/** * 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_OPT #include "common/sql_mode/ob_sql_mode_utils.h" #include "share/ob_i_data_access_service.h" #include "share/schema/ob_part_mgr_util.h" #include "sql/ob_sql_define.h" #include "sql/optimizer/ob_table_location.h" #include "sql/ob_sql_utils.h" #include "sql/ob_sql_trans_control.h" #include "sql/resolver/dml/ob_update_stmt.h" #include "sql/resolver/dml/ob_insert_stmt.h" #include "sql/resolver/dml/ob_delete_resolver.h" #include "sql/rewrite/ob_query_range_provider.h" #include "share/part/ob_part_mgr_ad.h" #include "sql/code_generator/ob_code_generator_impl.h" #include "sql/code_generator/ob_expr_generator_impl.h" #include "sql/engine/expr/ob_sql_expression.h" #include "sql/engine/expr/ob_expr_func_part_hash.h" #include "sql/engine/expr/ob_expr_column_conv.h" #include "storage/ob_dml_param.h" #include "storage/ob_partition_service.h" #include "sql/engine/expr/ob_expr_result_type_util.h" #include "sql/ob_sql_mock_schema_utils.h" using namespace oceanbase::transaction; using namespace oceanbase::sql; using namespace oceanbase::common; using namespace oceanbase::share; using namespace oceanbase::share::schema; static int get_part_id_by_mod(const int64_t calc_result, const int64_t part_num, int64_t& part_id) { int ret = OB_SUCCESS; if (calc_result < 0 || 0 == part_num) { ret = OB_INVALID_ARGUMENT; LOG_WARN("Input arguments is invalid", K(calc_result), K(part_num), K(ret)); } else { part_id = calc_result % part_num; } return ret; } static bool is_all_ranges_empty(const ObQueryRangeArray& query_array, bool& is_empty) { int ret = OB_SUCCESS; is_empty = true; for (int i = 0; is_empty && OB_SUCCESS == ret && i < query_array.count(); i++) { if (NULL == query_array.at(i)) { ret = OB_ERR_UNEXPECTED; } else if (!query_array.at(i)->empty()) { is_empty = false; } } return ret; } bool ObListPartMapKey::operator==(const ObListPartMapKey& other) const { return row_ == other.row_; } int64_t ObListPartMapKey::hash() const { int64_t hash_value = 0; for (int64_t i = 0; i < row_.get_count(); i++) { hash_value = row_.get_cell(i).hash(hash_value); } return hash_value; } bool ObHashPartMapKey::operator==(const ObHashPartMapKey& other) const { return part_idx_ == other.part_idx_; } int64_t ObHashPartMapKey::hash() const { int64_t hash_value = 0; ObObj idx_obj(part_idx_); hash_value = idx_obj.hash(hash_value); return hash_value; } bool TableLocationKey::operator==(const TableLocationKey& other) const { return table_id_ == other.table_id_ && ref_table_id_ == other.ref_table_id_; } bool TableLocationKey::operator!=(const TableLocationKey& other) const { return !(*this == other); } int ObTableLocation::PartProjector::init_part_projector( const ObRawExpr* part_expr, ObPartitionLevel part_level, RowDesc& row_desc) { int ret = OB_SUCCESS; if (PARTITION_LEVEL_ONE == part_level) { ret = init_part_projector(part_expr, row_desc); } else if (PARTITION_LEVEL_TWO == part_level) { ret = init_subpart_projector(part_expr, row_desc); } else { /*do nothing*/ } return ret; } int ObTableLocation::PartProjector::init_part_projector(const ObRawExpr* part_expr, RowDesc& row_desc) { return init_part_projector(part_expr, row_desc, part_projector_, part_projector_size_); } int ObTableLocation::PartProjector::init_subpart_projector(const ObRawExpr* part_expr, RowDesc& row_desc) { return init_part_projector(part_expr, row_desc, subpart_projector_, subpart_projector_size_); } int ObTableLocation::PartProjector::init_part_projector( const ObRawExpr* part_expr, RowDesc& row_desc, int32_t*& projector, int64_t& projector_size) { int ret = OB_SUCCESS; ObSEArray part_columns; if (OB_FAIL(ObRawExprUtils::extract_column_exprs(part_expr, part_columns))) { LOG_WARN("extract column exprs failed", K(ret)); } else { projector_size = part_columns.count(); if (OB_ISNULL(projector = static_cast(allocator_.alloc(projector_size * sizeof(int64_t))))) { ret = OB_ALLOCATE_MEMORY_FAILED; LOG_WARN("allocate memory failed", K(projector_size)); } for (int64_t i = 0; OB_SUCC(ret) && i < projector_size; ++i) { int64_t idx = OB_INVALID_INDEX; const ObRawExpr* part_column = part_columns.at(i); if (OB_ISNULL(part_column)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("part column is null"); } else if (OB_UNLIKELY(!part_column->is_column_ref_expr())) { ret = OB_ERR_UNEXPECTED; LOG_WARN("part column isn't column reference", K(ret), K(*part_column)); } else if (OB_FAIL(row_desc.get_idx(part_column, idx)) && OB_ENTRY_NOT_EXIST != ret) { LOG_WARN("get idx failed", K(ret)); } else if (OB_ENTRY_NOT_EXIST == ret) { ret = OB_SUCCESS; const ObColumnRefRawExpr* col_ref = static_cast(part_column); ObColumnExpression* virtual_col = NULL; if (OB_UNLIKELY(!col_ref->is_generated_column())) { ret = OB_ERR_UNEXPECTED; LOG_WARN("column reference isn't generated column", K(ret), K(*col_ref)); } else if (OB_FAIL(ObExprGeneratorImpl::gen_expression_with_row_desc( sql_expr_factory_, expr_op_factory_, row_desc, col_ref->get_dependant_expr(), virtual_col))) { LOG_WARN("generate expression with row desc failed", K(ret), K(*col_ref), K(row_desc)); } else { virtual_col->set_result_index(row_desc.get_column_num()); if (OB_FAIL(row_desc.add_column(const_cast(part_column)))) { LOG_WARN("add part column to row desc failed", K(ret)); } else if (OB_FAIL(ObSqlExpressionUtil::add_expr_to_list(virtual_column_exprs_, virtual_col))) { LOG_WARN("add virtual column expr failed", K(ret)); } } } if (OB_SUCC(ret)) { if (OB_FAIL(row_desc.get_idx(part_column, idx))) { LOG_WARN("part_column isn't invalid", K(ret), K(*part_column)); } else { projector[i] = static_cast(idx); } } } } return ret; } int ObTableLocation::PartProjector::calc_part_row( const stmt::StmtType& stmt_type, ObExecContext& ctx, const ObNewRow& input_row, ObNewRow*& part_row) const { int ret = OB_SUCCESS; ObNewRow& cur_part_row = ctx.get_part_row_manager().get_part_row(); if (virtual_column_exprs_.get_size() <= 0) { cur_part_row.cells_ = input_row.cells_; cur_part_row.count_ = column_cnt_; } else { cur_part_row.count_ = column_cnt_; ObExprCtx expr_ctx; if (OB_FAIL(ObSQLUtils::wrap_expr_ctx(stmt_type, ctx, ctx.get_allocator(), expr_ctx))) { LOG_WARN("wrap expr ctx failed", K(ret)); } else if (OB_ISNULL(cur_part_row.cells_)) { int64_t row_size = sizeof(ObObj) * column_cnt_; cur_part_row.cells_ = static_cast(ctx.get_allocator().alloc(row_size)); if (OB_ISNULL(cur_part_row.cells_)) { ret = OB_ALLOCATE_MEMORY_FAILED; LOG_WARN("allocate memory for current part row failed", K(ret), K(row_size)); } } if (OB_SUCC(ret)) { int64_t copy_row_size = (column_cnt_ - virtual_column_exprs_.get_size()) * sizeof(ObObj); memcpy(cur_part_row.cells_, input_row.cells_, copy_row_size); } DLIST_FOREACH(node, virtual_column_exprs_) { const ObColumnExpression* virtual_col = static_cast(node); if (OB_FAIL(virtual_col->calc_and_project(expr_ctx, cur_part_row))) { LOG_WARN("calc and project part row failed", K(ret)); } } } if (OB_SUCC(ret)) { part_row = &cur_part_row; } return ret; } void ObTableLocation::PartProjector::project_part_row(ObPartitionLevel part_level, ObNewRow& part_row) const { int32_t* projector = NULL; int64_t projector_size = 0; if (part_level == PARTITION_LEVEL_ONE) { projector = part_projector_; projector_size = part_projector_size_; } else if (part_level == PARTITION_LEVEL_TWO) { projector = subpart_projector_; projector_size = subpart_projector_size_; } else { /*do nothing*/ } part_row.projector_ = projector; part_row.projector_size_ = projector_size; } int ObTableLocation::PartProjector::deep_copy(const PartProjector& other) { int ret = OB_SUCCESS; void* ptr = NULL; int64_t buf_len = 0; part_projector_size_ = other.part_projector_size_; subpart_projector_size_ = other.subpart_projector_size_; column_cnt_ = other.column_cnt_; if (other.part_projector_ != NULL) { buf_len = sizeof(int32_t) * other.part_projector_size_; if (OB_ISNULL(ptr = allocator_.alloc(buf_len))) { ret = OB_ALLOCATE_MEMORY_FAILED; LOG_WARN("allocate projector buffer failed", K(buf_len), K_(part_projector)); } else { part_projector_ = static_cast(ptr); memcpy(part_projector_, other.part_projector_, buf_len); } } if (OB_SUCC(ret) && other.subpart_projector_ != NULL) { buf_len = sizeof(int32_t) * other.subpart_projector_size_; if (OB_ISNULL(ptr = allocator_.alloc(buf_len))) { ret = OB_ALLOCATE_MEMORY_FAILED; LOG_WARN("allocate subpart projector buffer failed", K(buf_len), K_(subpart_projector_size)); } else { subpart_projector_ = static_cast(ptr); memcpy(subpart_projector_, other.subpart_projector_, buf_len); } } DLIST_FOREACH(node, other.virtual_column_exprs_) { ObColumnExpression* virtual_col = NULL; const ObColumnExpression* other_col = static_cast(node); if (OB_FAIL(sql_expr_factory_.alloc(virtual_col)) || OB_ISNULL(virtual_col)) { ret = COVER_SUCC(OB_ERR_UNEXPECTED); LOG_WARN("alloc virtual column failed", K(ret)); } else if (OB_FAIL(virtual_col->assign(*other_col))) { LOG_WARN("assign virtual column failed", K(ret)); } else if (OB_FAIL(ObSqlExpressionUtil::add_expr_to_list(virtual_column_exprs_, virtual_col))) { LOG_WARN("add expr to list failed", K(ret)); } } return ret; } OB_DEF_SERIALIZE(ObTableLocation::PartProjector) { int ret = OB_SUCCESS; OB_UNIS_ENCODE_ARRAY(part_projector_, part_projector_size_); OB_UNIS_ENCODE_ARRAY(subpart_projector_, subpart_projector_size_); OB_UNIS_ENCODE(column_cnt_); if (OB_SUCC(ret)) { if (OB_FAIL(serialize_dlist(virtual_column_exprs_, buf, buf_len, pos))) { LOG_WARN("serialize virtual column expr list failed", K(ret), K(buf_len), K(pos)); } } return ret; } OB_DEF_SERIALIZE_SIZE(ObTableLocation::PartProjector) { int64_t len = 0; OB_UNIS_ADD_LEN_ARRAY(part_projector_, part_projector_size_); OB_UNIS_ADD_LEN_ARRAY(subpart_projector_, subpart_projector_size_); OB_UNIS_ADD_LEN(column_cnt_); len += get_dlist_serialize_size(virtual_column_exprs_); return len; } OB_DEF_DESERIALIZE(ObTableLocation::PartProjector) { int ret = OB_SUCCESS; void* ptr = NULL; int64_t vir_col_size = 0; OB_UNIS_DECODE(part_projector_size_); if (OB_SUCC(ret) && part_projector_size_ > 0) { int64_t buf_len = sizeof(int32_t) * part_projector_size_; if (OB_ISNULL(ptr = allocator_.alloc(buf_len))) { ret = OB_ALLOCATE_MEMORY_FAILED; LOG_WARN("allocate projector buffer failed", K(buf_len), K_(part_projector)); } else { part_projector_ = static_cast(ptr); OB_UNIS_DECODE_ARRAY(part_projector_, part_projector_size_); } } OB_UNIS_DECODE(subpart_projector_size_); if (OB_SUCC(ret) && subpart_projector_size_ > 0) { int64_t buf_len = sizeof(int32_t) * subpart_projector_size_; if (OB_ISNULL(ptr = allocator_.alloc(buf_len))) { ret = OB_ALLOCATE_MEMORY_FAILED; LOG_WARN("allocate projector buffer failed", K(buf_len), K_(subpart_projector)); } else { subpart_projector_ = static_cast(ptr); OB_UNIS_DECODE_ARRAY(subpart_projector_, subpart_projector_size_); } } OB_UNIS_DECODE(column_cnt_); OB_UNIS_DECODE(vir_col_size); for (int64_t i = 0; OB_SUCC(ret) && i < vir_col_size; ++i) { ObColumnExpression* virtual_column = NULL; if (OB_FAIL(sql_expr_factory_.alloc(virtual_column))) { LOG_WARN("allocate virtual column failed", K(ret), K(i)); } OB_UNIS_DECODE(*virtual_column); if (OB_SUCC(ret) && OB_FAIL(ObSqlExpressionUtil::add_expr_to_list(virtual_column_exprs_, virtual_column))) { LOG_WARN("add expr to virtual column expr list failed", K(ret)); } } return ret; } ObPartLocCalcNode* ObPartLocCalcNode::create_part_calc_node( ObIAllocator& allocator, ObIArray& calc_nodes, ObPartLocCalcNode::NodeType type) { void* ptr = NULL; ObPartLocCalcNode* ret_node = NULL; switch (type) { case ObPartLocCalcNode::QUERY_RANGE: { ptr = allocator.alloc(sizeof(ObPLQueryRangeNode)); if (NULL != ptr) { ret_node = new (ptr) ObPLQueryRangeNode(allocator); } break; } case ObPartLocCalcNode::FUNC_VALUE: { ptr = allocator.alloc(sizeof(ObPLFuncValueNode)); if (NULL != ptr) { ret_node = new (ptr) ObPLFuncValueNode(allocator); } break; } case ObPartLocCalcNode::COLUMN_VALUE: { ptr = allocator.alloc(sizeof(ObPLColumnValueNode)); if (NULL != ptr) { ret_node = new (ptr) ObPLColumnValueNode(allocator); } break; } case ObPartLocCalcNode::CALC_AND: { ptr = allocator.alloc(sizeof(ObPLAndNode)); if (NULL != ptr) { ret_node = new (ptr) ObPLAndNode(allocator); } break; } case ObPartLocCalcNode::CALC_OR: { ptr = allocator.alloc(sizeof(ObPLOrNode)); if (NULL != ptr) { ret_node = new (ptr) ObPLOrNode(allocator); } break; } default: { LOG_WARN("Invalid ObPartLocCalcNode type", K(type)); break; } } if (OB_UNLIKELY(NULL == ptr) || OB_UNLIKELY(NULL == ret_node)) { LOG_WARN("Failed to allocate ObPartLocCalcNode", K(type)); } else if (OB_SUCCESS != calc_nodes.push_back(ret_node)) { ret_node->~ObPartLocCalcNode(); allocator.free(ret_node); ret_node = NULL; LOG_WARN("Store ObPartLocCalcNode failed"); } else { } // do nothing return ret_node; } int ObPLAndNode::deep_copy( ObIAllocator& allocator, ObIArray& calc_nodes, ObPartLocCalcNode*& other) const { int ret = OB_SUCCESS; if (OB_ISNULL(other = create_part_calc_node(allocator, calc_nodes, CALC_AND))) { ret = OB_ALLOCATE_MEMORY_FAILED; LOG_ERROR("Allocate calc node failed", K(ret)); } else { ObPartLocCalcNode* left_node = NULL; ObPartLocCalcNode* right_node = NULL; if (NULL != left_node_ && OB_FAIL(left_node_->deep_copy(allocator, calc_nodes, left_node))) { LOG_WARN("Failed to deep copy left node", K(ret)); } else if (NULL != right_node_ && OB_FAIL(right_node_->deep_copy(allocator, calc_nodes, right_node))) { LOG_WARN("Failed todeep copy right node", K(ret)); } else { ObPLAndNode* and_node = static_cast(other); and_node->left_node_ = left_node; and_node->right_node_ = right_node; } } return ret; } int ObPLOrNode::deep_copy( ObIAllocator& allocator, ObIArray& calc_nodes, ObPartLocCalcNode*& other) const { int ret = OB_SUCCESS; if (OB_ISNULL(other = create_part_calc_node(allocator, calc_nodes, CALC_OR))) { ret = OB_ALLOCATE_MEMORY_FAILED; LOG_ERROR("Allocate calc node failed", K(ret)); } else { ObPartLocCalcNode* left_node = NULL; ObPartLocCalcNode* right_node = NULL; if (NULL != left_node_ && OB_FAIL(left_node_->deep_copy(allocator, calc_nodes, left_node))) { LOG_WARN("Failed to deep copy left node", K(ret)); } else if (NULL != right_node_ && OB_FAIL(right_node_->deep_copy(allocator, calc_nodes, right_node))) { LOG_WARN("Failed todeep copy right node", K(ret)); } else { ObPLOrNode* or_node = static_cast(other); or_node->left_node_ = left_node; or_node->right_node_ = right_node; } } return ret; } int ObPLQueryRangeNode::deep_copy( ObIAllocator& allocator, ObIArray& calc_nodes, ObPartLocCalcNode*& other) const { int ret = OB_SUCCESS; if (OB_ISNULL(other = create_part_calc_node(allocator, calc_nodes, QUERY_RANGE))) { ret = OB_ALLOCATE_MEMORY_FAILED; LOG_ERROR("Allocate calc node failed", K(ret)); } else { ObPLQueryRangeNode* qr_node = static_cast(other); if (OB_FAIL(qr_node->pre_query_range_.deep_copy(pre_query_range_))) { LOG_WARN("Failed to deep copy pre query range", K(ret)); } } return ret; } int ObPLFuncValueNode::deep_copy( ObIAllocator& allocator, ObIArray& calc_nodes, ObPartLocCalcNode*& other) const { int ret = OB_SUCCESS; if (OB_ISNULL(other = create_part_calc_node(allocator, calc_nodes, FUNC_VALUE))) { ret = OB_ALLOCATE_MEMORY_FAILED; LOG_ERROR("Allocate calc node failed", K(ret)); } else { ObPLFuncValueNode* func_node = static_cast(other); func_node->res_type_ = res_type_; func_node->param_idx_ = param_idx_; if (OB_FAIL(deep_copy_obj(allocator, value_, func_node->value_))) { LOG_WARN("Failed to deep copy value", K(ret)); } else { ObIArray& param_values = func_node->param_value_; for (int64_t idx = 0; OB_SUCC(ret) && idx < param_value_.count(); ++idx) { ObObj dst; const ParamValuePair& value_pair = param_value_.at(idx); if (OB_FAIL(deep_copy_obj(allocator, value_pair.obj_value_, dst))) { LOG_WARN("Failed to deep copy obj", K(ret)); } else if (OB_FAIL(param_values.push_back(ParamValuePair(value_pair.param_idx_, dst)))) { LOG_WARN("Failed to add ParamValuePair", K(ret)); } else { } } } } return ret; } int ObPLColumnValueNode::deep_copy( ObIAllocator& allocator, ObIArray& calc_nodes, ObPartLocCalcNode*& other) const { int ret = OB_SUCCESS; if (OB_ISNULL(other = create_part_calc_node(allocator, calc_nodes, COLUMN_VALUE))) { ret = OB_ALLOCATE_MEMORY_FAILED; LOG_ERROR("Allocate calc node failed", K(ret)); } else { ObPLColumnValueNode* column_node = static_cast(other); column_node->res_type_ = res_type_; column_node->param_idx_ = param_idx_; if (OB_FAIL(deep_copy_obj(allocator, value_, column_node->value_))) { LOG_WARN("Failed to deep copy obj", K(ret)); } } return ret; } int ObTableLocation::add_range_part_schema(const ObTableSchema& table_schema) { int ret = OB_SUCCESS; void* ptr1 = NULL; void* ptr2 = NULL; use_range_part_opt_ = true; partition_num_ = table_schema.get_partition_num(); ObPartition** part_array = table_schema.get_part_array(); if (partition_num_ <= 0) { ret = OB_ERR_UNEXPECTED; LOG_WARN("partition number should not greater than 0", K(ret), K(partition_num_)); } else { if (OB_ISNULL(ptr1 = allocator_.alloc(sizeof(ObObj) * partition_num_))) { ret = OB_ALLOCATE_MEMORY_FAILED; LOG_WARN("failed to allocate memory", K(ret), K(partition_num_)); } else if (OB_ISNULL(ptr2 = allocator_.alloc(sizeof(int64_t) * partition_num_))) { ret = OB_ALLOCATE_MEMORY_FAILED; LOG_WARN("failed to allocate memory", K(ret), K(partition_num_)); } else { range_obj_arr_ = new (ptr1) ObObj[partition_num_](); range_part_id_arr_ = static_cast(ptr2); } } for (int64_t i = 0; OB_SUCC(ret) && i < table_schema.get_partition_num(); i++) { ObPartition* part = part_array[i]; if (OB_ISNULL(part)) { ret = OB_SCHEMA_ERROR; LOG_WARN("get invalid partiton array", K(ret), K(i), K(partition_num_)); } else if (part->get_high_bound_val().get_obj_cnt() != 1) { ret = OB_ERR_UNEXPECTED; LOG_WARN("high bound val should have one obj", K(ret), K(part->get_high_bound_val().get_obj_cnt())); } else if (OB_FAIL(ob_write_obj(allocator_, part->get_high_bound_val().get_obj_ptr()[0], range_obj_arr_[i]))) { LOG_WARN("failed to write obj", K(ret), K(i)); } else { range_part_id_arr_[i] = part->get_part_id(); } LOG_TRACE("add range part", K(partition_num_), K(i), K(part->get_high_bound_val()), K(range_obj_arr_[i]), K(range_part_id_arr_[i])); } return ret; } int ObTableLocation::get_part_id_from_part_idx(int64_t part_idx, int64_t& part_id) const { int ret = OB_SUCCESS; ObHashPartMapKey key; ObHashPartMapValue* value = NULL; key.part_idx_ = part_idx; part_id = part_idx; if (0 == hash_part_array_.count()) { part_id = part_idx; } else { ret = hash_part_map_.get_refactored(key, value); if (OB_FAIL(ret)) { LOG_WARN("fail to get_refactored", K(ret)); } else { part_id = value->part_id_; } } return ret; } int ObTableLocation::add_part_idx_to_part_id_map(const ObTableSchema& table_schema) { int ret = OB_SUCCESS; ObPartition** part_array = table_schema.get_part_array(); for (int64_t i = 0; OB_SUCC(ret) && i < table_schema.get_partition_num(); i++) { if (OB_ISNULL(part_array[i])) { ret = OB_SCHEMA_ERROR; LOG_WARN("get invalid partiton array", K(ret), K(i)); } else { ObHashPartMapValue value; value.part_id_ = part_array[i]->get_part_id(); if (-1 == part_array[i]->get_part_idx()) { value.key_.part_idx_ = i; } else { value.key_.part_idx_ = part_array[i]->get_part_idx(); } if (value.part_id_ != value.key_.part_idx_) { if (OB_FAIL(hash_part_array_.push_back(value))) { LOG_WARN("fail to push back value", K(ret)); } LOG_TRACE("add new part idx->part id item", K(ret), K(value.part_id_), K(value.key_.part_idx_)); } } } for (int64_t i = 0; OB_SUCC(ret) && i < hash_part_array_.count(); i++) { if (OB_FAIL(hash_part_map_.set_refactored(hash_part_array_.at(i).key_, &hash_part_array_.at(i)))) { LOG_WARN("fail to set value", K(ret)); } } return ret; } int ObTableLocation::add_hash_part_schema(const ObTableSchema& table_schema) { int ret = OB_SUCCESS; use_hash_part_opt_ = true; first_part_num_ = table_schema.get_first_part_num(); if (OB_FAIL(add_part_idx_to_part_id_map(table_schema))) { LOG_WARN("failed to add part idx to part id map", K(ret)); } else if (UNKNOWN_FAST_CALC == fast_calc_part_opt_) { fast_calc_part_opt_ = CAN_FAST_CALC; if (OB_FAIL(init_fast_calc_info())) { LOG_WARN("fail to init fast calc info, ignore error", K(ret)); ret = OB_SUCCESS; fast_calc_part_opt_ = CANNOT_FAST_CALC; } } return ret; } int ObTableLocation::add_list_part_schema(const ObTableSchema& table_schema, const ObTimeZoneInfo* tz_info) { int ret = OB_SUCCESS; use_list_part_map_ = true; ObPartition** part_array = table_schema.get_part_array(); LOG_TRACE("begin add_list_part_schema", K(table_schema), K(ret)); const common::ObPartitionKeyInfo& part_key_info = table_schema.get_partition_key_info(); const ObRowkeyColumn* column = NULL; for (int64_t i = 0; OB_SUCC(ret) && i < table_schema.get_partition_num(); i++) { ObPartition* part = part_array[i]; for (int64_t j = 0; OB_SUCC(ret) && j < part->get_list_row_values().count(); j++) { ObListPartMapValue value; value.part_id_ = part->get_part_id(); const common::ObNewRow& tmp_row = part->get_list_row_values().at(j); if (lib::is_oracle_mode() && part_key_info.contain_timestamp_ltz_column()) { if (OB_FAIL( ob_write_row_with_cast_timestamp_ltz(allocator_, tmp_row, value.key_.row_, part_key_info, tz_info))) { LOG_WARN("fail to write row", K(ret)); } } else { if (OB_FAIL(ob_write_row(allocator_, tmp_row, value.key_.row_))) { LOG_WARN("fail to write row", K(ret)); } } if (OB_SUCC(ret)) { if (value.key_.row_.get_count() == 1 && value.key_.row_.get_cell(0).is_max_value()) { list_default_part_id_ = value.part_id_; } else { if (OB_FAIL(list_part_array_.push_back(value))) { LOG_WARN("fail to push back value", K(ret)); } else { LOG_TRACE("succ to push_back list_part_array", K(i), K(value), K(ret)); } } } } } for (int64_t i = 0; OB_SUCC(ret) && i < list_part_array_.count(); i++) { if (OB_FAIL(list_part_map_.set_refactored(list_part_array_.at(i).key_, &list_part_array_.at(i)))) { LOG_WARN("fail to set value", K(ret)); } } if (OB_SUCC(ret)) { if (0 == list_part_array_.count() && OB_FAIL(list_part_map_.init())) { LOG_WARN("fail to init list_part_map_", K(ret)); } else if (UNKNOWN_FAST_CALC == fast_calc_part_opt_) { fast_calc_part_opt_ = CAN_FAST_CALC; if (OB_FAIL(init_fast_calc_info())) { LOG_WARN("fail to init fast calc info, ignore error", K(ret)); ret = OB_SUCCESS; fast_calc_part_opt_ = CANNOT_FAST_CALC; } } } return ret; } int ObTableLocation::init_fast_calc_info() { int ret = OB_SUCCESS; bool insert_or_replace = is_simple_insert_or_replace(); if (insert_or_replace) { if (1 != key_exprs_.count() || OB_ISNULL(key_exprs_.at(0)) || 1 != key_exprs_.at(0)->get_expr_items().count() || 1 != key_conv_exprs_.count() || OB_ISNULL(key_conv_exprs_.at(0)) || 6 != key_conv_exprs_.at(0)->get_expr_items().count()) { ret = OB_INVALID_ARGUMENT; LOG_WARN( "param is not expected as judge can do fast optimizaion", K(key_exprs_.count()), K(key_conv_exprs_.count())); } else { const ObPostExprItem& key_item = key_exprs_.at(0)->get_expr_items().at(0); const ObPostExprItem& key_cvt_item = key_conv_exprs_.at(0)->get_expr_items().at(5); if (T_QUESTIONMARK == key_item.get_item_type()) { const ObObj* obj = NULL; int64_t param_idx = -1; if (OB_FAIL(key_item.get_obj().get_unknown(param_idx))) { LOG_WARN("fail to get unknown", K(ret), K(key_item.get_obj())); } else if (OB_FAIL(part_expr_param_idxs_.push_back(param_idx))) { LOG_WARN("fail to init parat expr param idx", K(ret)); } } } } else { const ObPLQueryRangeNode* calc_node2 = static_cast(calc_node_); if (OB_ISNULL(calc_node2) || OB_ISNULL(calc_node2->pre_query_range_.get_table_grapth().key_part_head_) || OB_ISNULL(calc_node2->pre_query_range_.get_table_grapth().key_part_head_->normal_keypart_)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("unexpected null ptr", K(ret), K(calc_node2)); } else { const ObQueryRange& query_range = calc_node2->pre_query_range_; ObObj result = query_range.get_table_grapth().key_part_head_->normal_keypart_->start_; if (result.is_unknown()) { int64_t param_idx = -1; if (OB_FAIL(result.get_unknown(param_idx))) { LOG_WARN("fail to get unknown", K(ret), K(result)); } else if (OB_FAIL(part_expr_param_idxs_.push_back(param_idx))) { LOG_WARN("fail to init parat expr param idx", K(ret)); } } } } return ret; } int ObTableLocation::ob_write_row_with_cast_timestamp_ltz(common::ObIAllocator& allocator, const ObNewRow& src, ObNewRow& dst, const common::ObPartitionKeyInfo& part_key_info, const common::ObTimeZoneInfo* tz_info) { int ret = OB_SUCCESS; void* ptr1 = NULL; void* ptr2 = NULL; if (src.count_ <= 0) { dst.count_ = src.count_; dst.cells_ = NULL; dst.projector_size_ = 0; dst.projector_ = NULL; } else if (OB_UNLIKELY(part_key_info.get_size() != src.count_)) { ret = OB_ERR_UNEXPECTED; LOG_ERROR("part_key_info's size is not equal to ObNewRow", "size1", part_key_info.get_size(), "size2", src.count_, K(part_key_info), K(src), K(ret)); } else if (OB_ISNULL(ptr1 = allocator.alloc(sizeof(ObObj) * src.count_))) { ret = OB_ALLOCATE_MEMORY_FAILED; LOG_ERROR("out of memory"); } else if (NULL != src.projector_ && OB_ISNULL(ptr2 = allocator.alloc(sizeof(int32_t) * src.projector_size_))) { ret = OB_ALLOCATE_MEMORY_FAILED; LOG_ERROR("out of memory"); } else { if (NULL != src.projector_) { MEMCPY(ptr2, src.projector_, sizeof(int32_t) * src.projector_size_); } ObObj* objs = new (ptr1) ObObj[src.count_](); const ObRowkeyColumn* tmp_column = NULL; for (int64_t i = 0; OB_SUCC(ret) && i < src.count_; ++i) { const ObObj& cell = src.cells_[i]; if (OB_ISNULL(tmp_column = part_key_info.get_column(i))) { ret = OB_ERR_UNEXPECTED; LOG_WARN("get_column failed", K(part_key_info), K(i), K(ret)); } else if (tmp_column->get_meta_type().is_timestamp_ltz() && cell.is_timestamp_tz()) { ObOTimestampData tmp_otd; if (OB_FAIL(ObTimeConverter::otimestamp_to_otimestamp( ObTimestampTZType, cell.get_otimestamp_value(), tz_info, ObTimestampLTZType, tmp_otd))) { LOG_WARN("failed to otimestamp_to_otimestamp", KPC(tz_info), K(cell), K(ret)); } else { objs[i].set_otimestamp_value(ObTimestampLTZType, tmp_otd); } } else { if (OB_FAIL(ob_write_obj(allocator, src.cells_[i], objs[i]))) { _OB_LOG(WARN, "copy ObObj error, row=%s, i=%ld, ret=%d", to_cstring(src.cells_[i]), i, ret); } } } if (OB_SUCC(ret)) { dst.count_ = src.count_; dst.cells_ = objs; dst.projector_size_ = src.projector_size_; dst.projector_ = (NULL != src.projector_) ? static_cast(ptr2) : NULL; } } if (OB_FAIL(ret)) { if (NULL != ptr1) { allocator.free(ptr1); ptr1 = NULL; } if (NULL != ptr2) { allocator.free(ptr2); ptr2 = NULL; } } return ret; } int ObTableLocation::get_location_type(const common::ObAddr& server, const ObPhyPartitionLocationInfoIArray& phy_part_loc_info_list, ObTableLocationType& location_type) { int ret = OB_SUCCESS; location_type = OB_TBL_LOCATION_UNINITIALIZED; if (0 == phy_part_loc_info_list.count()) { location_type = OB_TBL_LOCATION_LOCAL; } else if (1 == phy_part_loc_info_list.count()) { share::ObReplicaLocation replica_location; if (OB_FAIL(phy_part_loc_info_list.at(0).get_selected_replica(replica_location))) { LOG_WARN("fail to get selected replica", K(phy_part_loc_info_list.at(0))); } else if (!replica_location.is_valid()) { ret = OB_ERR_UNEXPECTED; LOG_ERROR("replica location is invalid", K(ret), K(replica_location)); } else { location_type = ((server == replica_location.server_) ? OB_TBL_LOCATION_LOCAL : OB_TBL_LOCATION_REMOTE); } } else { location_type = OB_TBL_LOCATION_DISTRIBUTED; } return ret; } int ObTableLocation::get_vt_partition_id( ObExecContext& exec_ctx, const uint64_t ref_table_id, ObIArray* partition_ids, int64_t* fake_id) { int ret = OB_SUCCESS; ObTaskExecutorCtx* task_exec_ctx = exec_ctx.get_task_executor_ctx(); share::ObIPartitionLocationCache* partition_location_cache = NULL; ObSEArray part_location_list; const int64_t expire_renew_time = 0; bool is_cache_hit = false; if (NULL == task_exec_ctx) { ret = OB_NOT_INIT; LOG_WARN("Task exec context should not be NULL", K(ret)); } else if (!is_virtual_table(ref_table_id)) { ret = OB_INVALID_ARGUMENT; LOG_WARN("Get virtual table partition, ref_table_id should be virtual table", K(ret)); } else if (NULL == (partition_location_cache = task_exec_ctx->get_partition_location_cache())) { ret = OB_NOT_INIT; LOG_WARN("partition_location_cache not inited", K(ret)); } else if (OB_FAIL( partition_location_cache->get(ref_table_id, part_location_list, expire_renew_time, is_cache_hit))) { LOG_WARN("fail get virtual_table location", K(ref_table_id)); } else { common::ObAddr self_addr = exec_ctx.get_addr(); common::ObAddr addr; bool find_local = false; ObPartitionLocation partition_location; for (int64_t i = 0; OB_SUCC(ret) && i < part_location_list.count(); i++) { int64_t partition_id = 0; if (OB_FAIL(part_location_list.at(i, partition_location))) { LOG_WARN("fail to get partition location", K(part_location_list), K(i)); } else if (partition_location.get_replica_locations().count() != 1) { ret = OB_ERR_UNEXPECTED; LOG_WARN("virtual table replication count must be 1", K(partition_location.get_partition_cnt())); } else { addr = partition_location.get_replica_locations().at(0).server_; if (OB_FAIL(task_exec_ctx->calc_virtual_partition_id(ref_table_id, addr, partition_id))) { LOG_WARN("Failed to calc virtual partition id", K(addr), K(ret)); } else if (OB_INVALID_PARTITION_ID == partition_id) { // ignore invalid partition id } else if (NULL != partition_ids && OB_FAIL(partition_ids->push_back(partition_id))) { LOG_WARN("Push partition id to partition ids error", "partition id", partition_id, K(ret)); } else if (NULL != fake_id && !find_local) { *fake_id = partition_id; if (addr == self_addr) { find_local = true; if (NULL == partition_ids) { break; } } } else { // do nothing } } } // end of for } if (OB_SUCCESS == ret && NULL != partition_ids && 0 == partition_ids->count()) { ret = OB_ERR_UNEXPECTED; LOG_USER_ERROR(OB_ERR_UNEXPECTED, "No server servers the virtual table"); } return ret; } ObTableLocation::ObTableLocation(const ObTableLocation& other) : inner_allocator_(ObModIds::OB_SQL_TABLE_LOCATION), allocator_(inner_allocator_), calc_node_(NULL), gen_col_node_(NULL), subcalc_node_(NULL), sub_gen_col_node_(NULL), sql_expression_factory_(allocator_), expr_op_factory_(allocator_), part_expr_(NULL), gen_col_expr_(NULL), subpart_expr_(NULL), sub_gen_col_expr_(NULL), first_partition_id_(-1), part_projector_(inner_allocator_, sql_expression_factory_, expr_op_factory_), range_obj_arr_(NULL), range_part_id_arr_(NULL) { *this = other; } ObTableLocation& ObTableLocation::operator=(const ObTableLocation& other) { int ret = OB_SUCCESS; if (this != &other) { reset(); inited_ = other.inited_; table_id_ = other.table_id_; ref_table_id_ = other.ref_table_id_; is_partitioned_ = other.is_partitioned_; part_level_ = other.part_level_; part_type_ = other.part_type_; subpart_type_ = other.subpart_type_; part_get_all_ = other.part_get_all_; subpart_get_all_ = other.subpart_get_all_; is_col_part_expr_ = other.is_col_part_expr_; is_col_subpart_expr_ = other.is_col_subpart_expr_; is_oracle_temp_table_ = other.is_oracle_temp_table_; tablet_size_ = other.tablet_size_; index_table_id_ = other.index_table_id_; part_col_type_ = other.part_col_type_; part_collation_type_ = other.part_collation_type_; subpart_col_type_ = other.subpart_col_type_; subpart_collation_type_ = other.subpart_collation_type_; is_in_hit_ = other.is_in_hit_; first_partition_id_ = other.first_partition_id_; is_global_index_ = other.is_global_index_; related_part_expr_idx_ = other.related_part_expr_idx_; related_subpart_expr_idx_ = other.related_subpart_expr_idx_; use_list_part_map_ = other.use_list_part_map_; list_default_part_id_ = other.list_default_part_id_; use_hash_part_opt_ = other.use_hash_part_opt_; use_range_part_opt_ = other.use_range_part_opt_; fast_calc_part_opt_ = other.fast_calc_part_opt_; duplicate_type_ = other.duplicate_type_; first_part_num_ = other.first_part_num_; partition_num_ = other.partition_num_; part_num_ = other.part_num_; direction_ = other.direction_; simple_insert_ = other.simple_insert_; stmt_type_ = other.stmt_type_; literal_stmt_type_ = other.literal_stmt_type_; hint_read_consistency_ = other.hint_read_consistency_; is_contain_inner_table_ = other.is_contain_inner_table_; is_contain_select_for_update_ = other.is_contain_select_for_update_; is_contain_mv_ = other.is_contain_mv_; use_calc_part_by_rowid_ = other.use_calc_part_by_rowid_; is_valid_range_columns_part_range_ = other.is_valid_range_columns_part_range_; is_valid_range_columns_subpart_range_ = other.is_valid_range_columns_subpart_range_; report_err_for_pruned_partition_not_exist_ = other.report_err_for_pruned_partition_not_exist_; is_valid_temporal_part_range_ = other.is_valid_temporal_part_range_; is_valid_temporal_subpart_range_ = other.is_valid_temporal_subpart_range_; params_ = other.params_; for (int64_t i = 0; OB_SUCC(ret) && i < other.list_part_array_.count(); i++) { ObListPartMapValue value; value.part_id_ = other.list_part_array_.at(i).part_id_; if (OB_FAIL(ob_write_row(allocator_, other.list_part_array_.at(i).key_.row_, value.key_.row_))) { LOG_WARN("fail to write row", K(ret)); } else if (OB_FAIL(list_part_array_.push_back(value))) { LOG_WARN("fail to push back value", K(ret)); } } for (int64_t i = 0; OB_SUCC(ret) && i < list_part_array_.count(); i++) { if (OB_FAIL(list_part_map_.set_refactored(list_part_array_.at(i).key_, &list_part_array_.at(i)))) { LOG_WARN("fail to set value", K(ret)); } } if (OB_SUCC(ret) && use_list_part_map_ && 0 == list_part_array_.count()) { if (OB_FAIL(list_part_map_.init())) { LOG_WARN("fail to init list_part_map_", K(ret)); } LOG_TRACE("init list_part_map for single default value partition", K(ret)); } for (int64_t i = 0; OB_SUCC(ret) && i < other.hash_part_array_.count(); i++) { ObHashPartMapValue value; value.part_id_ = other.hash_part_array_.at(i).part_id_; if (FALSE_IT(value.key_.part_idx_ = other.hash_part_array_.at(i).key_.part_idx_)) { } else if (OB_FAIL(hash_part_array_.push_back(value))) { LOG_WARN("fail to push back value", K(ret)); } } for (int64_t i = 0; OB_SUCC(ret) && i < hash_part_array_.count(); i++) { if (OB_FAIL(hash_part_map_.set_refactored(hash_part_array_.at(i).key_, &hash_part_array_.at(i)))) { LOG_WARN("fail to set value", K(ret)); } } if (OB_SUCC(ret)) { part_expr_param_idxs_ = other.part_expr_param_idxs_; } if (OB_SUCC(ret) && OB_NOT_NULL(other.range_obj_arr_)) { void* ptr1 = NULL; if (OB_ISNULL(ptr1 = allocator_.alloc(sizeof(ObObj) * partition_num_))) { ret = OB_ALLOCATE_MEMORY_FAILED; LOG_WARN("failed to allocate memory", K(ret), K(partition_num_)); } else { range_obj_arr_ = new (ptr1) ObObj[partition_num_](); } for (int64_t i = 0; OB_SUCC(ret) && i < partition_num_; i++) { if (OB_FAIL(ob_write_obj(allocator_, other.range_obj_arr_[i], range_obj_arr_[i]))) { LOG_WARN("failed to write obj", K(ret), K(i)); } } } if (OB_SUCC(ret) && OB_NOT_NULL(other.range_part_id_arr_)) { void* ptr1 = NULL; if (OB_ISNULL(ptr1 = allocator_.alloc(sizeof(int64_t) * partition_num_))) { ret = OB_ALLOCATE_MEMORY_FAILED; LOG_WARN("failed to allocate memory", K(ret), K(partition_num_)); } else { range_part_id_arr_ = static_cast(ptr1); } for (int64_t i = 0; OB_SUCC(ret) && i < partition_num_; i++) { range_part_id_arr_[i] = other.range_part_id_arr_[i]; } } if (OB_SUCC(ret)) { if (NULL != other.calc_node_) { if (OB_FAIL(other.calc_node_->deep_copy(allocator_, calc_nodes_, calc_node_))) { LOG_WARN("Failed to deep copy node", K(ret)); } } } if (OB_SUCC(ret)) { if (NULL != other.part_expr_) { if (ObSqlExpressionUtil::copy_sql_expression(sql_expression_factory_, other.part_expr_, part_expr_)) { LOG_WARN("Failed to copy part expr", K(ret)); } } } if (OB_SUCC(ret)) { if (NULL != other.gen_col_node_) { if (OB_FAIL(other.gen_col_node_->deep_copy(allocator_, calc_nodes_, gen_col_node_))) { LOG_WARN("Failed to deep copy node", K(ret)); } } } if (OB_SUCC(ret)) { if (NULL != other.gen_col_expr_) { if (ObSqlExpressionUtil::copy_sql_expression(sql_expression_factory_, other.gen_col_expr_, gen_col_expr_)) { LOG_WARN("Failed to copy part expr", K(ret)); } } } if (OB_SUCC(ret)) { if (NULL != other.subpart_expr_) { if (OB_FAIL(ObSqlExpressionUtil::copy_sql_expression( sql_expression_factory_, other.subpart_expr_, subpart_expr_))) { LOG_WARN("Failed to sub part expr", K(ret)); } } } if (OB_SUCC(ret)) { if (NULL != other.subcalc_node_) { if (OB_FAIL(other.subcalc_node_->deep_copy(allocator_, calc_nodes_, subcalc_node_))) { LOG_WARN("Failed to deep copy node", K(ret)); } } } if (OB_SUCC(ret)) { if (NULL != other.sub_gen_col_node_) { if (OB_FAIL(other.sub_gen_col_node_->deep_copy(allocator_, calc_nodes_, sub_gen_col_node_))) { LOG_WARN("Failed to deep copy node", K(ret)); } } } if (OB_SUCC(ret)) { if (NULL != other.sub_gen_col_expr_) { if (ObSqlExpressionUtil::copy_sql_expression( sql_expression_factory_, other.sub_gen_col_expr_, sub_gen_col_expr_)) { LOG_WARN("Failed to copy part expr", K(ret)); } } } if (OB_SUCC(ret) && is_partitioned_) { if (OB_FAIL(ObSqlExpressionUtil::copy_sql_expressions(sql_expression_factory_, other.key_exprs_, key_exprs_))) { LOG_WARN("Failed to copy key exprs", K(ret)); } else if (OB_FAIL(ObSqlExpressionUtil::copy_sql_expressions( sql_expression_factory_, other.subkey_exprs_, subkey_exprs_))) { LOG_WARN("Failed to copy sub key exprs", K(ret)); } else if (OB_FAIL(ObSqlExpressionUtil::copy_sql_expressions( sql_expression_factory_, other.key_conv_exprs_, key_conv_exprs_))) { LOG_WARN("Failed to copy key conv exprs", K(ret)); } else if (OB_FAIL(ObSqlExpressionUtil::copy_sql_expressions( sql_expression_factory_, other.subkey_conv_exprs_, subkey_conv_exprs_))) { LOG_WARN("Failed to copy subkey conv exprs", K(ret)); } else if (OB_FAIL(part_projector_.deep_copy(other.part_projector_))) { LOG_WARN("deep copy part projector failed", K(ret)); } else { num_values_ = other.num_values_; } } if (OB_FAIL(part_hint_ids_.assign(other.part_hint_ids_))) { LOG_WARN("Failed to assign part hint ids", K(ret)); } } if (OB_FAIL(ret)) { inited_ = false; } return *this; } void ObTableLocation::reset() { inited_ = false; table_id_ = OB_INVALID_ID; ref_table_id_ = OB_INVALID_ID; is_partitioned_ = true; part_level_ = PARTITION_LEVEL_ZERO; part_type_ = PARTITION_FUNC_TYPE_MAX; subpart_type_ = share::schema::PARTITION_FUNC_TYPE_MAX; part_get_all_ = false; subpart_get_all_ = false; is_col_part_expr_ = false; is_col_subpart_expr_ = false; is_oracle_temp_table_ = false; tablet_size_ = common::OB_DEFAULT_TABLET_SIZE; calc_node_ = NULL; gen_col_node_ = NULL; subcalc_node_ = NULL; sub_gen_col_node_ = NULL; for (int64_t idx = 0; idx < calc_nodes_.count(); ++idx) { if (NULL != calc_nodes_.at(idx)) { calc_nodes_.at(idx)->~ObPartLocCalcNode(); } } calc_nodes_.reset(); sql_expression_factory_.destroy(); expr_op_factory_.destroy(); part_expr_ = NULL; gen_col_expr_ = NULL; subpart_expr_ = NULL; sub_gen_col_expr_ = NULL; simple_insert_ = false; stmt_type_ = stmt::T_NONE; literal_stmt_type_ = stmt::T_NONE; hint_read_consistency_ = INVALID_CONSISTENCY; is_contain_inner_table_ = false; is_contain_select_for_update_ = false; is_contain_mv_ = false; key_exprs_.reset(); subkey_exprs_.reset(); num_values_ = 0; key_conv_exprs_.reset(); subkey_conv_exprs_.reset(); part_hint_ids_.reset(); part_num_ = 1; direction_ = MAX_DIR; index_table_id_ = OB_INVALID_ID; inner_allocator_.reset(); part_collation_type_ = CS_TYPE_INVALID; subpart_col_type_ = ObNullType; subpart_collation_type_ = CS_TYPE_INVALID; first_partition_id_ = -1; is_in_hit_ = false; part_projector_.reset(); is_global_index_ = false; related_part_expr_idx_ = OB_INVALID_INDEX; related_subpart_expr_idx_ = OB_INVALID_INDEX; use_list_part_map_ = false; list_default_part_id_ = OB_INVALID_ID; use_hash_part_opt_ = false; use_range_part_opt_ = false; fast_calc_part_opt_ = NONE_FAST_CALC; duplicate_type_ = ObDuplicateType::NOT_DUPLICATE; first_part_num_ = 1; partition_num_ = 1; range_obj_arr_ = NULL; range_part_id_arr_ = NULL; list_part_map_.clear(); list_part_array_.reset(); hash_part_map_.clear(); hash_part_array_.reset(); part_expr_param_idxs_.reset(); is_valid_range_columns_part_range_ = false; is_valid_range_columns_subpart_range_ = false; is_valid_temporal_part_range_ = false; is_valid_temporal_subpart_range_ = false; params_ = NULL; } int ObTableLocation::init_table_location(ObSqlSchemaGuard& schema_guard, uint64_t table_id, uint64_t ref_table_id, ObDMLStmt& stmt, const RowDesc& row_desc, const bool is_dml_table, /*whether the ref_table is modified*/ const ObOrderDirection& direction) { int ret = OB_SUCCESS; const ObTableSchema* table_schema = NULL; const ObRawExpr* part_raw_expr = NULL; RowDesc loc_row_desc; table_id_ = table_id; ref_table_id_ = ref_table_id; stmt_type_ = stmt.get_stmt_type(); literal_stmt_type_ = stmt.get_literal_stmt_type(); hint_read_consistency_ = stmt.get_stmt_hint().get_query_hint().read_consistency_; is_partitioned_ = true; direction_ = direction; if (OB_ISNULL(stmt.get_query_ctx())) { ret = OB_ERR_UNEXPECTED; LOG_WARN("stmt query ctx is null"); } else { is_contain_inner_table_ = stmt.get_query_ctx()->is_contain_inner_table_; is_contain_select_for_update_ = stmt.get_query_ctx()->is_contain_select_for_update_; is_contain_mv_ = stmt.get_query_ctx()->is_contain_mv_; if (stmt.is_insert_stmt()) { set_simple_insert_or_replace(); report_err_for_pruned_partition_not_exist_ = true; } } if (OB_FAIL(ret)) { // do nothing } else if (OB_FAIL(schema_guard.get_table_schema(ref_table_id_, table_schema))) { LOG_WARN("get table schema failed", K(ref_table_id_), K(ret)); } else if (OB_ISNULL(table_schema)) { ret = OB_TABLE_NOT_EXIST; LOG_WARN("table not exist", K(ref_table_id_)); } else if (PARTITION_LEVEL_ZERO == (part_level_ = table_schema->get_part_level())) { is_partitioned_ = false; // Non-partitioned table, do not need to calc partition id } else if (PARTITION_LEVEL_ONE != part_level_ && PARTITION_LEVEL_TWO != part_level_) { ret = OB_ERR_UNEXPECTED; LOG_WARN("Partition level only support PARTITION_LEVEL_ONE or PARTITION_LEVEL_TWO", K(ret), K(part_level_)); } else if (FALSE_IT(is_oracle_temp_table_ = table_schema->is_oracle_tmp_table())) { } else if (OB_UNLIKELY( PARTITION_FUNC_TYPE_MAX <= (part_type_ = table_schema->get_part_option().get_part_func_type()))) { ret = OB_SCHEMA_ERROR; LOG_WARN("Part func type error", K(ret), K(ref_table_id_), K(part_type_)); } else if (OB_UNLIKELY(PARTITION_FUNC_TYPE_MAX <= (subpart_type_ = table_schema->get_sub_part_option().get_part_func_type()))) { ret = OB_SCHEMA_ERROR; LOG_WARN("Part func type error", K(ret), K(ref_table_id_), K(subpart_type_)); } else if (0 >= (part_num_ = table_schema->get_part_option().get_part_num())) { ret = OB_SCHEMA_ERROR; LOG_WARN("partitioned virtual table's part num should > 0", K(ret), K(part_num_)); } else if (OB_FAIL(loc_row_desc.init())) { LOG_WARN("init loc row desc failed", K(ret)); } else if (OB_FAIL(loc_row_desc.assign(row_desc))) { LOG_WARN("assign location row desc failed", K(ret)); } else { if (OB_ISNULL(part_raw_expr = get_related_part_expr(stmt, PARTITION_LEVEL_ONE, table_id, ref_table_id_))) { ret = OB_ERR_UNEXPECTED; LOG_WARN("partition expr is null", K(table_id), K(ref_table_id_)); } else if (PARTITION_FUNC_TYPE_RANGE_COLUMNS == part_type_ && OB_FAIL(can_get_part_by_range_for_range_columns(part_raw_expr, is_valid_range_columns_part_range_))) { LOG_WARN("failed ot check can get part by range for range columns", K(ret)); } else if (OB_FAIL(can_get_part_by_range_for_temporal_column(part_raw_expr, is_valid_temporal_part_range_))) { LOG_WARN("failed to check can get part by range for temporal column", K(ret)); } else if (FALSE_IT(is_col_part_expr_ = part_raw_expr->is_column_ref_expr())) { // never reach } else if (OB_FAIL(ObExprGeneratorImpl::gen_expression_with_row_desc( sql_expression_factory_, expr_op_factory_, loc_row_desc, part_raw_expr, part_expr_))) { LOG_WARN("gen expression with row desc failed", K(ret)); } else if (PARTITION_FUNC_TYPE_RANGE_COLUMNS == part_type_ || PARTITION_FUNC_TYPE_LIST_COLUMNS == part_type_) { if (OB_FAIL(part_projector_.init_part_projector(part_raw_expr, loc_row_desc))) { LOG_WARN("init part projector failed", K(ret)); } } else { LOG_TRACE("generated part expression", K(*part_raw_expr), K(*part_expr_)); } } if (OB_SUCC(ret)) { is_global_index_ = table_schema->is_global_index_table(); if (ObDuplicateScope::DUPLICATE_SCOPE_NONE != table_schema->get_duplicate_scope()) { duplicate_type_ = is_dml_table ? ObDuplicateType::DUPLICATE_IN_DML : ObDuplicateType::DUPLICATE; } else { duplicate_type_ = ObDuplicateType::NOT_DUPLICATE; } } if (OB_SUCC(ret) && PARTITION_LEVEL_TWO == table_schema->get_part_level()) { const ObRawExpr* subpart_raw_expr = NULL; if (OB_UNLIKELY( NULL == (subpart_raw_expr = get_related_part_expr(stmt, PARTITION_LEVEL_TWO, table_id_, ref_table_id_)))) { ret = OB_ERR_UNEXPECTED; LOG_WARN("sub partition expr not in stmt", K(ret), K(table_id_), K(ref_table_id_)); } else if (PARTITION_FUNC_TYPE_RANGE_COLUMNS == subpart_type_ && OB_FAIL( can_get_part_by_range_for_range_columns(subpart_raw_expr, is_valid_range_columns_subpart_range_))) { LOG_WARN("failed to check can get part by range for range columns", K(ret)); } else if (OB_FAIL(can_get_part_by_range_for_temporal_column(subpart_raw_expr, is_valid_temporal_subpart_range_))) { LOG_WARN("failed to check can get part by range for temporal column", K(ret)); } else if (OB_FAIL(ObExprGeneratorImpl::gen_expression_with_row_desc( sql_expression_factory_, expr_op_factory_, loc_row_desc, subpart_raw_expr, subpart_expr_))) { LOG_WARN("gen expression with row desc failed", K(ret)); } else if (PARTITION_FUNC_TYPE_RANGE_COLUMNS == subpart_type_ || PARTITION_FUNC_TYPE_LIST_COLUMNS == subpart_type_) { if (OB_FAIL(part_projector_.init_subpart_projector(subpart_raw_expr, loc_row_desc))) { LOG_WARN("init subpart projector failed", K(ret)); } } } if (OB_SUCC(ret)) { part_projector_.set_column_cnt(loc_row_desc.get_column_num()); bool check_dropped_schema = false; ObTablePartitionKeyIter iter(*table_schema, check_dropped_schema); int64_t partition_id = -1; if (OB_FAIL(iter.next_partition_id_v2(partition_id))) { // OB_ITER_END is unexpected too LOG_WARN("iter failed", K(table_id), K(ret)); } else if (-1 == partition_id) { ret = OB_ERR_UNEXPECTED; LOG_WARN("NULL ptr", K(table_id), K(ret)); } else { first_partition_id_ = partition_id; inited_ = true; } } return ret; } int ObTableLocation::init_table_location_with_rowkey(ObSqlSchemaGuard &schema_guard, uint64_t table_id, ObSQLSessionInfo &session_info, const bool is_dml_table /*= true*/) { int ret = OB_SUCCESS; ObSchemaChecker schema_checker; const ObTableSchema* table_schema = NULL; if (OB_FAIL(schema_checker.init(schema_guard))) { LOG_WARN("fail to init schema_checker", K(ret)); } else if (OB_FAIL(schema_checker.get_table_schema(table_id, table_schema))) { LOG_WARN("get table schema failed", K(table_id), K(ret)); } else if (OB_ISNULL(table_schema)) { ret = OB_TABLE_NOT_EXIST; LOG_WARN("table not exist", K(table_id)); } else if (table_schema->get_part_level() != PARTITION_LEVEL_ZERO && table_schema->is_old_no_pk_table()) { ret = OB_NOT_SUPPORTED; LOG_WARN("init table location with rowkey by hidden primary key partition table not supported"); } else { uint64_t real_table_id = table_schema->is_index_local_storage() ? table_schema->get_data_table_id() : table_id; ObResolverParams resolver_ctx; ObRawExprFactory expr_factory(allocator_); ObStmtFactory stmt_factory(allocator_); TableItem table_item; resolver_ctx.allocator_ = &allocator_; resolver_ctx.schema_checker_ = &schema_checker; resolver_ctx.session_info_ = &session_info; resolver_ctx.disable_privilege_check_ = PRIV_CHECK_FLAG_DISABLE; resolver_ctx.expr_factory_ = &expr_factory; resolver_ctx.stmt_factory_ = &stmt_factory; resolver_ctx.query_ctx_ = stmt_factory.get_query_ctx(); table_item.table_id_ = real_table_id; table_item.ref_id_ = real_table_id; table_item.type_ = TableItem::BASE_TABLE; RowDesc row_desc; ObDeleteResolver delete_resolver(resolver_ctx); ObDeleteStmt* delete_stmt = delete_resolver.create_stmt(); const ObTableSchema* real_table_schema = table_schema; if (OB_ISNULL(resolver_ctx.query_ctx_) || OB_ISNULL(delete_stmt)) { ret = OB_ALLOCATE_MEMORY_FAILED; LOG_WARN("create query_ctx or delete stmt failed", K_(resolver_ctx.query_ctx), K(delete_stmt)); } else if (OB_FAIL(delete_stmt->get_table_items().push_back(&table_item))) { LOG_WARN("store table item failed", K(ret)); } else if (OB_FAIL(delete_stmt->set_table_bit_index(real_table_id))) { LOG_WARN("set table bit index failed", K(ret), K(real_table_id)); } else if (OB_UNLIKELY(table_schema->is_index_local_storage()) && OB_FAIL(schema_guard.get_table_schema(real_table_id, real_table_schema))) { LOG_WARN("get real table schema failed", K(ret), K(real_table_id)); } else if (OB_FAIL(delete_resolver.resolve_table_partition_expr(table_item, *real_table_schema))) { LOG_WARN("resolve table partition expr failed", K(ret)); } else if (OB_FAIL(generate_rowkey_desc( *delete_stmt, table_schema->get_rowkey_info(), real_table_id, expr_factory, row_desc))) { LOG_WARN("generate rowkey desc failed", K(ret), K(real_table_id)); } else if (OB_FAIL(init_table_location(schema_guard, real_table_id, real_table_id, *delete_stmt, row_desc, is_dml_table, default_asc_direction()))) { LOG_WARN("init table location failed", K(ret), K(real_table_id)); } else if (OB_FAIL(clear_columnlized_in_row_desc(row_desc))) { LOG_WARN("Failed to clear columnlized in row desc", K(ret)); } } return ret; } int ObTableLocation::init(const ObTableSchema* table_schema, ObDMLStmt& stmt, ObSQLSessionInfo* session_info, const ObIArray& filter_exprs, const uint64_t table_id, const uint64_t ref_table_id, const ObPartHint* part_hint, const ObDataTypeCastParams& dtc_params, const bool is_dml_table, /*whether the ref_table is modified*/ common::ObIArray* sort_exprs, const ParamStore *params) { int ret = OB_SUCCESS; table_id_ = table_id; ref_table_id_ = ref_table_id; stmt_type_ = stmt.get_stmt_type(); literal_stmt_type_ = stmt.get_literal_stmt_type(); hint_read_consistency_ = stmt.get_stmt_hint().get_query_hint().read_consistency_; is_contain_inner_table_ = stmt.get_query_ctx()->is_contain_inner_table_; is_contain_select_for_update_ = stmt.get_query_ctx()->is_contain_select_for_update_; is_contain_mv_ = stmt.get_query_ctx()->is_contain_mv_; is_partitioned_ = true; params_ = params; // direction_ = direction; if (stmt.is_insert_stmt()) { report_err_for_pruned_partition_not_exist_ = true; } if (OB_UNLIKELY(inited_)) { ret = OB_INIT_TWICE; LOG_ERROR("table location init twice", K(ret)); } else if (OB_INVALID_ID == table_id || OB_INVALID_ID == ref_table_id || OB_ISNULL(table_schema)) { ret = OB_INVALID_ARGUMENT; LOG_WARN("Input arguments error", K(table_id), K(ref_table_id), K(ret)); } else if (PARTITION_LEVEL_ZERO == (part_level_ = table_schema->get_part_level())) { is_partitioned_ = false; // Non-partitioned table, do not need to calc partition id } else if (PARTITION_LEVEL_ONE != part_level_ && PARTITION_LEVEL_TWO != part_level_) { ret = OB_ERR_UNEXPECTED; LOG_WARN("Partition level only support PARTITION_LEVEL_ONE or PARTITION_LEVEL_TWO", K(ret), K(part_level_)); } else if (FALSE_IT(is_oracle_temp_table_ = table_schema->is_oracle_tmp_table())) { } else if (OB_UNLIKELY( PARTITION_FUNC_TYPE_MAX <= (part_type_ = table_schema->get_part_option().get_part_func_type()))) { ret = OB_SCHEMA_ERROR; LOG_WARN("Part func type error", K(ret), K(ref_table_id_), K(part_type_)); } else if (OB_UNLIKELY(PARTITION_FUNC_TYPE_MAX <= (subpart_type_ = table_schema->get_sub_part_option().get_part_func_type()))) { ret = OB_SCHEMA_ERROR; LOG_WARN("Part func type error", K(ret), K(ref_table_id_), K(subpart_type_)); } else if (0 >= (part_num_ = table_schema->get_part_option().get_part_num())) { ret = OB_SCHEMA_ERROR; LOG_WARN("partitioned virtual table's part num should > 0", K(ret), K(part_num_)); } else if (stmt.is_insert_stmt() && !static_cast(stmt).value_from_select()) { set_simple_insert_or_replace(); if (OB_FAIL(record_insert_partition_info(stmt, table_schema, session_info))) { LOG_WARN("Fail to record insert stmt partition info", K(stmt_type_), K(ret)); } } else if (0 >= (tablet_size_ = table_schema->get_tablet_size())) { ret = OB_SCHEMA_ERROR; LOG_WARN("table's tablet_size should > 0", K(ret), K(tablet_size_)); } else { is_in_hit_ = false; if (OB_FAIL(record_in_dml_partition_info(stmt, filter_exprs, is_in_hit_, table_schema))) { // for in filter LOG_WARN("fail to record_in_dml_partition_info", K(ret)); } else if (!is_in_hit_) { if (OB_FAIL(record_not_insert_dml_partition_info(stmt, table_schema, filter_exprs, dtc_params))) { LOG_WARN("Fail to record select or update partition info", K(stmt_type_), K(ret)); } else if (OB_FAIL(get_not_insert_dml_part_sort_expr(stmt, sort_exprs))) { LOG_WARN("Failed to get not insert dml sort key with parts", K(ret)); } else { } } } if (OB_SUCC(ret)) { is_global_index_ = table_schema->is_global_index_table(); bool check_dropped_schema = false; ObTablePartitionKeyIter iter(*table_schema, check_dropped_schema); int64_t partition_id = -1; if (OB_FAIL(iter.next_partition_id_v2(partition_id))) { // OB_ITER_END is unexpected too LOG_WARN("iter failed", K(table_id), K(ref_table_id), K(ret)); } else if (-1 == partition_id) { ret = OB_ERR_UNEXPECTED; LOG_WARN("NULL ptr", K(table_id), K(ref_table_id), K(ret)); } else { first_partition_id_ = partition_id; } } if (OB_SUCC(ret) && PARTITION_LEVEL_ONE == part_level_) { if (table_schema->is_list_part()) { if (OB_FAIL(add_list_part_schema(*table_schema, dtc_params.tz_info_))) { LOG_WARN("fail to add list part schema", K(ret)); } } else if (share::is_oracle_mode() && 1 == table_schema->get_partition_key_column_num() && table_schema->is_user_table()) { if (table_schema->is_hash_part()) { if (OB_FAIL(add_hash_part_schema(*table_schema))) { LOG_WARN("fail to add list part schema", K(ret)); } } else if (table_schema->is_range_part()) { if (OB_FAIL(add_range_part_schema(*table_schema))) { LOG_WARN("fail to add list part schema", K(ret)); } } } } if (OB_SUCC(ret)) { if (ObDuplicateScope::DUPLICATE_SCOPE_NONE != table_schema->get_duplicate_scope()) { duplicate_type_ = is_dml_table ? ObDuplicateType::DUPLICATE_IN_DML : ObDuplicateType::DUPLICATE; } else { duplicate_type_ = ObDuplicateType::NOT_DUPLICATE; } } if (OB_SUCC(ret) && NULL != part_hint) { ret = part_hint_ids_.assign(part_hint->part_ids_); } if (OB_SUCC(ret)) { inited_ = true; } return ret; } int ObTableLocation::get_is_weak_read(ObExecContext& exec_ctx, bool& is_weak_read) const { int ret = OB_SUCCESS; is_weak_read = false; ObSQLSessionInfo* session = exec_ctx.get_my_session(); ObTaskExecutorCtx* task_exec_ctx = exec_ctx.get_task_executor_ctx(); if (OB_ISNULL(session) || OB_ISNULL(task_exec_ctx)) { ret = OB_ERR_UNEXPECTED; LOG_ERROR("unexpeted null", K(ret), K(session), K(task_exec_ctx)); } else { ObConsistencyLevel consistency_level = INVALID_CONSISTENCY; int32_t trans_consistency_level = ObTransConsistencyLevel::UNKNOWN; int32_t trans_consistency_type = ObTransConsistencyType::UNKNOWN; int32_t read_snapshot_type = ObTransReadSnapshotType::UNKNOWN; const bool need_consistent_snapshot = true; if (stmt::T_SELECT == stmt_type_) { if (OB_UNLIKELY(INVALID_CONSISTENCY != hint_read_consistency_)) { consistency_level = hint_read_consistency_; } else { consistency_level = session->get_consistency_level(); } } else { consistency_level = STRONG; } trans_consistency_level = consistency_level; if (OB_FAIL(ObSqlTransControl::decide_trans_read_interface_specs("ObTableLocation::get_is_weak_read", *session, stmt_type_, literal_stmt_type_, is_contain_select_for_update_, is_contain_inner_table_, consistency_level, need_consistent_snapshot, trans_consistency_level, trans_consistency_type, read_snapshot_type))) { LOG_WARN("fail to decide trans read interface specs", K(ret), K(stmt_type_), K(literal_stmt_type_), K(is_contain_select_for_update_), K(is_contain_inner_table_), K(consistency_level), KPC(session)); } else { // check read follower is_weak_read = (ObTransConsistencyType::BOUNDED_STALENESS_READ == trans_consistency_type); } } return ret; } int ObTableLocation::calculate_partition_location_infos(ObExecContext& exec_ctx, common::ObPartMgr* part_mgr, const ParamStore& params, ObIPartitionLocationCache& location_cache, ObPhyPartitionLocationInfoIArray& phy_part_loc_info_list, const ObDataTypeCastParams& dtc_params, bool nonblock /*false*/) const { int ret = OB_SUCCESS; ObSEArray partition_ids; if (!inited_) { ret = OB_NOT_INIT; LOG_WARN("ObTableLocation not inited", K(ret)); } else if (OB_FAIL(calculate_partition_ids(exec_ctx, part_mgr, params, partition_ids, dtc_params))) { LOG_WARN("Failed to calculate partition ids", K(ret)); } else if (OB_FAIL(set_partition_locations( exec_ctx, location_cache, ref_table_id_, partition_ids, phy_part_loc_info_list, nonblock))) { LOG_WARN("Failed to set partition locations", K(ret), K(partition_ids)); } else { } // do nothing return ret; } int ObTableLocation::calculate_partition_ids_by_rowkey(ObSQLSessionInfo& session_info, ObSchemaGetterGuard& schema_guard, uint64_t table_id, const ObIArray& rowkeys, ObIArray& part_ids, ObIArray& rowkey_lists) { int ret = OB_SUCCESS; SMART_VAR(ObExecContext, exec_ctx) { ObSqlSchemaGuard sql_schema_guard; sql_schema_guard.set_schema_guard(&schema_guard); exec_ctx.set_my_session(&session_info); if (OB_UNLIKELY(is_virtual_table(table_id))) { ret = OB_NOT_SUPPORTED; LOG_USER_ERROR(OB_NOT_SUPPORTED, "Calculate virtual table partition id with rowkey"); } else if (OB_UNLIKELY(rowkeys.count() <= 0)) { if (PARTITION_LEVEL_ONE == part_level_) { if (OB_FAIL(get_all_part_ids(exec_ctx, &schema_guard, part_ids))) { LOG_WARN("Failed to get all part ids", K(ret)); } } else if (PARTITION_LEVEL_TWO == part_level_) { ObSEArray tmp_part_ids; if (OB_FAIL(get_all_part_ids(exec_ctx, &schema_guard, tmp_part_ids))) { LOG_WARN("Failed to get all part ids", K(ret)); } else if (OB_FAIL(get_all_part_ids(exec_ctx, &schema_guard, part_ids, &tmp_part_ids))) { LOG_WARN("Failed to get all subpart ids", K(ret)); } else { } } else { ret = OB_ERR_UNEXPECTED; LOG_WARN("Unkown part level", K(ret), K(part_level_), K(is_partitioned_)); } } else if (OB_FAIL(init_table_location_with_rowkey(sql_schema_guard, table_id, session_info))) { LOG_WARN("implicit init location failed", K(table_id), K(ret)); } else if (!is_partitioned_) { RowkeyArray rowkey_list; if (OB_FAIL(part_ids.push_back(0))) { LOG_WARN("Failed to push back partition id", K(ret)); } for (int64_t i = 0; OB_SUCC(ret) && i < rowkeys.count(); ++i) { if (OB_FAIL(rowkey_list.push_back(i))) { LOG_WARN("add rowkey index to rowkey list failed", K(ret)); } } if (OB_SUCC(ret)) { if (OB_FAIL(rowkey_lists.push_back(rowkey_list))) { LOG_WARN("store rowkey list to rowkey_lists failed", K(ret)); } } } else if (OB_FAIL(calc_partition_ids_by_rowkey(exec_ctx, &schema_guard, rowkeys, part_ids, rowkey_lists))) { LOG_WARN("calc parttion ids by rowkey failed", K(ret)); } } return ret; } int ObTableLocation::calculate_partition_id_by_row( ObExecContext& exec_ctx, ObPartMgr* part_mgr, const ObNewRow& row, int64_t& part_id) const { int ret = OB_SUCCESS; ObSEArray part_ids; int64_t part_idx = OB_INVALID_INDEX; if (OB_FAIL(calculate_partition_ids_by_row(exec_ctx, part_mgr, row, part_ids, part_idx))) { LOG_WARN("calculate partition ids by row failed", K(ret)); } else if (OB_UNLIKELY(part_ids.count() != 1) && OB_UNLIKELY(part_idx != 0)) { ret = OB_NO_PARTITION_FOR_GIVEN_VALUE; LOG_WARN("part ids is invalid", K(part_ids), K(part_idx)); } else { part_id = part_ids.at(0); } return ret; } int ObTableLocation::calculate_partition_ids_by_row(ObExecContext& exec_ctx, ObPartMgr* part_mgr, const ObNewRow& row, ObIArray& part_ids, int64_t& part_idx) const { int ret = OB_SUCCESS; ObNewRow* part_row = NULL; part_idx = OB_INVALID_INDEX; if (!is_partitioned_) { int64_t part_id = 0; if (OB_FAIL(add_var_to_array_no_dup(part_ids, part_id, &part_idx))) { LOG_WARN("Failed to push back partition id", K(ret)); } } else if (OB_FAIL(part_projector_.calc_part_row(stmt_type_, exec_ctx, row, part_row))) { ret = COVER_SUCC(OB_ERR_UNEXPECTED); LOG_WARN("calc part row failed", K(ret), K(part_row)); } else if (PARTITION_LEVEL_ONE == part_level_) { if (OB_FAIL(calc_partition_id_by_row(exec_ctx, part_mgr, *part_row, part_ids))) { LOG_WARN("calc partition id by row failed", K(ret)); } else { part_idx = exec_ctx.get_part_row_manager().get_part_idx(); } } else { ObSEArray tmp_part_ids; if (OB_FAIL(calc_partition_id_by_row(exec_ctx, part_mgr, *part_row, tmp_part_ids))) { LOG_WARN("calc partition id by row failed", K(ret)); } else if (OB_FAIL(calc_partition_id_by_row(exec_ctx, part_mgr, *part_row, part_ids, &tmp_part_ids))) { LOG_WARN("calc sub partition id by row failed", K(ret)); } else { part_idx = exec_ctx.get_part_row_manager().get_part_idx(); } } return ret; } int ObTableLocation::calculate_partition_ids_fast_for_non_insert( ObExecContext& exec_ctx, const ParamStore& param_store, ObObj& result, bool& has_optted) const { int ret = OB_SUCCESS; const ObPLQueryRangeNode* calc_node2 = static_cast(calc_node_); has_optted = false; if (OB_ISNULL(calc_node2) || OB_ISNULL(calc_node2->pre_query_range_.get_table_grapth().key_part_head_) || OB_ISNULL(calc_node2->pre_query_range_.get_table_grapth().key_part_head_->normal_keypart_)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("unexpected null ptr", K(ret), K(calc_node2)); } else { const ObQueryRange& query_range = calc_node2->pre_query_range_; result = query_range.get_table_grapth().key_part_head_->normal_keypart_->start_; if (result.is_unknown()) { if (OB_FAIL(query_range.get_param_value(result, param_store))) { LOG_WARN("get param value failed", K(ret)); } } if (OB_FAIL(ret)) { // do nothing ... } else { const ObObjType& type1 = result.get_type(); const ObObjType& type2 = query_range.get_table_grapth().key_part_head_->pos_.column_type_.get_type(); if (result.meta_.get_collation_type() != query_range.get_table_grapth().key_part_head_->pos_.column_type_.get_collation_type()) { // no optimize for diffent collation LOG_TRACE("collation not the same, won't optimize", K(query_range.get_table_grapth().key_part_head_->normal_keypart_->start_.meta_.get_collation_type()), K(query_range.get_table_grapth().key_part_head_->pos_.column_type_.get_collation_type())); } else { if (type1 != type2 && ob_is_string_tc(type1) == ob_is_string_tc(type2)) { ObArenaAllocator allocator(CURRENT_CONTEXT->get_malloc_allocator()); allocator.set_label("CalcNoInsert"); ObExprCtx expr_ctx; const ObObj* cast_result = NULL; // init expr ctx if (OB_FAIL(ObSQLUtils::wrap_expr_ctx(stmt_type_, exec_ctx, allocator, expr_ctx))) { LOG_WARN("Failed to wrap expr ctx", K(ret)); } else { // EXPR_DEFINE_CAST_CTX(expr_ctx, CM_NONE); ObCollationType cast_coll_type = query_range.get_table_grapth().key_part_head_->pos_.column_type_.get_collation_type(); ObCastMode cast_mode = (expr_ctx).cast_mode_ | CM_NONE; const ObDataTypeCastParams dtc_params = ObBasicSessionInfo::create_dtc_params((expr_ctx).my_session_); ObCastCtx cast_ctx( (expr_ctx).calc_buf_, &dtc_params, get_cur_time((expr_ctx).phy_plan_ctx_), cast_mode, cast_coll_type); EXPR_CAST_OBJ_V2(type2, result, cast_result); LOG_TRACE("cast happened when calc part id fast for non-insert", K(type2), K(result), K(*cast_result)); if (OB_SUCC(ret)) { if (OB_FAIL(deep_copy_obj(exec_ctx.get_allocator(), *cast_result, result))) { LOG_WARN("Failed to deep copy obj", K(ret)); } } } } if (OB_SUCC(ret) && !result.is_null() && result.is_valid_type()) { has_optted = true; } } } LOG_TRACE("calc part id fast for non-insert", K(ret), K(param_store), K(result), K(has_optted), K(use_hash_part_opt_), K(use_list_part_map_), K(query_range)); } return ret; } // for insert, merge int ObTableLocation::calculate_partition_ids_fast_for_insert( ObExecContext& exec_ctx, const ParamStore& param_store, ObObj& result, bool& has_optted) const { int ret = OB_SUCCESS; has_optted = false; if (1 != key_exprs_.count() || OB_ISNULL(key_exprs_.at(0)) || 1 != key_exprs_.at(0)->get_expr_items().count() || 1 != key_conv_exprs_.count() || OB_ISNULL(key_conv_exprs_.at(0)) || 6 != key_conv_exprs_.at(0)->get_expr_items().count()) { ret = OB_INVALID_ARGUMENT; LOG_WARN( "param is not expected as judge can do fast optimizaion", K(key_exprs_.count()), K(key_conv_exprs_.count())); } else { const ObPostExprItem& key_item = key_exprs_.at(0)->get_expr_items().at(0); const ObPostExprItem& key_cvt_item = key_conv_exprs_.at(0)->get_expr_items().at(5); if (T_QUESTIONMARK == key_item.get_item_type()) { const ObObj* obj = NULL; int64_t param_idx = -1; if (OB_FAIL(key_item.get_obj().get_unknown(param_idx))) { LOG_WARN("fail to get unknown", K(ret), K(key_item.get_obj())); } else if (OB_UNLIKELY(param_idx < 0 || param_idx >= param_store.count())) { ret = common::OB_ARRAY_OUT_OF_RANGE; LOG_WARN("wrong index of question mark position", K(param_idx), "param_count", param_store.count()); } else { obj = ¶m_store.at(param_idx); if (OB_ISNULL(obj)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("NULL obj returned", K(ret)); } else { result = *obj; } } } else if (IS_DATATYPE_OP(key_item.get_item_type())) { result = key_item.get_obj(); } else { ret = OB_ERR_UNEXPECTED; LOG_WARN("invalid key item type", K(key_item), K(ret)); } if (OB_SUCC(ret)) { // need cast when needed if (T_FUN_COLUMN_CONV == key_cvt_item.get_item_type() && OB_NOT_NULL(key_cvt_item.get_expr_operator())) { const ObObjType& type1 = result.get_type(); const ObObjType& type2 = key_cvt_item.get_expr_operator()->get_result_type().get_type(); if (result.meta_.get_collation_type() != key_cvt_item.get_expr_operator()->get_result_type().get_collation_type()) { // no optimize for diffent collation LOG_TRACE("collation not the same, won't optimize", K(result.meta_.get_collation_type()), K(key_cvt_item.get_expr_operator()->get_result_type().get_collation_type())); } else { if (type1 != type2 && ob_is_string_tc(type1) == ob_is_string_tc(type2)) { ObArenaAllocator allocator(CURRENT_CONTEXT->get_malloc_allocator()); allocator.set_label("CalcInsert"); ObExprCtx expr_ctx; const ObObj* cast_result = NULL; // init expr ctx if (OB_FAIL(ObSQLUtils::wrap_expr_ctx(stmt_type_, exec_ctx, allocator, expr_ctx))) { LOG_WARN("Failed to wrap expr ctx", K(ret)); } else { ObCollationType cast_coll_type = key_cvt_item.get_expr_operator()->get_result_type().get_collation_type(); ObCastMode cast_mode = (expr_ctx).cast_mode_ | CM_NONE; const ObDataTypeCastParams dtc_params = ObBasicSessionInfo::create_dtc_params((expr_ctx).my_session_); ObCastCtx cast_ctx( (expr_ctx).calc_buf_, &dtc_params, get_cur_time((expr_ctx).phy_plan_ctx_), cast_mode, cast_coll_type); EXPR_CAST_OBJ_V2(type2, result, cast_result); LOG_TRACE("cast happened when calc part id fast for insert", K(type2), K(result), K(*cast_result)); if (OB_SUCC(ret)) { if (OB_FAIL(deep_copy_obj(exec_ctx.get_allocator(), *cast_result, result))) { LOG_WARN("Failed to deep copy obj", K(ret)); } } } } if (OB_SUCC(ret) && result.get_type() == type2) { has_optted = true; } } } } LOG_TRACE("calc part id fast for insert", K(ret), K(param_store), K(result), K(has_optted), K(use_hash_part_opt_), K(use_list_part_map_), K(key_item), K(key_cvt_item)); } return ret; } bool ObTableLocation::calculate_partition_ids_fast( ObExecContext& exec_ctx, const ParamStore& param_store, ObIArray& partition_ids) const { int ret = OB_SUCCESS; bool has_optted = false; int64_t part_idx = OB_INVALID_INDEX; ObObj result; bool insert_or_replace = is_simple_insert_or_replace(); if (insert_or_replace) { if (OB_FAIL(calculate_partition_ids_fast_for_insert(exec_ctx, param_store, result, has_optted))) { LOG_WARN("failed to calc part id fast for ins, error will be ignored", K(ret)); } } else { if (OB_FAIL(calculate_partition_ids_fast_for_non_insert(exec_ctx, param_store, result, has_optted))) { LOG_WARN("failed to calc part id fast for non-ins, error will be ignored", K(ret)); } } if (OB_SUCC(ret) && has_optted) { if (use_hash_part_opt_) { ObObj hash_result; if (PARTITION_FUNC_TYPE_HASH == part_type_ && OB_FAIL(ObExprFuncPartOldHash::calc_value_for_oracle(&result, 1, hash_result))) { LOG_WARN("Failed to calc hash value oracle mode", K(ret)); } else if (PARTITION_FUNC_TYPE_HASH_V2 == part_type_ && OB_FAIL(ObExprFuncPartHash::calc_value_for_oracle(&result, 1, hash_result))) { LOG_WARN("Failed to calc hash value oracle mode", K(ret)); } else if (OB_FAIL(get_hash_part(hash_result, insert_or_replace, partition_ids, &part_idx))) { LOG_WARN("fail to get hash part", K(ret)); } else { exec_ctx.get_part_row_manager().set_part_idx(part_idx); } } else if (use_list_part_map_) { if (OB_FAIL(get_list_part(result, insert_or_replace, partition_ids, &part_idx))) { LOG_WARN("fail to get list part", K(ret)); } else { exec_ctx.get_part_row_manager().set_part_idx(part_idx); } } } if (OB_FAIL(ret)) { has_optted = false; } LOG_TRACE("calc part id fast opt", K(has_optted), K(ret), K(param_store), K(part_idx), K(partition_ids), K(result), K(insert_or_replace)); return has_optted; } int ObTableLocation::calculate_partition_ids(ObExecContext& exec_ctx, common::ObPartMgr* part_mgr, const ParamStore& params, ObIArray& partition_ids, const ObDataTypeCastParams& dtc_params) const { int ret = OB_SUCCESS; if (!inited_) { ret = OB_NOT_INIT; LOG_WARN("ObTableLocation not inited", K(ret)); } else if (use_calc_part_by_rowid_) { ObSchemaGetterGuard* schema_guard = dynamic_cast(part_mgr); if (OB_ISNULL(schema_guard)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("unexpected null schema guard", K(ret)); } else if (OB_FAIL(calculate_partition_ids_with_rowid(exec_ctx, *schema_guard, params, partition_ids))) { LOG_WARN("failed to calculate partition ids", K(ret)); } } else { if (CAN_FAST_CALC == fast_calc_part_opt_ && calculate_partition_ids_fast(exec_ctx, params, partition_ids)) { // do nothing ... } else if (is_simple_insert_or_replace()) { if (part_get_all_) { if (PARTITION_LEVEL_ONE == part_level_) { if (OB_FAIL(get_all_part_ids(exec_ctx, part_mgr, partition_ids))) { LOG_WARN("Failed to get all part ids", K(ret)); } } else if (PARTITION_LEVEL_TWO == part_level_) { ObSEArray tmp_part_ids; if (OB_FAIL(get_all_part_ids(exec_ctx, part_mgr, tmp_part_ids))) { LOG_WARN("Failed to get all part ids", K(ret)); } else if (OB_FAIL(get_all_part_ids(exec_ctx, part_mgr, partition_ids, &tmp_part_ids))) { LOG_WARN("Failed to get all subpart ids", K(ret)); } else { } } } else if (OB_FAIL(calc_partition_ids_by_stored_expr(exec_ctx, part_mgr, partition_ids, dtc_params))) { LOG_WARN("Calc partition ids by stored expr error", K_(stmt_type), K(ret)); } } else if (is_in_hit_) { if (OB_FAIL(calc_partition_ids_by_in_expr(exec_ctx, part_mgr, partition_ids, dtc_params))) { LOG_WARN("fail to calc_partition_ids_by_in_expr", K(ret)); } } else { if (!is_partitioned_) { if (OB_FAIL(partition_ids.push_back(0))) { LOG_WARN("Failed to push back partition id", K(ret)); } } else if (PARTITION_LEVEL_ONE == part_level_) { if (OB_FAIL(calc_partition_ids_by_calc_node(exec_ctx, part_mgr, params, calc_node_, gen_col_node_, gen_col_expr_, part_get_all_, partition_ids, dtc_params))) { LOG_WARN("Calc partition ids by calc node error", K_(stmt_type), K(ret)); } } else { ObSEArray part_ids; if (OB_FAIL(calc_partition_ids_by_calc_node(exec_ctx, part_mgr, params, calc_node_, gen_col_node_, gen_col_expr_, part_get_all_, part_ids, dtc_params))) { LOG_WARN("Calc partition ids by calc node error", K_(stmt_type), K(ret)); } else if (OB_FAIL(calc_partition_ids_by_calc_node(exec_ctx, part_mgr, params, subcalc_node_, sub_gen_col_node_, sub_gen_col_expr_, subpart_get_all_, partition_ids, dtc_params, &part_ids))) { LOG_WARN("Calc partition ids by calc node error", K_(stmt_type), K(ret)); } else { } } } NG_TRACE(tl_calc_by_range_end); // deal partition hint if (OB_SUCCESS == ret && part_hint_ids_.count() > 0) { if (OB_FAIL(deal_partition_selection(partition_ids))) { LOG_WARN("deal partition select failed", K(ret)); } } // As in transaction and engine, partition_ids' count should not be 0, // fill fake id. if (OB_SUCCESS == ret && 0 == partition_ids.count()) { int64_t fake_id = first_partition_id_; if (part_hint_ids_.count() > 0) { fake_id = part_hint_ids_.at(0); } if (is_partitioned_ && is_virtual_table(ref_table_id_)) { if (OB_FAIL(get_vt_partition_id(exec_ctx, ref_table_id_, NULL, &fake_id))) { LOG_WARN("Get virtual table fake id error", K(ret)); } } if (OB_SUCC(ret)) { if (OB_FAIL(partition_ids.push_back(fake_id))) { LOG_WARN("Add fake partition id error", K(ret)); } } } } NG_TRACE(tl_calc_part_id_end); return ret; } int ObTableLocation::set_partition_locations(ObExecContext& exec_ctx, ObIPartitionLocationCache& location_cache, const uint64_t ref_table_id, const ObIArray& partition_ids, ObPhyPartitionLocationInfoIArray& phy_part_loc_info_list, bool nonblock /*false*/) { int ret = OB_SUCCESS; int fail_ret = OB_SUCCESS; const int64_t expire_renew_time = 0; bool is_cache_hit = false; if (OB_INVALID_ID == ref_table_id || partition_ids.empty()) { ret = OB_INVALID_ARGUMENT; LOG_WARN("invalid argument", K(ret), K(ref_table_id), K(partition_ids.empty())); } else { phy_part_loc_info_list.reset(); int64_t N = partition_ids.count(); NG_TRACE(get_location_cache_begin); ObSQLSessionInfo* session = exec_ctx.get_my_session(); if (OB_ISNULL(session)) { ret = OB_ERR_UNEXPECTED; LOG_ERROR("some param is NULL", K(ret), K(session)); } else if (OB_FAIL(phy_part_loc_info_list.prepare_allocate(N))) { LOG_WARN("Partitoin location list prepare error", K(ret)); } else { ObPartitionLocation location; for (int64_t i = 0; OB_SUCC(ret) && i < N; ++i) { location.reset(); ObPhyPartitionLocationInfo& part_loc_info = phy_part_loc_info_list.at(i); if (is_link_table_id(ref_table_id)) { ret = location_cache.get_link_table_location(ref_table_id, location); } else if (nonblock) { ret = location_cache.nonblock_get(ref_table_id, partition_ids.at(i), location); } else { ret = location_cache.get(ref_table_id, partition_ids.at(i), location, expire_renew_time, is_cache_hit); } if (OB_FAIL(ret)) { location.set_table_id(ref_table_id); location.set_partition_id(partition_ids.at(i)); const static int64_t ANY_PARTITION_COUNT = 12345; location.set_partition_cnt(ANY_PARTITION_COUNT); if (OB_UNLIKELY(OB_SUCCESS != (fail_ret = part_loc_info.set_part_loc_with_only_readable_replica( location, session->get_retry_info().get_invalid_servers())))) { LOG_WARN("fail to set partition location", K(ret), K(fail_ret), K(location), K(session->get_retry_info().get_invalid_servers())); } LOG_WARN("Get partition error, then set partition key for location cache renew later", K(ret), K(ref_table_id), "partition_id", partition_ids.at(i), K(part_loc_info)); } else { if (GCTX.is_standby_cluster() && !ObMultiClusterUtil::is_cluster_private_table(location.get_table_id())) { // do nothing // no leader for non private tables of standby cluster } else if (OB_FAIL(location.check_strong_leader_exist())) { if (OB_LOCATION_LEADER_NOT_EXIST == ret) { if (nonblock) { ret = location_cache.nonblock_get(ref_table_id, partition_ids.at(i), location); } else { ret = location_cache.get( ref_table_id, partition_ids.at(i), location, location.get_renew_time(), is_cache_hit); } if (OB_FAIL(ret)) { LOG_WARN("Get partition with force renew error", K(ret), K(ref_table_id), "partition_id", partition_ids.at(i)); } } else { LOG_WARN("location check leader exist failed", K(ret), K(location)); } } if (OB_SUCC(ret) && OB_FAIL(part_loc_info.set_part_loc_with_only_readable_replica( location, session->get_retry_info().get_invalid_servers()))) { LOG_WARN("fail to set partition location with only readable replica", K(ret), K(location), K(session->get_retry_info().get_invalid_servers())); } } } NG_TRACE(get_location_cache_end); } } return ret; } int ObTableLocation::get_part_col_type( const ObRawExpr* expr, ObObjType& col_type, ObCollationType& collation_type, const ObTableSchema* table_schema) { int ret = OB_SUCCESS; if (NULL == expr) { ret = OB_INVALID_ARGUMENT; } else if (T_REF_COLUMN != expr->get_expr_type()) { ret = OB_INVALID_ARGUMENT; } else { const ObColumnRefRawExpr* col = static_cast(expr); const ObColumnSchemaV2* col_schema = table_schema->get_column_schema(col->get_column_id()); if (NULL == col_schema) { ret = OB_SCHEMA_ERROR; } else { col_type = col_schema->get_data_type(); collation_type = col_schema->get_meta_type().get_collation_type(); } } return ret; } int ObTableLocation::convert_row_obj_type(const ObNewRow& from, ObNewRow& to, ObObjType col_type, ObCollationType collation_type, const ObDataTypeCastParams& dtc_params, bool& is_all, bool& is_none) const { int ret = OB_SUCCESS; const ObObj& tmp = from.get_cell(0); ObObj& out_obj = to.get_cell(0); ObObj tmp_out_obj; ObObj tmp_out_obj2; ObObjType res_type = ObNullType; is_none = false; if (ob_obj_type_class(tmp.get_type()) == ob_obj_type_class(col_type) && tmp.get_collation_type() == collation_type) { is_all = false; out_obj = tmp; } else { if (OB_FAIL(ObExprResultTypeUtil::get_relational_cmp_type(res_type, col_type, tmp.get_type()))) { LOG_WARN("fail to get_relational_cmp_type", K(ret)); } else { bool is_cast_monotonic = false; if (OB_FAIL(ObObjCaster::is_cast_monotonic(col_type, res_type, is_cast_monotonic))) { LOG_WARN("check is cast monotonic failed", K(ret)); } else if (is_cast_monotonic) { if (OB_FAIL(ObObjCaster::is_cast_monotonic(res_type, col_type, is_cast_monotonic))) { LOG_WARN("check is cast monotonic failed", K(ret)); } } int64_t result = 0; if (OB_SUCC(ret)) { if (is_cast_monotonic) { is_all = false; ObCastCtx cast_ctx(&allocator_, &dtc_params, CM_NONE, collation_type); if (OB_FAIL(ObObjCaster::to_type(res_type, cast_ctx, tmp, tmp_out_obj))) { LOG_WARN("fail to cast", K(ret), K(res_type)); } else if (OB_FAIL(ObObjCaster::to_type(col_type, cast_ctx, tmp_out_obj, tmp_out_obj2))) { LOG_WARN("fail to cast", K(ret), K(col_type)); } else if (OB_FAIL(ObRelationalExprOperator::compare_nullsafe( result, tmp_out_obj, tmp_out_obj2, cast_ctx, res_type, collation_type))) { LOG_WARN("fail to cmp", K(ret)); } if (OB_SUCC(ret)) { if (result == 0) { out_obj = tmp_out_obj2; } else { is_none = true; } } else { ret = OB_SUCCESS; is_all = true; } } else { is_all = true; } } } } return ret; } int ObTableLocation::calc_partition_ids_by_in_expr(ObExecContext& exec_ctx, common::ObPartMgr* part_mgr, ObIArray& partition_ids, const ObDataTypeCastParams& dtc_params) const { UNUSED(dtc_params); int ret = OB_SUCCESS; if (key_exprs_.count() != subkey_exprs_.count()) { ret = OB_ERR_UNEXPECTED; } if (!is_partitioned_) { if (OB_FAIL(partition_ids.push_back(0))) { LOG_WARN("Failed to push back partition id", K(ret)); } } else { ObArenaAllocator allocator(CURRENT_CONTEXT->get_malloc_allocator()); allocator.set_label("CalcByInExpr"); ObExprCtx expr_ctx; ObNewRow part_row; ObNewRow subpart_row; // init expr ctx if (OB_FAIL(ObSQLUtils::wrap_expr_ctx(stmt_type_, exec_ctx, allocator, expr_ctx))) { LOG_WARN("Failed to wrap expr ctx", K(ret)); } // init all ObNewRow if (OB_FAIL(ret)) { } else if (OB_FAIL(init_row(allocator, 1, part_row))) { LOG_WARN("Failed to init row", K(ret)); } {} // do nothing if (PARTITION_LEVEL_TWO == part_level_) { if (OB_FAIL(ret)) { } else if (OB_FAIL(init_row(allocator, 1, subpart_row))) { LOG_WARN("Failed to init row", K(ret)); } else { } // do nothing } // calc ObNewRow for calc partition id for (int64_t value_idx = 0; OB_SUCC(ret) && value_idx < key_exprs_.count(); ++value_idx) { // Get part_row for calc conv expr if (OB_FAIL(calc_row(expr_ctx, key_exprs_, 1, value_idx, part_row, part_row))) { LOG_WARN("Failed to calc part row", K(ret)); } // calc partition id and add it to partition ids no duplicate if (OB_SUCC(ret)) { if (OB_FAIL(calc_row(expr_ctx, subkey_exprs_, 1, value_idx, subpart_row, subpart_row))) { LOG_WARN("Failed to calc subpart_row", K(ret)); } } ObSEArray part_ids; bool is_all = false; bool is_none = false; if (OB_SUCC(ret)) { if (OB_FAIL(convert_row_obj_type( part_row, part_row, part_col_type_, part_collation_type_, dtc_params, is_all, is_none))) { LOG_WARN("fail to convert_row_obj_type", K(ret)); } else if (!is_none) { if (is_all) { if (OB_FAIL(get_all_part_ids(exec_ctx, part_mgr, part_ids))) { LOG_WARN("Failed to get all part ids", K(ret)); } } else { if (OB_FAIL(calc_partition_id_by_row(exec_ctx, part_mgr, part_row, part_ids))) { LOG_WARN("Calc partition id by row error", K(ret)); } } } } if (OB_SUCC(ret)) { if (OB_FAIL(convert_row_obj_type( subpart_row, subpart_row, subpart_col_type_, subpart_collation_type_, dtc_params, is_all, is_none))) { LOG_WARN("fail to convert_row_obj_type", K(ret)); } else if (!is_none) { if (is_all) { if (OB_FAIL(get_all_part_ids(exec_ctx, part_mgr, partition_ids, &part_ids))) { LOG_WARN("Failed to get all subpart ids", K(ret)); } } else if (OB_FAIL(calc_partition_id_by_row(exec_ctx, part_mgr, subpart_row, partition_ids, &part_ids))) { LOG_WARN("Calc partitioin id by row error", K(ret)); } } } } } return ret; } int ObTableLocation::if_exprs_contain_column(const ObIArray& filter_exprs, bool& contain_column) { int ret = OB_SUCCESS; contain_column = false; for (int64_t i = 0; OB_SUCC(ret) && !contain_column && i < filter_exprs.count(); i++) { if (NULL == filter_exprs.at(i)) { ret = OB_ERR_UNEXPECTED; } else { if (filter_exprs.at(i)->has_flag(CNT_COLUMN)) { contain_column = true; } } } return ret; } int ObTableLocation::set_location_calc_node(ObDMLStmt& stmt, const ObIArray& filter_exprs, const ObPartitionLevel part_level, const ObDataTypeCastParams& dtc_params, ObSqlExpression*& part_expr, ObSqlExpression*& gen_col_expr, bool& is_col_part_expr, ObPartLocCalcNode*& calc_node, ObPartLocCalcNode*& gen_col_node, bool& get_all) { int ret = OB_SUCCESS; ObSEArray part_columns; ObSEArray gen_cols; const ObRawExpr* part_raw_expr = NULL; if (OB_FAIL(get_partition_column_info( stmt, part_level, part_columns, gen_cols, part_raw_expr, part_expr, gen_col_expr, is_col_part_expr))) { LOG_WARN("Failed to get partition column info", K(ret)); } else if (filter_exprs.empty()) { get_all = true; } else if (OB_FAIL( get_location_calc_node(part_columns, part_raw_expr, filter_exprs, calc_node, get_all, dtc_params))) { LOG_WARN("Failed to get location calc node", K(ret)); } else if (gen_cols.count() > 0) { // analyze information with dependented column of generated column bool always_true = false; if (OB_FAIL(get_query_range_node(gen_cols, filter_exprs, always_true, gen_col_node, dtc_params))) { LOG_WARN("Get query range node error", K(ret)); } else if (always_true) { gen_col_node = NULL; } else { } // do nothing } return ret; } /* T_OP_IN -- T_OP_ROW --T_REF_COLUMN --T_REF_COLUMN -- T_OP_ROW --T_OP_ROW --T_QUESTIONMARK --T_QUESTIONMARK --T_OP_ROW --T_QUESTIONMARK --T_QUESTIONMARK */ //in expr int ObTableLocation::record_in_dml_partition_info( ObDMLStmt& stmt, const ObIArray& filter_exprs, bool& hit, const ObTableSchema* table_schema) { int ret = OB_SUCCESS; ObRawExpr* filter_expr = NULL; ObRawExpr* left_expr = NULL; ObRawExpr* right_expr = NULL; hit = true; if (PARTITION_LEVEL_TWO != part_level_) { hit = false; } if (hit) { if (filter_exprs.count() != 1) { hit = false; } else { filter_expr = filter_exprs.at(0); } } const ObRawExpr* part_raw_expr = NULL; const ObRawExpr* subpart_raw_expr = NULL; if (OB_SUCC(ret) && hit) { part_raw_expr = get_related_part_expr(stmt, PARTITION_LEVEL_ONE, table_id_, ref_table_id_); if (NULL == part_raw_expr) { ret = OB_ERR_UNEXPECTED; } else if (T_REF_COLUMN != part_raw_expr->get_expr_type()) { hit = false; } } if (OB_SUCC(ret) && hit) { if (OB_FAIL(get_part_col_type(part_raw_expr, part_col_type_, part_collation_type_, table_schema))) { LOG_WARN("fail to get part col type", K(ret)); } } if (OB_SUCC(ret) && hit) { subpart_raw_expr = get_related_part_expr(stmt, PARTITION_LEVEL_TWO, table_id_, ref_table_id_); if (NULL == subpart_raw_expr) { ret = OB_ERR_UNEXPECTED; } else if (T_REF_COLUMN != subpart_raw_expr->get_expr_type()) { hit = false; } } if (OB_SUCC(ret) && hit) { if (OB_FAIL(get_part_col_type(subpart_raw_expr, subpart_col_type_, subpart_collation_type_, table_schema))) { LOG_WARN("fail to get part col type", K(ret)); } } if (OB_SUCC(ret) && hit) { if (T_OP_IN != filter_expr->get_expr_type()) { hit = false; } else { ObOpRawExpr* op_raw_expr = static_cast(filter_expr); if (2 != op_raw_expr->get_param_count()) { hit = false; } else { left_expr = op_raw_expr->get_param_expr(0); right_expr = op_raw_expr->get_param_expr(1); } } } if (OB_SUCC(ret) && hit) { if (T_OP_ROW != left_expr->get_expr_type()) { hit = false; } } int64_t pos1 = -1; int64_t pos2 = -1; if (OB_SUCC(ret) && hit) { ObOpRawExpr* op_left_expr = static_cast(left_expr); if (2 > op_left_expr->get_param_count()) { hit = false; } else { for (int64_t i = 0; i < op_left_expr->get_param_count(); i++) { ObRawExpr* tmp = op_left_expr->get_param_expr(i); if (tmp->same_as(*part_raw_expr)) { pos1 = i; break; } } for (int64_t i = 0; i < op_left_expr->get_param_count(); i++) { ObRawExpr* tmp = op_left_expr->get_param_expr(i); if (tmp->same_as(*subpart_raw_expr)) { pos2 = i; break; } } if (pos1 != -1 && pos2 != -1 && pos1 != pos2) { hit = true; } else { hit = false; } } } if (OB_SUCC(ret) && hit) { if (T_OP_ROW != right_expr->get_expr_type()) { hit = false; } } if (OB_SUCC(ret) && hit) { ObOpRawExpr* op_left_expr = static_cast(left_expr); ObOpRawExpr* op_right_expr = static_cast(right_expr); for (int64_t i = 0; OB_SUCC(ret) && i < op_right_expr->get_param_count(); i++) { ObRawExpr* tmp = op_right_expr->get_param_expr(i); if (T_OP_ROW != tmp->get_expr_type()) { hit = false; break; } ObOpRawExpr* value_expr = static_cast(tmp); if (op_left_expr->get_param_count() != value_expr->get_param_count()) { hit = false; break; } if (OB_FAIL(add_key_expr(key_exprs_, value_expr->get_param_expr(pos1)))) { LOG_WARN("fail to add key expr", K(ret)); } else if (OB_FAIL(add_key_expr(subkey_exprs_, value_expr->get_param_expr(pos2)))) { LOG_WARN("fail to add key expr", K(ret)); } } } ObSEArray part_columns; ObSEArray gen_cols; ObSEArray subpart_columns; ObSEArray sub_gen_cols; if (OB_SUCC(ret) && hit) { if (OB_FAIL(get_partition_column_info(stmt, PARTITION_LEVEL_ONE, part_columns, gen_cols, part_raw_expr, part_expr_, gen_col_expr_, is_col_part_expr_))) { LOG_WARN("Failed to get partition column info", K(ret)); } else if (OB_FAIL(get_partition_column_info(stmt, PARTITION_LEVEL_TWO, subpart_columns, sub_gen_cols, subpart_raw_expr, subpart_expr_, sub_gen_col_expr_, is_col_subpart_expr_))) { LOG_WARN("Failed to get sub partition column info", K(ret)); } } return ret; } int ObTableLocation::record_not_insert_dml_partition_info(ObDMLStmt& stmt, const ObTableSchema* table_schema, const ObIArray& filter_exprs, const ObDataTypeCastParams& dtc_params) { int ret = OB_SUCCESS; if (OB_FAIL(set_location_calc_node(stmt, filter_exprs, PARTITION_LEVEL_ONE, dtc_params, part_expr_, gen_col_expr_, is_col_part_expr_, calc_node_, gen_col_node_, part_get_all_))) { LOG_WARN("failed to set location calc node for first-level partition", K(ret)); } else if (PARTITION_LEVEL_TWO == part_level_ && OB_FAIL(set_location_calc_node(stmt, filter_exprs, part_level_, dtc_params, subpart_expr_, sub_gen_col_expr_, is_col_subpart_expr_, subcalc_node_, sub_gen_col_node_, subpart_get_all_))) { LOG_WARN("failed to set location calc node for second-level partition", K(ret)); } if (OB_SUCC(ret) && share::is_oracle_mode() && OB_NOT_NULL(table_schema) && table_schema->is_user_table() && 1 == table_schema->get_partition_key_column_num() && PARTITION_LEVEL_ONE == part_level_ && is_col_part_expr_ && NONE_FAST_CALC == fast_calc_part_opt_ && OB_NOT_NULL(calc_node_) && calc_node_->is_query_range_node() && OB_ISNULL(gen_col_node_) && OB_ISNULL(gen_col_expr_) && !part_get_all_) { const ObPLQueryRangeNode* calc_node2 = static_cast(calc_node_); const ObQueryRange& query_range = calc_node2->pre_query_range_; if (!query_range.need_deep_copy() && query_range.is_precise_get() && OB_NOT_NULL(query_range.get_table_grapth().key_part_head_) && query_range.get_table_grapth().key_part_head_->is_equal_condition()) { fast_calc_part_opt_ = UNKNOWN_FAST_CALC; } LOG_TRACE("check can fast opt", K(*calc_node2), K(fast_calc_part_opt_), K(query_range.need_deep_copy()), K(query_range.is_precise_get()), K(*query_range.get_table_grapth().key_part_head_), K(query_range.get_table_grapth().key_part_head_->is_equal_condition()), K(query_range)); } return ret; } int ObTableLocation::get_not_insert_dml_part_sort_expr(ObDMLStmt& stmt, ObIArray* sort_exprs) const { int ret = OB_SUCCESS; if (NULL != sort_exprs) { ObRawExpr* part_expr = NULL; if (PARTITION_LEVEL_ONE == part_level_) { if ((PARTITION_FUNC_TYPE_RANGE == part_type_ && is_col_part_expr_) || (PARTITION_FUNC_TYPE_RANGE_COLUMNS == part_type_)) { part_expr = get_related_part_expr(stmt, PARTITION_LEVEL_ONE, table_id_, ref_table_id_); } } else if (PARTITION_LEVEL_TWO == part_level_ && ((PARTITION_FUNC_TYPE_RANGE == subpart_type_ && is_col_subpart_expr_) || PARTITION_FUNC_TYPE_RANGE_COLUMNS == subpart_type_)) { if (!part_get_all_ && NULL != calc_node_) { if (calc_node_->is_column_value_node()) { part_expr = get_related_part_expr(stmt, PARTITION_LEVEL_TWO, table_id_, ref_table_id_); } else if (calc_node_->is_query_range_node()) { if (static_cast(calc_node_)->pre_query_range_.is_precise_get()) { part_expr = get_related_part_expr(stmt, PARTITION_LEVEL_TWO, table_id_, ref_table_id_); } } else { } } } else { } if (NULL != part_expr) { if (part_expr->is_column_ref_expr()) { if (OB_FAIL(sort_exprs->push_back(part_expr))) { LOG_WARN("Failed to add sort exprs", K(ret)); } } else if (T_OP_ROW == part_expr->get_expr_type()) { int64_t param_num = part_expr->get_param_count(); ObRawExpr* col_expr = NULL; for (int64_t idx = 0; OB_SUCC(ret) && idx < param_num; ++idx) { if (OB_ISNULL(col_expr = part_expr->get_param_expr(idx))) { ret = OB_ERR_UNEXPECTED; LOG_WARN("Col expr should not be NULL", K(ret)); } else if (!col_expr->is_column_ref_expr()) { ret = OB_ERR_UNEXPECTED; LOG_WARN("Param expr should be column expr", K(ret)); } else if (OB_FAIL(sort_exprs->push_back(col_expr))) { LOG_WARN("Failed to add sort exprs", K(ret)); } else { } // do nothing } } else if (related_part_expr_idx_ != OB_INVALID_INDEX) { // do nothing } else { ret = OB_ERR_UNEXPECTED; LOG_WARN("Part expr should be Column or T_OP_ROW of column", K(ret), KPNAME(part_expr)); } } } return ret; } int ObTableLocation::get_location_calc_node(ObIArray& partition_columns, const ObRawExpr* partition_expr, const ObIArray& filter_exprs, ObPartLocCalcNode*& res_node, bool& get_all, const ObDataTypeCastParams& dtc_params) { int ret = OB_SUCCESS; uint64_t column_id = OB_INVALID_ID; get_all = false; bool only_range_node = false; if (partition_expr->is_column_ref_expr() || is_virtual_table(ref_table_id_)) { // partition expr is signle column, only query range needed // In future column list is also only query range needed. only_range_node = true; } else if (partition_columns.count() == 1) { column_id = partition_columns.at(0).column_id_; } else { /*do nothing*/ } if (OB_FAIL(ret)) { } else if (only_range_node) { bool always_true = false; ObPartLocCalcNode* calc_node = NULL; if (OB_FAIL(get_query_range_node(partition_columns, filter_exprs, always_true, calc_node, dtc_params))) { LOG_WARN("Get query range node error", K(ret)); } else if (always_true) { get_all = true; } else { res_node = calc_node; } } else { ObSEArray normal_filters; bool func_always_true = true; ObPartLocCalcNode* func_node = NULL; for (int64_t idx = 0; OB_SUCC(ret) && idx < filter_exprs.count(); ++idx) { bool cnt_func_expr = false; bool always_true = false; ObPartLocCalcNode* calc_node = NULL; if (OB_FAIL(analyze_filter(partition_columns, partition_expr, column_id, filter_exprs.at(idx), always_true, calc_node, cnt_func_expr, dtc_params))) { LOG_WARN("Failed to analyze filter", K(ret)); } else { if (!always_true && NULL != calc_node) { func_always_true = false; } if (!cnt_func_expr) { if (OB_FAIL(normal_filters.push_back(filter_exprs.at(idx)))) { LOG_WARN("Failed to add filter", K(ret)); } } else if (OB_FAIL(add_and_node(calc_node, func_node))) { LOG_WARN("Failed to add and node", K(ret)); } else { } // do nothing } } if (OB_SUCC(ret)) { bool column_always_true = false; ObPartLocCalcNode* column_node = NULL; if (normal_filters.count() > 0) { if (OB_FAIL( get_query_range_node(partition_columns, filter_exprs, column_always_true, column_node, dtc_params))) { LOG_WARN("Failed to get query range node", K(ret)); } } if (OB_FAIL(ret)) { } else if (func_always_true && column_always_true) { get_all = true; } else if (func_always_true) { res_node = column_node; } else if (column_always_true) { res_node = func_node; } else if (OB_FAIL(add_and_node(func_node, column_node))) { LOG_WARN("Failed to add and node", K(ret)); } else { res_node = column_node; } } } return ret; } int ObTableLocation::get_query_range_node(const ColumnIArray& partition_columns, const ObIArray& filter_exprs, bool& always_true, ObPartLocCalcNode*& calc_node, const ObDataTypeCastParams& dtc_params) { int ret = OB_SUCCESS; if (filter_exprs.empty()) { always_true = true; } else if (OB_ISNULL(calc_node = ObPartLocCalcNode::create_part_calc_node( allocator_, calc_nodes_, ObPartLocCalcNode::QUERY_RANGE))) { ret = OB_ALLOCATE_MEMORY_FAILED; LOG_ERROR("Allocate memory failed", K(ret)); } else { ObPLQueryRangeNode* node = static_cast(calc_node); if (OB_FAIL(node->pre_query_range_.preliminary_extract_query_range(partition_columns, filter_exprs, dtc_params, params_))) { LOG_WARN("Failed to pre extract query range", K(ret)); } else if (node->pre_query_range_.is_precise_whole_range()) { // pre query range is whole range, indicate that there are no partition condition in filters, // so you need to get all part ids always_true = true; calc_node = NULL; } } return ret; } int ObTableLocation::analyze_filter(const ObIArray& partition_columns, const ObRawExpr* partition_expr, uint64_t column_id, const ObRawExpr* filter, bool& always_true, ObPartLocCalcNode*& calc_node, bool& cnt_func_expr, const ObDataTypeCastParams& dtc_params) { int ret = OB_SUCCESS; if (OB_ISNULL(filter)) { ret = OB_INVALID_ARGUMENT; LOG_WARN("Filter should not be NULL", K(ret)); } else if (T_OP_OR == filter->get_expr_type() || T_OP_AND == filter->get_expr_type()) { const ObOpRawExpr* op_expr = static_cast(filter); for (int64_t idx = 0; OB_SUCC(ret) && idx < op_expr->get_param_count(); ++idx) { ObPartLocCalcNode* cur_node = NULL; bool f_always_true = false; if (OB_FAIL(analyze_filter(partition_columns, partition_expr, column_id, op_expr->get_param_expr(idx), f_always_true, cur_node, cnt_func_expr, dtc_params))) { LOG_WARN("Failed to replace sub_expr bool filter", K(ret)); } else if (T_OP_OR == filter->get_expr_type()) { if (f_always_true || NULL == cur_node) { always_true = true; calc_node = NULL; } else if (OB_FAIL(add_or_node(cur_node, calc_node))) { LOG_WARN("Failed to add or node", K(ret)); } else { } } else { if (f_always_true || NULL == cur_node) { // do nothing } else if (OB_FAIL(add_and_node(cur_node, calc_node))) { LOG_WARN("Failed to add and node", K(ret)); } else { } } } } else if (T_OP_IN == filter->get_expr_type()) { // todo extract_in_op } else if (T_OP_EQ == filter->get_expr_type()) { const ObRawExpr* l_expr = filter->get_param_expr(0); const ObRawExpr* r_expr = filter->get_param_expr(1); if (OB_FAIL(extract_eq_op(l_expr, r_expr, partition_expr, column_id, filter->get_result_type(), cnt_func_expr, always_true, calc_node))) { LOG_WARN("Failed to extract equal expr", K(ret)); } } else { } return ret; } int ObTableLocation::extract_eq_op(const ObRawExpr* l_expr, const ObRawExpr* r_expr, const ObRawExpr* partition_expr, const uint64_t column_id, const ObExprResType& res_type, bool& cnt_func_expr, bool& always_true, ObPartLocCalcNode*& calc_node) { int ret = OB_SUCCESS; UNUSED(column_id); always_true = false; if (OB_ISNULL(l_expr) || OB_ISNULL(r_expr) || OB_ISNULL(partition_expr)) { ret = OB_INVALID_ARGUMENT; LOG_WARN("expr should not be NULL", K(ret), K(l_expr), K(r_expr), K(partition_expr)); } else if ((l_expr->has_flag(CNT_COLUMN) && !(l_expr->has_flag(IS_COLUMN)) && r_expr->has_flag(IS_CONST)) || (r_expr->has_flag(CNT_COLUMN) && !(r_expr->has_flag(IS_COLUMN)) && l_expr->has_flag(IS_CONST))) { const ObRawExpr* func_expr = l_expr->has_flag(CNT_COLUMN) ? l_expr : r_expr; const ObRawExpr* c_expr = l_expr->has_flag(IS_CONST) ? l_expr : r_expr; const ObConstRawExpr* const_expr = static_cast(c_expr); bool equal = false; ObExprEqualCheckContext equal_ctx; bool true_false = true; if (!ObQueryRange::can_be_extract_range(T_OP_EQ, func_expr->get_result_type(), res_type.get_calc_meta(), const_expr->get_result_type().get_type(), true_false)) { always_true = true_false; } else if (OB_FAIL(check_expr_equal(partition_expr, func_expr, equal, equal_ctx))) { LOG_WARN("Failed to check equal expr", K(ret)); } else if (equal) { if (NULL == (calc_node = ObPartLocCalcNode::create_part_calc_node( allocator_, calc_nodes_, ObPartLocCalcNode::FUNC_VALUE))) { ret = OB_ALLOCATE_MEMORY_FAILED; LOG_ERROR("Failed to create expr calc node", K(ret)); } else { ObPLFuncValueNode* node = static_cast(calc_node); node->res_type_ = res_type; cnt_func_expr = true; for (int64_t idx = 0; OB_SUCC(ret) && idx < equal_ctx.param_expr_.count(); ++idx) { ObExprEqualCheckContext::ParamExprPair& param_pair = equal_ctx.param_expr_.at(idx); if (OB_ISNULL(param_pair.expr_)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("Param expr should not be NULL", K(ret)); } else if (param_pair.param_idx_ < 0) { ret = OB_ERR_ILLEGAL_INDEX; LOG_WARN("Wrong index of question mark position", K(ret), "param_idx", param_pair.param_idx_); } else if (!param_pair.expr_->is_const_expr() || T_QUESTIONMARK == param_pair.expr_->get_expr_type()) { ret = OB_ERR_UNEXPECTED; LOG_WARN("Param pair expr should be const and const in expr_to_find should not be T_QUESTIONMARK", K(ret)); } else { const ObObj& expect_val = static_cast(param_pair.expr_)->get_value(); ObObj dst; if (OB_FAIL(deep_copy_obj(allocator_, expect_val, dst))) { LOG_WARN("Failed to deep copy obj", K(ret)); } else if (OB_FAIL(node->param_value_.push_back( ObPLFuncValueNode::ParamValuePair(param_pair.param_idx_, dst)))) { LOG_WARN("Failed to add param value pair", K(ret)); } else { } // do nothing } } if (OB_FAIL(ret)) { } else if (T_QUESTIONMARK == const_expr->get_expr_type()) { node->param_idx_ = const_expr->get_value().get_unknown(); if (node->param_idx_ < 0) { ret = OB_ERR_UNEXPECTED; LOG_WARN("param idx should not be less than 0", K(ret)); } } else { ObObj value; if (OB_FAIL(deep_copy_obj(allocator_, const_expr->get_value(), node->value_))) { LOG_WARN("Failed to deep copy const value", K(ret)); } } } } else { } // do nothing } else if ((l_expr->has_flag(IS_COLUMN) && r_expr->has_flag(IS_CONST)) || (r_expr->has_flag(IS_COLUMN) && l_expr->has_flag(IS_CONST))) { const ObRawExpr* col_expr = l_expr->has_flag(IS_COLUMN) ? l_expr : r_expr; const ObRawExpr* c_expr = l_expr->has_flag(IS_CONST) ? l_expr : r_expr; const ObConstRawExpr* const_expr = static_cast(c_expr); const ObColumnRefRawExpr* column_expr = static_cast(col_expr); if (column_id == column_expr->get_column_id()) { bool true_false = false; if (!ObQueryRange::can_be_extract_range(T_OP_EQ, col_expr->get_result_type(), res_type.get_calc_meta(), const_expr->get_result_type().get_type(), true_false)) { always_true = true_false; } else if (NULL == (calc_node = ObPartLocCalcNode::create_part_calc_node( allocator_, calc_nodes_, ObPartLocCalcNode::COLUMN_VALUE))) { ret = OB_ALLOCATE_MEMORY_FAILED; LOG_ERROR("Failed to create expr calc node", K(ret)); } else { ObPLColumnValueNode* node = static_cast(calc_node); node->res_type_ = res_type; if (T_QUESTIONMARK == const_expr->get_expr_type()) { node->param_idx_ = const_expr->get_value().get_unknown(); if (node->param_idx_ < 0) { ret = OB_ERR_UNEXPECTED; LOG_WARN("param idx should not be less than 0", K(ret)); } } else { ObObj value; if (OB_FAIL(deep_copy_obj(allocator_, const_expr->get_value(), node->value_))) { LOG_WARN("Failed to deep copy const value", K(ret)); } } } } } return ret; } int ObTableLocation::check_expr_equal( const ObRawExpr* partition_expr, const ObRawExpr* check_expr, bool& equal, ObExprEqualCheckContext& equal_ctx) { int ret = OB_SUCCESS; equal = partition_expr->same_as(*check_expr, &equal_ctx); if (OB_SUCCESS != equal_ctx.err_code_) { ret = equal_ctx.err_code_; LOG_WARN("Failed to check whether expr equal", K(ret)); } return ret; } // int ObTableLocation::calc_sub_select_partition_ids(ObExecContext &exec_ctx, ObIArray &partition_ids) const //{ // int ret = OB_SUCCESS; // ObTaskExecutorCtx &task_exec_ctx = exec_ctx.get_task_exec_ctx(); // const ObPhyTableLocationInfoIArray *tbl_loc_infos = NULL; // if (OB_UNLIKELY(OB_INVALID_ID == subselect_table_id_)) { // ret = OB_ERR_UNEXPECTED; // LOG_WARN("table location is invalid", K(subselect_table_id_)); // } else if (OB_ISNULL(tbl_loc_infos = task_exec_ctx.get_global_table_location_infos())) { // ret = OB_ERR_UNEXPECTED; // LOG_WARN("table location info is null"); // } else { // const ObPhyTableLocationInfo *tbl_location_info = NULL; // for (int64_t i = 0; OB_SUCC(ret) && tbl_location_info == NULL && i < tbl_loc_infos->count(); ++i) { // if (tbl_loc_infos->at(i).get_table_location_key() == subselect_table_id_) { // tbl_location_info = &(tbl_loc_infos->at(i)); // } // } // if (OB_SUCC(ret) && OB_ISNULL(tbl_location_info)) { // ret = OB_ERR_UNEXPECTED; // LOG_WARN("table partition location not found", K(tbl_location_info)); // } // if (OB_SUCC(ret)) { // const ObPhyPartitionLocationInfoIArray &part_list = tbl_location_info->get_phy_part_loc_info_list(); // for (int64_t i = 0; OB_SUCC(ret) && i < part_list.count(); ++i) { // if (OB_FAIL(ObOptimizerUtil::add_index_no_duplicate(partition_ids, // part_list.at(i).get_partition_location().get_partition_id()))) { // LOG_WARN("add id no duplicated failed", K(part_list.at(i).get_partition_location().get_partition_id())); // } // } // } // } // return ret; //} // int ObTableLocation::calc_insert_select_partition_rule(ObSchemaGetterGuard &schema_guard, // const ObInsertStmt &insert_stmt, // const ObSelectStmt &sub_select) //{ // int ret = OB_SUCCESS; // if (sub_select.get_table_size() == 1) { // //ignore, only analyzer single table // const TableItem *table_item = sub_select.get_table_item(0); // const ObTableSchema *sel_tbl = NULL; // const ObTableSchema *inst_tbl = NULL; // bool is_same_part = false; // uint64_t ins_tbl_id = insert_stmt.get_table_id(); // if (OB_ISNULL(table_item)) { // ret = OB_ERR_UNEXPECTED; // LOG_WARN("table item is null"); // } else if (!table_item->is_basic_table()) { // //ignore, only analyzer basic table // } else if (OB_FAIL(schema_guard.get_table_schema(table_item->ref_id_, sel_tbl))) { // LOG_WARN("get table schema failed", K(ret), K(table_item->ref_id_)); // } else if (OB_FAIL(schema_guard.get_table_schema(insert_stmt.get_table_id(), inst_tbl))) { // LOG_WARN("get table schema failed", K(ret), K(insert_stmt.get_table_id())); // } else if (!inst_tbl->is_partitioned_table()) { // is_same_part = false; // } else if (OB_FAIL(ObOptimizerUtil::has_same_partition(*inst_tbl, get_related_part_expr(insert_stmt, // PARTITION_LEVEL_ONE, ins_tbl_id, ins_tbl_id), *sel_tbl, // get_related_part_expr(sub_select, PARTITION_LEVEL_ONE, // table_item->table_id_, table_item->ref_id_), // PARTITION_LEVEL_ONE, is_same_part))) { // LOG_WARN("check whether has same partition failed", K(ret)); // } else if (is_same_part && inst_tbl->get_part_level() == PARTITION_LEVEL_TWO) { // if (OB_FAIL(ObOptimizerUtil::has_same_partition(*inst_tbl, get_related_part_expr(insert_stmt, // PARTITION_LEVEL_TWO, ins_tbl_id, ins_tbl_id), // *sel_tbl, get_related_part_expr(sub_select, PARTITION_LEVEL_TWO, // table_item->table_id_, table_item->ref_id_), // PARTITION_LEVEL_TWO, is_same_part))) { // LOG_WARN("check whether has same partition failed", K(ret)); // } // } // if (OB_SUCC(ret) && is_same_part) { // //check whether partition key from sub select // bool has_same_key = false; // const ObPartitionKeyInfo &inst_partkeys = inst_tbl->get_partition_key_info(); // const ObPartitionKeyInfo &inst_subpart_keys = inst_tbl->get_subpartition_key_info(); // const ObPartitionKeyInfo &sel_partkeys = sel_tbl->get_partition_key_info(); // const ObPartitionKeyInfo &sel_subpart_keys = sel_tbl->get_subpartition_key_info(); // if (OB_FAIL(ObOptimizerUtil::all_same_partition_key(inst_partkeys, sel_partkeys, insert_stmt, sub_select, // has_same_key))) { // LOG_WARN("check all same partition key failed", K(ret), K(inst_partkeys), K(sel_partkeys)); // } else if (!has_same_key) { // //ignore // } else if (OB_FAIL(ObOptimizerUtil::all_same_partition_key(inst_subpart_keys, sel_subpart_keys, // insert_stmt, sub_select, has_same_key))) { // LOG_WARN("check all same subpartition key failed", K(ret), K(inst_subpart_keys), K(sel_subpart_keys)); // } else if (has_same_key) { // same_part_with_select_ = true; // subselect_table_id_ = table_item->table_id_; // } // } // } // return ret; //} int ObTableLocation::record_insert_partition_info( ObDMLStmt& stmt, const share::schema::ObTableSchema* table_schema, ObSQLSessionInfo* session_info) { int ret = OB_SUCCESS; bool has_auto_inc_part_key = false; bool partkey_has_subquery = false; bool has_assign_user_var = false; ObInsertStmt& insert_stmt = static_cast(stmt); ObSEArray partition_columns; ObSEArray gen_cols; // actual not used in insert stmt const ObRawExpr* partition_raw_expr = NULL; if (OB_FAIL(insert_stmt.part_key_has_subquery(partkey_has_subquery))) { LOG_WARN("failed to check whether insert stmt has part key", K(ret)); } else if (OB_FAIL(insert_stmt.part_key_has_auto_inc(has_auto_inc_part_key))) { LOG_WARN("check to check whether part key containts auto inc column", K(ret)); } else if (OB_FAIL(insert_stmt.has_ref_assign_user_var(has_assign_user_var))) { LOG_WARN("failed to check stmt has ref assign user var", K(ret)); } else if ((insert_stmt.has_part_key_sequence() || partkey_has_subquery || has_auto_inc_part_key || has_assign_user_var) && PARTITION_LEVEL_ZERO != table_schema->get_part_level()) { part_get_all_ = true; } else if (OB_FAIL(get_partition_column_info(stmt, PARTITION_LEVEL_ONE, partition_columns, gen_cols, partition_raw_expr, part_expr_, gen_col_expr_, is_col_part_expr_))) { LOG_WARN("Failed to get all range column info", K(ret)); } else if (OB_FAIL( record_insert_part_info(insert_stmt, session_info, partition_columns, key_exprs_, key_conv_exprs_))) { LOG_WARN("Failed to record insert partition info", K(ret)); } else if (OB_FAIL(gen_insert_part_row_projector( partition_raw_expr, partition_columns, PARTITION_LEVEL_ONE, part_type_))) { LOG_WARN("generate insert part row projector failed", K(ret), K_(part_type)); } else if (PARTITION_LEVEL_TWO == part_level_) { partition_columns.reuse(); gen_cols.reuse(); if (OB_FAIL(get_partition_column_info(stmt, PARTITION_LEVEL_TWO, partition_columns, gen_cols, partition_raw_expr, subpart_expr_, sub_gen_col_expr_, is_col_subpart_expr_))) { LOG_WARN("Failed to get all range column info", K(ret)); } else if (OB_FAIL(record_insert_part_info( insert_stmt, session_info, partition_columns, subkey_exprs_, subkey_conv_exprs_))) { LOG_WARN("Failed to record insert partition info", K(ret)); } else if (OB_FAIL(gen_insert_part_row_projector( partition_raw_expr, partition_columns, PARTITION_LEVEL_TWO, subpart_type_))) { LOG_WARN("gen insert part row projector failed", K(ret), K_(subpart_type)); } else { } } else { } // do nothing return ret; } int ObTableLocation::generate_rowkey_desc(ObDMLStmt& stmt, const ObRowkeyInfo& rowkey_info, uint64_t data_table_id, ObRawExprFactory& expr_factory, RowDesc& row_desc) { int ret = OB_SUCCESS; if (OB_FAIL(row_desc.init())) { LOG_WARN("Failed to init row desc", K(ret)); } for (int64_t i = 0; OB_SUCC(ret) && i < rowkey_info.get_size(); ++i) { uint64_t rowkey_id = OB_INVALID_ID; if (OB_FAIL(rowkey_info.get_column_id(i, rowkey_id))) { LOG_WARN("get rowkey column id failed", K(ret), K(i)); } else { ObColumnRefRawExpr* rowkey_col = stmt.get_column_expr_by_id(data_table_id, rowkey_id); if (OB_ISNULL(rowkey_col)) { if (OB_FAIL(expr_factory.create_raw_expr(T_REF_COLUMN, rowkey_col))) { LOG_WARN("create mock rowkey column expr failed", K(ret)); } else if (OB_FAIL(row_desc.add_column(rowkey_col))) { LOG_WARN("add rowkey column expr to row desc failed", K(ret)); } } else if (OB_FAIL(row_desc.add_column(rowkey_col))) { LOG_WARN("add rowkey column expr to row desc failed", K(ret)); } } } return ret; } int ObTableLocation::get_partition_column_info(ObDMLStmt& stmt, const ObPartitionLevel part_level, ObIArray& partition_columns, ObIArray& gen_cols, const ObRawExpr*& partition_raw_expr, ObSqlExpression*& partition_expression, ObSqlExpression*& gen_col_expression, bool& is_col_part_expr) { int ret = OB_SUCCESS; partition_raw_expr = NULL; ObRawExpr* gen_col_expr = NULL; RowDesc row_desc; RowDesc gen_row_desc; if (PARTITION_LEVEL_ONE != part_level && PARTITION_LEVEL_TWO != part_level) { ret = OB_ERR_UNEXPECTED; LOG_WARN("part level should be One or Two", K(ret)); } else if (OB_ISNULL(partition_raw_expr = get_related_part_expr(stmt, part_level, table_id_, ref_table_id_))) { ret = OB_ERR_UNEXPECTED; LOG_WARN("Partition expr not in stmt", K(ret), K(table_id_), K(part_level), K(ref_table_id_)); } else if (PARTITION_LEVEL_ONE == part_level && PARTITION_FUNC_TYPE_RANGE_COLUMNS == part_type_ && OB_FAIL(can_get_part_by_range_for_range_columns(partition_raw_expr, is_valid_range_columns_part_range_))) { LOG_WARN("failed ot check can get part by range for range columns", K(ret)); } else if (PARTITION_LEVEL_TWO == part_level && PARTITION_FUNC_TYPE_RANGE_COLUMNS == subpart_type_ && OB_FAIL( can_get_part_by_range_for_range_columns(partition_raw_expr, is_valid_range_columns_subpart_range_))) { LOG_WARN("failed ot check can get part by range for range columns", K(ret)); } else if (PARTITION_LEVEL_ONE == part_level && OB_FAIL(can_get_part_by_range_for_temporal_column(partition_raw_expr, is_valid_temporal_part_range_))) { LOG_WARN("failed ot check can get part by range for range columns", K(ret)); } else if (PARTITION_LEVEL_TWO == part_level && OB_FAIL(can_get_part_by_range_for_temporal_column(partition_raw_expr, is_valid_temporal_subpart_range_))) { LOG_WARN("failed ot check can get part by range for range columns", K(ret)); } else if (FALSE_IT(is_col_part_expr = partition_raw_expr->is_column_ref_expr())) { } else if (OB_FAIL(row_desc.init())) { LOG_WARN("Failed to init row desc", K(ret)); } else if (OB_FAIL(gen_row_desc.init())) { LOG_WARN("Failed to init row desc", K(ret)); } else if (OB_FAIL(add_partition_columns( stmt, partition_raw_expr, partition_columns, gen_cols, gen_col_expr, row_desc, gen_row_desc))) { LOG_WARN("Failed to add partitoin column", K(ret)); } else { if (gen_cols.count() > 0) { if (partition_columns.count() > 1) { gen_cols.reset(); } else if (OB_FAIL(ObExprGeneratorImpl::gen_expression_with_row_desc( sql_expression_factory_, expr_op_factory_, gen_row_desc, gen_col_expr, gen_col_expression))) { LOG_WARN("Failed to gen expression with row desc", K(ret)); } else { } // do nothing } // generate partition_expression with partition columns row_desc if (OB_SUCC(ret)) { if (OB_FAIL(ObExprGeneratorImpl::gen_expression_with_row_desc( sql_expression_factory_, expr_op_factory_, row_desc, partition_raw_expr, partition_expression))) { LOG_WARN("Failed to gen expression with row desc", K(ret)); } } // clear IS_COLUMNLIZED flag if (OB_SUCC(ret)) { if (OB_FAIL(clear_columnlized_in_row_desc(row_desc))) { LOG_WARN("Failed to clear columnlized in row desc", K(ret)); } else if (OB_FAIL(clear_columnlized_in_row_desc(gen_row_desc))) { LOG_WARN("Failed to clear columnlized in row desc", K(ret)); } else { } // do nothing } } return ret; } int ObTableLocation::add_partition_columns(ObDMLStmt& stmt, const ObRawExpr* part_expr, ObIArray& partition_columns, ObIArray& gen_cols, ObRawExpr*& gen_col_expr, RowDesc& row_desc, RowDesc& gen_row_desc, const bool only_gen_cols) { int ret = OB_SUCCESS; ObSEArray cur_vars; if (OB_ISNULL(part_expr)) { ret = OB_INVALID_ARGUMENT; LOG_WARN("Part expr is NULL", K(ret)); } else if (OB_FAIL(ObRawExprUtils::extract_column_exprs(part_expr, cur_vars))) { LOG_WARN("get column exprs error", K(ret)); } else { ObRawExpr* var = NULL; uint64_t column_id = OB_INVALID_ID; uint64_t table_id = OB_INVALID_ID; ObColumnRefRawExpr* col_expr = NULL; for (int64_t idx = 0; OB_SUCC(ret) && idx < cur_vars.count(); ++idx) { if (OB_ISNULL(var = cur_vars.at(idx))) { ret = OB_ERR_UNEXPECTED; LOG_WARN("Var should not be NULL in column exprs", K(ret)); } else if (!var->is_column_ref_expr()) { ret = OB_ERR_UNEXPECTED; LOG_WARN("Var should be column", K(ret)); } else if (FALSE_IT(col_expr = static_cast(var))) { } else if (OB_UNLIKELY(OB_INVALID_ID == (column_id = col_expr->get_column_id())) || OB_UNLIKELY(OB_INVALID_ID == (table_id = col_expr->get_table_id()))) { ret = OB_ERR_UNEXPECTED; LOG_WARN("Column id should not be OB_INVALID_ID", K(ret)); } else if (only_gen_cols) { // only deal dependented columns for generated partition column if (OB_FAIL(add_partition_column(stmt, table_id, column_id, gen_cols, gen_row_desc))) { LOG_WARN("Failed to add partiton column", K(ret)); } } else { if (col_expr->is_generated_column()) { if (OB_ISNULL(col_expr->get_dependant_expr())) { ret = OB_ERR_UNEXPECTED; LOG_WARN("Generated column's dependent expr is NULL", K(ret)); } else if (is_simple_insert_or_replace()) { if (OB_FAIL(add_partition_columns(stmt, col_expr->get_dependant_expr(), partition_columns, gen_cols, gen_col_expr, row_desc, gen_row_desc))) { LOG_WARN("Failed to add partition column", K(ret)); } } else if (cur_vars.count() > 1) { // do nothing.Only deal case with one partition column. } else { gen_col_expr = col_expr->get_dependant_expr(); if (OB_FAIL(add_partition_columns(stmt, col_expr->get_dependant_expr(), partition_columns, gen_cols, gen_col_expr, row_desc, gen_row_desc, true))) { LOG_WARN("Failed to add gen columns", K(ret)); } } } if (OB_SUCC(ret)) { if (OB_FAIL(add_partition_column(stmt, table_id, column_id, partition_columns, row_desc))) { LOG_WARN("Failed to add partiton column", K(ret)); } } } // end of else } // end of for } return ret; } int ObTableLocation::add_partition_column(ObDMLStmt& stmt, const uint64_t table_id, const uint64_t column_id, ObIArray& partition_columns, RowDesc& row_desc) { int ret = OB_SUCCESS; bool is_different = true; for (int64_t idx = 0; OB_SUCC(ret) && is_different && idx < partition_columns.count(); ++idx) { if (partition_columns.at(idx).column_id_ == column_id) { is_different = false; } } if (OB_SUCC(ret)) { if (is_different) { ColumnItem* column_item = NULL; if (NULL == (column_item = stmt.get_column_item_by_id(table_id, column_id))) { ret = OB_ERR_UNEXPECTED; LOG_WARN("Failed to get column item by id", K(table_id), K(column_id), K(ret)); } else if (OB_ISNULL(column_item->get_expr())) { ret = OB_ERR_UNEXPECTED; LOG_WARN("Column item's expr is NULL", K(ret)); } else if (OB_FAIL(row_desc.add_column(column_item->get_expr()))) { LOG_WARN("Failed to add column item to temporary row desc", K(ret)); } else if (OB_FAIL(partition_columns.push_back(*column_item))) { LOG_WARN("Failed to add column item to partition columns", K(ret)); } else if (OB_FAIL(column_item->get_expr()->add_flag(IS_COLUMNLIZED))) { LOG_WARN("failed to add flag IS_COLUMNLIZED", K(ret)); } else { } } } return ret; } int ObTableLocation::add_key_expr(IKeyExprs& key_exprs, ObRawExpr* expr) { int ret = OB_SUCCESS; ObSqlExpression* sql_expr = NULL; if (NULL == expr) { ret = OB_INVALID_ARGUMENT; LOG_WARN("Expr should not be NULL", K(expr), K(ret)); } else if (!expr->is_const_expr() && !expr->has_flag(IS_CALCULABLE_EXPR)) { ret = OB_NOT_SUPPORTED; LOG_USER_ERROR(OB_NOT_SUPPORTED, "non-const or non-calculable expression partition key"); } else if (OB_FAIL(sql_expression_factory_.alloc(sql_expr))) { LOG_WARN("Failed to alloc sql_expr", K(ret)); } else if (OB_ISNULL(sql_expr)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("Alloc partition expr error", K(ret)); } else { RowDesc row_desc; // empty row desc ObExprGeneratorImpl expr_generator(expr_op_factory_, 0, 0, NULL, row_desc); if (OB_FAIL(expr_generator.generate(*expr, *sql_expr))) { LOG_WARN("Failed to generate sql expression", K(ret)); } else if (OB_FAIL(key_exprs.push_back(sql_expr))) { LOG_WARN("Failed to add sql expr to array", K(ret)); } else { // do nothing } } return ret; } int ObTableLocation::add_key_expr_with_row_desc(IKeyExprs& key_exprs, RowDesc& row_desc, ObRawExpr* expr) { int ret = OB_SUCCESS; ObSqlExpression* sql_expr = NULL; if (NULL == expr) { ret = OB_INVALID_ARGUMENT; LOG_WARN("Expr should not be NULL", K(expr), K(ret)); } else if (OB_FAIL(sql_expression_factory_.alloc(sql_expr))) { LOG_WARN("fail to alloc sql-expr", K(ret)); } else if (OB_ISNULL(sql_expr)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("Alloc partition expr error", K(ret)); } else { ObExprGeneratorImpl expr_generator(expr_op_factory_, 0, 0, NULL, row_desc); if (OB_FAIL(expr_generator.generate(*expr, *sql_expr))) { LOG_WARN("Failed to generate sql expression", K(ret)); } else if (OB_FAIL(key_exprs.push_back(sql_expr))) { LOG_WARN("Failed to add sql expr to array", K(ret)); } else { } } return ret; } int ObTableLocation::calc_partition_ids_by_calc_node(ObExecContext& exec_ctx, common::ObPartMgr* part_mgr, const ParamStore& params, const ObPartLocCalcNode* calc_node, const ObPartLocCalcNode* gen_col_node, const ObSqlExpression* gen_col_expr, const bool part_col_get_all, ObIArray& partition_ids, const ObDataTypeCastParams& dtc_params, const ObIArray* part_ids) const { int ret = OB_SUCCESS; if (!is_partitioned_) { if (OB_FAIL(partition_ids.push_back(0))) { LOG_WARN("Failed to push back partition id", K(ret)); } } else { ObSEArray gen_part_ids; bool part_col_all_part = false; bool gen_col_all_part = false; // get partition ids with information of partition columns if (!part_col_get_all) { // partition condition is not empty, so you need to calc partition id by partition key if (OB_FAIL(calc_partition_ids_by_calc_node( exec_ctx, part_mgr, params, calc_node, partition_ids, part_col_all_part, dtc_params, part_ids))) { LOG_WARN("Failed to calc partitoin ids by calc node", K(ret)); } } else { part_col_all_part = true; } if (OB_SUCC(ret)) { if (NULL != gen_col_node && NULL != gen_col_expr) { // partition key is generated column and dependent column condition is not empty // so you need to calc partition id by dependent column condition if (!gen_col_node->is_query_range_node()) { ret = OB_ERR_UNEXPECTED; LOG_WARN("column dependented by generated column calc node should be query range node", K(ret)); } else if (OB_FAIL(calc_query_range_partition_ids(exec_ctx, part_mgr, params, static_cast(gen_col_node), gen_part_ids, gen_col_all_part, dtc_params, part_ids, gen_col_expr))) { LOG_WARN("Failed to calcl partition ids by gen col node", K(ret)); } } else { gen_col_all_part = true; } } if (OB_SUCC(ret)) { if (!part_col_all_part && !gen_col_all_part) { // partition key condition is not empty and generated column dependent condition is not empty // so you need to intersect partition ids extracted by these two conditions if (OB_FAIL(intersect_partition_ids(gen_part_ids, partition_ids))) { // intersect ids LOG_WARN("Failed to intersect partition ids", K(ret)); } } else if (!part_col_all_part && gen_col_all_part) { // generated column condition is empty, but partition key condition is not empty, // use the partition ids extracted by partition key condition directly, do nothing } else if (part_col_all_part && !gen_col_all_part) { // generated column condition is not empty, but partition key condition is empty, // use the partiiton ids extracted by generated column condition, so append to partition_ids if (OB_FAIL(append(partition_ids, gen_part_ids))) { LOG_WARN("append partition ids failed", K(ret)); } } else { // part_col_all_part=true && gen_col_all_part=true // has no any partition condition, get all partition ids in schema if (OB_FAIL(get_all_part_ids(exec_ctx, part_mgr, partition_ids, part_ids))) { LOG_WARN("Get all part ids error", K(ret)); } } } } return ret; } int ObTableLocation::intersect_partition_ids( const ObIArray& to_inter_ids, ObIArray& partition_ids) const { int ret = OB_SUCCESS; ObSEArray intersect_tmp; for (int64_t idx = 0; OB_SUCC(ret) && idx < partition_ids.count(); ++idx) { if (has_exist_in_array(to_inter_ids, partition_ids.at(idx), NULL)) { if (OB_FAIL(intersect_tmp.push_back(partition_ids.at(idx)))) { LOG_WARN("Failed to add partition id", K(ret)); } } } if (OB_SUCC(ret)) { partition_ids.reset(); if (OB_FAIL(partition_ids.assign(intersect_tmp))) { LOG_WARN("Failed to assign intersect tmp ids", K(ret)); } } return ret; } int ObTableLocation::calc_partition_ids_by_calc_node(ObExecContext& exec_ctx, common::ObPartMgr* part_mgr, const ParamStore& params, const ObPartLocCalcNode* calc_node, ObIArray& partition_ids, bool& all_part, const ObDataTypeCastParams& dtc_params, const ObIArray* part_ids) const { int ret = OB_SUCCESS; all_part = false; if (OB_UNLIKELY(NULL == calc_node)) { ret = OB_INVALID_ARGUMENT; LOG_WARN("Calc node should not be NULL", K(ret)); } else if (ObPartLocCalcNode::CALC_AND == calc_node->get_node_type()) { if (OB_FAIL(calc_and_partition_ids(exec_ctx, part_mgr, params, static_cast(calc_node), partition_ids, all_part, dtc_params, part_ids))) { LOG_WARN("Failed to calc and partition ids", K(ret)); } } else if (ObPartLocCalcNode::CALC_OR == calc_node->get_node_type()) { if (OB_FAIL(calc_or_partition_ids(exec_ctx, part_mgr, params, static_cast(calc_node), partition_ids, all_part, dtc_params, part_ids))) { LOG_WARN("Failed to calc and partition ids", K(ret)); } } else if (ObPartLocCalcNode::QUERY_RANGE == calc_node->get_node_type()) { if (OB_FAIL(calc_query_range_partition_ids(exec_ctx, part_mgr, params, static_cast(calc_node), partition_ids, all_part, dtc_params, part_ids))) { LOG_WARN("Failed to calc and partition ids", K(ret)); } } else if (ObPartLocCalcNode::FUNC_VALUE == calc_node->get_node_type()) { if (OB_FAIL(calc_func_value_partition_ids(exec_ctx, part_mgr, params, static_cast(calc_node), partition_ids, all_part, dtc_params, part_ids))) { LOG_WARN("Failed to calc and partition ids", K(ret)); } } else if (ObPartLocCalcNode::COLUMN_VALUE == calc_node->get_node_type()) { if (OB_FAIL(calc_column_value_partition_ids(exec_ctx, part_mgr, params, static_cast(calc_node), partition_ids, all_part, dtc_params, part_ids))) { LOG_WARN("Failed to calc and partition ids", K(ret)); } } else { ret = OB_ERR_UNEXPECTED; LOG_WARN("Unknown calc node type", K(ret)); } return ret; } int ObTableLocation::calc_and_partition_ids(ObExecContext& exec_ctx, common::ObPartMgr* part_mgr, const ParamStore& params, const ObPLAndNode* calc_node, ObIArray& partition_ids, bool& all_part, const ObDataTypeCastParams& dtc_params, const ObIArray* part_ids) const { int ret = OB_SUCCESS; if (OB_ISNULL(calc_node)) { ret = OB_INVALID_ARGUMENT; LOG_WARN("Calc node should not be NULL", K(ret)); } else if (OB_ISNULL(calc_node->left_node_) || OB_ISNULL(calc_node->right_node_)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("And node shoul have left and right node", K(ret)); } else { ObSEArray left_part_ids; bool left_all = false; ObSEArray right_part_ids; bool right_all = false; if (OB_FAIL(calc_partition_ids_by_calc_node( exec_ctx, part_mgr, params, calc_node->left_node_, left_part_ids, left_all, dtc_params, part_ids))) { LOG_WARN("Calc node error", K(ret)); } else if (OB_FAIL(calc_partition_ids_by_calc_node(exec_ctx, part_mgr, params, calc_node->right_node_, right_part_ids, right_all, dtc_params, part_ids))) { LOG_WARN("Calc node error", K(ret)); } else if (left_all && right_all) { all_part = true; } else if (left_all) { if (OB_FAIL(partition_ids.assign(right_part_ids))) { LOG_WARN("Failed to assign part ids", K(ret)); } } else if (right_all) { if (OB_FAIL(partition_ids.assign(left_part_ids))) { LOG_WARN("Failed to assign part ids", K(ret)); } } else { for (int64_t l_idx = 0; OB_SUCC(ret) && l_idx < left_part_ids.count(); ++l_idx) { for (int64_t r_idx = 0; OB_SUCC(ret) && r_idx < right_part_ids.count(); ++r_idx) { if (right_part_ids.at(r_idx) == left_part_ids.at(l_idx)) { if (OB_FAIL(partition_ids.push_back(left_part_ids.at(l_idx)))) { LOG_WARN("Failed to add part id", K(ret)); } } } // end of r_idx } // end of l_idx } } return ret; } int ObTableLocation::calc_or_partition_ids(ObExecContext& exec_ctx, common::ObPartMgr* part_mgr, const ParamStore& params, const ObPLOrNode* calc_node, ObIArray& partition_ids, bool& all_part, const ObDataTypeCastParams& dtc_params, const ObIArray* part_ids) const { int ret = OB_SUCCESS; if (OB_ISNULL(calc_node)) { ret = OB_INVALID_ARGUMENT; LOG_WARN("Calc node should not be NULL", K(ret)); } else if (OB_ISNULL(calc_node->left_node_) || OB_ISNULL(calc_node->right_node_)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("And node shoul have left and right node", K(ret)); } else { ObSEArray left_part_ids; bool left_all = false; ObSEArray right_part_ids; bool right_all = false; if (OB_FAIL(calc_partition_ids_by_calc_node( exec_ctx, part_mgr, params, calc_node->left_node_, left_part_ids, left_all, dtc_params, part_ids))) { LOG_WARN("Calc node error", K(ret)); } else if (OB_FAIL(calc_partition_ids_by_calc_node(exec_ctx, part_mgr, params, calc_node->right_node_, right_part_ids, right_all, dtc_params, part_ids))) { LOG_WARN("Calc node error", K(ret)); } else if (left_all || right_all) { all_part = true; } else if (OB_FAIL(append_array_no_dup(partition_ids, left_part_ids))) { LOG_WARN("Failed to append array", K(ret)); } else if (OB_FAIL(append_array_no_dup(partition_ids, right_part_ids))) { LOG_WARN("Failed to append array", K(ret)); } else { } } return ret; } int ObTableLocation::calc_query_range_partition_ids(ObExecContext& exec_ctx, common::ObPartMgr* part_mgr, const ParamStore& params, const ObPLQueryRangeNode* calc_node, ObIArray& partition_ids, bool& all_part, const ObDataTypeCastParams& dtc_params, const ObIArray* part_ids, const ObSqlExpression* gen_col_expr) const { UNUSED(part_mgr); UNUSED(part_ids); int ret = OB_SUCCESS; if (OB_ISNULL(calc_node)) { ret = OB_INVALID_ARGUMENT; LOG_WARN("Calc node should not be NULL", K(ret)); } else { all_part = false; ObQueryRangeArray query_ranges; ObArenaAllocator allocator(CURRENT_CONTEXT->get_malloc_allocator()); allocator.set_label("CalcQRPartIds"); bool is_all_single_value_ranges = true; if (OB_FAIL(calc_node->pre_query_range_.get_tablet_ranges( allocator, params, query_ranges, is_all_single_value_ranges, dtc_params))) { LOG_WARN("get tablet ranges failed", K(ret)); } else if (query_ranges.count() == 0) { ret = OB_ERR_UNEXPECTED; LOG_WARN("Query ranges' count should not be 0", "query range count", query_ranges.count(), K(ret)); } else { bool is_empty = true; if (OB_FAIL(is_all_ranges_empty(query_ranges, is_empty))) { LOG_WARN("fail to check all ranges", K(query_ranges)); } else if (!is_empty) { if (OB_FAIL(calc_partition_ids_by_ranges(exec_ctx, part_mgr, query_ranges, is_all_single_value_ranges, partition_ids, all_part, part_ids, gen_col_expr))) { LOG_WARN("Failed to get partition ids", K(ret), K(table_id_)); } } else { } // do nothing. partition ids will be empty } } return ret; } int ObTableLocation::calc_func_value_partition_ids(ObExecContext& exec_ctx, common::ObPartMgr* part_mgr, const ParamStore& params, const ObPLFuncValueNode* calc_node, ObIArray& partition_ids, bool& all_part, const ObDataTypeCastParams& dtc_params, const ObIArray* part_ids) const { int ret = OB_SUCCESS; UNUSED(exec_ctx); UNUSED(all_part); if (OB_ISNULL(calc_node)) { ret = OB_INVALID_ARGUMENT; LOG_WARN("Calc node should not be NULL", K(ret)); } else if (calc_node->param_idx_ < 0 && calc_node->value_.is_invalid_type()) { ret = OB_ERR_UNEXPECTED; LOG_WARN("func value node should has param idx or value", K(ret)); } else { bool value_satisfy = true; for (int64_t idx = 0; OB_SUCC(ret) && idx < calc_node->param_value_.count(); ++idx) { const ObPLFuncValueNode::ParamValuePair& pair = calc_node->param_value_.at(idx); if (pair.param_idx_ < 0 || pair.param_idx_ >= params.count()) { ret = OB_INVALID_INDEX; LOG_WARN("Param idx error", K(ret), "param idx", pair.param_idx_, "count", params.count()); } else if (!params.at(pair.param_idx_).is_equal(pair.obj_value_, CS_TYPE_BINARY)) { value_satisfy = false; break; } else { } // do nothing } if (OB_FAIL(ret)) { } else if (!value_satisfy) { all_part = true; } else { ObObj result; if (calc_node->param_idx_ >= 0) { if (calc_node->param_idx_ >= params.count()) { ret = OB_INVALID_INDEX; LOG_WARN("Param idx error", K(ret), "param_idx", calc_node->param_idx_, "count", params.count()); } else { result = params.at(calc_node->param_idx_); } } else { result = calc_node->value_; } if (OB_SUCC(ret)) { ObObj tmp; ObArenaAllocator allocator(CURRENT_CONTEXT->get_malloc_allocator()); allocator.set_label("CalcFVPartIds"); ObCastCtx cast_ctx(&allocator, &dtc_params, CM_NONE, calc_node->res_type_.get_collation_type()); ObExprCtx expr_ctx; bool is_strict = false; int64_t part_idx = OB_INVALID_INDEX; if (OB_FAIL(ObSQLUtils::wrap_expr_ctx(stmt_type_, exec_ctx, allocator, expr_ctx))) { LOG_WARN("Failed to wrap expr ctx", K(ret)); } else if (OB_ISNULL(expr_ctx.my_session_)) { ret = OB_ERR_UNEXPECTED; LOG_ERROR("unexpected error. null session", K(expr_ctx.my_session_), K(ret)); } else if (FALSE_IT(is_strict = is_strict_mode(expr_ctx.my_session_->get_sql_mode()))) { // can not reach here } else if (OB_FAIL(ObExprColumnConv::convert_with_null_check( tmp, result, calc_node->res_type_, is_strict, cast_ctx))) { LOG_WARN("Cast result type failed", K(ret), K(result), "type", calc_node->res_type_.get_type()); } else if (OB_FAIL(calc_partition_id_by_func_value( expr_ctx, part_mgr, tmp, true, partition_ids, part_ids, &part_idx))) { LOG_WARN("Failed to calc partition id by func value", K(ret)); } else { exec_ctx.get_part_row_manager().set_part_idx(part_idx); } } } } return ret; } int ObTableLocation::calc_column_value_partition_ids(ObExecContext& exec_ctx, common::ObPartMgr* part_mgr, const ParamStore& params, const ObPLColumnValueNode* calc_node, ObIArray& partition_ids, bool& all_part, const ObDataTypeCastParams& dtc_params, const ObIArray* part_ids) const { int ret = OB_SUCCESS; UNUSED(part_mgr); UNUSED(all_part); UNUSED(part_ids); if (OB_ISNULL(calc_node)) { ret = OB_INVALID_ARGUMENT; LOG_WARN("Calc node should not be NULL", K(ret)); } else if (calc_node->param_idx_ < 0 && calc_node->value_.is_invalid_type()) { ret = OB_ERR_UNEXPECTED; LOG_WARN("func value node should has param idx or value", K(ret)); } else { ObObj value; if (calc_node->param_idx_ >= 0) { if (calc_node->param_idx_ >= params.count()) { ret = OB_ERR_ILLEGAL_INDEX; LOG_WARN("Param idx error", K(ret), "param_idx", calc_node->param_idx_, "count", params.count()); } else { value = params.at(calc_node->param_idx_); } } else { value = calc_node->value_; } if (OB_SUCC(ret)) { ObObj tmp; ObExprCtx expr_ctx; ObArenaAllocator allocator(CURRENT_CONTEXT->get_malloc_allocator()); allocator.set_label("CalcCVPartIds"); ObCastCtx cast_ctx(&allocator, &dtc_params, CM_NONE, calc_node->res_type_.get_collation_type()); bool is_strict = false; if (OB_FAIL(ObSQLUtils::wrap_expr_ctx(stmt_type_, exec_ctx, allocator, expr_ctx))) { LOG_WARN("Failed to wrap expr ctx", K(ret)); } else if (OB_ISNULL(expr_ctx.my_session_)) { ret = OB_ERR_UNEXPECTED; LOG_ERROR("unexpected error. null session", K(expr_ctx.my_session_), K(ret)); } else if (FALSE_IT(is_strict = is_strict_mode(expr_ctx.my_session_->get_sql_mode()))) { // can not reach here } else if (OB_FAIL(ObExprColumnConv::convert_with_null_check( tmp, value, calc_node->res_type_, is_strict, cast_ctx))) { LOG_WARN("Cast result type failed", K(ret), K(value), "type", calc_node->res_type_); } else { ObNewRow result_row; // allocate obj first void* ptr = NULL; if (NULL == (ptr = allocator.alloc(sizeof(ObObj)))) { ret = OB_ALLOCATE_MEMORY_FAILED; LOG_ERROR("failed to allocate obj", K(ret)); } else { result_row.cells_ = new (ptr) ObObj(); result_row.count_ = 1; result_row.cells_[0] = tmp; if (OB_FAIL(calc_partition_id_by_row(exec_ctx, part_mgr, result_row, partition_ids, part_ids))) { LOG_WARN("Calc partition id by row error", K(ret)); } } } } } return ret; } int ObTableLocation::calc_partition_ids_by_stored_expr(ObExecContext& exec_ctx, common::ObPartMgr* part_mgr, ObIArray& partition_ids, const ObDataTypeCastParams& dtc_params) const { UNUSED(dtc_params); int ret = OB_SUCCESS; if (!is_partitioned_) { if (OB_FAIL(partition_ids.push_back(0))) { LOG_WARN("Failed to push back partition id", K(ret)); } } else if (num_values_ <= 0 || key_conv_exprs_.count() <= 0 || (PARTITION_LEVEL_TWO == part_level_ && subkey_conv_exprs_.count() <= 0)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("Num values, (sub)key conv exprs count should not less than 1", K(ret), K_(num_values), K(key_conv_exprs_.count()), K_(part_level), K(subkey_conv_exprs_.count())); } else { ObArenaAllocator allocator(CURRENT_CONTEXT->get_malloc_allocator()); allocator.set_label("CalcStoredExpr"); ObExprCtx expr_ctx; ObNewRow part_row; ObNewRow subpart_row; ObNewRow part_conv_row; ObNewRow subpart_conv_row; const int64_t key_column_num = key_exprs_.count() / num_values_; const int64_t subkey_column_num = subkey_exprs_.count() / num_values_; const int64_t key_conv_count = key_conv_exprs_.count(); const int64_t subkey_conv_count = subkey_conv_exprs_.count(); // init expr ctx if (OB_FAIL(ObSQLUtils::wrap_expr_ctx(stmt_type_, exec_ctx, allocator, expr_ctx))) { LOG_WARN("Failed to wrap expr ctx", K(ret)); } // init all ObNewRow if (OB_FAIL(ret)) { } else if (OB_FAIL(init_row(allocator, key_column_num, part_row))) { LOG_WARN("Failed to init row", K(ret)); } {} // do nothing if (PARTITION_LEVEL_TWO == part_level_) { if (OB_FAIL(ret)) { } else if (OB_FAIL(init_row(allocator, subkey_column_num, subpart_row))) { LOG_WARN("Failed to init row", K(ret)); } else { } // do nothing } if (OB_FAIL(ret)) { } else if (OB_FAIL(init_row(allocator, key_conv_count, part_conv_row))) { LOG_WARN("Failed to init part conv row", K(ret)); } else if (PARTITION_LEVEL_TWO == part_level_) { if (OB_FAIL(init_row(allocator, subkey_conv_count, subpart_conv_row))) { LOG_WARN("Failed to init subpart conv row", K(ret)); } } else { } // do nothing // calc ObNewRow for calc partition id exec_ctx.get_part_row_manager().reset(); for (int64_t value_idx = 0; OB_SUCC(ret) && value_idx < num_values_; ++value_idx) { // Get part_row for calc conv expr if (OB_FAIL(calc_row(expr_ctx, key_exprs_, key_column_num, value_idx, part_row, part_row))) { LOG_WARN("Failed to calc part row", K(ret)); } else if (OB_FAIL(calc_row(expr_ctx, key_conv_exprs_, key_conv_count, 0, part_row, part_conv_row))) { LOG_WARN("Failed to calc part conv row", K(ret)); } else { } // do nothing // calc partition id and add it to partition ids no duplicate if (OB_SUCC(ret) && PARTITION_LEVEL_TWO == part_level_) { if (OB_FAIL(calc_row(expr_ctx, subkey_exprs_, subkey_column_num, value_idx, subpart_row, subpart_row))) { LOG_WARN("Failed to calc subpart_row", K(ret)); } else if (OB_FAIL( calc_row(expr_ctx, subkey_conv_exprs_, subkey_conv_count, 0, subpart_row, subpart_conv_row))) { LOG_WARN("Failed to calc subpart_conv_row", K(ret)); } else { } // do nothing } if (OB_SUCC(ret)) { if (PARTITION_LEVEL_ONE == part_level_) { if (OB_FAIL(calc_partition_id_by_row(exec_ctx, part_mgr, part_conv_row, partition_ids))) { LOG_WARN("Calc partition id by row error", K(ret)); } } else if (PARTITION_LEVEL_TWO == part_level_) { ObSEArray part_ids; if (OB_FAIL(calc_partition_id_by_row(exec_ctx, part_mgr, part_conv_row, part_ids))) { LOG_WARN("Calc partition id by row error", K(ret)); } else if (OB_FAIL( calc_partition_id_by_row(exec_ctx, part_mgr, subpart_conv_row, partition_ids, &part_ids))) { LOG_WARN("Calc partitioin id by row error", K(ret)); } else { } // do nothing } else { ret = OB_ERR_UNEXPECTED; LOG_WARN("Unexpected partition level", K(ret), K_(part_level)); } } if (OB_SUCC(ret) && is_simple_insert_or_replace() && num_values_ > 1 && !is_virtual_table(ref_table_id_)) { int64_t part_idx = exec_ctx.get_part_row_manager().get_part_idx(); if (OB_FAIL(exec_ctx.get_part_row_manager().add_row_for_part(part_idx, value_idx))) { LOG_WARN("add row for part id failed", K(ret), K(part_idx), K(partition_ids)); } } // As no allocator in obj, this place did not destruct obj. } // end of for value_idx } return ret; } // int ObTableLocation::calc_partition_ids_by_sub_select(ObExecContext &exec_ctx, // common::ObPartMgr *part_mgr, // ObIArray &partition_ids) const //{ // int ret = OB_SUCCESS; // if (!is_partitioned_) { // if (OB_FAIL(partition_ids.push_back(0))) { // LOG_WARN("Failed to add partition id", K(ret)); // } // } else if (same_part_with_select_) { // if (OB_FAIL(calc_sub_select_partition_ids(exec_ctx, partition_ids))) { // LOG_WARN("assign subselect_part ids failed", K(ret)); // } // } else if (PARTITION_LEVEL_ONE == part_level_) { // if (OB_FAIL(get_all_part_ids(exec_ctx, part_mgr, partition_ids))) { // LOG_WARN("Failed to get all part ids", K(ret)); // } // } else if (PARTITION_LEVEL_TWO == part_level_) { // ObSEArray part_ids; // if (OB_FAIL(get_all_part_ids(exec_ctx, part_mgr, part_ids))) { // LOG_WARN("Failed to get all part ids", K(ret)); // } else if (OB_FAIL(get_all_part_ids(exec_ctx, part_mgr, partition_ids, &part_ids))) { // LOG_WARN("Failed to get all subpart ids", K(ret)); // } else { } // } else { // ret = OB_ERR_UNEXPECTED; // LOG_WARN("Unkown part level", K(ret), K(part_level_), K(is_partitioned_)); // } // return ret; //} int ObTableLocation::calc_partition_ids_by_ranges(ObExecContext& exec_ctx, common::ObPartMgr* part_mgr, const ObIArray& ranges, const bool is_all_single_value_ranges, ObIArray& partition_ids, bool& all_part, const ObIArray* part_ids, const ObSqlExpression* gen_col_expr) const { int ret = OB_SUCCESS; bool get_part_by_range = false; bool need_calc_new_range = false; all_part = false; ObSEArray new_ranges; ObArenaAllocator allocator_for_range(CURRENT_CONTEXT->get_malloc_allocator()); if (OB_ISNULL(part_mgr)) { ret = OB_INVALID_ARGUMENT; LOG_WARN("Part mgr should not be NULL", K(ret)); } else if (NULL != gen_col_expr) { get_part_by_range = false; need_calc_new_range = false; all_part = !is_all_single_value_ranges; } else if (NULL == part_ids) { // PARTITION_LEVEL_ONE if (!is_range_part(part_type_) || (PARTITION_FUNC_TYPE_RANGE == part_type_ && !is_col_part_expr_) || (PARTITION_FUNC_TYPE_RANGE_COLUMNS == part_type_ && !is_valid_range_columns_part_range_)) { if (!is_all_single_value_ranges) { if (is_valid_temporal_part_range_) { need_calc_new_range = true; } else { all_part = true; } } } else { get_part_by_range = true; } } else { // PARTITION_LEVEL_TWO if (!is_range_part(subpart_type_) || (PARTITION_FUNC_TYPE_RANGE == subpart_type_ && !is_col_subpart_expr_) || (PARTITION_FUNC_TYPE_RANGE_COLUMNS == subpart_type_ && !is_valid_range_columns_subpart_range_)) { if (!is_all_single_value_ranges) { if (is_valid_temporal_subpart_range_) { need_calc_new_range = true; } else { all_part = true; } } } else { get_part_by_range = true; } } // if the part_key/subpart_key is in the form like year(datetime), the non-single-value range // may be used to prune partition after calc by part_expr if (OB_SUCC(ret) && need_calc_new_range) { bool is_all_single_value_new_ranges = false; if (OB_FAIL(calc_range_by_part_expr( exec_ctx, ranges, part_ids, allocator_for_range, new_ranges, is_all_single_value_new_ranges))) { LOG_WARN("fail to calc range by part expr", K(ret)); } else if ((NULL == part_ids && PARTITION_FUNC_TYPE_RANGE == part_type_) || (NULL != part_ids && PARTITION_FUNC_TYPE_RANGE == subpart_type_)) { get_part_by_range = true; } else if (!is_all_single_value_new_ranges) { all_part = true; } } if (OB_SUCC(ret) && !all_part) { if (get_part_by_range) { if (part_ids != NULL && use_range_part_opt_) { ret = OB_ERR_UNEXPECTED; LOG_WARN("use range part opt with partition level two", K(ret)); } else if (need_calc_new_range) { OZ(get_part_ids_by_ranges(part_mgr, new_ranges, partition_ids, part_ids)); } else if (use_range_part_opt_ && 1 == ranges.count() && ranges.at(0)->is_single_rowkey()) { bool insert_or_replace = is_simple_insert_or_replace(); if (OB_FAIL(get_range_part(ranges.at(0), insert_or_replace, partition_ids))) { LOG_WARN("fail to get range part", K(ret)); } } else if (OB_FAIL(get_part_ids_by_ranges(part_mgr, ranges, partition_ids, part_ids))) { LOG_WARN("Failed to get part ids by ranges", K(ret)); } } else { ObArenaAllocator allocator(CURRENT_CONTEXT->get_malloc_allocator()); allocator.set_label("CalcByRanges"); ObExprCtx expr_ctx; if (OB_FAIL(ObSQLUtils::wrap_expr_ctx(stmt_type_, exec_ctx, allocator, expr_ctx))) { LOG_WARN("Failed to wrap expr ctx", K(ret)); } for (int64_t i = 0; OB_SUCC(ret) && i < ranges.count(); ++i) { ObNewRange* range = ranges.at(i); ObNewRow input_row; if (OB_ISNULL(range)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("invalid range", K(ret)); } else { input_row.cells_ = const_cast(range->start_key_.get_obj_ptr()); input_row.count_ = (range->start_key_.get_obj_cnt()); if (NULL != gen_col_expr) { ObObj gen_col_val; if (OB_FAIL(gen_col_expr->calc(expr_ctx, input_row, gen_col_val))) { LOG_WARN("Failed to get column exprs", K(ret)); } else { ObNewRow result_row; result_row.cells_ = &gen_col_val; result_row.count_ = 1; if (OB_FAIL(calc_partition_id_by_row(exec_ctx, part_mgr, result_row, partition_ids, part_ids))) { LOG_WARN("Failed to calc partition id by row", K(ret)); } } } else if (OB_FAIL(calc_partition_id_by_row(exec_ctx, part_mgr, input_row, partition_ids, part_ids))) { LOG_WARN("Calc partition id by row error", K(ret)); } else { } // do nothing } } } } return ret; } int ObTableLocation::get_part_ids_by_ranges(common::ObPartMgr* part_mgr, const ObIArray& ranges, ObIArray& partition_ids, const ObIArray* part_ids) const { int ret = OB_SUCCESS; if (OB_ISNULL(part_mgr)) { ret = OB_INVALID_ARGUMENT; LOG_WARN("Part mgr should not be NULL", K(ret)); } else if (NULL == part_ids) { if (OB_FAIL(ObPartMgrAD::get_part( part_mgr, ref_table_id_, PARTITION_LEVEL_ONE, -1, default_asc_direction(), ranges, partition_ids))) { LOG_WARN("Failed to get part", K(ret)); } } else { ObSEArray subpart_ids; for (int64_t p_idx = 0; OB_SUCC(ret) && p_idx < part_ids->count(); ++p_idx) { subpart_ids.reuse(); int64_t part_id = part_ids->at(p_idx); if (OB_FAIL(ObPartMgrAD::get_part( part_mgr, ref_table_id_, PARTITION_LEVEL_TWO, part_id, default_asc_direction(), ranges, subpart_ids))) { LOG_WARN("get partition id from part mgr error", K(ret)); } else { for (int64_t s_idx = 0; OB_SUCC(ret) && s_idx < subpart_ids.count(); ++s_idx) { if (OB_FAIL( partition_ids.push_back(generate_phy_part_id(part_id, subpart_ids.at(s_idx), PARTITION_LEVEL_TWO)))) { LOG_WARN("Failed to add partition ids", K(ret)); } } } } } return ret; } int ObTableLocation::calc_partition_id_by_func_value(ObExprCtx& expr_ctx, common::ObPartMgr* part_mgr, const ObObj& func_value, const bool calc_oracle_hash, ObIArray& partition_ids, const ObIArray* part_ids, int64_t* part_idx) const { int ret = OB_SUCCESS; ObObj result = func_value; UNUSED(expr_ctx); if (OB_SUCC(ret) && !is_inner_table(ref_table_id_)) { bool hash_type = false; bool hash_type_v2 = false; if (NULL == part_ids) { hash_type = (PARTITION_FUNC_TYPE_HASH == part_type_); hash_type_v2 = (PARTITION_FUNC_TYPE_HASH_V2 == part_type_); } else { hash_type = (PARTITION_FUNC_TYPE_HASH == subpart_type_); hash_type_v2 = (PARTITION_FUNC_TYPE_HASH_V2 == subpart_type_); } if (hash_type || hash_type_v2) { if (hash_type) { if (share::is_oracle_mode()) { if (calc_oracle_hash && OB_FAIL(ObExprFuncPartOldHash::calc_value_for_oracle(&func_value, 1, result))) { LOG_WARN("Failed to calc hash value oracle mode", K(ret)); } } else { if (OB_FAIL(ObExprFuncPartOldHash::calc_value_for_mysql(func_value, result))) { LOG_WARN("Failed to calc hash value mysql mode", K(ret)); } } } else if (hash_type_v2) { if (share::is_oracle_mode()) { if (calc_oracle_hash && OB_FAIL(ObExprFuncPartHash::calc_value_for_oracle(&func_value, 1, result))) { LOG_WARN("Failed to calc hash value oracle mode", K(ret)); } } else { if (OB_FAIL(ObExprFuncPartHash::calc_value_for_mysql(func_value, result))) { LOG_WARN("Failed to calc hash value mysql mode", K(ret)); } } } } } if (OB_FAIL(ret)) { } else if (is_virtual_table(ref_table_id_) || is_inner_table(ref_table_id_)) { // only one level and part expr has part type name, like hash(), key() int64_t calc_result = 0; int64_t part_id = 0; if (OB_FAIL(result.get_int(calc_result))) { LOG_WARN("Fail to get int64 from result", K(result), K(ret)); } else if (OB_INVALID_PARTITION_ID == calc_result && is_virtual_table(ref_table_id_)) { // addr is invalid, and partition id calculated by this addr is also invalid, so, do nothing } else if (OB_FAIL(get_part_id_by_mod(calc_result, part_num_, part_id))) { LOG_WARN("Fail to calculate part id", K(ret)); } else if (OB_FAIL(add_var_to_array_no_dup(partition_ids, part_id, part_idx))) { LOG_WARN("Fail to add partition id into array no duplicate", K(ret)); } else { } } else { if (NULL == part_ids) { if (OB_FAIL(ObPartMgrAD::get_part(part_mgr, ref_table_id_, PARTITION_LEVEL_ONE, part_type_, report_err_for_pruned_partition_not_exist_, -1, result, partition_ids, part_idx))) { LOG_WARN("Failed to get part id", K(ret)); } } else { for (int64_t idx = 0; OB_SUCC(ret) && idx < part_ids->count(); ++idx) { if (OB_FAIL(ObPartMgrAD::get_part(part_mgr, ref_table_id_, PARTITION_LEVEL_TWO, subpart_type_, report_err_for_pruned_partition_not_exist_, part_ids->at(idx), result, partition_ids, part_idx))) { LOG_WARN("Failed to get part id", K(ret)); } } } } return ret; } int ObTableLocation::calc_partition_ids_by_rowkey(ObExecContext& exec_ctx, ObPartMgr* part_mgr, const ObIArray& rowkeys, ObIArray& part_ids, ObIArray& rowkey_lists) const { int ret = OB_SUCCESS; ObNewRow cur_row; RowkeyArray rowkey_list; ObSEArray tmp_part_ids; ObNewRow* part_row = NULL; for (int64_t i = 0; OB_SUCC(ret) && i < rowkeys.count(); ++i) { cur_row.cells_ = const_cast(rowkeys.at(i).get_obj_ptr()); cur_row.count_ = rowkeys.at(i).get_obj_cnt(); if (OB_FAIL(part_projector_.calc_part_row(stmt_type_, exec_ctx, cur_row, part_row)) || OB_ISNULL(part_row)) { ret = COVER_SUCC(OB_ERR_UNEXPECTED); LOG_WARN("calc part row failed", K(ret)); } else if (PARTITION_LEVEL_ONE == part_level_) { if (OB_FAIL(calc_partition_id_by_row(exec_ctx, part_mgr, *part_row, part_ids))) { LOG_WARN("calc partition id by row failed", K(ret)); } } else { tmp_part_ids.reuse(); if (OB_FAIL(calc_partition_id_by_row(exec_ctx, part_mgr, *part_row, tmp_part_ids))) { LOG_WARN("calc partition id by row failed", K(ret)); } else if (OB_FAIL(calc_partition_id_by_row(exec_ctx, part_mgr, *part_row, part_ids, &tmp_part_ids))) { LOG_WARN("calc sub partition id by row failed", K(ret)); } } if (OB_SUCC(ret) && !use_calc_part_by_rowid_) { int64_t part_idx = exec_ctx.get_part_row_manager().get_part_idx(); if (OB_UNLIKELY(part_idx >= 0 && part_idx < rowkey_lists.count())) { if (OB_FAIL(rowkey_lists.at(part_idx).push_back(i))) { LOG_WARN("store rowkey to rowkey_lists failed", K(ret)); } } else if (OB_LIKELY(rowkey_lists.count() == part_idx)) { rowkey_list.reuse(); if (OB_FAIL(rowkey_list.push_back(i))) { LOG_WARN("store rowkey to rowkey_list failed", K(ret)); } else if (OB_FAIL(rowkey_lists.push_back(rowkey_list))) { LOG_WARN("store rowkey list failed", K(ret)); } } else { ret = OB_ERR_UNEXPECTED; LOG_WARN("part_idx is invalid", K(part_idx), K(rowkey_lists.count())); } } } return ret; } int ObTableLocation::get_list_part( const ObNewRow& row, bool insert_or_replace, common::ObIArray& partition_ids, int64_t* part_idx) const { UNUSED(insert_or_replace); int ret = OB_SUCCESS; ObListPartMapValue* value = NULL; ObListPartMapKey key; key.row_ = row; ret = list_part_map_.get_refactored(key, value); if (ret == OB_HASH_NOT_EXIST) { LOG_TRACE("get list part not exist", K(key)); if (list_default_part_id_ == OB_INVALID_ID) { if (report_err_for_pruned_partition_not_exist_) { ret = OB_NO_PARTITION_FOR_GIVEN_VALUE; } else { ret = OB_SUCCESS; } } else { if (OB_FAIL(add_var_to_array_no_dup(partition_ids, list_default_part_id_, part_idx))) { LOG_WARN("Failed to add var to array no dup", K(ret)); } } } else if (OB_FAIL(ret)) { LOG_WARN("fail to get_refactored", K(ret), K(inited_)); } else { if (OB_FAIL(add_var_to_array_no_dup(partition_ids, value->part_id_, part_idx))) { LOG_WARN("Failed to add var to array no dup", K(ret)); } } return ret; } int ObTableLocation::get_list_part( ObObj& obj, bool insert_or_replace, common::ObIArray& partition_ids, int64_t* part_idx) const { ObNewRow row; row.assign(&obj, 1); return get_list_part(row, insert_or_replace, partition_ids, part_idx); } int ObTableLocation::get_hash_part( const ObObj& func_value, bool insert_or_replace, common::ObIArray& partition_ids, int64_t* part_idx) const { int ret = OB_SUCCESS; int64_t partition_idx = 0; int64_t val = 0; int64_t partition_id = 0; UNUSED(insert_or_replace); if (OB_FAIL(func_value.get_int(val))) { LOG_WARN("failed to get int val", K(ret)); } else if (val < 0) { ret = OB_ERR_UNEXPECTED; LOG_WARN("Val should not be less than 0", K(ret), K(val)); } else if (OB_FAIL(ObPartitionUtils::calc_hash_part_idx(val, first_part_num_, partition_idx))) { LOG_WARN("Failed to get hash part", K(ret)); } else if (partition_idx < 0 || partition_idx > first_part_num_) { ret = OB_INVALID_ARGUMENT; LOG_WARN("invalid argument", K(ret), K(partition_idx), K(first_part_num_)); } else if (OB_FAIL(get_part_id_from_part_idx(partition_idx, partition_id))) { LOG_WARN("failed to get part id from part idx", K(ret), K(partition_idx)); } else if (OB_FAIL(add_var_to_array_no_dup(partition_ids, partition_id, part_idx))) { LOG_WARN("Failed to add var to array no dup", K(ret)); } LOG_TRACE("optimization in get_hash_part", K(first_part_num_), K(insert_or_replace), K(fast_calc_part_opt_), K(ret), K(func_value), K(partition_idx), K(*part_idx), K(inited_)); return ret; } int ObTableLocation::get_range_part( const ObNewRow& row, bool insert_or_replace, common::ObIArray& partition_ids, int64_t* part_idx) const { UNUSED(insert_or_replace); int ret = OB_SUCCESS; int64_t high = partition_num_ - 1; int64_t low = 0; int64_t mid = 0; int64_t res = high; const ObObj& cur_obj = row.get_cell(0); if (1 != row.get_count()) { ret = OB_ERR_UNEXPECTED; LOG_WARN("get range part with optimization should have 1 column", K(ret), K(row.get_count())); } else if (cur_obj.is_null()) { // For Insert or replace stmt, if no partition, report error if (!range_obj_arr_[high].is_max_value() && report_err_for_pruned_partition_not_exist_) { ret = OB_NO_PARTITION_FOR_GIVEN_VALUE; LOG_USER_WARN(OB_NO_PARTITION_FOR_GIVEN_VALUE); } } else { while (low <= high) { mid = (low + high) / 2; if (ObObjCmpFuncs::compare_oper_nullsafe( range_obj_arr_[mid], cur_obj, range_obj_arr_[mid].get_collation_type(), CO_GT)) { high = mid - 1; res = mid; } else { low = mid + 1; } } // while if (res == partition_num_ - 1) { if (!range_obj_arr_[res].is_max_value() && !ObObjCmpFuncs::compare_oper_nullsafe( range_obj_arr_[res], cur_obj, range_obj_arr_[mid].get_collation_type(), CO_GT)) { if (report_err_for_pruned_partition_not_exist_) { ret = OB_NO_PARTITION_FOR_GIVEN_VALUE; LOG_USER_WARN(OB_NO_PARTITION_FOR_GIVEN_VALUE); } } } } if (OB_FAIL(ret)) { } else if (OB_FAIL(add_var_to_array_no_dup(partition_ids, range_part_id_arr_[res], part_idx))) { LOG_WARN("Failed to add var to array no dup", K(ret)); } LOG_TRACE("optimization in get_range_part", K(partition_num_), K(insert_or_replace), K(ret), K(row), K(cur_obj), K(res), K(range_part_id_arr_[res]), K(*part_idx), K(partition_ids)); return ret; } int ObTableLocation::get_range_part( const ObNewRange* range, bool insert_or_replace, common::ObIArray& partition_ids) const { int ret = OB_SUCCESS; ObNewRow input_row; int64_t part_idx = 0; if (OB_ISNULL(range)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("invalid range", K(ret)); } else { input_row.cells_ = const_cast(range->start_key_.get_obj_ptr()); input_row.count_ = (range->start_key_.get_obj_cnt()); if (OB_FAIL(get_range_part(input_row, insert_or_replace, partition_ids, &part_idx))) { LOG_WARN("failed to get range part by ObNewRow", K(ret)); } } return ret; } int ObTableLocation::calc_partition_id_by_row(ObExecContext& exec_ctx, common::ObPartMgr* part_mgr, ObNewRow& row, ObIArray& partition_ids, const ObIArray* part_ids) const { int ret = OB_SUCCESS; ObObj func_result; ObTaskExecutorCtx* tctx = NULL; ObArenaAllocator allocator(CURRENT_CONTEXT->get_malloc_allocator()); allocator.set_label("CalcByRow"); ObExprCtx expr_ctx; if (OB_FAIL(ObSQLUtils::wrap_expr_ctx(stmt_type_, exec_ctx, allocator, expr_ctx))) { LOG_WARN("Failed to wrap expr ctx", K(ret)); } else if (is_virtual_table(ref_table_id_) && OB_ISNULL(tctx = GET_TASK_EXECUTOR_CTX(exec_ctx))) { ret = OB_ERR_UNEXPECTED; LOG_WARN("task exec ctx is NULL", K(ret)); } else if (is_virtual_table(ref_table_id_) && OB_FAIL(tctx->init_calc_virtual_part_id_params(ref_table_id_))) { LOG_WARN("fail to init_calc_virtual_part_id_params", K(ret), K(ref_table_id_)); tctx->reset_calc_virtual_part_id_params(); } else { bool insert_or_replace = is_simple_insert_or_replace(); bool range_columns = false; int64_t part_idx = OB_INVALID_INDEX; if (NULL == part_ids) { if (PARTITION_FUNC_TYPE_RANGE_COLUMNS == part_type_ || PARTITION_FUNC_TYPE_LIST_COLUMNS == part_type_) { part_projector_.project_part_row(PARTITION_LEVEL_ONE, row); if (related_part_expr_idx_ == OB_INVALID_INDEX) { if (use_list_part_map_) { if (OB_FAIL(get_list_part(row, report_err_for_pruned_partition_not_exist_, partition_ids, &part_idx))) { LOG_WARN("fail to get list part", K(row), K(ret)); } } else if (use_range_part_opt_) { if (OB_FAIL(get_range_part(row, report_err_for_pruned_partition_not_exist_, partition_ids, &part_idx))) { LOG_WARN("fail to get range part", K(row), K(ret)); } } else { if (OB_FAIL(ObPartMgrAD::get_part(part_mgr, ref_table_id_, PARTITION_LEVEL_ONE, part_type_, report_err_for_pruned_partition_not_exist_, -1, row, partition_ids, &part_idx))) { LOG_WARN("Failed to get part id", K(ret), K(row)); } } if (OB_SUCC(ret)) { exec_ctx.get_part_row_manager().set_part_idx(part_idx); } } else { if (OB_ISNULL(part_expr_)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("part_expr_ should not be NULL", K(ret), K(table_id_), K(ref_table_id_)); } else if (OB_FAIL(part_expr_->calc(expr_ctx, row, func_result))) { LOG_WARN("Failed to calc hash expr", K(ret), K(row), K(ref_table_id_)); } else { if (use_list_part_map_) { if (OB_FAIL(get_list_part( func_result, report_err_for_pruned_partition_not_exist_, partition_ids, &part_idx))) { LOG_WARN("fail to get list part", K(ret)); } } else if (use_range_part_opt_) { if (OB_FAIL(get_range_part(row, report_err_for_pruned_partition_not_exist_, partition_ids, &part_idx))) { LOG_WARN("fail to get range part", K(ret)); } } else { if (OB_FAIL(ObPartMgrAD::get_part(part_mgr, ref_table_id_, PARTITION_LEVEL_ONE, part_type_, report_err_for_pruned_partition_not_exist_, -1, func_result, partition_ids, &part_idx))) { LOG_WARN("Failed to get part id", K(ret), K(func_result)); } } if (OB_SUCC(ret)) { exec_ctx.get_part_row_manager().set_part_idx(part_idx); } } } range_columns = true; } else if (OB_ISNULL(part_expr_)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("part_expr_ should not be NULL", K(ret), K(table_id_), K(ref_table_id_)); } else if (OB_FAIL(part_expr_->calc(expr_ctx, row, func_result))) { LOG_WARN("Failed to calc hash expr", K(ret), K(row), K(ref_table_id_)); } else { } } else if (PARTITION_FUNC_TYPE_RANGE_COLUMNS == subpart_type_ || PARTITION_FUNC_TYPE_LIST_COLUMNS == subpart_type_) { part_projector_.project_part_row(PARTITION_LEVEL_TWO, row); for (int64_t idx = 0; OB_SUCC(ret) && idx < part_ids->count(); ++idx) { if (OB_FAIL(ObPartMgrAD::get_part(part_mgr, ref_table_id_, PARTITION_LEVEL_TWO, subpart_type_, report_err_for_pruned_partition_not_exist_, part_ids->at(idx), row, partition_ids, &part_idx))) { LOG_WARN("Failed to get part id", K(ret)); } } range_columns = true; if (OB_SUCC(ret)) { exec_ctx.get_part_row_manager().set_part_idx(part_idx); } } else if (OB_ISNULL(subpart_expr_)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("subpart_expr_ should not be NULL", K(ret)); } else if (OB_FAIL(subpart_expr_->calc(expr_ctx, row, func_result))) { LOG_WARN("Failed to calc hash expr", K(ret), K(row), K(ref_table_id_)); } else { } // do nothing if (OB_FAIL(ret) || range_columns) { } else { if (use_hash_part_opt_) { if (OB_FAIL(get_hash_part(func_result, report_err_for_pruned_partition_not_exist_, partition_ids, &part_idx))) { LOG_WARN("fail to get hash part", K(ret)); } } else if (OB_FAIL(calc_partition_id_by_func_value( expr_ctx, part_mgr, func_result, false, partition_ids, part_ids, &part_idx))) { LOG_WARN("Failed to calc partiton id by func value", K(ret)); } if (OB_SUCC(ret)) { exec_ctx.get_part_row_manager().set_part_idx(part_idx); } } if (is_virtual_table(ref_table_id_)) { tctx->reset_calc_virtual_part_id_params(); } } return ret; } int ObTableLocation::get_all_part_ids(ObExecContext& exec_ctx, common::ObPartMgr* part_mgr, ObIArray& partition_ids, const ObIArray* part_ids) const { int ret = OB_SUCCESS; if (!is_partitioned_) { if (OB_FAIL(partition_ids.push_back(0))) { LOG_WARN("Failed to add partition id", K(ret)); } } else if (is_partitioned_ && is_virtual_table(ref_table_id_)) { if (OB_FAIL(get_vt_partition_id(exec_ctx, ref_table_id_, &partition_ids, NULL))) { LOG_WARN("Failed to get virtual table partition ids", K_(ref_table_id), K(ret)); } } else if (is_inner_table(ref_table_id_)) { for (int64_t i = 0; OB_SUCC(ret) && i < part_num_; ++i) { if (OB_FAIL(partition_ids.push_back(i))) { LOG_WARN("Push partition id to partition_ids error", "partition id", i, K(ret)); } } } else { if (NULL == part_ids) { if (OB_FAIL(ObPartMgrAD::get_all_part( part_mgr, ref_table_id_, PARTITION_LEVEL_ONE, -1, default_asc_direction(), partition_ids))) { LOG_WARN("Failed to get all partition ids", K(ret)); } } else { ObSEArray sub_part_ids; for (int64_t idx = 0; OB_SUCC(ret) && idx < part_ids->count(); ++idx) { sub_part_ids.reuse(); int64_t part_id = part_ids->at(idx); if (OB_FAIL(ObPartMgrAD::get_all_part(part_mgr, ref_table_id_, PARTITION_LEVEL_TWO, part_ids->at(idx), default_asc_direction(), sub_part_ids))) { LOG_WARN("Failed to get all part", K(ret)); } else { for (int64_t s_idx = 0; OB_SUCC(ret) && s_idx < sub_part_ids.count(); ++s_idx) { int64_t phy_part_id = generate_phy_part_id(part_id, sub_part_ids.at(s_idx), PARTITION_LEVEL_TWO); if (OB_FAIL(add_var_to_array_no_dup(partition_ids, phy_part_id))) { LOG_WARN("Failed to add part id to partition_ids", K(ret)); } } } } } } return ret; } int ObTableLocation::deal_dml_partition_selection(int64_t part_id) const { int ret = OB_SUCCESS; if (!part_hint_ids_.empty()) { bool found = false; for (int j = 0; !found && j < part_hint_ids_.count(); j++) { if (part_id == part_hint_ids_.at(j)) { found = true; } } if (!found) { ret = OB_PARTITION_NOT_MATCH; LOG_DEBUG("Partition not match", K(ret), K(part_id)); } } return ret; } int ObTableLocation::deal_partition_selection(ObIArray& part_ids) const { int ret = OB_SUCCESS; if (is_simple_insert_or_replace()) { // if insert partition can be resolved accurately, deal partition selection in the plan generated phase if (!part_get_all_) { for (int i = 0; OB_SUCC(ret) && i < part_ids.count(); ++i) { if (OB_FAIL(deal_dml_partition_selection(part_ids.at(i)))) { LOG_WARN("deal insert partition selection failed", K(ret)); } } } } else { // other stmt_types ObSEArray tmp_ids; for (int i = 0; OB_SUCC(ret) && i < part_ids.count(); i++) { if (OB_FAIL(tmp_ids.push_back(part_ids.at(i)))) { LOG_WARN("Push partition id to part_ids error", "partition id", part_ids.at(i), K(ret)); } } part_ids.reset(); bool found = false; for (int tmp_idx = 0; OB_SUCC(ret) && tmp_idx < tmp_ids.count(); tmp_idx++) { found = false; for (int hint_idx = 0; !found && hint_idx < part_hint_ids_.count(); hint_idx++) { if (tmp_ids.at(tmp_idx) == part_hint_ids_.at(hint_idx)) { found = true; } } if (found && OB_FAIL(part_ids.push_back(tmp_ids.at(tmp_idx)))) { LOG_WARN("Push partition id to part_ids error", "partition id", tmp_ids.at(tmp_idx), K(ret)); } } } return ret; } int ObTableLocation::add_and_node(ObPartLocCalcNode* l_node, ObPartLocCalcNode*& r_node) { int ret = OB_SUCCESS; if (NULL == l_node && NULL == r_node) { ret = OB_INVALID_ARGUMENT; LOG_WARN("l_node and r_node should not both be NULL", K(ret)); } else if (NULL == l_node || NULL == r_node) { r_node = (NULL == l_node) ? r_node : l_node; } else { ObPLAndNode* and_node = NULL; if (NULL == (and_node = static_cast( ObPartLocCalcNode::create_part_calc_node(allocator_, calc_nodes_, ObPartLocCalcNode::CALC_AND)))) { ret = OB_ALLOCATE_MEMORY_FAILED; LOG_ERROR("Failed to allocate part calc node", K(ret)); } else { and_node->left_node_ = l_node; and_node->right_node_ = r_node; r_node = and_node; } } return ret; } int ObTableLocation::add_or_node(ObPartLocCalcNode* l_node, ObPartLocCalcNode*& r_node) { int ret = OB_SUCCESS; if (OB_ISNULL(l_node)) { ret = OB_INVALID_ARGUMENT; LOG_WARN("l_node should not be NULL", K(ret)); } else if (NULL == r_node) { r_node = l_node; } else { ObPLOrNode* or_node = NULL; if (NULL == (or_node = static_cast( ObPartLocCalcNode::create_part_calc_node(allocator_, calc_nodes_, ObPartLocCalcNode::CALC_OR)))) { ret = OB_ALLOCATE_MEMORY_FAILED; LOG_ERROR("Failed to allocate part calc node", K(ret)); } else { or_node->left_node_ = l_node; or_node->right_node_ = r_node; r_node = or_node; } } return ret; } ///////private functions only use sql_expression_factory_ and expr_op_factory_.//// ///////These functions can moved to nother place. //// int ObTableLocation::record_insert_part_info(ObInsertStmt& insert_stmt, ObSQLSessionInfo* session_info, const ObIArray& partition_columns, IKeyExprs& key_exprs, IKeyExprs& key_conv_exprs) { int ret = OB_SUCCESS; const ObIArray* value_desc = NULL; const ObIArray* table_columns = insert_stmt.get_table_columns(); const ObIArray* value_vector = NULL; const int64_t part_column_count = partition_columns.count(); ObSEArray value_desc_heap_table; ObSEArray value_vector_heap_table; if (insert_stmt.get_part_generated_col_dep_cols().count() == 0) { value_desc = &insert_stmt.get_values_desc(); value_vector = &insert_stmt.get_value_vectors(); } else { // generated col as part key in heap table, need get all dep col as value desc OZ(insert_stmt.get_values_desc_for_heap_table(value_desc_heap_table)); OZ(insert_stmt.get_value_vectors_for_heap_table(value_vector_heap_table)); OX(value_desc = &value_desc_heap_table); OX(value_vector = &value_vector_heap_table); } if (OB_SUCC(ret)) { const int64_t value_desc_count = value_desc->count(); const int64_t value_count = value_vector->count(); ObSEArray value_need_idx; // construct pkey idx if (insert_stmt.is_all_const_values()) { for (int64_t key_idx = 0; OB_SUCC(ret) && key_idx < part_column_count; key_idx++) { // column num of partition key uint64_t column_id = partition_columns.at(key_idx).column_id_; if (OB_FAIL(add_key_col_idx_in_val_desc(*value_desc, column_id, value_need_idx))) { LOG_WARN("Failed to get key column idx", K(ret)); } } } else { for (int64_t value_idx = 0; OB_SUCC(ret) && value_idx < value_desc_count; ++value_idx) { // Value with subquery can't be calculated, remove it from value_need_idx. // Previous code already guarantee that part key not contain subquery. bool has_subquery = false; for (int64_t j = value_idx; OB_SUCC(ret) && !has_subquery && j < value_count; j += value_desc_count) { ObRawExpr *expr = value_vector->at(j); if (OB_ISNULL(expr)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("get null expr", K(ret), K(j)); } else if (expr->has_flag(CNT_SUB_QUERY) || expr->has_flag(CNT_EXEC_PARAM)) { has_subquery = true; } } if (OB_SUCC(ret) && !has_subquery) { if (OB_ISNULL(value_desc->at(value_idx))) { ret = OB_ERR_UNEXPECTED; LOG_WARN("value desc expr is null"); } else if (OB_FAIL(value_need_idx.push_back(value_idx))) { LOG_WARN("Failed to add value idx", K(ret)); } } } } const int64_t num_keys = value_need_idx.count(); // construct value_row_desc with value_need_idx RowDesc value_row_desc; RowDesc extra_row_desc; ObColumnRefRawExpr* expr = NULL; if (OB_SUCC(ret)) { if (OB_FAIL(value_row_desc.init())) { LOG_WARN("Value row desc init error", K(ret)); } else if (OB_FAIL(extra_row_desc.init())) { LOG_WARN("Extra row desc init error", K(ret)); } } for (int64_t need_idx = 0; OB_SUCC(ret) && need_idx < num_keys; ++need_idx) { if (OB_FAIL(value_desc->at(value_need_idx.at(need_idx), expr))) { LOG_WARN("value need idx error", K(ret), K(need_idx), "value desc cnt", value_desc->count()); } else if (OB_ISNULL(expr)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("expr is NULL", K(ret)); } else if (OB_FAIL(value_row_desc.add_column(expr))) { LOG_WARN("Failed to add column", K(ret)); } else if (OB_FAIL(expr->add_flag(IS_COLUMNLIZED))) { LOG_WARN("Failed to add IS_COLUMNLIZED flag", K(ret)); } else { } // do nothing } ObColumnRefRawExpr* value_column = NULL; ObColumnRefRawExpr* table_column = NULL; for (int64_t i = 0; OB_SUCC(ret) && i < value_row_desc.get_columns().count(); i++) { OV(value_row_desc.get_column(i)->get_expr_type() == T_REF_COLUMN); OV(OB_NOT_NULL(value_column = static_cast(value_row_desc.get_column(i)))); for (int64_t j = 0; OB_SUCC(ret) && j < table_columns->count(); j++) { OV(OB_NOT_NULL(table_column = table_columns->at(j))); if (value_column->get_column_id() == table_column->get_column_id()) { OZ(extra_row_desc.add_column(table_column)); } } } OV(value_row_desc.get_columns().count() == extra_row_desc.get_columns().count(), OB_ERR_UNEXPECTED, value_row_desc.get_columns(), extra_row_desc.get_columns()); // Add value_expr to key_exprs if (OB_FAIL(ret)) { } else if (0 == value_desc_count || 0 != (value_count % value_desc_count)) { ret = OB_ERR_UNEXPECTED; SQL_OPT_LOG(WARN, "invalid row desc", K(ret), K(value_count), K(value_desc_count)); } else { num_values_ = value_count / value_desc_count; ObRawExpr* value_expr = NULL; for (int64_t value_idx = 0; OB_SUCC(ret) && !part_get_all_ && value_idx < num_values_; ++value_idx) { for (int64_t key_idx = 0; OB_SUCC(ret) && !part_get_all_ && key_idx < num_keys; ++key_idx) { if (OB_FAIL(value_vector->at(value_need_idx.at(key_idx) + value_idx * value_desc_count, value_expr))) { LOG_WARN("Failed to get value expr", K(ret)); } else if (OB_NOT_NULL(value_expr) && (value_expr->has_flag(CNT_RAND_FUNC) || value_expr->has_flag(CNT_STATE_FUNC))) { part_get_all_ = true; } else if (OB_FAIL(add_key_expr_with_row_desc(key_exprs, value_row_desc, value_expr))) { LOG_WARN("Failed to add key expr", K(ret)); } else { } } // end of for key_idx } // end of for value_idx } // Get key column conv expression for (int64_t key_idx = 0; OB_SUCC(ret) && key_idx < partition_columns.count(); ++key_idx) { uint64_t column_id = partition_columns.at(key_idx).column_id_; if (OB_FAIL(add_key_conv_expr( insert_stmt, session_info, value_row_desc, extra_row_desc, column_id, key_conv_exprs))) { LOG_WARN("Add key conv exprs", K(ret)); } } if (OB_SUCC(ret) && !part_get_all_ && NONE_FAST_CALC == fast_calc_part_opt_ && share::is_oracle_mode()) { ObRawExpr* value_expr = NULL; ObRawExpr* col_conv_expr = NULL; ObColumnRefRawExpr* col_expr = NULL; if (1 == num_values_ && 1 == num_keys && 1 == partition_columns.count() && 1 == key_exprs_.count()) { if (OB_FAIL(value_vector->at(value_need_idx.at(0), value_expr))) { LOG_WARN("Failed to get value expr", K(ret)); } else { const ObIArray& column_conv_exprs = insert_stmt.get_column_conv_functions(); const ObIArray* table_column = insert_stmt.get_table_columns(); bool found = false; for (int64_t idx = 0; OB_SUCC(ret) && !found && idx < table_column->count(); ++idx) { if (OB_ISNULL(col_expr = table_column->at(idx))) { ret = OB_ERR_UNEXPECTED; LOG_WARN("get invalid column item", K(ret), K(col_expr), K(idx)); } else if (partition_columns.at(0).column_id_ != col_expr->get_column_id()) { // do nothing } else if (OB_ISNULL(col_conv_expr = column_conv_exprs.at(idx))) { ret = OB_ERR_UNEXPECTED; LOG_WARN("Column conv expr should not be NULL", K(ret)); } else { found = true; } } if (found && OB_SUCC(ret)) { const ObPostExprItem& key_item = key_exprs_.at(0)->get_expr_items().at(0); if (IS_DATATYPE_OR_QUESTIONMARK_OP(key_item.get_item_type())) { if (value_expr->get_data_type() == col_conv_expr->get_data_type()) { fast_calc_part_opt_ = UNKNOWN_FAST_CALC; } else if (ob_is_string_tc(value_expr->get_data_type()) && ob_is_string_tc(col_conv_expr->get_data_type())) { fast_calc_part_opt_ = UNKNOWN_FAST_CALC; } } } } } LOG_TRACE("check can fast calc id opt ", K(fast_calc_part_opt_), K(ret)); } if (NONE_FAST_CALC == fast_calc_part_opt_) { fast_calc_part_opt_ = CANNOT_FAST_CALC; } if (OB_SUCC(ret)) { if (OB_FAIL(clear_columnlized_in_row_desc(value_row_desc))) { LOG_WARN("Failed to clear columnlized in row desc", K(ret)); } } } return ret; } int ObTableLocation::gen_insert_part_row_projector(const ObRawExpr* partition_raw_expr, const ObIArray& partition_columns, ObPartitionLevel part_level, ObPartitionFuncType part_type) { int ret = OB_SUCCESS; if (PARTITION_FUNC_TYPE_RANGE_COLUMNS == part_type || PARTITION_FUNC_TYPE_LIST_COLUMNS == part_type) { RowDesc part_row_desc; if (OB_FAIL(part_row_desc.init())) { LOG_WARN("init part row desc failed", K(ret)); } for (int64_t i = 0; OB_SUCC(ret) && i < partition_columns.count(); ++i) { uint64_t column_id = partition_columns.at(i).column_id_; ObRawExpr* expr = partition_columns.at(i).expr_; if (OB_FAIL(part_row_desc.add_column(expr))) { LOG_WARN("add column to part row desc failed", K(ret), K(i), K(column_id), KPC(expr)); } } if (OB_SUCC(ret)) { if (OB_FAIL(part_projector_.init_part_projector(partition_raw_expr, part_level, part_row_desc))) { LOG_WARN("init part row projector failed", K(ret), K(part_row_desc), KPC(partition_raw_expr)); } else if (OB_FAIL(clear_columnlized_in_row_desc(part_row_desc))) { LOG_WARN("Failed to clear columnlized in row desc", K(ret)); } } } return ret; } int ObTableLocation::add_key_col_idx_in_val_desc( const ObIArray& value_desc, const uint64_t column_id, ObIArray& value_need_idx) { int ret = OB_SUCCESS; const int64_t value_desc_count = value_desc.count(); bool found = false; for (int64_t idx = 0; OB_SUCC(ret) && !found && idx < value_desc_count; ++idx) { if (OB_ISNULL(value_desc.at(idx))) { ret = OB_ERR_UNEXPECTED; LOG_WARN("invalid row desc"); } else if (value_desc.at(idx)->get_column_id() != column_id) { // do nothing } else if (OB_FAIL(value_need_idx.push_back(idx))) { LOG_WARN("Failed to add key col idx", K(ret)); } else { found = true; } } return ret; } int ObTableLocation::add_key_conv_expr(ObInsertStmt& insert_stmt, ObSQLSessionInfo* session_info, RowDesc& value_row_desc, RowDesc& extra_row_desc, uint64_t column_id, IKeyExprs& key_conv_exprs) { int ret = OB_SUCCESS; UNUSED(extra_row_desc); bool found = false; const ObIArray* table_column = insert_stmt.get_table_columns(); const ObIArray& column_conv_exprs = insert_stmt.get_column_conv_functions(); ObRawExpr* col_conv_expr = NULL; ObColumnRefRawExpr* col_expr = NULL; ObRawExprFactory expr_factory(allocator_); CK(OB_NOT_NULL(table_column)); CK(table_column->count() == column_conv_exprs.count()); CK(OB_NOT_NULL(session_info)); for (int64_t idx = 0; OB_SUCC(ret) && !found && idx < table_column->count(); ++idx) { RowDesc* row_desc = NULL; if (OB_ISNULL(col_expr = table_column->at(idx))) { ret = OB_ERR_UNEXPECTED; LOG_WARN("get invalid column item", K(ret), K(col_expr), K(idx)); } else if (column_id != col_expr->get_column_id()) { // do nothing } else if (OB_ISNULL(col_conv_expr = column_conv_exprs.at(idx))) { ret = OB_ERR_UNEXPECTED; LOG_WARN("Column conv expr should not be NULL", K(ret)); } else { // row_desc = col_conv_expr->is_for_generated_column() ? &extra_row_desc : &value_row_desc; row_desc = &value_row_desc; if (col_conv_expr->is_for_generated_column() && !session_info->use_static_typing_engine()) { ObRawExpr* copy_expr = NULL; if (OB_FAIL(ObRawExprUtils::copy_expr(expr_factory, col_conv_expr, copy_expr, COPY_REF_DEFAULT))) { LOG_WARN("deep copy expr failed", K(ret)); } else if (OB_FAIL(recursive_convert_generated_column(*table_column, column_conv_exprs, copy_expr))) { LOG_WARN("faield to recursive convert generated column", K(ret)); } else { col_conv_expr = copy_expr; } } if (OB_FAIL(ret)) { } else if (OB_FAIL(add_key_expr_with_row_desc(key_conv_exprs, *row_desc, col_conv_expr))) { LOG_WARN("Failed to add key expr", K(ret)); } else { found = true; } } } return ret; } int ObTableLocation::clear_columnlized_in_row_desc(RowDesc& row_desc) { int ret = OB_SUCCESS; int64_t row_desc_count = row_desc.get_column_num(); ObRawExpr* expr = NULL; for (int64_t idx = 0; OB_SUCC(ret) && idx < row_desc_count; ++idx) { if (OB_ISNULL(expr = row_desc.get_column(idx))) { ret = OB_ERR_UNEXPECTED; LOG_WARN("Expr in row desc should not be NULL", K(ret)); } else if (OB_FAIL(expr->clear_flag(IS_COLUMNLIZED))) { LOG_WARN("Failed to clear IS_COLUMNLIZED flag", K(ret)); } else { } // do nothing } return ret; } int ObTableLocation::init_row(ObIAllocator& allocator, const int64_t column_num, ObNewRow& row) const { int ret = OB_SUCCESS; void* ptr = NULL; if (column_num <= 0) { } else if (OB_ISNULL(ptr = allocator.alloc(sizeof(ObObj) * column_num))) { ret = OB_ALLOCATE_MEMORY_FAILED; LOG_ERROR("failed to allocate pkey values", K(ret), K(column_num)); } else { row.cells_ = new (ptr) ObObj[column_num]; row.count_ = column_num; } return ret; } int ObTableLocation::calc_row(ObExprCtx& expr_ctx, const IKeyExprs& key_exprs, const int64_t key_count, const int64_t value_idx, ObNewRow& intput_row, ObNewRow& output_row) const { int ret = OB_SUCCESS; if (key_count <= 0) { // do nothing } else if (OB_ISNULL(output_row.cells_) || output_row.count_ < key_count) { ret = OB_ERR_UNEXPECTED; LOG_WARN("output_row row not init correct with key_count", K(ret), K(key_count), K(output_row)); } else { ObSqlExpression* sql_expr = NULL; const int64_t start_pos = value_idx * key_count; for (int64_t key_idx = 0; OB_SUCC(ret) && key_idx < key_count; ++key_idx) { if (OB_FAIL(key_exprs.at(key_idx + start_pos, sql_expr))) { LOG_WARN("Failed to get sql expr", K(ret)); } else if (OB_ISNULL(sql_expr)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("Sql expr should not be NULL", K(ret)); } else if (OB_FAIL(sql_expr->calc(expr_ctx, intput_row, output_row.cells_[key_idx]))) { LOG_WARN("Get const or calc expr value error", K(ret)); } else { } } } return ret; } int ObTableLocation::calc_up_key_exprs_partition_id(ObExecContext& exec_ctx, ObPartMgr* part_mgr, const IKeyExprs& key_exprs, const int64_t expect_idx, bool& cross_part, const int64_t part_idx) const { int ret = OB_SUCCESS; const int64_t key_count = key_exprs.count(); cross_part = false; ObArenaAllocator allocator(CURRENT_CONTEXT->get_malloc_allocator()); allocator.set_label("CalcUpKey"); ObNewRow part_row; ObExprCtx expr_ctx; ObSEArray update_ids; if (key_exprs.count() <= 0) { ret = OB_ERR_UNEXPECTED; LOG_WARN("Key exprs count should not less than 1", K(ret)); } else if (OB_FAIL(ObSQLUtils::wrap_expr_ctx(stmt_type_, exec_ctx, allocator, expr_ctx))) { LOG_WARN("Failed to wrap expr ctx", K(ret)); } else if (OB_FAIL(init_row(allocator, key_count, part_row))) { LOG_WARN("Failed to init row", K(ret)); } else if (OB_FAIL(calc_row(expr_ctx, key_exprs, key_count, 0, part_row, part_row))) { LOG_WARN("Failed to calc part row", K(ret)); } else if (OB_INVALID_INDEX == part_idx) { if (OB_FAIL(calc_partition_id_by_row(exec_ctx, part_mgr, part_row, update_ids, NULL))) { LOG_WARN("Calc partition id by row error", K(ret)); } } else { ObSEArray part_ids; if (OB_FAIL(part_ids.push_back(part_idx))) { LOG_WARN("Failed to add part idx", K(ret)); } else if (OB_FAIL(calc_partition_id_by_row(exec_ctx, part_mgr, part_row, update_ids, &part_ids))) { LOG_WARN("Calc partition id by row error", K(ret)); } else { } // do nothing } // check if (OB_FAIL(ret)) { } else if (0 == update_ids.count()) { ret = OB_NO_PARTITION_FOR_GIVEN_VALUE; } else if (update_ids.count() != 1) { cross_part = true; } else if (OB_INVALID_INDEX == part_idx) { cross_part = (update_ids.at(0) != expect_idx); } else { cross_part = (extract_subpart_idx(update_ids.at(0)) != expect_idx); } return ret; } int ObTableLocation::set_log_op_infos(const uint64_t index_table_id, const ObOrderDirection& direction) { int ret = OB_SUCCESS; index_table_id_ = index_table_id; if (OB_UNLIKELY(MAX_DIR != direction_)) { ret = OB_INIT_TWICE; LOG_ERROR("direction_ has been set", K(ret), K(direction_), K(direction)); } else { direction_ = direction; } return ret; } int ObTableLocation::append_phy_table_location(ObExecContext& ctx, uint64_t table_location_key, uint64_t ref_table_id, bool is_weak, const ObIArray& part_ids, const ObOrderDirection& order_direction) { int ret = OB_SUCCESS; ObPhyTableLocationInfo phy_location_info; ObTaskExecutorCtx& executor_ctx = ctx.get_task_exec_ctx(); ObIPartitionLocationCache* location_cache = executor_ctx.get_partition_location_cache(); ObPhysicalPlanCtx* plan_ctx = ctx.get_physical_plan_ctx(); ObSQLSessionInfo* session_info = ctx.get_my_session(); ObPhyTableLocation* phy_table_loc = ObTaskExecutorCtxUtil::get_phy_table_location_for_update(executor_ctx, table_location_key, ref_table_id); phy_location_info.set_direction(order_direction); if (OB_ISNULL(plan_ctx) || OB_ISNULL(session_info) || OB_ISNULL(location_cache)) { ret = OB_INVALID_ARGUMENT; LOG_WARN("invalid argument", K(plan_ctx), K(session_info), K(location_cache)); } else if (order_direction != UNORDERED) { ret = OB_NOT_SUPPORTED; LOG_WARN("append partition location info with order direction not support", K(ret), K(order_direction)); } else if (phy_table_loc != NULL) { // append physical table location ObSEArray expected_part_ids; if (OB_FAIL(phy_table_loc->find_not_include_part_ids(part_ids, expected_part_ids))) { LOG_WARN("find not include part ids failed", K(ret), K(part_ids), KPC(phy_table_loc)); } else if (expected_part_ids.empty()) { // do nothing } else if (OB_FAIL(get_phy_table_location_info(ctx, table_location_key, ref_table_id, is_weak, expected_part_ids, *location_cache, phy_location_info))) { LOG_WARN("get phy table location info failed", K(ret)); } else if (OB_FAIL(phy_table_loc->add_partition_locations(phy_location_info))) { LOG_WARN("add partition locations failed", K(ret), K(phy_location_info)); } } else if (OB_FAIL(get_phy_table_location_info( ctx, table_location_key, ref_table_id, is_weak, part_ids, *location_cache, phy_location_info))) { LOG_WARN("get phy table location info failed", K(ret)); } else if (OB_FAIL(executor_ctx.append_table_location(phy_location_info))) { LOG_WARN("append table location failed", K(ret), K(phy_location_info)); } return ret; } int ObTableLocation::get_phy_table_location_info(ObExecContext& ctx, uint64_t table_location_key, uint64_t ref_table_id, bool is_weak, const ObIArray& part_ids, ObIPartitionLocationCache& location_cache, ObPhyTableLocationInfo& phy_location_info) { int ret = OB_SUCCESS; ObPhysicalPlanCtx* plan_ctx = NULL; ObSQLSessionInfo* session_info = NULL; if (OB_ISNULL(plan_ctx = ctx.get_physical_plan_ctx()) || OB_ISNULL(ctx.get_task_executor_ctx()) || OB_ISNULL(session_info = ctx.get_my_session())) { ret = OB_ERR_UNEXPECTED; LOG_WARN("plan_ctx is null", K(plan_ctx), K(ctx.get_task_executor_ctx()), K(session_info)); } else if (OB_FAIL(ObTableLocation::set_partition_locations(ctx, location_cache, ref_table_id, part_ids, phy_location_info.get_phy_part_loc_info_list_for_update()))) { LOG_WARN("set partition locations failed", K(ret)); } else { phy_location_info.set_table_location_key(table_location_key, ref_table_id); ObSEArray phy_location_info_ptrs; share::schema::ObMultiVersionSchemaService* schema_service = NULL; share::schema::ObSchemaGetterGuard schema_guard; const ObTableSchema* table_schema = NULL; const uint64_t tenant_id = extract_tenant_id(ref_table_id); if (OB_INVALID_ID != ref_table_id && extract_pure_id(ref_table_id) > OB_MIN_USER_TABLE_ID) { ObTaskExecutorCtx& task_exec_ctx = ctx.get_task_exec_ctx(); if (OB_ISNULL(schema_service = task_exec_ctx.schema_service_)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("schema_service is null", K(ret)); } else if (OB_FAIL(schema_service->get_tenant_schema_guard(tenant_id, schema_guard))) { LOG_WARN("failed to get schema guard", K(ret)); } else if (OB_FAIL(schema_guard.get_table_schema(ref_table_id, table_schema))) { LOG_WARN("get table schema failed"); } else if (OB_ISNULL(table_schema)) { ret = OB_SCHEMA_ERROR; LOG_WARN("schema error, maybe schema version changed, need retry"); } else if (ObDuplicateScope::DUPLICATE_SCOPE_NONE != table_schema->get_duplicate_scope()) { // phy_location_info.set_duplicate_type(ObDuplicateType::DUPLICATE); phy_location_info.set_duplicate_type(ObDuplicateType::DUPLICATE_IN_DML); LOG_TRACE( "won't set duplicate property since it is being modified", K(table_schema->get_table_name_str()), K(lbt())); } } if (OB_FAIL(ret)) { // do nothing } else if (OB_FAIL(phy_location_info_ptrs.push_back(&phy_location_info))) { LOG_WARN("store physical location info failed", K(ret)); } else if (OB_FAIL(ObLogPlan::select_replicas(ctx, is_weak, ctx.get_addr(), phy_location_info_ptrs))) { LOG_WARN("fail to select replicas", K(ret), K(ctx.get_addr()), K(phy_location_info_ptrs)); } } return ret; } /*void ObTableLocation::set_index_table_id(const uint64_t index_table_id) { index_table_id_ = index_table_id; } int ObTableLocation::set_pre_query_range(const ObQueryRange *pre_query_range) { int ret = OB_SUCCESS; if (OB_ISNULL(pre_query_range)) { } else if (OB_FAIL(pre_query_range_.deep_copy(*pre_query_range))) { LOG_WARN("failed to copy pre query range", K(ret)); } if (OB_ISNULL(pre_query_range)) { LOG_TRACE("set pre query range", K(ret), K(pre_query_range)); } else { LOG_TRACE("set pre query range", K(ret), K(*pre_query_range), K(pre_query_range_)); } return ret; } int ObTableLocation::set_direction(const ObOrderDirection &direction) { int ret = OB_SUCCESS; if (OB_UNLIKELY(MAX_DIR != direction_)) { ret = OB_INIT_TWICE; LOG_ERROR("direction_ has been set", K(ret), K(direction_), K(direction)); } else { direction_ = direction; } return ret; }*/ int ObPartIdRowMapManager::add_row_for_part(int64_t part_idx, int64_t row_id) { int ret = OB_SUCCESS; // linear search right now. maybe, we can run binary search even interpolation search to get a better perf. // if you are free, please do not be shy to improve this. if (OB_UNLIKELY(part_idx < 0) || OB_UNLIKELY(part_idx > manager_.count())) { ret = OB_ERR_UNEXPECTED; LOG_WARN("part idx is invalid", K(part_idx), K(manager_.count()), K(ret)); } else if (OB_LIKELY(part_idx < manager_.count())) { if (OB_FAIL(manager_.at(part_idx).list_.push_back(row_id))) { LOG_WARN("push row id to manager failed", K(ret)); } } else { MapEntry entry; if (OB_FAIL(entry.list_.push_back(row_id))) { LOG_WARN("push row id failed", K(ret), K(part_idx), K(row_id)); } else if (OB_FAIL(manager_.push_back(entry))) { LOG_WARN("push entry failed", K(ret), K(part_idx), K(row_id)); } } return ret; } const ObPartIdRowMapManager::ObRowIdList* ObPartIdRowMapManager::get_row_id_list(int64_t part_index) { const ObPartIdRowMapManager::ObRowIdList* ret = NULL; // linear search right now. maybe, we can run binary search even interpolation search to get a better perf. // if you are free, please do not be shy to improve this. if (part_index >= 0 && part_index < manager_.count()) { ret = &(manager_.at(part_index).list_); } return ret; } int ObPartIdRowMapManager::MapEntry::assign(const ObPartIdRowMapManager::MapEntry& other) { int ret = OB_SUCCESS; if (this != &other) { if (OB_FAIL(list_.assign(other.list_))) { LOG_WARN("copy list failed", K(ret)); } } return ret; } int ObPartIdRowMapManager::assign(const ObPartIdRowMapManager& other) { int ret = OB_SUCCESS; ARRAY_FOREACH(other.manager_, i) { MapEntry map_entry; if (OB_FAIL(map_entry.assign(other.manager_.at(i)))) { LOG_WARN("assign manager entry failed", K(ret), K(i)); } else if (OB_FAIL(manager_.push_back(map_entry))) { LOG_WARN("store map entry failed", K(ret)); } } return ret; } int ObPLQueryRangeNode::get_range(ObIAllocator& allocator, const ParamStore& params, ObQueryRangeArray& query_ranges, bool& is_all_single_value_ranges, bool& is_empty, const ObDataTypeCastParams& dtc_params) const { int ret = OB_SUCCESS; if (OB_FAIL(pre_query_range_.get_tablet_ranges( allocator, params, query_ranges, is_all_single_value_ranges, dtc_params))) { LOG_WARN("get tablet ranges failed", K(ret)); } else if (OB_FAIL(is_all_ranges_empty(query_ranges, is_empty))) { LOG_WARN("fail to check all ranges", K(query_ranges)); } else if (query_ranges.count() == 0) { ret = OB_ERR_UNEXPECTED; LOG_WARN("Query ranges' count should not be 0", "query range count", query_ranges.count(), K(ret)); } else { } return ret; } OB_DEF_SERIALIZE(ObTableLocation) { int ret = OB_SUCCESS; bool has_part_expr = (part_expr_ != NULL); bool has_subpart_expr = (subpart_expr_ != NULL); LST_DO_CODE(OB_UNIS_ENCODE, table_id_, ref_table_id_, stmt_type_, literal_stmt_type_, hint_read_consistency_, is_contain_inner_table_, is_contain_select_for_update_, is_contain_mv_, is_partitioned_, direction_, part_level_, part_type_, subpart_type_, part_num_, is_global_index_, has_part_expr, has_subpart_expr, part_projector_, first_partition_id_, inited_); if (OB_SUCC(ret) && has_part_expr) { OB_UNIS_ENCODE(*part_expr_); } if (OB_SUCC(ret) && has_subpart_expr) { OB_UNIS_ENCODE(*subpart_expr_); } if (OB_SUCC(ret)) { LST_DO_CODE(OB_UNIS_ENCODE, is_oracle_temp_table_); } if (OB_SUCC(ret)) { LST_DO_CODE(OB_UNIS_ENCODE, duplicate_type_); } return ret; } OB_DEF_SERIALIZE_SIZE(ObTableLocation) { int64_t len = 0; bool has_part_expr = (part_expr_ != NULL); bool has_subpart_expr = (subpart_expr_ != NULL); LST_DO_CODE(OB_UNIS_ADD_LEN, table_id_, ref_table_id_, stmt_type_, literal_stmt_type_, hint_read_consistency_, is_contain_inner_table_, is_contain_select_for_update_, is_contain_mv_, is_partitioned_, direction_, part_level_, part_type_, subpart_type_, part_num_, is_global_index_, has_part_expr, has_subpart_expr, part_projector_, first_partition_id_, inited_, is_oracle_temp_table_, duplicate_type_); if (has_part_expr) { OB_UNIS_ADD_LEN(*part_expr_); } if (has_subpart_expr) { OB_UNIS_ADD_LEN(*subpart_expr_); } return len; } OB_DEF_DESERIALIZE(ObTableLocation) { int ret = OB_SUCCESS; bool has_part_expr = false; bool has_subpart_expr = false; LST_DO_CODE(OB_UNIS_DECODE, table_id_, ref_table_id_, stmt_type_, literal_stmt_type_, hint_read_consistency_, is_contain_inner_table_, is_contain_select_for_update_, is_contain_mv_, is_partitioned_, direction_, part_level_, part_type_, subpart_type_, part_num_, is_global_index_, has_part_expr, has_subpart_expr, part_projector_, first_partition_id_, inited_); if (OB_SUCC(ret) && has_part_expr) { if (OB_FAIL(sql_expression_factory_.alloc(part_expr_))) { LOG_WARN("allocate part expr failed", K(ret)); } else if (OB_ISNULL(part_expr_)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("part_expr_ is null"); } else { OB_UNIS_DECODE(*part_expr_); } } if (OB_SUCC(ret) && has_subpart_expr) { if (OB_FAIL(sql_expression_factory_.alloc(subpart_expr_))) { LOG_WARN("allocate part expr failed", K(ret)); } else if (OB_ISNULL(subpart_expr_)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("part_expr_ is null"); } else { OB_UNIS_DECODE(*subpart_expr_); } } if (OB_SUCC(ret)) { LST_DO_CODE(OB_UNIS_DECODE, is_oracle_temp_table_); } if (OB_SUCC(ret)) { LST_DO_CODE(OB_UNIS_DECODE, duplicate_type_); } return ret; } ObRawExpr* ObTableLocation::get_related_part_expr( const ObDMLStmt& stmt, share::schema::ObPartitionLevel part_level, uint64_t table_id, uint64_t index_tid) const { ObRawExpr* ret = NULL; if (part_level == PARTITION_LEVEL_ONE) { if (related_part_expr_idx_ == OB_INVALID_INDEX) { ret = stmt.get_part_expr(table_id, index_tid); } else { ret = stmt.get_related_part_expr(table_id, index_tid, related_part_expr_idx_); } } else if (part_level == PARTITION_LEVEL_TWO) { if (related_subpart_expr_idx_ == OB_INVALID_INDEX) { ret = stmt.get_subpart_expr(table_id, index_tid); } else { ret = stmt.get_related_subpart_expr(table_id, index_tid, related_subpart_expr_idx_); } } return ret; } int ObTableLocation::get_partition_ids_by_range(ObExecContext& exec_ctx, ObPartMgr* part_mgr, const ObNewRange* part_range, const ObNewRange* gen_range, ObIArray& partition_ids, const ObIArray* level_one_part_ids) const { int ret = OB_SUCCESS; ObPartLocCalcNode* gen_col_node = NULL == level_one_part_ids ? gen_col_node_ : sub_gen_col_node_; ObSqlExpression* gen_col_expr = NULL == level_one_part_ids ? gen_col_expr_ : sub_gen_col_expr_; ObSEArray gen_part_ids; bool all_part_by_part_range = false; bool all_part_by_gen_range = false; if (OB_UNLIKELY(!inited_)) { ret = OB_NOT_INIT; LOG_WARN("ObTableLocation not inited", K(ret)); } else if (OB_UNLIKELY(is_simple_insert_or_replace())) { ret = OB_ERR_UNEXPECTED; LOG_WARN("insert/replace stmt should not get partition ids by range", K(ret)); } else if (!is_partitioned_) { if (OB_FAIL(partition_ids.push_back(0))) { LOG_WARN("Failed to push back partition id", K(ret)); } } else { if (NULL == part_range) { all_part_by_part_range = true; } else if (OB_FAIL(calc_partition_ids_by_range( exec_ctx, part_mgr, part_range, partition_ids, all_part_by_part_range, level_one_part_ids))) { LOG_WARN("Failed to calc partitoin ids by calc node", K(ret)); } if (OB_SUCC(ret)) { if (NULL == gen_range || OB_ISNULL(gen_col_node) || OB_ISNULL(gen_col_expr)) { all_part_by_gen_range = true; } else if (OB_FAIL(calc_partition_ids_by_range(exec_ctx, part_mgr, gen_range, gen_part_ids, all_part_by_gen_range, level_one_part_ids, gen_col_expr))) { LOG_WARN("Failed to calcl partition ids by gen col node", K(ret)); } } if (OB_SUCC(ret)) { if (!all_part_by_part_range && !all_part_by_gen_range) { if (OB_FAIL(intersect_partition_ids(gen_part_ids, partition_ids))) { LOG_WARN("Failed to intersect partition ids", K(ret)); } } else if (!all_part_by_part_range && all_part_by_gen_range) { // do nothing } else if (all_part_by_part_range && !all_part_by_gen_range) { if (OB_FAIL(append(partition_ids, gen_part_ids))) { LOG_WARN("append partition ids failed", K(ret)); } } else if (OB_FAIL(get_all_part_ids(exec_ctx, part_mgr, partition_ids, level_one_part_ids))) { LOG_WARN("Get all part ids error", K(ret)); } } } return ret; } int ObTableLocation::calc_partition_ids_by_range(ObExecContext& exec_ctx, ObPartMgr* part_mgr, const ObNewRange* range, ObIArray& partition_ids, bool& all_part, const ObIArray* part_ids, const ObSqlExpression* gen_col_expr) const { int ret = OB_SUCCESS; all_part = false; ObSEArray dummy_query_ranges; if (OB_ISNULL(range)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("get null ObNewRange", K(ret)); } else if (range->empty()) { // do nothing. partition ids will be empty } else if (OB_FAIL(dummy_query_ranges.push_back(const_cast(range)))) { LOG_WARN("failed to push back query range", K(ret)); } else if (OB_FAIL(calc_partition_ids_by_ranges(exec_ctx, part_mgr, dummy_query_ranges, range->is_single_rowkey(), partition_ids, all_part, part_ids, gen_col_expr))) { LOG_WARN("Failed to get partition ids", K(ret), K(table_id_)); } return ret; } int ObTableLocation::init_table_location_with_row_desc(ObSqlSchemaGuard &schema_guard, uint64_t table_id, RowDesc &input_row_desc, ObSQLSessionInfo &session_info, const bool is_dml_table) { int ret = OB_SUCCESS; ObSchemaChecker schema_checker; const ObTableSchema* table_schema = NULL; RowDesc row_desc; uint64_t real_table_id = OB_INVALID_ID; if (OB_FAIL(schema_checker.init(schema_guard))) { LOG_WARN("fail to init schema_checker", K(ret)); } else if (OB_FAIL(schema_checker.get_table_schema(table_id, table_schema))) { LOG_WARN("get table schema failed", K(ret), K(table_id)); } else if (OB_ISNULL(table_schema)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("get null table schema", K(ret), K(table_id)); } else { real_table_id = table_schema->is_index_local_storage() ? table_schema->get_data_table_id() : table_id; // reslove partition expr ObResolverParams resolver_ctx; ObRawExprFactory expr_factory(allocator_); ObStmtFactory stmt_factory(allocator_); TableItem table_item; resolver_ctx.allocator_ = &allocator_; resolver_ctx.schema_checker_ = &schema_checker; resolver_ctx.session_info_ = &session_info; resolver_ctx.disable_privilege_check_ = true; resolver_ctx.expr_factory_ = &expr_factory; resolver_ctx.stmt_factory_ = &stmt_factory; resolver_ctx.query_ctx_ = stmt_factory.get_query_ctx(); table_item.table_id_ = real_table_id; table_item.ref_id_ = real_table_id; table_item.type_ = TableItem::BASE_TABLE; ObDeleteResolver delete_resolver(resolver_ctx); ObDeleteStmt* delete_stmt = delete_resolver.create_stmt(); const ObTableSchema* real_table_schema = table_schema; if (OB_ISNULL(resolver_ctx.query_ctx_) || OB_ISNULL(delete_stmt)) { ret = OB_ALLOCATE_MEMORY_FAILED; LOG_WARN("create query_ctx or delete stmt failed", K_(resolver_ctx.query_ctx), K(delete_stmt)); } else if (OB_FAIL(delete_stmt->get_table_items().push_back(&table_item))) { LOG_WARN("store table item failed", K(ret)); } else if (OB_FAIL(delete_stmt->set_table_bit_index(real_table_id))) { LOG_WARN("set table bit index failed", K(ret), K(real_table_id)); } else if (OB_UNLIKELY(table_schema->is_index_local_storage()) && OB_FAIL(schema_guard.get_table_schema(real_table_id, real_table_schema))) { LOG_WARN("get real table schema failed", K(ret), K(real_table_id)); } else if (OB_FAIL(delete_resolver.resolve_table_partition_expr(table_item, *real_table_schema))) { LOG_WARN("resolve table partition expr failed", K(ret)); } else if (OB_FAIL(generate_row_desc_from_row_desc( *delete_stmt, real_table_id, expr_factory, input_row_desc, row_desc))) { LOG_WARN("generate rowkey desc failed", K(ret), K(real_table_id)); } else if (OB_FAIL(init_table_location(schema_guard, real_table_id, real_table_id, *delete_stmt, row_desc, is_dml_table, default_asc_direction()))) { LOG_WARN("init table location failed", K(ret), K(real_table_id)); } else if (OB_FAIL(clear_columnlized_in_row_desc(row_desc))) { LOG_WARN("Failed to clear columnlized in row desc", K(ret)); } } return ret; } int ObTableLocation::init_table_location_with_rowid(ObSqlSchemaGuard& schema_guard, const ObIArray& param_index, const uint64_t table_id, const uint64_t ref_table_id, ObSQLSessionInfo& session_info, const bool is_dml_table) { int ret = OB_SUCCESS; uint64_t real_table_id = ref_table_id; if (ObSQLMockSchemaUtils::is_mock_index(real_table_id)) { real_table_id = ObSQLMockSchemaUtils::get_baseid_from_rowid_index_id(real_table_id); } if (OB_FAIL(init_table_location_with_rowkey(schema_guard, real_table_id, session_info, is_dml_table))) { LOG_WARN("failed to init table location with rowkey", K(ret)); } else if (OB_FAIL(part_expr_param_idxs_.assign(param_index))) { LOG_WARN("failed to assign array", K(ret)); } else { use_calc_part_by_rowid_ = true; // init_table_location_with_rowkey will set direction_ to default_acs_direction // here we change it to MAX_DIR, it will be set in log_table_scan direction_ = MAX_DIR; table_id_ = table_id; // logical table id } return ret; } int ObTableLocation::generate_row_desc_from_row_desc(ObDMLStmt& stmt, const uint64_t data_table_id, ObRawExprFactory& expr_factory, const RowDesc& input_row_desc, RowDesc& row_desc) { int ret = OB_SUCCESS; ObColumnRefRawExpr* col_expr = NULL; if (OB_FAIL(row_desc.init())) { LOG_WARN("Failed to init row desc", K(ret)); } for (int64_t i = 0; OB_SUCC(ret) && i < input_row_desc.get_column_num(); ++i) { ObRawExpr* expr = input_row_desc.get_column(i); if (OB_ISNULL(expr)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("get null expr", K(ret)); } else if (OB_LIKELY(expr->is_column_ref_expr())) { uint64_t column_id = static_cast(expr)->get_column_id(); col_expr = stmt.get_column_expr_by_id(data_table_id, column_id); if (OB_ISNULL(col_expr)) { if (OB_FAIL(expr_factory.create_raw_expr(T_REF_COLUMN, col_expr))) { LOG_WARN("create mock rowkey column expr failed", K(ret)); } else if (OB_FAIL(row_desc.add_column(col_expr))) { LOG_WARN("add rowkey column expr to row desc failed", K(ret)); } } else if (OB_FAIL(row_desc.add_column(col_expr))) { LOG_WARN("add rowkey column expr to row desc failed", K(ret)); } } else { if (OB_FAIL(expr_factory.create_raw_expr(T_REF_COLUMN, col_expr))) { LOG_WARN("create mock rowkey column expr failed", K(ret)); } else if (OB_FAIL(row_desc.add_column(col_expr))) { LOG_WARN("add rowkey column expr to row desc failed", K(ret)); } } } return ret; } int ObTableLocation::calc_partition_location_infos_with_rowid(ObExecContext& exec_ctx, share::schema::ObSchemaGetterGuard& schema_guard, const ParamStore& params, share::ObIPartitionLocationCache& location_cache, ObPhyPartitionLocationInfoIArray& phy_part_loc_info_list, bool nonblock) const { int ret = OB_SUCCESS; if (!inited_) { ret = OB_NOT_INIT; LOG_WARN("not inited", K(ret)); } else if (!use_calc_part_by_rowid_) { ret = OB_ERR_UNEXPECTED; LOG_WARN("unexecpted table location flag", K(ret), K(use_calc_part_by_rowid_)); } ObArray part_ids; if (OB_FAIL(ret)) { // do nothing } else if (OB_FAIL(calculate_partition_ids_with_rowid(exec_ctx, schema_guard, params, part_ids))) { LOG_WARN("failed to calculate partition ids", K(ret)); } else if (OB_FAIL(set_partition_locations( exec_ctx, location_cache, ref_table_id_, part_ids, phy_part_loc_info_list, nonblock))) { LOG_WARN("failed to set partition locations", K(ret)); } else { } return ret; } int ObTableLocation::calculate_partition_ids_with_rowid(ObExecContext& exec_ctx, share::schema::ObSchemaGetterGuard& schema_guard, const ParamStore& params, common::ObIArray& part_ids) const { int ret = OB_SUCCESS; if (!inited_) { ret = OB_NOT_INIT; LOG_WARN("not inited table location", K(ret)); } else if (!use_calc_part_by_rowid_) { ret = OB_ERR_UNEXPECTED; LOG_WARN("unexpected error happended", K(ret)); } else if (!is_partitioned_) { ret = part_ids.push_back(0); } else { ObArray urowid_objs; for (int i = 0; OB_SUCC(ret) && i < part_expr_param_idxs_.count(); i++) { int64_t idx = part_expr_param_idxs_.at(i); if (OB_UNLIKELY(idx < 0 || idx >= params.count())) { ret = OB_INVALID_ARGUMENT; LOG_WARN("invalid param index", K(ret), K(idx)); } else if (OB_FAIL(urowid_objs.push_back(params.at(idx)))) { LOG_WARN("failed to push back element", K(ret)); } } ObSEArray rowkey_list; ObArray rowkey_arr; // construct rowkeys ObObj* obj_buf = NULL; for (int i = 0; OB_SUCC(ret) && i < urowid_objs.count(); i++) { ObArray pk_vals; if (OB_FAIL(urowid_objs.at(i).get_urowid().get_pk_vals(pk_vals))) { LOG_WARN("failed to get pk vals", K(ret)); } else if (OB_ISNULL(obj_buf = (ObObj*)exec_ctx.get_allocator().alloc(sizeof(ObObj) * pk_vals.count()))) { LOG_WARN("failed to allocate memory", K(ret)); } else { for (int k = 0; k < pk_vals.count(); k++) { (void)new (obj_buf + k) ObObj(); obj_buf[k] = pk_vals.at(k); } ObRowkey rowkey(obj_buf, pk_vals.count()); if (OB_FAIL(rowkey_arr.push_back(rowkey))) { LOG_WARN("failed to push back element", K(ret)); } } } // for end const ObTableSchema* base_table_schema = NULL; ObArray rowkey_descs; bool is_all_part_get = false; if (OB_FAIL(ret)) { // do nothing } else if (OB_FAIL(schema_guard.get_table_schema(ref_table_id_, base_table_schema))) { LOG_WARN("failed to get table schema", K(ret)); } else if (OB_ISNULL(base_table_schema)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("invalid null table schema", K(ret)); } else if (OB_FAIL(base_table_schema->get_rowkey_column_ids(rowkey_descs))) { LOG_WARN("failed to get rowkey column ids", K(ret)); } else { // check wether all rowkey infos are valid, if not, return all part ids for (int i = 0; !is_all_part_get && i < rowkey_arr.count(); i++) { if (OB_UNLIKELY(rowkey_arr.at(i).get_obj_cnt() != rowkey_descs.count())) { is_all_part_get = true; } else { for (int j = 0; !is_all_part_get && j < rowkey_descs.count(); j++) { const ObObj* obj_ptr = rowkey_arr.at(i).get_obj_ptr(); if (!obj_ptr[j].meta_.is_null() && !ObSQLUtils::is_same_type_for_compare(obj_ptr[j].meta_, rowkey_descs.at(j).col_type_)) { is_all_part_get = true; } } } } // for end } if (OB_FAIL(ret)) { // do nothing } else if (is_all_part_get) { if (!is_partitioned_) { ret = part_ids.push_back(0); } else if (PARTITION_LEVEL_ONE == part_level_) { if (OB_FAIL(get_all_part_ids(exec_ctx, &schema_guard, part_ids))) { LOG_WARN("failed to get all part ids", K(ret)); } } else if (PARTITION_LEVEL_TWO == part_level_) { ObArray tmp_part_ids; if (OB_FAIL(get_all_part_ids(exec_ctx, &schema_guard, tmp_part_ids))) { LOG_WARN("failed to get partition ids", K(ret)); } else if (OB_FAIL(get_all_part_ids(exec_ctx, &schema_guard, part_ids, &tmp_part_ids))) { LOG_WARN("failed to get all partition ids", K(ret)); } } if (OB_SUCC(ret)) { LOG_TRACE("get all part ids", K(part_ids)); } } else if (OB_FAIL(calc_partition_ids_by_rowkey(exec_ctx, &schema_guard, rowkey_arr, part_ids, rowkey_list))) { LOG_WARN("failed to calc partition ids", K(ret)); } else if (part_ids.empty()) { int64_t fake_id = first_partition_id_; if (part_hint_ids_.count() > 0) { fake_id = part_hint_ids_.at(0); } if (is_partitioned_ && is_virtual_table(ref_table_id_)) { if (OB_FAIL(get_vt_partition_id(exec_ctx, ref_table_id_, NULL, &fake_id))) { LOG_WARN("Get virtual table fake id error", K(ret)); } } if (OB_SUCC(ret)) { if (OB_FAIL(part_ids.push_back(fake_id))) { LOG_WARN("Add fake partition id error", K(ret)); } else { LOG_TRACE("get all partition ids", K(part_ids)); } } } else { LOG_TRACE("get all partition ids", K(part_ids)); } } return ret; } int ObTableLocation::can_get_part_by_range_for_range_columns(const ObRawExpr* part_expr, bool& is_valid) const { int ret = OB_SUCCESS; is_valid = false; if (OB_ISNULL(part_expr)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("get unexpected null", K(ret)); } else if (part_expr->is_column_ref_expr()) { is_valid = true; } else if (T_OP_ROW == part_expr->get_expr_type()) { const ObRawExpr* col_expr = NULL; is_valid = true; for (int64_t i = 0; OB_SUCC(ret) && is_valid && i < part_expr->get_param_count(); ++i) { if (OB_ISNULL(col_expr = part_expr->get_param_expr(i))) { ret = OB_ERR_UNEXPECTED; LOG_WARN("get unexpected null", K(ret)); } else if (!col_expr->is_column_ref_expr()) { is_valid = false; } } } else { is_valid = false; } return ret; } int ObTableLocation::recursive_convert_generated_column( const ObIArray& table_column, const ObIArray& column_conv_exprs, ObRawExpr*& expr) { int ret = OB_SUCCESS; if (OB_ISNULL(expr)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("get unexpected null", K(ret)); } else if (expr->is_column_ref_expr()) { bool found = false; const int64_t column_id = static_cast(expr)->get_column_id(); ObRawExpr* col_conv_expr = NULL; ObColumnRefRawExpr* col_expr = NULL; for (int64_t i = 0; OB_SUCC(ret) && !found && i < table_column.count(); ++i) { if (OB_ISNULL(col_expr = table_column.at(i))) { ret = OB_ERR_UNEXPECTED; LOG_WARN("get invalid column item", K(ret), K(col_expr), K(i)); } else if (column_id != col_expr->get_column_id()) { // do nothing } else if (OB_ISNULL(col_conv_expr = column_conv_exprs.at(i))) { ret = OB_ERR_UNEXPECTED; LOG_WARN("Column conv expr should not be NULL", K(ret)); } else { expr = col_conv_expr; found = true; } } } else if (T_FUN_COLUMN_CONV == expr->get_expr_type()) { if (OB_FAIL(recursive_convert_generated_column(table_column, column_conv_exprs, expr->get_param_expr(4)))) { LOG_WARN("failed to recursive convert generated column", K(ret)); } } else { for (int64_t i = 0; OB_SUCC(ret) && i < expr->get_param_count(); ++i) { if (OB_FAIL(recursive_convert_generated_column(table_column, column_conv_exprs, expr->get_param_expr(i)))) { LOG_WARN("failed to recursive convert generated column", K(ret)); } } } return ret; } int ObTableLocation::can_get_part_by_range_for_temporal_column(const ObRawExpr *part_expr, bool &is_valid) const { int ret = OB_SUCCESS; is_valid = false; if (OB_ISNULL(part_expr)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("get unexpected null", K(ret)); } else if (lib::is_oracle_mode()) { // do nothing } else { switch (part_expr->get_expr_type()) { case T_FUN_SYS_TO_DAYS: case T_FUN_SYS_TO_SECONDS: case T_FUN_SYS_YEAR: { for (int64_t i = 0; OB_SUCC(ret) && i < part_expr->get_param_count(); ++i) { const ObRawExpr *sub_expr = part_expr->get_param_expr(i); const ObRawExpr *real_sub_expr = NULL; if (OB_FAIL(ObRawExprUtils::get_real_expr_without_cast(true, sub_expr, real_sub_expr))) { LOG_WARN("fail to get real expr", K(ret)); } else if (real_sub_expr->is_column_ref_expr() && (ObDateType == real_sub_expr->get_result_type().get_type() || ObDateTimeType == real_sub_expr->get_result_type().get_type())) { is_valid = true; } } break; } case T_FUN_SYS_UNIX_TIMESTAMP: { for (int64_t i = 0; OB_SUCC(ret) && i < part_expr->get_param_count(); ++i) { const ObRawExpr *sub_expr = part_expr->get_param_expr(i); const ObRawExpr *real_sub_expr = NULL; if (OB_FAIL(ObRawExprUtils::get_real_expr_without_cast(true, sub_expr, real_sub_expr))) { LOG_WARN("fail to get real expr", K(ret)); } else if (real_sub_expr->is_column_ref_expr() && ObTimestampType == real_sub_expr->get_result_type().get_type()) { is_valid = true; } } break; } default: { is_valid = false; } } } return ret; } int ObTableLocation::calc_range_by_part_expr(ObExecContext &exec_ctx, const ObIArray &ranges, const ObIArray *part_ids, ObIAllocator &allocator, ObIArray &new_ranges, bool &is_all_single_value_ranges) const { int ret = OB_SUCCESS; ObExprCtx expr_ctx; ObSqlExpression *expr = NULL == part_ids ? part_expr_ : subpart_expr_; is_all_single_value_ranges = true; if (OB_FAIL(ObSQLUtils::wrap_expr_ctx(stmt_type_, exec_ctx, allocator, expr_ctx))) { LOG_WARN("Failed to wrap expr ctx", K(ret)); } else if (OB_ISNULL(expr)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("expr should not be NULL", K(ret)); } for (int64 i = 0; OB_SUCC(ret) && i < ranges.count(); ++i) { ObNewRange *range = ranges.at(i); ObNewRange *new_range = NULL; if (OB_ISNULL(range)) { ret = OB_ERR_UNEXPECTED; LOG_WARN("invalid range", K(ret)); } else if (OB_ISNULL(new_range = static_cast(allocator.alloc(sizeof(ObNewRange))))) { ret = OB_ALLOCATE_MEMORY_FAILED; LOG_ERROR("alloc memory failed", K(ret)); } else { new (new_range) ObNewRange(); new_range->table_id_ = range->table_id_; // the range after calc is always close even though the original range is open new_range->border_flag_.set_inclusive_start(); new_range->border_flag_.set_inclusive_end(); if (range->start_key_.is_min_row()) { new_range->start_key_.set_min_row(); } else { ObNewRow input_row; ObObj *func_result = NULL; input_row.cells_ = const_cast(range->start_key_.get_obj_ptr()); input_row.count_ = (range->start_key_.get_obj_cnt()); OV(OB_NOT_NULL(func_result = static_cast(allocator.alloc(sizeof(ObObj)))), OB_ALLOCATE_MEMORY_FAILED); OZ(expr->calc(expr_ctx, input_row, *func_result), input_row, table_id_); OX(new_range->start_key_.assign(func_result, 1)); } if (OB_FAIL(ret)) { } else if (range->end_key_.is_max_row()) { new_range->end_key_.set_max_row(); } else { ObNewRow input_row; ObObj *func_result = NULL; input_row.cells_ = const_cast(range->end_key_.get_obj_ptr()); input_row.count_ = (range->end_key_.get_obj_cnt()); OV(OB_NOT_NULL(func_result = static_cast(allocator.alloc(sizeof(ObObj)))), OB_ALLOCATE_MEMORY_FAILED); OZ(expr->calc(expr_ctx, input_row, *func_result), input_row, table_id_); OX(new_range->end_key_.assign(func_result, 1)); } OZ(new_ranges.push_back(new_range)); if (OB_SUCC(ret) && is_all_single_value_ranges) { is_all_single_value_ranges = is_all_single_value_ranges && new_range->is_single_rowkey(); } } } return ret; }