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0959abc1dc347c7401c4875aab8b8cfc777d4738
doris/be/src/exec/intersect_node.cpp
yangzhg 0959abc1dc [ExceptNode] Implement except node (#3056) 
implement except node,
support  statement like:

``` 
select a from t1 except select b from t2
```
2020-03-17 10:54:40 +08:00

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// Licensed to the Apache Software Foundation (ASF) under one
// or more contributor license agreements. See the NOTICE file
// distributed with this work for additional information
// regarding copyright ownership. The ASF licenses this file
// to you under the Apache License, Version 2.0 (the
// "License"); you may not use this file except in compliance
// with the License. You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing,
// software distributed under the License is distributed on an
// "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
// KIND, either express or implied. See the License for the
// specific language governing permissions and limitations
// under the License.
#include "exec/intersect_node.h"
#include "exec/hash_table.hpp"
#include "exprs/expr.h"
#include "runtime/row_batch.h"
#include "runtime/runtime_state.h"
namespace doris {
IntersectNode::IntersectNode(ObjectPool* pool, const TPlanNode& tnode, const DescriptorTbl& descs)
: ExecNode(pool, tnode, descs) {}
Status IntersectNode::init(const TPlanNode& tnode, RuntimeState* state) {
RETURN_IF_ERROR(ExecNode::init(tnode, state));
DCHECK(tnode.__isset.intersect_node);
DCHECK_EQ(_conjunct_ctxs.size(), 0);
DCHECK_GE(_children.size(), 2);
// Create result_expr_ctx_lists_ from thrift exprs.
auto& result_texpr_lists = tnode.intersect_node.result_expr_lists;
for (auto& texprs : result_texpr_lists) {
std::vector<ExprContext*> ctxs;
RETURN_IF_ERROR(Expr::create_expr_trees(_pool, texprs, &ctxs));
_child_expr_lists.push_back(ctxs);
}
return Status::OK();
}
Status IntersectNode::prepare(RuntimeState* state) {
RETURN_IF_ERROR(ExecNode::prepare(state));
_build_pool.reset(new MemPool(mem_tracker()));
_build_timer = ADD_TIMER(runtime_profile(), "BuildTime");
_probe_timer = ADD_TIMER(runtime_profile(), "ProbeTime");
SCOPED_TIMER(_runtime_profile->total_time_counter());
for (size_t i = 0; i < _child_expr_lists.size(); ++i) {
RETURN_IF_ERROR(Expr::prepare(_child_expr_lists[i], state, child(i)->row_desc(),
expr_mem_tracker()));
}
_build_tuple_size = child(0)->row_desc().tuple_descriptors().size();
_build_tuple_row_size = _build_tuple_size * sizeof(Tuple*);
_build_tuple_idx.reserve(_build_tuple_size);
for (int i = 0; i < _build_tuple_size; ++i) {
TupleDescriptor* build_tuple_desc = child(0)->row_desc().tuple_descriptors()[i];
_build_tuple_idx.push_back(_row_descriptor.get_tuple_idx(build_tuple_desc->id()));
}
_find_nulls = std::vector<bool>(_build_tuple_size, true);
return Status::OK();
}
Status IntersectNode::close(RuntimeState* state) {
if (is_closed()) {
return Status::OK();
}
for (auto& exprs : _child_expr_lists) {
Expr::close(exprs, state);
}
RETURN_IF_ERROR(exec_debug_action(TExecNodePhase::CLOSE));
// Must reset _probe_batch in close() to release resources
_probe_batch.reset(NULL);
if (_memory_used_counter != NULL && _hash_tbl.get() != NULL) {
COUNTER_UPDATE(_memory_used_counter, _build_pool->peak_allocated_bytes());
COUNTER_UPDATE(_memory_used_counter, _hash_tbl->byte_size());
}
if (_hash_tbl.get() != NULL) {
_hash_tbl->close();
}
if (_build_pool.get() != NULL) {
_build_pool->free_all();
}
return ExecNode::close(state);
}
// the actual intersect operation is in this function,
// 1 build a hash table from child(0)
// 2 probe with child(1), then filter the hash table and find the matched item, use them to rebuild a hash table
// repeat [2] this for all the rest child
Status IntersectNode::open(RuntimeState* state) {
RETURN_IF_ERROR(ExecNode::open(state));
RETURN_IF_ERROR(exec_debug_action(TExecNodePhase::OPEN));
SCOPED_TIMER(_runtime_profile->total_time_counter());
RETURN_IF_CANCELLED(state);
// open result expr lists.
for (const vector<ExprContext*>& exprs : _child_expr_lists) {
RETURN_IF_ERROR(Expr::open(exprs, state));
}
// initial build hash table
_hash_tbl.reset(new HashTable(_child_expr_lists[0], _child_expr_lists[1], _build_tuple_size,
true, _find_nulls, id(), mem_tracker(), 1024));
RowBatch build_batch(child(0)->row_desc(), state->batch_size(), mem_tracker());
RETURN_IF_ERROR(child(0)->open(state));
bool eos = false;
while (!eos) {
SCOPED_TIMER(_build_timer);
RETURN_IF_CANCELLED(state);
RETURN_IF_ERROR(child(0)->get_next(state, &build_batch, &eos));
// take ownership of tuple data of build_batch
_build_pool->acquire_data(build_batch.tuple_data_pool(), false);
RETURN_IF_LIMIT_EXCEEDED(state, " Intersect, while constructing the hash table.");
for (int i = 0; i < build_batch.num_rows(); ++i) {
_hash_tbl->insert_unique(build_batch.get_row(i));
}
VLOG_ROW << "hash table content: " << _hash_tbl->debug_string(true, &child(0)->row_desc());
build_batch.reset();
}
// if a table is empty, the result must be empty
if (_hash_tbl->size() == 0) {
_hash_tbl_iterator = _hash_tbl->begin();
return Status::OK();
}
for (int i = 1; i < _children.size(); ++i) {
if (i > 1) {
SCOPED_TIMER(_build_timer);
std::unique_ptr<HashTable> temp_tbl(
new HashTable(_child_expr_lists[0], _child_expr_lists[i], _build_tuple_size,
true, _find_nulls, id(), mem_tracker(), 1024));
_hash_tbl_iterator = _hash_tbl->begin();
while (_hash_tbl_iterator.has_next()) {
if (_hash_tbl_iterator.matched()) {
temp_tbl->insert(_hash_tbl_iterator.get_row());
}
_hash_tbl_iterator.next<false>();
}
_hash_tbl.swap(temp_tbl);
temp_tbl->close();
VLOG_ROW << "hash table content: "
<< _hash_tbl->debug_string(true, &child(0)->row_desc());
// if a table is empty, the result must be empty
if (_hash_tbl->size() == 0) {
break;
}
}
// probe
_probe_batch.reset(new RowBatch(child(i)->row_desc(), state->batch_size(), mem_tracker()));
ScopedTimer<MonotonicStopWatch> probe_timer(_probe_timer);
RETURN_IF_ERROR(child(i)->open(state));
eos = false;
while (!eos) {
RETURN_IF_CANCELLED(state);
RETURN_IF_ERROR(child(i)->get_next(state, _probe_batch.get(), &eos));
RETURN_IF_LIMIT_EXCEEDED(state, " Intersect , while probing the hash table.");
for (int j = 0; j < _probe_batch->num_rows(); ++j) {
_hash_tbl_iterator = _hash_tbl->find(_probe_batch->get_row(j));
if (_hash_tbl_iterator != _hash_tbl->end()) {
_hash_tbl_iterator.set_matched();
}
}
_probe_batch->reset();
}
}
_hash_tbl_iterator = _hash_tbl->begin();
return Status::OK();
}
Status IntersectNode::get_next(RuntimeState* state, RowBatch* out_batch, bool* eos) {
RETURN_IF_ERROR(exec_debug_action(TExecNodePhase::GETNEXT));
RETURN_IF_CANCELLED(state);
SCOPED_TIMER(_runtime_profile->total_time_counter());
*eos = true;
if (reached_limit()) {
return Status::OK();
}
while (_hash_tbl_iterator.has_next()) {
if (_hash_tbl_iterator.matched()) {
int row_idx = out_batch->add_row();
TupleRow* out_row = out_batch->get_row(row_idx);
uint8_t* out_ptr = reinterpret_cast<uint8_t*>(out_row);
memcpy(out_ptr, _hash_tbl_iterator.get_row(), _build_tuple_row_size);
out_batch->commit_last_row();
++_num_rows_returned;
}
_hash_tbl_iterator.next<false>();
*eos = !_hash_tbl_iterator.has_next() || reached_limit();
if (out_batch->is_full() || out_batch->at_resource_limit() || *eos) {
return Status::OK();
}
}
return Status::OK();
}
} // namespace doris
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