXPECT(stats->log_stats.index_offset > 0);
block_source_from_strbuf(&source, &writer_buf);
err = reftable_new_reader(&reader, &source, "filename");
EXPECT_ERR(err);
/*
* Seeking the log uses the log index now. In case there is any
* confusion regarding indices we would notice here.
*/
err = reftable_reader_seek_log(reader, &it, "");
EXPECT_ERR(err);
reftable_iterator_destroy(&it);
reftable_writer_free(writer);
reftable_reader_free(reader);
strbuf_release(&writer_buf);
strbuf_release(&buf);
}
static void test_write_multi_level_index(void)
{
struct reftable_write_options opts = {
.block_size = 100,
};
struct strbuf writer_buf = STRBUF_INIT, buf = STRBUF_INIT;
struct reftable_block_source source = { 0 };
struct reftable_iterator it = { 0 };
const struct reftable_stats *stats;
struct reftable_writer *writer;
struct reftable_reader *reader;
int err;
writer = reftable_new_writer(&strbuf_add_void, &noop_flush, &writer_buf, &opts);
reftable_writer_set_limits(writer, 1, 1);
for (size_t i = 0; i < 200; i++) {
struct reftable_ref_record ref = {
.update_index = 1,
.value_type = REFTABLE_REF_VAL1,
.value.val1 = {i},
};
strbuf_reset(&buf);
strbuf_addf(&buf, "refs/heads/%03" PRIuMAX, (uintmax_t)i);
ref.refname = buf.buf,
err = reftable_writer_add_ref(writer, &ref);
EXPECT_ERR(err);
}
reftable_writer_close(writer);
/*
* The written refs should be sufficiently large to result in a
* multi-level index.
*/
stats = reftable_writer_stats(writer);
EXPECT(stats->ref_stats.max_index_level == 2);
block_source_from_strbuf(&source, &writer_buf);
err = reftable_new_reader(&reader, &source, "filename");
EXPECT_ERR(err);
/*
* Seeking the last ref should work as expected.
*/
err = reftable_reader_seek_ref(reader, &it, "refs/heads/199");
EXPECT_ERR(err);
reftable_iterator_destroy(&it);
reftable_writer_free(writer);
reftable_reader_free(reader);
strbuf_release(&writer_buf);
strbuf_release(&buf);
}
static void test_corrupt_table_empty(void)
{
struct strbuf buf = STRBUF_INIT;
struct reftable_block_source source = { NULL };
struct reftable_reader rd = { NULL };
int err;
block_source_from_strbuf(&source, &buf);
err = init_reader(&rd, &source, "file.log");
EXPECT(err == REFTABLE_FORMAT_ERROR);
}
static void test_corrupt_table(void)
{
uint8_t zeros[1024] = { 0 };
struct strbuf buf = STRBUF_INIT;
struct reftable_block_source source = { NULL };
struct reftable_reader rd = { NULL };
int err;
strbuf_add(&buf, zeros, sizeof(zeros));
block_source_from_strbuf(&source, &buf);
err = init_reader(&rd, &source, "file.log");
EXPECT(err == REFTABLE_FORMAT_ERROR);
strbuf_release(&buf);
}
int readwrite_test_main(int argc, const char *argv[])
{
RUN_TEST(test_log_zlib_corruption);
RUN_TEST(test_corrupt_table);
RUN_TEST(test_corrupt_table_empty);
RUN_TEST(test_log_write_read);
RUN_TEST(test_write_key_order);
RUN_TEST(test_table_read_write_seek_linear_sha256);
RUN_TEST(test_log_buffer_size);
RUN_TEST(test_table_write_small_table);
RUN_TEST(test_buffer);
RUN_TEST(test_table_read_api);
RUN_TEST(test_table_read_write_sequential);
RUN_TEST(test_table_read_write_seek_linear);
RUN_TEST(test_table_read_write_seek_index);
RUN_TEST(test_table_refs_for_no_index);
RUN_TEST(test_table_refs_for_obj_index);
RUN_TEST(test_write_empty_key);
RUN_TEST(test_write_empty_table);
RUN_TEST(test_log_overflow);
RUN_TEST(test_write_object_id_length);
RUN_TEST(test_write_object_id_min_length);
RUN_TEST(test_write_multiple_indices);
RUN_TEST(test_write_multi_level_index);
return 0;
}