/* 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 */ #define DISABLE_SIGN_COMPARE_WARNINGS #include "test-lib.h" #include "lib-reftable.h" #include "reftable/basics.h" #include "reftable/blocksource.h" #include "reftable/reader.h" #include "reftable/reftable-error.h" #include "reftable/reftable-writer.h" #include "strbuf.h" static const int update_index = 5; static void t_buffer(void) { struct reftable_buf buf = REFTABLE_BUF_INIT; struct reftable_block_source source = { 0 }; struct reftable_block out = { 0 }; int n; uint8_t in[] = "hello"; check(!reftable_buf_add(&buf, in, sizeof(in))); block_source_from_buf(&source, &buf); check_int(block_source_size(&source), ==, 6); n = block_source_read_block(&source, &out, 0, sizeof(in)); check_int(n, ==, sizeof(in)); check(!memcmp(in, out.data, n)); reftable_block_done(&out); n = block_source_read_block(&source, &out, 1, 2); check_int(n, ==, 2); check(!memcmp(out.data, "el", 2)); reftable_block_done(&out); block_source_close(&source); reftable_buf_release(&buf); } static void write_table(char ***names, struct reftable_buf *buf, int N, int block_size, enum reftable_hash hash_id) { struct reftable_write_options opts = { .block_size = block_size, .hash_id = hash_id, }; struct reftable_ref_record *refs; struct reftable_log_record *logs; int i; REFTABLE_CALLOC_ARRAY(*names, N + 1); check(*names != NULL); REFTABLE_CALLOC_ARRAY(refs, N); check(refs != NULL); REFTABLE_CALLOC_ARRAY(logs, N); check(logs != NULL); for (i = 0; i < N; i++) { refs[i].refname = (*names)[i] = xstrfmt("refs/heads/branch%02d", i); refs[i].update_index = update_index; refs[i].value_type = REFTABLE_REF_VAL1; t_reftable_set_hash(refs[i].value.val1, i, REFTABLE_HASH_SHA1); } for (i = 0; i < N; i++) { logs[i].refname = (*names)[i]; logs[i].update_index = update_index; logs[i].value_type = REFTABLE_LOG_UPDATE; t_reftable_set_hash(logs[i].value.update.new_hash, i, REFTABLE_HASH_SHA1); logs[i].value.update.message = (char *) "message"; } t_reftable_write_to_buf(buf, refs, N, logs, N, &opts); reftable_free(refs); reftable_free(logs); } static void t_log_buffer_size(void) { struct reftable_buf buf = REFTABLE_BUF_INIT; struct reftable_write_options opts = { .block_size = 4096, }; int err; int i; struct reftable_log_record log = { .refname = (char *) "refs/heads/master", .update_index = update_index, .value_type = REFTABLE_LOG_UPDATE, .value = { .update = { .name = (char *) "Han-Wen Nienhuys", .email = (char *) "hanwen@google.com", .tz_offset = 100, .time = 0x5e430672, .message = (char *) "commit: 9\n", } } }; struct reftable_writer *w = t_reftable_strbuf_writer(&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 < REFTABLE_HASH_SIZE_SHA1; i++) { log.value.update.old_hash[i] = (uint8_t)(git_rand(0) % 256); log.value.update.new_hash[i] = (uint8_t)(git_rand(0) % 256); } reftable_writer_set_limits(w, update_index, update_index); err = reftable_writer_add_log(w, &log); check(!err); err = reftable_writer_close(w); check(!err); reftable_writer_free(w); reftable_buf_release(&buf); } static void t_log_overflow(void) { struct reftable_buf buf = REFTABLE_BUF_INIT; char msg[256] = { 0 }; struct reftable_write_options opts = { .block_size = ARRAY_SIZE(msg), }; int err; struct reftable_log_record log = { .refname = (char *) "refs/heads/master", .update_index = update_index, .value_type = REFTABLE_LOG_UPDATE, .value = { .update = { .old_hash = { 1 }, .new_hash = { 2 }, .name = (char *) "Han-Wen Nienhuys", .email = (char *) "hanwen@google.com", .tz_offset = 100, .time = 0x5e430672, .message = msg, }, }, }; struct reftable_writer *w = t_reftable_strbuf_writer(&buf, &opts); memset(msg, 'x', sizeof(msg) - 1); reftable_writer_set_limits(w, update_index, update_index); err = reftable_writer_add_log(w, &log); check_int(err, ==, REFTABLE_ENTRY_TOO_BIG_ERROR); reftable_writer_free(w); reftable_buf_release(&buf); } static void t_log_write_limits(void) { struct reftable_write_options opts = { 0 }; struct reftable_buf buf = REFTABLE_BUF_INIT; struct reftable_writer *w = t_reftable_strbuf_writer(&buf, &opts); struct reftable_log_record log = { .refname = (char *)"refs/head/master", .update_index = 0, .value_type = REFTABLE_LOG_UPDATE, .value = { .update = { .old_hash = { 1 }, .new_hash = { 2 }, .name = (char *)"Han-Wen Nienhuys", .email = (char *)"hanwen@google.com", .tz_offset = 100, .time = 0x5e430672, }, }, }; int err; reftable_writer_set_limits(w, 1, 1); /* write with update_index (0) below set limits (1, 1) */ err = reftable_writer_add_log(w, &log); check_int(err, ==, 0); /* write with update_index (1) in the set limits (1, 1) */ log.update_index = 1; err = reftable_writer_add_log(w, &log); check_int(err, ==, 0); /* write with update_index (3) above set limits (1, 1) */ log.update_index = 3; err = reftable_writer_add_log(w, &log); check_int(err, ==, REFTABLE_API_ERROR); reftable_writer_free(w); reftable_buf_release(&buf); } static void t_log_write_read(void) { struct reftable_write_options opts = { .block_size = 256, }; struct reftable_ref_record ref = { 0 }; struct reftable_log_record log = { 0 }; struct reftable_iterator it = { 0 }; struct reftable_reader *reader; struct reftable_block_source source = { 0 }; struct reftable_buf buf = REFTABLE_BUF_INIT; struct reftable_writer *w = t_reftable_strbuf_writer(&buf, &opts); const struct reftable_stats *stats = NULL; int N = 2, err, i, n; char **names; names = reftable_calloc(N + 1, sizeof(*names)); check(names != NULL); reftable_writer_set_limits(w, 0, N); for (i = 0; i < N; i++) { char name[256]; struct reftable_ref_record ref = { 0 }; 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); check(!err); } for (i = 0; i < N; i++) { struct reftable_log_record log = { 0 }; log.refname = names[i]; log.update_index = i; log.value_type = REFTABLE_LOG_UPDATE; t_reftable_set_hash(log.value.update.old_hash, i, REFTABLE_HASH_SHA1); t_reftable_set_hash(log.value.update.new_hash, i + 1, REFTABLE_HASH_SHA1); err = reftable_writer_add_log(w, &log); check(!err); } n = reftable_writer_close(w); check_int(n, ==, 0); stats = reftable_writer_stats(w); check_int(stats->log_stats.blocks, >, 0); reftable_writer_free(w); w = NULL; block_source_from_buf(&source, &buf); err = reftable_reader_new(&reader, &source, "file.log"); check(!err); err = reftable_reader_init_ref_iterator(reader, &it); check(!err); err = reftable_iterator_seek_ref(&it, names[N - 1]); check(!err); err = reftable_iterator_next_ref(&it, &ref); check(!err); /* end of iteration. */ err = reftable_iterator_next_ref(&it, &ref); check_int(err, >, 0); reftable_iterator_destroy(&it); reftable_ref_record_release(&ref); err = reftable_reader_init_log_iterator(reader, &it); check(!err); err = reftable_iterator_seek_log(&it, ""); check(!err); for (i = 0; ; i++) { int err = reftable_iterator_next_log(&it, &log); if (err > 0) break; check(!err); check_str(names[i], log.refname); check_int(i, ==, log.update_index); reftable_log_record_release(&log); } check_int(i, ==, N); reftable_iterator_destroy(&it); /* cleanup. */ reftable_buf_release(&buf); free_names(names); reftable_reader_decref(reader); } static void t_log_zlib_corruption(void) { struct reftable_write_options opts = { .block_size = 256, }; struct reftable_iterator it = { 0 }; struct reftable_reader *reader; struct reftable_block_source source = { 0 }; struct reftable_buf buf = REFTABLE_BUF_INIT; struct reftable_writer *w = t_reftable_strbuf_writer(&buf, &opts); const struct reftable_stats *stats = NULL; char message[100] = { 0 }; int err, i, n; struct reftable_log_record log = { .refname = (char *) "refname", .value_type = REFTABLE_LOG_UPDATE, .value = { .update = { .new_hash = { 1 }, .old_hash = { 2 }, .name = (char *) "My Name", .email = (char *) "myname@invalid", .message = message, }, }, }; for (i = 0; i < sizeof(message) - 1; i++) message[i] = (uint8_t)(git_rand(0) % 64 + ' '); reftable_writer_set_limits(w, 1, 1); err = reftable_writer_add_log(w, &log); check(!err); n = reftable_writer_close(w); check_int(n, ==, 0); stats = reftable_writer_stats(w); check_int(stats->log_stats.blocks, >, 0); reftable_writer_free(w); w = NULL; /* corrupt the data. */ buf.buf[50] ^= 0x99; block_source_from_buf(&source, &buf); err = reftable_reader_new(&reader, &source, "file.log"); check(!err); err = reftable_reader_init_log_iterator(reader, &it); check(!err); err = reftable_iterator_seek_log(&it, "refname"); check_int(err, ==, REFTABLE_ZLIB_ERROR); reftable_iterator_destroy(&it); /* cleanup. */ reftable_reader_decref(reader); reftable_buf_release(&buf); } static void t_table_read_write_sequential(void) { char **names; struct reftable_buf buf = REFTABLE_BUF_INIT; int N = 50; struct reftable_iterator it = { 0 }; struct reftable_block_source source = { 0 }; struct reftable_reader *reader; int err = 0; int j = 0; write_table(&names, &buf, N, 256, REFTABLE_HASH_SHA1); block_source_from_buf(&source, &buf); err = reftable_reader_new(&reader, &source, "file.ref"); check(!err); err = reftable_reader_init_ref_iterator(reader, &it); check(!err); err = reftable_iterator_seek_ref(&it, ""); check(!err); for (j = 0; ; j++) { struct reftable_ref_record ref = { 0 }; int r = reftable_iterator_next_ref(&it, &ref); check_int(r, >=, 0); if (r > 0) break; check_str(names[j], ref.refname); check_int(update_index, ==, ref.update_index); reftable_ref_record_release(&ref); } check_int(j, ==, N); reftable_iterator_destroy(&it); reftable_reader_decref(reader); reftable_buf_release(&buf); free_names(names); } static void t_table_write_small_table(void) { char **names; struct reftable_buf buf = REFTABLE_BUF_INIT; int N = 1; write_table(&names, &buf, N, 4096, REFTABLE_HASH_SHA1); check_int(buf.len, <, 200); reftable_buf_release(&buf); free_names(names); } static void t_table_read_api(void) { char **names; struct reftable_buf buf = REFTABLE_BUF_INIT; int N = 50; struct reftable_reader *reader; struct reftable_block_source source = { 0 }; int err; struct reftable_log_record log = { 0 }; struct reftable_iterator it = { 0 }; write_table(&names, &buf, N, 256, REFTABLE_HASH_SHA1); block_source_from_buf(&source, &buf); err = reftable_reader_new(&reader, &source, "file.ref"); check(!err); err = reftable_reader_init_ref_iterator(reader, &it); check(!err); err = reftable_iterator_seek_ref(&it, names[0]); check(!err); err = reftable_iterator_next_log(&it, &log); check_int(err, ==, REFTABLE_API_ERROR); reftable_buf_release(&buf); free_names(names); reftable_iterator_destroy(&it); reftable_reader_decref(reader); reftable_buf_release(&buf); } static void t_table_read_write_seek(int index, enum reftable_hash hash_id) { char **names; struct reftable_buf buf = REFTABLE_BUF_INIT; int N = 50; struct reftable_reader *reader; struct reftable_block_source source = { 0 }; int err; int i = 0; struct reftable_iterator it = { 0 }; struct reftable_buf pastLast = REFTABLE_BUF_INIT; struct reftable_ref_record ref = { 0 }; write_table(&names, &buf, N, 256, hash_id); block_source_from_buf(&source, &buf); err = reftable_reader_new(&reader, &source, "file.ref"); check(!err); check_int(hash_id, ==, reftable_reader_hash_id(reader)); if (!index) { reader->ref_offsets.index_offset = 0; } else { check_int(reader->ref_offsets.index_offset, >, 0); } for (i = 1; i < N; i++) { err = reftable_reader_init_ref_iterator(reader, &it); check(!err); err = reftable_iterator_seek_ref(&it, names[i]); check(!err); err = reftable_iterator_next_ref(&it, &ref); check(!err); check_str(names[i], ref.refname); check_int(REFTABLE_REF_VAL1, ==, ref.value_type); check_int(i, ==, ref.value.val1[0]); reftable_ref_record_release(&ref); reftable_iterator_destroy(&it); } check(!reftable_buf_addstr(&pastLast, names[N - 1])); check(!reftable_buf_addstr(&pastLast, "/")); err = reftable_reader_init_ref_iterator(reader, &it); check(!err); err = reftable_iterator_seek_ref(&it, pastLast.buf); if (err == 0) { struct reftable_ref_record ref = { 0 }; int err = reftable_iterator_next_ref(&it, &ref); check_int(err, >, 0); } else { check_int(err, >, 0); } reftable_buf_release(&pastLast); reftable_iterator_destroy(&it); reftable_buf_release(&buf); free_names(names); reftable_reader_decref(reader); } static void t_table_read_write_seek_linear(void) { t_table_read_write_seek(0, REFTABLE_HASH_SHA1); } static void t_table_read_write_seek_linear_sha256(void) { t_table_read_write_seek(0, REFTABLE_HASH_SHA256); } static void t_table_read_write_seek_index(void) { t_table_read_write_seek(1, REFTABLE_HASH_SHA1); } static void t_table_refs_for(int indexed) { char **want_names; int want_names_len = 0; uint8_t want_hash[REFTABLE_HASH_SIZE_SHA1]; struct reftable_write_options opts = { .block_size = 256, }; struct reftable_ref_record ref = { 0 }; struct reftable_reader *reader; struct reftable_block_source source = { 0 }; struct reftable_buf buf = REFTABLE_BUF_INIT; struct reftable_writer *w = t_reftable_strbuf_writer(&buf, &opts); struct reftable_iterator it = { 0 }; int N = 50, n, j, err, i; want_names = reftable_calloc(N + 1, sizeof(*want_names)); check(want_names != NULL); t_reftable_set_hash(want_hash, 4, REFTABLE_HASH_SHA1); for (i = 0; i < N; i++) { uint8_t hash[REFTABLE_HASH_SIZE_SHA1]; char fill[51] = { 0 }; char name[100]; struct reftable_ref_record ref = { 0 }; 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; t_reftable_set_hash(ref.value.val2.value, i / 4, REFTABLE_HASH_SHA1); t_reftable_set_hash(ref.value.val2.target_value, 3 + i / 4, REFTABLE_HASH_SHA1); /* 80 bytes / entry, so 3 entries per block. Yields 17 */ /* blocks. */ n = reftable_writer_add_ref(w, &ref); check_int(n, ==, 0); if (!memcmp(ref.value.val2.value, want_hash, REFTABLE_HASH_SIZE_SHA1) || !memcmp(ref.value.val2.target_value, want_hash, REFTABLE_HASH_SIZE_SHA1)) want_names[want_names_len++] = xstrdup(name); } n = reftable_writer_close(w); check_int(n, ==, 0); reftable_writer_free(w); w = NULL; block_source_from_buf(&source, &buf); err = reftable_reader_new(&reader, &source, "file.ref"); check(!err); if (!indexed) reader->obj_offsets.is_present = 0; err = reftable_reader_init_ref_iterator(reader, &it); check(!err); err = reftable_iterator_seek_ref(&it, ""); check(!err); reftable_iterator_destroy(&it); err = reftable_reader_refs_for(reader, &it, want_hash); check(!err); for (j = 0; ; j++) { int err = reftable_iterator_next_ref(&it, &ref); check_int(err, >=, 0); if (err > 0) break; check_int(j, <, want_names_len); check_str(ref.refname, want_names[j]); reftable_ref_record_release(&ref); } check_int(j, ==, want_names_len); reftable_buf_release(&buf); free_names(want_names); reftable_iterator_destroy(&it); reftable_reader_decref(reader); } static void t_table_refs_for_no_index(void) { t_table_refs_for(0); } static void t_table_refs_for_obj_index(void) { t_table_refs_for(1); } static void t_write_empty_table(void) { struct reftable_write_options opts = { 0 }; struct reftable_buf buf = REFTABLE_BUF_INIT; struct reftable_writer *w = t_reftable_strbuf_writer(&buf, &opts); struct reftable_block_source source = { 0 }; struct reftable_reader *rd = NULL; struct reftable_ref_record rec = { 0 }; struct reftable_iterator it = { 0 }; int err; reftable_writer_set_limits(w, 1, 1); err = reftable_writer_close(w); check_int(err, ==, REFTABLE_EMPTY_TABLE_ERROR); reftable_writer_free(w); check_uint(buf.len, ==, header_size(1) + footer_size(1)); block_source_from_buf(&source, &buf); err = reftable_reader_new(&rd, &source, "filename"); check(!err); err = reftable_reader_init_ref_iterator(rd, &it); check(!err); err = reftable_iterator_seek_ref(&it, ""); check(!err); err = reftable_iterator_next_ref(&it, &rec); check_int(err, >, 0); reftable_iterator_destroy(&it); reftable_reader_decref(rd); reftable_buf_release(&buf); } static void t_write_object_id_min_length(void) { struct reftable_write_options opts = { .block_size = 75, }; struct reftable_buf buf = REFTABLE_BUF_INIT; struct reftable_writer *w = t_reftable_strbuf_writer(&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); check(!err); } err = reftable_writer_close(w); check(!err); check_int(reftable_writer_stats(w)->object_id_len, ==, 2); reftable_writer_free(w); reftable_buf_release(&buf); } static void t_write_object_id_length(void) { struct reftable_write_options opts = { .block_size = 75, }; struct reftable_buf buf = REFTABLE_BUF_INIT; struct reftable_writer *w = t_reftable_strbuf_writer(&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); check(!err); } err = reftable_writer_close(w); check(!err); check_int(reftable_writer_stats(w)->object_id_len, ==, 16); reftable_writer_free(w); reftable_buf_release(&buf); } static void t_write_empty_key(void) { struct reftable_write_options opts = { 0 }; struct reftable_buf buf = REFTABLE_BUF_INIT; struct reftable_writer *w = t_reftable_strbuf_writer(&buf, &opts); struct reftable_ref_record ref = { .refname = (char *) "", .update_index = 1, .value_type = REFTABLE_REF_DELETION, }; int err; reftable_writer_set_limits(w, 1, 1); err = reftable_writer_add_ref(w, &ref); check_int(err, ==, REFTABLE_API_ERROR); err = reftable_writer_close(w); check_int(err, ==, REFTABLE_EMPTY_TABLE_ERROR); reftable_writer_free(w); reftable_buf_release(&buf); } static void t_write_key_order(void) { struct reftable_write_options opts = { 0 }; struct reftable_buf buf = REFTABLE_BUF_INIT; struct reftable_writer *w = t_reftable_strbuf_writer(&buf, &opts); struct reftable_ref_record refs[2] = { { .refname = (char *) "b", .update_index = 1, .value_type = REFTABLE_REF_SYMREF, .value = { .symref = (char *) "target", }, }, { .refname = (char *) "a", .update_index = 1, .value_type = REFTABLE_REF_SYMREF, .value = { .symref = (char *) "target", }, } }; int err; reftable_writer_set_limits(w, 1, 1); err = reftable_writer_add_ref(w, &refs[0]); check(!err); err = reftable_writer_add_ref(w, &refs[1]); check_int(err, ==, REFTABLE_API_ERROR); refs[0].update_index = 2; err = reftable_writer_add_ref(w, &refs[0]); check_int(err, ==, REFTABLE_API_ERROR); reftable_writer_close(w); reftable_writer_free(w); reftable_buf_release(&buf); } static void t_write_multiple_indices(void) { struct reftable_write_options opts = { .block_size = 100, }; struct reftable_buf writer_buf = REFTABLE_BUF_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; char buf[128]; int err, i; writer = t_reftable_strbuf_writer(&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}, }; snprintf(buf, sizeof(buf), "refs/heads/%04d", i); ref.refname = buf; err = reftable_writer_add_ref(writer, &ref); check(!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 }, }, }; snprintf(buf, sizeof(buf), "refs/heads/%04d", i); log.refname = buf; err = reftable_writer_add_log(writer, &log); check(!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); check_int(stats->ref_stats.index_offset, >, 0); check_int(stats->obj_stats.index_offset, >, 0); check_int(stats->log_stats.index_offset, >, 0); block_source_from_buf(&source, &writer_buf); err = reftable_reader_new(&reader, &source, "filename"); check(!err); /* * Seeking the log uses the log index now. In case there is any * confusion regarding indices we would notice here. */ err = reftable_reader_init_log_iterator(reader, &it); check(!err); err = reftable_iterator_seek_log(&it, ""); check(!err); reftable_iterator_destroy(&it); reftable_writer_free(writer); reftable_reader_decref(reader); reftable_buf_release(&writer_buf); } static void t_write_multi_level_index(void) { struct reftable_write_options opts = { .block_size = 100, }; struct reftable_buf writer_buf = REFTABLE_BUF_INIT, buf = REFTABLE_BUF_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 = t_reftable_strbuf_writer(&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}, }; char buf[128]; snprintf(buf, sizeof(buf), "refs/heads/%03" PRIuMAX, (uintmax_t)i); ref.refname = buf; err = reftable_writer_add_ref(writer, &ref); check(!err); } reftable_writer_close(writer); /* * The written refs should be sufficiently large to result in a * multi-level index. */ stats = reftable_writer_stats(writer); check_int(stats->ref_stats.max_index_level, ==, 2); block_source_from_buf(&source, &writer_buf); err = reftable_reader_new(&reader, &source, "filename"); check(!err); /* * Seeking the last ref should work as expected. */ err = reftable_reader_init_ref_iterator(reader, &it); check(!err); err = reftable_iterator_seek_ref(&it, "refs/heads/199"); check(!err); reftable_iterator_destroy(&it); reftable_writer_free(writer); reftable_reader_decref(reader); reftable_buf_release(&writer_buf); reftable_buf_release(&buf); } static void t_corrupt_table_empty(void) { struct reftable_buf buf = REFTABLE_BUF_INIT; struct reftable_block_source source = { 0 }; struct reftable_reader *reader; int err; block_source_from_buf(&source, &buf); err = reftable_reader_new(&reader, &source, "file.log"); check_int(err, ==, REFTABLE_FORMAT_ERROR); } static void t_corrupt_table(void) { uint8_t zeros[1024] = { 0 }; struct reftable_buf buf = REFTABLE_BUF_INIT; struct reftable_block_source source = { 0 }; struct reftable_reader *reader; int err; check(!reftable_buf_add(&buf, zeros, sizeof(zeros))); block_source_from_buf(&source, &buf); err = reftable_reader_new(&reader, &source, "file.log"); check_int(err, ==, REFTABLE_FORMAT_ERROR); reftable_buf_release(&buf); } int cmd_main(int argc UNUSED, const char *argv[] UNUSED) { TEST(t_buffer(), "strbuf works as blocksource"); TEST(t_corrupt_table(), "read-write on corrupted table"); TEST(t_corrupt_table_empty(), "read-write on an empty table"); TEST(t_log_buffer_size(), "buffer extension for log compression"); TEST(t_log_overflow(), "log overflow returns expected error"); TEST(t_log_write_limits(), "writer limits for writing log records"); TEST(t_log_write_read(), "read-write on log records"); TEST(t_log_zlib_corruption(), "reading corrupted log record returns expected error"); TEST(t_table_read_api(), "read on a table"); TEST(t_table_read_write_seek_index(), "read-write on a table with index"); TEST(t_table_read_write_seek_linear(), "read-write on a table without index (SHA1)"); TEST(t_table_read_write_seek_linear_sha256(), "read-write on a table without index (SHA256)"); TEST(t_table_read_write_sequential(), "sequential read-write on a table"); TEST(t_table_refs_for_no_index(), "refs-only table with no index"); TEST(t_table_refs_for_obj_index(), "refs-only table with index"); TEST(t_table_write_small_table(), "write_table works"); TEST(t_write_empty_key(), "write on refs with empty keys"); TEST(t_write_empty_table(), "read-write on empty tables"); TEST(t_write_key_order(), "refs must be written in increasing order"); TEST(t_write_multi_level_index(), "table with multi-level index"); TEST(t_write_multiple_indices(), "table with indices for multiple block types"); TEST(t_write_object_id_length(), "prefix compression on writing refs"); TEST(t_write_object_id_min_length(), "prefix compression on writing refs"); return test_done(); }