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oceanbase/unittest/sql/engine/basic/test_chunk_row_store.cpp
stdliu f8c5c2647f [FEAT MERGE] Merge syslog user experience improvement to master 
Co-authored-by: Charles0429 <xiezhenjiang@gmail.com>
Co-authored-by: tino247 <tino247@126.com>
Co-authored-by: chaser-ch <chaser.ch@antgroup.com>
2023-02-06 15:52:24 +08:00

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/**
* Copyright (c) 2021 OceanBase
* OceanBase CE is licensed under Mulan PubL v2.
* You can use this software according to the terms and conditions of the Mulan PubL v2.
* You may obtain a copy of Mulan PubL v2 at:
* http://license.coscl.org.cn/MulanPubL-2.0
* THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OF ANY KIND,
* EITHER EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO NON-INFRINGEMENT,
* MERCHANTABILITY OR FIT FOR A PARTICULAR PURPOSE.
* See the Mulan PubL v2 for more details.
*/
#define USING_LOG_PREFIX SQL
#include <gtest/gtest.h>
#include "lib/alloc/ob_malloc_allocator.h"
#include "lib/allocator/ob_malloc.h"
#include "storage/blocksstable/ob_data_file_prepare.h"
#include "storage/blocksstable/ob_tmp_file.h"
#include "sql/engine/basic/ob_chunk_row_store.h"
#include "sql/engine/basic/ob_ra_row_store.h"
#include "common/row/ob_row_store.h"
#include "share/config/ob_server_config.h"
#include "sql/ob_sql_init.h"
#include "share/ob_simple_mem_limit_getter.h"
namespace oceanbase
{
namespace sql
{
using namespace common;
static ObSimpleMemLimitGetter getter;
class TestEnv : public ::testing::Environment
{
public:
virtual void SetUp() override
{
GCONF.enable_sql_operator_dump.set_value("True");
int ret = OB_SUCCESS;
lib::ObMallocAllocator *malloc_allocator = lib::ObMallocAllocator::get_instance();
//ret = malloc_allocator->create_tenant_ctx_allocator(OB_SYS_TENANT_ID);
//ASSERT_EQ(OB_SUCCESS, ret);
ret = malloc_allocator->create_and_add_tenant_allocator(OB_SYS_TENANT_ID);
ASSERT_EQ(OB_SUCCESS, ret);
int s = (int)time(NULL);
LOG_WARN("initial setup random seed", K(s));
srandom(s);
}
virtual void TearDown() override
{
}
};
#define CALL(func, ...) func(__VA_ARGS__); ASSERT_FALSE(HasFatalFailure());
class TestChunkRowStore : public blocksstable::TestDataFilePrepare
{
public:
TestChunkRowStore() : blocksstable::TestDataFilePrepare(&getter,
"TestDisk_chunk_row_store", 2<<20, 5000)
{
}
virtual void SetUp() override
{
int ret = OB_SUCCESS;
ASSERT_EQ(OB_SUCCESS, init_tenant_mgr());
blocksstable::TestDataFilePrepare::SetUp();
ret = blocksstable::ObTmpFileManager::get_instance().init();
ASSERT_EQ(OB_SUCCESS, ret);
static ObTenantBase tenant_ctx(tenant_id_);
ObTenantEnv::set_tenant(&tenant_ctx);
ObTenantIOManager *io_service = nullptr;
EXPECT_EQ(OB_SUCCESS, ObTenantIOManager::mtl_init(io_service));
row_.count_ = COLS;
row_.cells_ = cells_;
cells_[1].set_null();
row_verify_.count_ = COLS;
row_verify_.cells_ = cells_;
//mem limit 1M
ret = rs_.init(1L << 20, tenant_id_, ctx_id_, label_);
ASSERT_EQ(OB_SUCCESS, ret);
ASSERT_EQ(OB_SUCCESS, rs_.alloc_dir_id());
memset(str_buf_, 'z', BUF_SIZE);
LOG_WARN("setup finished", K_(row));
}
int init_tenant_mgr();
virtual void TearDown() override
{
it_.reset();
rs_.reset();
rs_.~ObChunkRowStore();
blocksstable::ObTmpFileManager::get_instance().destroy();
blocksstable::TestDataFilePrepare::TearDown();
LOG_INFO("TearDown finished", K_(rs));
}
ObNewRow &gen_row(int64_t row_id)
{
cells_[0].set_int(row_id);
int64_t max_size = 512;
if (enable_big_row_ && row_id > 0 && random() % 100000 < 5) {
max_size = 1 << 20;
}
int64_t size = 10 + random() % max_size;
cells_[2].set_varchar(str_buf_, (int)size);
return row_;
}
//varify next row
//template <typename T>
void verify_row(ObChunkRowStore::Iterator& it, int64_t n, bool verify_all = false)
{
int ret = it.get_next_row(row_verify_);
ASSERT_EQ(OB_SUCCESS, ret);
int64_t v;
row_verify_.get_cell(0).get_int(v);
if (verify_all) {
row_verify_.get_cell(1).is_null();
ObString s = row_verify_.get_cell(2).get_varchar();
if (0 != strncmp(str_buf_, s.ptr(), s.length())) {
LOG_WARN("verify failed", K(s.ptr()), K(s.length()), K(v), K(n));
}
ASSERT_EQ(0, strncmp(str_buf_, s.ptr(), s.length()));
}
if (n >= 0) {
if (n != v) {
LOG_WARN("verify failed", K(n), K(v));
}
ASSERT_EQ(n, v);
}
}
void verify_next_row(int64_t id = -1, bool verify_all = false)
{
if (!it_.is_valid()) {
ASSERT_EQ(rs_.begin(it_), 0);
}
return verify_row(it_, id, verify_all);
}
void verify_n_rows(ObChunkRowStore &rs, ObChunkRowStore::Iterator& it,
int64_t n, bool verify_all = false, int64_t chunk_size = 0, int64_t start = 0)
{
if (!it.is_valid()) {
ASSERT_EQ(rs.begin(it), 0);
it.set_chunk_read_size(chunk_size);
}
for (int64_t i = start; i < n; i++) {
CALL(verify_row, it, i, verify_all);
// if (i % 1000 == 0) {
// LOG_WARN("verified rows:", K(i));
// }
}
}
void verify_n_rows(int64_t n, bool verify_all = false)
{
return verify_n_rows(rs_, it_, n, verify_all);
}
void append_rows(ObChunkRowStore &rs, int64_t cnt)
{
int64_t ret = OB_SUCCESS;
int64_t base = rs.get_row_cnt();
for (int64_t i = 0; i < cnt; i++) {
ObNewRow &row = gen_row(base + i);
ret = rs.add_row(row);
ASSERT_EQ(OB_SUCCESS, ret);
//if (i % 1000 == 0) {
// LOG_WARN("appended rows:", K(i));
//}
}
ASSERT_EQ(base + cnt, rs.get_row_cnt());
}
void append_rows(int64_t cnt)
{
return append_rows(rs_, cnt);
}
void test_time(int64_t block_size, int64_t rows)
{
ObArenaAllocator alloc(ObModIds::OB_MODULE_PAGE_ALLOCATOR, 2 << 20);
ObChunkRowStore rs(&alloc);
ASSERT_EQ(OB_SUCCESS, rs.alloc_dir_id());
int64_t v = 0;
int64_t i;
int64_t begin = ObTimeUtil::current_time();
int ret = OB_SUCCESS;
ret = rs.init(0, tenant_id_, ctx_id_, label_);
ASSERT_EQ(OB_SUCCESS, ret);
rs.set_block_size(block_size);
begin = ObTimeUtil::current_time();
for (i = 0; i < rows; i++) {
ObNewRow &row = gen_row(i);
ret = rs.add_row(row);
ASSERT_EQ(OB_SUCCESS, ret);
//if (i % 1000 == 0) {
// LOG_WARN("appended rows:", K(i));
//}
}
LOG_WARN("rs write time:", K(block_size), K(rows), K(rs.get_block_cnt()), K(rs.get_block_list_cnt()),
K(ObTimeUtil::current_time() - begin));
begin = ObTimeUtil::current_time();
ObChunkRowStore::Iterator it;
ASSERT_EQ(rs.begin(it), 0);
i = 0;
while (OB_SUCC(it.get_next_row(row_verify_))) {
row_verify_.get_cell(0).get_int(v);
ASSERT_EQ(i, v);
i++;
}
LOG_WARN("rc scan time:", K(block_size), K(rows), K(ObTimeUtil::current_time() - begin));
}
void with_or_without_chunk(bool is_with);
protected:
const static int64_t COLS = 3;
bool enable_big_row_ = false;
ObObj cells_[COLS];
ObObj ver_cells_[COLS];
ObNewRow row_;
ObNewRow row_verify_;
ObChunkRowStore rs_;
ObChunkRowStore::Iterator it_;
int64_t tenant_id_ = OB_SYS_TENANT_ID;
int64_t ctx_id_ = ObCtxIds::WORK_AREA;
const char *label_ = ObModIds::OB_SQL_ROW_STORE;
const static int64_t BUF_SIZE = 2 << 20;
char str_buf_[BUF_SIZE];
};
int TestChunkRowStore::init_tenant_mgr()
{
int ret = OB_SUCCESS;
ObAddr self;
oceanbase::rpc::frame::ObReqTransport req_transport(NULL, NULL);
oceanbase::obrpc::ObSrvRpcProxy rpc_proxy;
oceanbase::obrpc::ObCommonRpcProxy rs_rpc_proxy;
oceanbase::share::ObRsMgr rs_mgr;
int64_t tenant_id = OB_SYS_TENANT_ID;
self.set_ip_addr("127.0.0.1", 8086);
ret = getter.add_tenant(tenant_id,
2L * 1024L * 1024L * 1024L, 4L * 1024L * 1024L * 1024L);
EXPECT_EQ(OB_SUCCESS, ret);
const int64_t ulmt = 128LL << 30;
const int64_t llmt = 128LL << 30;
ret = getter.add_tenant(OB_SERVER_TENANT_ID,
ulmt,
llmt);
EXPECT_EQ(OB_SUCCESS, ret);
oceanbase::lib::set_memory_limit(128LL << 32);
return ret;
}
TEST_F(TestChunkRowStore, basic)
{
int ret = OB_SUCCESS;
LOG_INFO("starting basic test: append 3000 rows");
CALL(append_rows, 3000); // approximate 1MB, no need to dump
CALL(verify_n_rows, rs_.get_row_cnt(), true);
LOG_WARN("basic test: varified rows", K(rs_.get_row_cnt()));
it_.reset();
LOG_INFO("starting basic test: append 10000 rows");
CALL(append_rows, 10000); //need to dump
rs_.finish_add_row();
LOG_WARN("mem", K(rs_.get_mem_hold()), K(rs_.get_mem_used()));
ASSERT_EQ(13000, rs_.get_row_cnt());
LOG_INFO("starting basic test: verify rows");
CALL(verify_n_rows, rs_.get_row_cnt() - 1, true);
ret = it_.get_next_row(row_verify_);
ASSERT_EQ(OB_SUCCESS, ret);
ret = it_.get_next_row(row_verify_);
ASSERT_EQ(OB_ITER_END, ret);
it_.reset();
ret = it_.get_next_row(row_verify_);
ASSERT_EQ(OB_SUCCESS, ret);
LOG_WARN("first row", K_(row_verify));
it_.reset();
rs_.reset();
LOG_INFO("starting basic test: big row 20000 rows");
enable_big_row_ = true;
ret = rs_.init(1L << 20, tenant_id_, ctx_id_, label_);
ASSERT_EQ(OB_SUCCESS, ret);
CALL(append_rows, 20000);
LOG_WARN("mem before finish add", K(rs_.get_mem_hold()), K(rs_.get_mem_used()));
ASSERT_EQ(20000, rs_.get_row_cnt());
rs_.finish_add_row();
LOG_WARN("mem after finish add", K(rs_.get_mem_hold()), K(rs_.get_mem_used()));
CALL(verify_n_rows, rs_.get_row_cnt(), true);
LOG_WARN("big row finished");
it_.reset();
rs_.reset();
}
TEST_F(TestChunkRowStore, multi_iter)
{
int ret = OB_SUCCESS;
int total = 100;
int64_t i = 0;
int64_t j = 0;
ObChunkRowStore rs;
ASSERT_EQ(OB_SUCCESS, rs.alloc_dir_id());
ret = rs.init(1 << 20, tenant_id_, ctx_id_, label_);
ASSERT_EQ(OB_SUCCESS, ret);
LOG_INFO("starting basic test: append 3000 rows");
CALL(append_rows, rs, total); // approximate 1MB, no need to dump
rs.finish_add_row();
LOG_WARN("Multi_iter", K_(rs.mem_hold), K_(rs.mem_used));
ObChunkRowStore::Iterator it1;
ASSERT_EQ(OB_SUCCESS, rs.begin(it1));
for (i = 0; i < 10; i++) {
CALL(verify_row, it1, i, true);
if (i % 1000 == 0) {
LOG_WARN("verified rows:", K(i));
}
}
ObChunkRowStore::Iterator it2;
ASSERT_EQ(OB_SUCCESS, rs.begin(it2));
for (j = 0; j < 50; j++) {
CALL(verify_row, it2, j, true);
}
for (; i < total; i++) {
CALL(verify_row, it1, i, true);
}
for (; j < total; j++) {
CALL(verify_row, it2, j, true);
}
it1.reset();
it2.reset();
LOG_WARN("Multi_iter", K_(rs.mem_hold), K_(rs.mem_used));
rs.reset();
}
TEST_F(TestChunkRowStore, keep_projector0)
{
ObChunkRowStore rs(NULL);
ASSERT_EQ(OB_SUCCESS, rs.alloc_dir_id());
ASSERT_EQ(OB_SUCCESS, rs.init(100 << 20, OB_SERVER_TENANT_ID, ObCtxIds::DEFAULT_CTX_ID,
common::ObModIds::OB_SQL_CHUNK_ROW_STORE, true));
const int64_t OBJ_CNT = 3;
ObObj objs[OBJ_CNT];
ObNewRow r;
r.cells_ = objs;
r.count_ = OBJ_CNT;
int64_t val = 0;
for (int64_t i = 0; i < OBJ_CNT; i++) {
objs[i].set_int(val);
val++;
}
int32_t projector[] = {0, 2};
r.projector_ = projector;
r.projector_size_ = ARRAYSIZEOF(projector);
ASSERT_EQ(OB_SUCCESS, rs.add_row(r));
for (int64_t i = 0; i < OBJ_CNT; i++) {
objs[i].set_int(val);
val++;
}
ASSERT_EQ(OB_SUCCESS, rs.add_row(r));
ObChunkRowStore::Iterator it1;
ASSERT_EQ(OB_SUCCESS, rs.begin(it1));
r.projector_size_ =0;
r.projector_ = NULL;
ASSERT_EQ(OB_SUCCESS, it1.get_next_row(r));
// only fill cells, projector_ unchanged.
ASSERT_EQ(NULL, r.projector_);
ASSERT_EQ(0, r.get_cell(0).get_int());
ASSERT_EQ(0, r.cells_[0].get_int());
ASSERT_EQ(2, r.get_cell(1).get_int());
ASSERT_EQ(2, r.cells_[1].get_int());
ObNewRow *rr;
ASSERT_EQ(OB_SUCCESS, it1.get_next_row(rr));
ASSERT_TRUE(NULL == rr->projector_);
ASSERT_EQ(OBJ_CNT, rr->get_cell(0).get_int());
ASSERT_EQ(OBJ_CNT, rr->cells_[0].get_int());
ASSERT_EQ(OBJ_CNT + 2, rr->get_cell(1).get_int());
ASSERT_EQ(OBJ_CNT + 2, rr->cells_[1].get_int());
it1.reset();
rs.reset();
}
TEST_F(TestChunkRowStore, keep_projector2)
{
ObChunkRowStore rs(NULL);
ASSERT_EQ(OB_SUCCESS, rs.alloc_dir_id());
ASSERT_EQ(OB_SUCCESS, rs.init(100 << 20, OB_SERVER_TENANT_ID, ObCtxIds::DEFAULT_CTX_ID,
common::ObModIds::OB_SQL_CHUNK_ROW_STORE, true,
ObChunkRowStore::STORE_MODE::FULL));
const int64_t OBJ_CNT = 3;
ObObj objs[OBJ_CNT];
ObNewRow r;
r.cells_ = objs;
r.count_ = OBJ_CNT;
int64_t val = 0;
for (int64_t i = 0; i < OBJ_CNT; i++) {
objs[i].set_int(val);
val++;
}
int32_t projector[] = {0, 2};
r.projector_ = projector;
r.projector_size_ = ARRAYSIZEOF(projector);
ASSERT_EQ(OB_SUCCESS, rs.add_row(r));
for (int64_t i = 0; i < OBJ_CNT; i++) {
objs[i].set_int(val);
val++;
}
r.projector_size_--;
ASSERT_NE(OB_SUCCESS, rs.add_row(r));
r.projector_size_++;
ASSERT_EQ(OB_SUCCESS, rs.add_row(r));
ObChunkRowStore::Iterator it1;
ASSERT_EQ(OB_SUCCESS, rs.begin(it1));
ASSERT_EQ(OB_SUCCESS, it1.get_next_row(r));
// only fill cells, projector_ unchanged.
ASSERT_EQ(projector, r.projector_);
ASSERT_EQ(0, r.get_cell(0).get_int());
ASSERT_EQ(1, r.cells_[1].get_int());
ASSERT_EQ(2, r.get_cell(1).get_int());
ObNewRow *rr;
ASSERT_EQ(OB_SUCCESS, it1.get_next_row(rr));
ASSERT_TRUE(NULL != rr->projector_);
ASSERT_NE(projector, rr->projector_);
ASSERT_EQ(ARRAYSIZEOF(projector), rr->get_count());
ASSERT_EQ(OBJ_CNT, rr->get_cell(0).get_int());
ASSERT_EQ(OBJ_CNT + 1, rr->cells_[1].get_int());
ASSERT_EQ(OBJ_CNT + 2, rr->get_cell(1).get_int());
it1.reset();
rs.reset();
}
TEST_F(TestChunkRowStore, keep_projector2_with_copy)
{
ObChunkRowStore rs(NULL);
ASSERT_EQ(OB_SUCCESS, rs.alloc_dir_id());
ASSERT_EQ(OB_SUCCESS, rs.init(100 << 20, OB_SERVER_TENANT_ID, ObCtxIds::DEFAULT_CTX_ID,
common::ObModIds::OB_SQL_CHUNK_ROW_STORE, true,
ObChunkRowStore::STORE_MODE::FULL));
ObChunkRowStore rs2(NULL);
ASSERT_EQ(OB_SUCCESS, rs2.alloc_dir_id());
ASSERT_EQ(OB_SUCCESS, rs2.init(100 << 20, OB_SERVER_TENANT_ID, ObCtxIds::DEFAULT_CTX_ID,
common::ObModIds::OB_SQL_CHUNK_ROW_STORE, true,
ObChunkRowStore::STORE_MODE::FULL));
const int64_t OBJ_CNT = 3;
ObObj objs[OBJ_CNT];
ObNewRow r;
r.cells_ = objs;
r.count_ = OBJ_CNT;
int64_t val = 0;
for (int64_t i = 0; i < OBJ_CNT; i++) {
objs[i].set_int(val);
val++;
}
int32_t projector[] = {0, 2};
r.projector_ = projector;
r.projector_size_ = ARRAYSIZEOF(projector);
ASSERT_EQ(OB_SUCCESS, rs.add_row(r));
for (int64_t i = 0; i < OBJ_CNT; i++) {
objs[i].set_int(val);
val++;
}
ASSERT_EQ(OB_SUCCESS, rs.add_row(r));
ObChunkRowStore::Iterator it1;
ASSERT_EQ(OB_SUCCESS, rs.begin(it1));
const ObChunkRowStore::StoredRow* sr;
ASSERT_EQ(OB_SUCCESS, it1.get_next_row(sr));
ASSERT_EQ(OB_SUCCESS, rs2.copy_row(sr, &rs));
ASSERT_EQ(OB_SUCCESS, it1.get_next_row(sr));
ASSERT_EQ(OB_SUCCESS, rs2.copy_row(sr, &rs));
ObChunkRowStore::Iterator it2;
ASSERT_EQ(OB_SUCCESS, rs2.begin(it2));
ObNewRow *rr;
ASSERT_EQ(OB_SUCCESS, it2.get_next_row(rr));
// only fill cells, projector_ unchanged.
ASSERT_EQ(0, rr->get_cell(0).get_int());
ASSERT_EQ(1, rr->cells_[1].get_int());
ASSERT_EQ(2, rr->get_cell(1).get_int());
ASSERT_EQ(OB_SUCCESS, it2.get_next_row(rr));
ASSERT_TRUE(NULL != rr->projector_);
ASSERT_NE(projector, rr->projector_);
ASSERT_EQ(ARRAYSIZEOF(projector), rr->get_count());
ASSERT_EQ(OBJ_CNT, rr->get_cell(0).get_int());
ASSERT_EQ(OBJ_CNT + 1, rr->cells_[1].get_int());
ASSERT_EQ(OBJ_CNT + 2, rr->get_cell(1).get_int());
it1.reset();
rs.reset();
it2.reset();
rs2.reset();
}
TEST_F(TestChunkRowStore, basic2)
{
int ret = OB_SUCCESS;
ObChunkRowStore rs;
ASSERT_EQ(OB_SUCCESS, rs.alloc_dir_id());
ObChunkRowStore::Iterator it;
//mem limit 5M
ret = rs.init(5L << 20, tenant_id_, ctx_id_, label_);
ASSERT_EQ(OB_SUCCESS, ret);
CALL(append_rows, rs, 100000);
ASSERT_GT(rs.get_mem_hold(), 0);
ASSERT_GT(rs.get_file_size(), 0);
LOG_WARN("mem and disk", K(rs.get_mem_hold()), K(rs.get_file_size()));
rs.finish_add_row();
LOG_WARN("mem and disk after finish add", K(rs.get_mem_hold()), K(rs.get_file_size()));
CALL(verify_n_rows, rs, it, rs.get_row_cnt(), true);
it.reset();
rs.reset();
}
TEST_F(TestChunkRowStore, chunk_iterator)
{
int ret = OB_SUCCESS;
ObChunkRowStore rs;
ASSERT_EQ(OB_SUCCESS, rs.alloc_dir_id());
ObChunkRowStore::ChunkIterator chunk_it;
ObChunkRowStore::RowIterator it;
//mem limit 5M
ret = rs.init(5L << 20, tenant_id_, ctx_id_, label_);
ASSERT_EQ(OB_SUCCESS, ret);
CALL(append_rows, rs, 100000);
ASSERT_GT(rs.get_mem_hold(), 0);
ASSERT_GT(rs.get_file_size(), 0);
LOG_WARN("mem and disk", K(rs.get_mem_hold()), K(rs.get_file_size()));
ASSERT_EQ(rs.get_row_cnt(), 100000);
ASSERT_EQ(rs.get_row_cnt_in_memory() + rs.get_row_cnt_on_disk(), 100000);
rs.finish_add_row();
ASSERT_EQ(OB_SUCCESS, rs.begin(chunk_it, ObChunkRowStore::BLOCK_SIZE * 4));
const ObChunkRowStore::StoredRow *v_sr = NULL;
int64_t v;
int64_t extend_v;
int64_t row_cnt = 0;
int i = 0;
ret = chunk_it.load_next_chunk(it);
ASSERT_EQ(OB_SUCCESS, ret);
row_cnt += chunk_it.get_cur_chunk_row_cnt();
LOG_WARN("got chunk of rows:", K(row_cnt));
while(OB_SUCC(ret)) {
ret = it.get_next_row(v_sr);
if (ret == OB_ITER_END) {
ret = chunk_it.load_next_chunk(it);
if (ret == OB_ITER_END) {
break;
}
ASSERT_EQ(OB_SUCCESS, ret);
row_cnt += chunk_it.get_cur_chunk_row_cnt();
LOG_WARN("got chunk of rows:", K(row_cnt));
ret = it.get_next_row(v_sr);
}
ASSERT_EQ(OB_SUCCESS, ret);
ret = it.convert_to_row(row_verify_, v_sr);
ASSERT_EQ(OB_SUCCESS, ret);
row_verify_.get_cell(0).get_int(v);
row_verify_.get_cell(1).is_null();
ObString s = row_verify_.get_cell(2).get_varchar();
if (0 != strncmp(str_buf_, s.ptr(), s.length())) {
LOG_WARN("verify failed", K(s.ptr()), K(s.length()));
}
ASSERT_EQ(0, strncmp(str_buf_, s.ptr(), s.length()));
ASSERT_EQ(i, v);
i++;
}
ASSERT_EQ(row_cnt, 100000);
it.reset();
chunk_it.reset();
rs.reset();
}
TEST_F(TestChunkRowStore, test_copy_row)
{
int ret = OB_SUCCESS;
int64_t rows = 1000;
ObChunkRowStore rs;
ASSERT_EQ(OB_SUCCESS, rs.alloc_dir_id());
ObChunkRowStore::Iterator it;
const ObChunkRowStore::StoredRow *sr;
LOG_INFO("starting mem_perf test: append rows", K(rows));
int64_t begin = ObTimeUtil::current_time();
ret = rs.init(0, tenant_id_, ctx_id_, label_);
ASSERT_EQ(OB_SUCCESS, ret);
CALL(append_rows, rs, rows);
ASSERT_EQ(OB_SUCCESS, rs.begin(it));
ASSERT_EQ(OB_SUCCESS, it.get_next_row(sr));
}
TEST_F(TestChunkRowStore, mem_perf)
{
int ret = OB_SUCCESS;
int64_t rows = 2000000;
ObChunkRowStore rs;
ASSERT_EQ(OB_SUCCESS, rs.alloc_dir_id());
ObChunkRowStore::Iterator it;
LOG_INFO("starting mem_perf test: append rows", K(rows));
int64_t begin = ObTimeUtil::current_time();
ret = rs.init(0, tenant_id_, ctx_id_, label_);
ASSERT_EQ(OB_SUCCESS, ret);
CALL(append_rows, rs, rows);
LOG_WARN("write time:", K(rows), K(ObTimeUtil::current_time() - begin));
CALL(verify_n_rows, rs, it, 10000, true);
LOG_WARN("mem", K(rs.get_mem_hold()), K(rs.get_mem_used()));
it.reset();
begin = ObTimeUtil::current_time();
CALL(verify_n_rows, rs, it, rows, true);
LOG_WARN("scan time:", K(rows), K(ObTimeUtil::current_time() - begin));
it.reset();
rs.reset();
}
TEST_F(TestChunkRowStore, time_cmp)
{
int ret = OB_SUCCESS;
int64_t rows = 100;
int64_t v = 0;
int64_t i = 0;
test_time(0, rows);
test_time(0, rows);
test_time(8L << 10, rows);
test_time(256L << 10, rows);
test_time(512L << 10, rows);
test_time(1L << 20, rows);
test_time(2L << 20, rows);
test_time(4L << 20, rows);
ObArenaAllocator allocra(ObModIds::OB_MODULE_PAGE_ALLOCATOR, 2 << 20);
ObRARowStore ra(&allocra);
ra.init(0, tenant_id_, ctx_id_, label_);
int64_t begin = ObTimeUtil::current_time();
for (int64_t i = 0; i < rows; i++) {
ObNewRow &row = gen_row(i);
ret = ra.add_row(row);
ASSERT_EQ(OB_SUCCESS, ret);
if (i % 1000 == 0) {
LOG_WARN("appended rows:", K(i));
}
}
LOG_WARN("ra write time:", K(rows), K(ra.get_mem_hold()), K(ra.get_file_size()),
K(ObTimeUtil::current_time() - begin));
begin = ObTimeUtil::current_time();
i = 0;
while (OB_SUCC(ra.get_row(i, row_verify_))) {
row_verify_.get_cell(0).get_int(v);
ASSERT_EQ(i, v);
i++;
}
LOG_WARN("old rc scan time:", K(rows), K(ObTimeUtil::current_time() - begin));
ra.reset();
ObArenaAllocator allocrs(ObModIds::OB_MODULE_PAGE_ALLOCATOR, 2 << 20);
ObRowStore rs_old(allocrs);
rs_old.set_ctx_id(ctx_id_);
rs_old.set_label(label_);
rs_old.set_tenant_id(tenant_id_);
begin = ObTimeUtil::current_time();
for (int64_t i = 0; i < rows; i++) {
ObNewRow &row = gen_row(i);
ret = rs_old.add_row(row);
ASSERT_EQ(OB_SUCCESS, ret);
if (i % 1000 == 0) {
LOG_WARN("appended rows:", K(i));
}
}
LOG_WARN("old rs write time:", K(rows), K(rs_old.get_block_count()), K(rs_old.get_block_size()),
K(rs_old.get_used_mem_size()), K(ObTimeUtil::current_time() - begin));
begin = ObTimeUtil::current_time();
ObRowStore::Iterator it_old = rs_old.begin();
i = 0;
while (OB_SUCC(it_old.get_next_row(row_verify_))) {
row_verify_.get_cell(0).get_int(v);
ASSERT_EQ(i, v);
i++;
}
LOG_WARN("old rc scan time:", K(rows), K(ObTimeUtil::current_time() - begin));
it_old.reset();
rs_old.reset();
}
/*
TEST_F(TestOARowStore, disk_time_cmp)
{
int ret = OB_SUCCESS;
int64_t rows = 2000000;
ObChunkRowStore rs;
ASSERT_EQ(OB_SUCCESS, rs.alloc_dir_id());
int64_t v = 0;
int64_t i;
int64_t begin = ObTimeUtil::current_time();
ret = rs.init(1 << 20, tenant_id_, ctx_id_, label_);
ASSERT_EQ(OB_SUCCESS, ret);
begin = ObTimeUtil::current_time();
for (int64_t i = 0; i < rows; i++) {
ObNewRow &row = gen_row(i);
ret = rs.add_row(row);
ASSERT_EQ(OB_SUCCESS, ret);
if (i % 1000 == 0) {
LOG_WARN("appended rows:", K(i));
}
}
LOG_WARN("rs write time:", K(rows), K(ObTimeUtil::current_time() - begin));
begin = ObTimeUtil::current_time();
ObChunkRowStore::Iterator it = rs.begin();
i = 0;
while (OB_SUCC(it.get_next_row(row_verify_))) {
row_verify_.get_cell(0).get_int(v);
ASSERT_EQ(i, v);
i++;
}
LOG_WARN("rc scan time:", K(rows), K(ObTimeUtil::current_time() - begin));
ObRowStore rs_old;
rs_old.set_ctx_id(ctx_id_);
rs_old.set_label(label_);
rs_old.set_tenant_id(tenant_id_);
begin = ObTimeUtil::current_time();
for (int64_t i = 0; i < rows; i++) {
ObNewRow &row = gen_row(i);
ret = rs_old.add_row(row);
ASSERT_EQ(OB_SUCCESS, ret);
if (i % 1000 == 0) {
LOG_WARN("appended rows:", K(i));
}
}
LOG_WARN("old rs write time:", K(rows), K(ObTimeUtil::current_time() - begin));
begin = ObTimeUtil::current_time();
ObRowStore::Iterator it_old = rs_old.begin();
i = 0;
while (OB_SUCC(it_old.get_next_row(row_verify_))) {
row_verify_.get_cell(0).get_int(v);
ASSERT_EQ(i, v);
i++;
}
LOG_WARN("old rc scan time:", K(rows), K(ObTimeUtil::current_time() - begin));
it_old.reset();
rs_old.reset();
}
*/
TEST_F(TestChunkRowStore, disk)
{
int64_t begin = 0;
int64_t write_time = 0;
int64_t round = 500;
int64_t rows = round * 10000;
LOG_INFO("starting write disk test: append rows", K(rows));
ObChunkRowStore rs;
ASSERT_EQ(OB_SUCCESS, rs.alloc_dir_id());
ObChunkRowStore::Iterator it;
ASSERT_EQ(OB_SUCCESS, rs.init(0, tenant_id_, ctx_id_, label_));
rs.set_mem_limit(100L << 20);
for (int64_t i = 0; i < round; i++) {
if (i == round / 2) {
enable_big_row_ = true;
}
begin = common::ObTimeUtil::current_time();
CALL(append_rows, rs, 10000);
write_time += common::ObTimeUtil::current_time() - begin;
}
LOG_INFO("mem and disk", K(rows), K(rs.get_mem_hold()), K(rs.get_mem_used()), K(rs.get_file_size()));
LOG_INFO("disk write:", K(rows), K(write_time));
ASSERT_EQ(OB_SUCCESS, rs.finish_add_row());
LOG_INFO("mem and disk after finish", K(rows), K(rs.get_mem_hold()), K(rs.get_mem_used()), K(rs.get_file_size()));
it.reset();
begin = ObTimeUtil::current_time();
CALL(verify_n_rows, rs, it, rs.get_row_cnt(), true);
LOG_INFO("disk scan time:", K(rows), K(ObTimeUtil::current_time() - begin));
it.reset();
rs.reset();
}
TEST_F(TestChunkRowStore, disk_with_chunk)
{
int64_t begin = 0;
int64_t write_time = 0;
int64_t round = 2;
int64_t cnt = 10000;
int64_t rows = round * cnt;
LOG_INFO("starting write disk test: append rows", K(rows));
ObChunkRowStore rs;
ASSERT_EQ(OB_SUCCESS, rs.alloc_dir_id());
ObChunkRowStore::Iterator it;
ASSERT_EQ(OB_SUCCESS, rs.init(0, tenant_id_, ctx_id_, label_));
rs.set_mem_limit(1L << 20);
for (int64_t i = 0; i < round; i++) {
//if (i == round / 2) {
//enable_big_row_ = true;
// }
begin = common::ObTimeUtil::current_time();
CALL(append_rows, rs, cnt);
write_time += common::ObTimeUtil::current_time() - begin;
}
LOG_INFO("mem and disk", K(rows), K(rs.get_mem_hold()), K(rs.get_mem_used()), K(rs.get_file_size()));
LOG_INFO("disk write:", K(rows), K(write_time));
ASSERT_EQ(OB_SUCCESS, rs.finish_add_row());
LOG_INFO("mem and disk after finish", K(rows), K(rs.get_mem_hold()), K(rs.get_mem_used()), K(rs.get_file_size()), K(rs.max_blk_size_), K(rs.min_blk_size_), K(rs.n_block_in_file_));
it.reset();
begin = ObTimeUtil::current_time();
CALL(verify_n_rows, rs, it, rs.get_row_cnt(), true);
LOG_INFO("disk without chunk scan time:", K(rows), K(ObTimeUtil::current_time() - begin));
it.reset();
begin = ObTimeUtil::current_time();
CALL(verify_n_rows, rs, it, rs.get_row_cnt(), true);
LOG_INFO("disk without chunk scan time2:", K(rows), K(ObTimeUtil::current_time() - begin));
it.reset();
begin = ObTimeUtil::current_time();
CALL(verify_n_rows, rs, it, rs.get_row_cnt(), true, 1L << 20);
LOG_INFO("disk with chunk scan time:", K(rows), K(ObTimeUtil::current_time() - begin));
it.reset();
begin = ObTimeUtil::current_time();
CALL(verify_n_rows, rs, it, rs.get_row_cnt(), true, 2L << 20);
LOG_INFO("disk with chunk scan time:", K(rows), K(ObTimeUtil::current_time() - begin));
it.reset();
begin = ObTimeUtil::current_time();
CALL(verify_n_rows, rs, it, rs.get_row_cnt(), true, 8L << 20);
LOG_INFO("disk with chunk scan time:", K(rows), K(ObTimeUtil::current_time() - begin));
it.reset();
begin = ObTimeUtil::current_time();
CALL(verify_n_rows, rs, it, rs.get_row_cnt(), true, 10L << 20);
LOG_INFO("disk with chunk scan time:", K(rows), K(ObTimeUtil::current_time() - begin));
it.reset();
begin = ObTimeUtil::current_time();
CALL(verify_n_rows, rs, it, rs.get_row_cnt(), true, 16L << 20);
LOG_INFO("disk with chunk scan time:", K(rows), K(ObTimeUtil::current_time() - begin));
it.reset();
begin = ObTimeUtil::current_time();
CALL(verify_n_rows, rs, it, rs.get_row_cnt(), true, 20L << 20);
LOG_INFO("disk with chunk scan time:", K(rows), K(ObTimeUtil::current_time() - begin));
it.reset();
rs.reset();
}
// test chunk row store根据内存比例进行dump,去掉了这层逻辑,是否dump由上层驱动
//case from oarowstore
// TEST_F(TestChunkRowStore, start_dump_by_total_mem_used)
// {
// LOG_INFO("starting dump mem test: append rows", K(500000));
// int ret = OB_SUCCESS;
// ObChunkRowStore rs;
// ASSERT_EQ(OB_SUCCESS, rs.alloc_dir_id());
// ObChunkRowStore::Iterator it;
// ret = rs.init(0, tenant_id_, ctx_id_, mod_id_);
// CALL(append_rows, rs, 500000);
// int64_t avg_row_size = rs.get_mem_hold() / rs.get_row_cnt();
// LOG_WARN("average row size", K(avg_row_size));
// lib::ObMallocAllocator *malloc_allocator = lib::ObMallocAllocator::get_instance();
// malloc_allocator->set_tenant_limit(OB_SYS_TENANT_ID, 1L << 30);
// ASSERT_EQ(OB_SUCCESS, ret);
// // 50MB for work area
// ret = lib::set_wa_limit(OB_SYS_TENANT_ID, 5);
// ASSERT_EQ(OB_SUCCESS, ret);
// rs.reset();
// ret = rs.init(0, tenant_id_, ctx_id_, mod_id_);
// ASSERT_EQ(OB_SUCCESS, ret);
// // case1: trigger dump by memory mod usage (60% of limit, 30MB)
// // write 28MB, all in memory
// CALL(append_rows, rs, (28L << 20) / avg_row_size);
// ASSERT_EQ(rs.get_file_size(), 0);
// // append 10MB, need dump
// CALL(append_rows, rs, (10L << 20) / avg_row_size);
// ASSERT_GT(rs.get_file_size(), 0);
// rs.reset();
// ret = rs.init(0, tenant_id_, ctx_id_, mod_id_);
// ASSERT_EQ(OB_SUCCESS, ret);
// // case2: trigger dump by memory ctx usage (80% of limit, 40MB)
// ObMemAttr attr = default_memattr;
// attr.tenant_id_ = tenant_id_;
// attr.ctx_id_ = ctx_id_;
// // memory ctx hold 20MB
// void *mem = ob_malloc(20L << 20, attr);
// // write 15MB, in memory
// CALL(append_rows, rs, (15L << 20) / avg_row_size);
// ASSERT_EQ(rs.get_file_size(), 0);
// // append 10MB, need dump
// CALL(append_rows, rs, (10L << 20) / avg_row_size);
// ASSERT_GT(rs.get_file_size(), 0);
// ob_free(mem);
// // case3: write to disk disabled
// // write 40MB, all in memmory
// GCONF.enable_sql_operator_dump.set_value("False");
// rs.reset();
// ret = rs.init(0, tenant_id_, ctx_id_, mod_id_);
// ASSERT_EQ(OB_SUCCESS, ret);
// CALL(append_rows, rs, (40L << 20) / avg_row_size);
// ASSERT_EQ(rs.get_file_size(), 0);
// // append 20MB, exceed work area
// int64_t rows = (100L << 20) / avg_row_size;
// int64_t idx = 0;
// int64_t base = rs.get_row_cnt();
// for (; idx < rows; idx++) {
// if (OB_SUCCESS != rs.add_row(gen_row(base + idx))) {
// break;
// }
// }
// ASSERT_LT(idx, rows);
// lib::ObMallocAllocator::get_instance()->print_tenant_ctx_memory_usage(tenant_id_);
// lib::ObMallocAllocator::get_instance()->print_tenant_memory_usage(tenant_id_);
// ASSERT_EQ(rs.get_file_size(), 0);
// rs.reset();
// }
TEST_F(TestChunkRowStore, test_add_block)
{
int ret = OB_SUCCESS;
//send
ObChunkRowStore rs;
ASSERT_EQ(OB_SUCCESS, rs.alloc_dir_id());
ObChunkRowStore::Block *block;
ObArenaAllocator alloc(ObModIds::OB_MODULE_PAGE_ALLOCATOR, 2 << 20);
ObNewRow &row = gen_row(1);
int64_t row_size = ObChunkRowStore::Block::row_store_size(row);
ret = rs.init(0, tenant_id_, ctx_id_, label_);
ASSERT_EQ(OB_SUCCESS, ret);
int64_t min_size = rs.min_blk_size(row_size);
void *mem = alloc.alloc(min_size);
ret = rs.init_block_buffer(mem, min_size, block);
ASSERT_EQ(OB_SUCCESS, ret);
ret = rs.add_block(block, false);
ASSERT_EQ(OB_SUCCESS, ret);
CALL(append_rows, rs, 100);
rs.finish_add_row();
ret = block->unswizzling();
ASSERT_EQ(OB_SUCCESS, ret);
rs.remove_added_blocks();
rs.reset();
LOG_WARN("Molly size", K(block->get_buffer()->data_size()), K(block->get_buffer()->capacity()));
ObArenaAllocator alloc2(ObModIds::OB_MODULE_PAGE_ALLOCATOR, 2 << 20);
void *mem2 = alloc2.alloc(block->get_buffer()->data_size());
memcpy(mem2, mem, block->get_buffer()->data_size());
//recv
ObChunkRowStore rs2;
ASSERT_EQ(OB_SUCCESS, rs2.alloc_dir_id());
ObChunkRowStore::Block *block2 = reinterpret_cast<ObChunkRowStore::Block *>(mem2);
ret = rs2.init(0, tenant_id_, ctx_id_, label_);
ASSERT_EQ(OB_SUCCESS, ret);
ret = rs2.add_block(block2, true);
ASSERT_EQ(OB_SUCCESS, ret);
ObChunkRowStore::Iterator it2;
ASSERT_EQ(OB_SUCCESS, rs2.begin(it2));
CALL(verify_n_rows, rs2, it2, 99, true);
ASSERT_EQ(true, it2.has_next());
CALL(verify_n_rows, rs2, it2, 100, true, 0, 99);
ASSERT_FALSE(it2.has_next());
ASSERT_EQ(OB_ITER_END, it2.get_next_row(row));
rs2.remove_added_blocks();
it2.reset();
rs2.reset();
}
TEST_F(TestChunkRowStore, row_extend_row)
{
int64_t begin = 0;
int64_t write_time = 0;
int64_t round = 500;
int64_t rows = round * 10000;
LOG_INFO("starting write disk test: append rows", K(rows));
ObChunkRowStore rs;
ASSERT_EQ(OB_SUCCESS, rs.alloc_dir_id());
ObChunkRowStore::Iterator it;
ASSERT_EQ(OB_SUCCESS,
rs.init(0, tenant_id_, ctx_id_, label_, true, ObChunkRowStore::WITHOUT_PROJECTOR, 8));
LOG_INFO("starting basic test: append 3000 rows");
int64_t ret = OB_SUCCESS;
int64_t base = rs.get_row_cnt();
ObChunkRowStore::StoredRow* sr = NULL;
const ObChunkRowStore::StoredRow* v_sr = NULL;
for (int64_t i = 0; i < 100; i++) {
ObNewRow &row = gen_row(i);
ret = rs.add_row(row, &sr);
ASSERT_EQ(OB_SUCCESS, ret);
*static_cast<int64_t*>(sr->get_extra_payload()) = i;
}
ASSERT_EQ(OB_SUCCESS, rs.begin(it));
sr = NULL;
int64_t v;
int64_t extend_v;
for (int64_t i = 0; i < 100; i++) {
int ret = it.get_next_row(v_sr);
ASSERT_EQ(OB_SUCCESS, ret);
ret = it.convert_to_row_with_obj(v_sr, row_verify_);
ASSERT_EQ(OB_SUCCESS, ret);
row_verify_.get_cell(0).get_int(v);
row_verify_.get_cell(1).is_null();
ObString s = row_verify_.get_cell(2).get_varchar();
if (0 != strncmp(str_buf_, s.ptr(), s.length())) {
LOG_WARN("verify failed", K(s.ptr()), K(s.length()));
}
ASSERT_EQ(0, strncmp(str_buf_, s.ptr(), s.length()));
extend_v = *(static_cast<int64_t*>(v_sr->get_extra_payload()));
if (i != v || i != extend_v) {
LOG_WARN("verify failed", K(i), K(v), K(extend_v));
}
ASSERT_EQ(i, v);
}
it.reset();
rs.reset();
}
TEST_F(TestChunkRowStore, test_both_disk_and_memory)
{
int64_t round = 2;
int64_t cnt = 100;
int64_t rows = round * cnt;
LOG_INFO("starting write disk test: append rows", K(rows));
ObChunkRowStore rs;
ASSERT_EQ(OB_SUCCESS, rs.alloc_dir_id());
ObChunkRowStore::Iterator it;
ASSERT_EQ(OB_SUCCESS, rs.init(0, tenant_id_, ctx_id_, label_));
rs.set_mem_limit(1L << 30);
// disk data
CALL(append_rows, rs, cnt);
ASSERT_EQ(OB_SUCCESS, rs.dump(false, true));
// in memory
CALL(append_rows, rs, cnt);
rs.finish_add_row(false);
CALL(verify_n_rows, rs, it, rs.get_row_cnt(), true, 16L << 20);
ASSERT_EQ(rs.get_row_cnt_on_disk(), rs.get_row_cnt_in_memory());
LOG_INFO("row store data count", K(rs.get_row_cnt_on_disk()), K(rs.get_row_cnt_in_memory()));
it.reset();
rs.reset();
}
TEST_F(TestChunkRowStore, test_only_disk_data)
{
int64_t round = 2;
int64_t cnt = 100;
int64_t rows = round * cnt;
LOG_INFO("starting write disk test: append rows", K(rows));
ObChunkRowStore rs;
ASSERT_EQ(OB_SUCCESS, rs.alloc_dir_id());
ObChunkRowStore::Iterator it;
ASSERT_EQ(OB_SUCCESS, rs.init(0, tenant_id_, ctx_id_, label_));
rs.set_mem_limit(1L << 30);
// disk data
CALL(append_rows, rs, cnt);
ASSERT_EQ(OB_SUCCESS, rs.dump(false, true));
rs.finish_add_row();
CALL(verify_n_rows, rs, it, rs.get_row_cnt(), true, 16L << 20);
LOG_INFO("row store data count", K(rs.get_row_cnt_on_disk()), K(rs.get_row_cnt_in_memory()));
it.reset();
rs.reset();
}
} // end namespace sql
} // end namespace oceanbase
void ignore_sig(int sig)
{
UNUSED(sig);
}
int main(int argc, char **argv)
{
signal(49, ignore_sig);
oceanbase::sql::init_sql_factories();
oceanbase::common::ObLogger::get_logger().set_file_name("test_chunk_row_store.log", true);
oceanbase::common::ObLogger::get_logger().set_log_level("INFO");
testing::InitGoogleTest(&argc, argv);
auto *env = new (oceanbase::sql::TestEnv);
testing::AddGlobalTestEnvironment(env);
int ret = RUN_ALL_TESTS();
OB_LOGGER.disable();
return ret;
}
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