be/src/vec/exec/scan/scanner_context.cpp - doris - Git at Google

 // 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 "scanner_context.h"

 #include <bthread/bthread.h>
 #include <fmt/format.h>
 #include <gen_cpp/Metrics_types.h>
 #include <glog/logging.h>

 #include <algorithm>
 #include <mutex>
 #include <ostream>
 #include <utility>

 #include "common/config.h"
 #include "common/status.h"
 #include "runtime/descriptors.h"
 #include "runtime/exec_env.h"
 #include "runtime/query_context.h"
 #include "runtime/runtime_state.h"
 #include "util/pretty_printer.h"
 #include "util/uid_util.h"
 #include "vec/core/block.h"
 #include "vec/exec/scan/scanner_scheduler.h"
 #include "vec/exec/scan/vscan_node.h"
 #include "vec/exec/scan/vscanner.h"

 namespace doris::vectorized {

 ScannerContext::ScannerContext(doris::RuntimeState* state_, doris::vectorized::VScanNode* parent,
                                const doris::TupleDescriptor* output_tuple_desc,
                                const std::list<VScannerSPtr>& scanners_, int64_t limit_,
                                int64_t max_bytes_in_blocks_queue_, const int num_parallel_instances)
         : _state(state_),
           _parent(parent),
           _output_tuple_desc(output_tuple_desc),
           _process_status(Status::OK()),
           _batch_size(state_->batch_size()),
           limit(limit_),
           _max_bytes_in_queue(max_bytes_in_blocks_queue_),
           _scanner_scheduler(state_->exec_env()->scanner_scheduler()),
           _scanners(scanners_),
           _scanners_ref(scanners_.begin(), scanners_.end()),
           _num_parallel_instances(num_parallel_instances) {
     ctx_id = UniqueId::gen_uid().to_string();
     if (_scanners.empty()) {
         _is_finished = true;
     }
     if (limit < 0) {
         limit = -1;
     }
 }

 // After init function call, should not access _parent
 Status ScannerContext::init() {
     // 1. Calculate max concurrency
     // TODO: now the max thread num <= config::doris_scanner_thread_pool_thread_num / 4
     // should find a more reasonable value.
     _max_thread_num = config::doris_scanner_thread_pool_thread_num / 4;
     if (_parent->_shared_scan_opt) {
         DCHECK(_num_parallel_instances > 0);
         _max_thread_num *= _num_parallel_instances;
     }
     _max_thread_num = _max_thread_num == 0 ? 1 : _max_thread_num;
     DCHECK(_max_thread_num > 0);
     _max_thread_num = std::min(_max_thread_num, (int32_t)_scanners.size());
     // For select * from table limit 10; should just use one thread.
     if (_parent->should_run_serial()) {
         _max_thread_num = 1;
     }

     _scanner_profile = _parent->_scanner_profile;
     _scanner_sched_counter = _parent->_scanner_sched_counter;
     _scanner_ctx_sched_counter = _parent->_scanner_ctx_sched_counter;
     _scanner_ctx_sched_time = _parent->_scanner_ctx_sched_time;
     _free_blocks_memory_usage = _parent->_free_blocks_memory_usage;
     _newly_create_free_blocks_num = _parent->_newly_create_free_blocks_num;
     _queued_blocks_memory_usage = _parent->_queued_blocks_memory_usage;
     _scanner_wait_batch_timer = _parent->_scanner_wait_batch_timer;
     // 2. Calculate the number of free blocks that all scanners can use.
     // The calculation logic is as follows:
     //  1. Assuming that at most M rows can be scanned in one scan(config::doris_scanner_row_num),
     //     then figure out how many blocks are required for one scan(_block_per_scanner).
     //  2. The maximum number of concurrency * the blocks required for one scan,
     //     that is, the number of blocks that all scanners can use.
     auto doris_scanner_row_num =
             limit == -1 ? config::doris_scanner_row_num
                         : std::min(static_cast<int64_t>(config::doris_scanner_row_num), limit);
     int real_block_size =
             limit == -1 ? _batch_size : std::min(static_cast<int64_t>(_batch_size), limit);
     _block_per_scanner = (doris_scanner_row_num + (real_block_size - 1)) / real_block_size;
     _free_blocks_capacity = _max_thread_num * _block_per_scanner;

 #ifndef BE_TEST
     // 3. get thread token
     thread_token = _state->get_query_ctx()->get_token();
 #endif

     // 4. This ctx will be submitted to the scanner scheduler right after init.
     // So set _num_scheduling_ctx to 1 here.
     _num_scheduling_ctx = 1;

     _num_unfinished_scanners = _scanners.size();

     COUNTER_SET(_parent->_max_scanner_thread_num, (int64_t)_max_thread_num);
     _parent->_runtime_profile->add_info_string("UseSpecificThreadToken",
                                                thread_token == nullptr ? "False" : "True");

     return Status::OK();
 }

 vectorized::BlockUPtr ScannerContext::get_free_block(bool* has_free_block,
                                                      bool get_block_not_empty) {
     vectorized::BlockUPtr block;
     if (_free_blocks.try_dequeue(block)) {
         if (!get_block_not_empty || block->mem_reuse()) {
             _free_blocks_capacity--;
             _free_blocks_memory_usage->add(-block->allocated_bytes());
             return block;
         }
     }

     COUNTER_UPDATE(_newly_create_free_blocks_num, 1);
     return vectorized::Block::create_unique(_output_tuple_desc->slots(), _batch_size,
                                             true /*ignore invalid slots*/);
 }

 void ScannerContext::return_free_block(std::unique_ptr<vectorized::Block> block) {
     block->clear_column_data();
     _free_blocks_memory_usage->add(block->allocated_bytes());
     _free_blocks.enqueue(std::move(block));
     ++_free_blocks_capacity;
 }

 void ScannerContext::append_blocks_to_queue(std::vector<vectorized::BlockUPtr>& blocks) {
     std::lock_guard l(_transfer_lock);
     auto old_bytes_in_queue = _cur_bytes_in_queue;
     for (auto& b : blocks) {
         auto st = validate_block_schema(b.get());
         if (!st.ok()) {
             set_status_on_error(st, false);
         }
         _cur_bytes_in_queue += b->allocated_bytes();
         _blocks_queue.push_back(std::move(b));
     }
     blocks.clear();
     _blocks_queue_added_cv.notify_one();
     _queued_blocks_memory_usage->add(_cur_bytes_in_queue - old_bytes_in_queue);
 }

 bool ScannerContext::empty_in_queue(int id) {
     std::unique_lock l(_transfer_lock);
     return _blocks_queue.empty();
 }

 Status ScannerContext::get_block_from_queue(RuntimeState* state, vectorized::BlockUPtr* block,
                                             bool* eos, int id, bool wait) {
     std::unique_lock l(_transfer_lock);
     // Normally, the scanner scheduler will schedule ctx.
     // But when the amount of data in the blocks queue exceeds the upper limit,
     // the scheduler will stop scheduling.
     // (if the scheduler continues to schedule, it will cause a lot of busy running).
     // At this point, consumers are required to trigger new scheduling to ensure that
     // data can be continuously fetched.
     if (has_enough_space_in_blocks_queue() && _num_running_scanners == 0) {
         auto state = _scanner_scheduler->submit(this);
         if (state.ok()) {
             _num_scheduling_ctx++;
         } else {
             set_status_on_error(state, false);
         }
     }
     // Wait for block from queue
     if (wait) {
         SCOPED_TIMER(_scanner_wait_batch_timer);
         while (!(!_blocks_queue.empty() || _is_finished || !status().ok() ||
                  state->is_cancelled())) {
             _blocks_queue_added_cv.wait(l);
         }
     }

     if (state->is_cancelled()) {
         set_status_on_error(Status::Cancelled("cancelled"), false);
     }

     if (!status().ok()) {
         return status();
     }

     if (!_blocks_queue.empty()) {
         *block = std::move(_blocks_queue.front());
         _blocks_queue.pop_front();

         auto block_bytes = (*block)->allocated_bytes();
         _cur_bytes_in_queue -= block_bytes;
         _queued_blocks_memory_usage->add(-block_bytes);
         return Status::OK();
     } else {
         *eos = _is_finished;
     }
     return Status::OK();
 }

 Status ScannerContext::validate_block_schema(Block* block) {
     size_t index = 0;
     for (auto& slot : _output_tuple_desc->slots()) {
         if (!slot->need_materialize()) {
             continue;
         }
         auto& data = block->get_by_position(index++);
         if (data.column->is_nullable() != data.type->is_nullable()) {
             return Status::Error<ErrorCode::INVALID_SCHEMA>(
                     "column(name: {}) nullable({}) does not match type nullable({}), slot(id: {}, "
                     "name:{})",
                     data.name, data.column->is_nullable(), data.type->is_nullable(), slot->id(),
                     slot->col_name());
         }

         if (data.column->is_nullable() != slot->is_nullable()) {
             return Status::Error<ErrorCode::INVALID_SCHEMA>(
                     "column(name: {}) nullable({}) does not match slot(id: {}, name: {}) "
                     "nullable({})",
                     data.name, data.column->is_nullable(), slot->id(), slot->col_name(),
                     slot->is_nullable());
         }
     }
     return Status::OK();
 }

 bool ScannerContext::set_status_on_error(const Status& status, bool need_lock) {
     std::unique_lock l(_transfer_lock, std::defer_lock);
     if (need_lock) {
         l.lock();
     }
     if (this->status().ok()) {
         _process_status = status;
         _status_error = true;
         _blocks_queue_added_cv.notify_one();
         _should_stop = true;
         return true;
     }
     return false;
 }

 Status ScannerContext::_close_and_clear_scanners(VScanNode* node, RuntimeState* state) {
     std::unique_lock l(_scanners_lock);
     if (state->enable_profile()) {
         std::stringstream scanner_statistics;
         std::stringstream scanner_rows_read;
         std::stringstream scanner_wait_worker_time;
         scanner_statistics << "[";
         scanner_rows_read << "[";
         scanner_wait_worker_time << "[";
         for (auto finished_scanner_time : _finished_scanner_runtime) {
             scanner_statistics << PrettyPrinter::print(finished_scanner_time, TUnit::TIME_NS)
                                << ", ";
         }
         for (auto finished_scanner_rows : _finished_scanner_rows_read) {
             scanner_rows_read << PrettyPrinter::print(finished_scanner_rows, TUnit::UNIT) << ", ";
         }
         for (auto finished_scanner_wait_time : _finished_scanner_wait_worker_time) {
             scanner_wait_worker_time
                     << PrettyPrinter::print(finished_scanner_wait_time, TUnit::TIME_NS) << ", ";
         }
         // Only unfinished scanners here
         for (auto& scanner : _scanners) {
             // Scanners are in ObjPool in ScanNode,
             // so no need to delete them here.
             // Add per scanner running time before close them
             scanner_statistics << PrettyPrinter::print(scanner->get_time_cost_ns(), TUnit::TIME_NS)
                                << ", ";
             scanner_rows_read << PrettyPrinter::print(scanner->get_rows_read(), TUnit::UNIT)
                               << ", ";
             scanner_wait_worker_time
                     << PrettyPrinter::print(scanner->get_scanner_wait_worker_timer(),
                                             TUnit::TIME_NS)
                     << ", ";
         }
         scanner_statistics << "]";
         scanner_rows_read << "]";
         scanner_wait_worker_time << "]";
         node->_scanner_profile->add_info_string("PerScannerRunningTime", scanner_statistics.str());
         node->_scanner_profile->add_info_string("PerScannerRowsRead", scanner_rows_read.str());
         node->_scanner_profile->add_info_string("PerScannerWaitTime",
                                                 scanner_wait_worker_time.str());
     }
     // Only unfinished scanners here
     for (auto& scanner : _scanners) {
         scanner->close(state);
         // Scanners are in ObjPool in ScanNode,
         // so no need to delete them here.
     }
     _scanners.clear();
     return Status::OK();
 }

 void ScannerContext::clear_and_join(VScanNode* node, RuntimeState* state) {
     std::unique_lock l(_transfer_lock);
     do {
         if (_num_running_scanners == 0 && _num_scheduling_ctx == 0) {
             break;
         } else {
             DCHECK(!state->enable_pipeline_exec());
             while (!(_num_running_scanners == 0 && _num_scheduling_ctx == 0)) {
                 _ctx_finish_cv.wait(l);
             }
             break;
         }
     } while (false);

     for (const auto& tid : _btids) {
         bthread_join(tid, nullptr);
     }
     // Must wait all running scanners stop running.
     // So that we can make sure to close all scanners.
     _close_and_clear_scanners(node, state);

     _blocks_queue.clear();
 }

 bool ScannerContext::no_schedule() {
     std::unique_lock l(_transfer_lock);
     return _num_running_scanners == 0 && _num_scheduling_ctx == 0;
 }

 std::string ScannerContext::debug_string() {
     return fmt::format(
             "id: {}, sacnners: {}, blocks in queue: {},"
             " status: {}, _should_stop: {}, _is_finished: {}, free blocks: {},"
             " limit: {}, _num_running_scanners: {}, _num_scheduling_ctx: {}, _max_thread_num: {},"
             " _block_per_scanner: {}, _cur_bytes_in_queue: {}, MAX_BYTE_OF_QUEUE: {}",
             ctx_id, _scanners.size(), _blocks_queue.size(), status().ok(), _should_stop,
             _is_finished, _free_blocks.size_approx(), limit, _num_running_scanners,
             _num_scheduling_ctx, _max_thread_num, _block_per_scanner, _cur_bytes_in_queue,
             _max_bytes_in_queue);
 }

 void ScannerContext::reschedule_scanner_ctx() {
     std::lock_guard l(_transfer_lock);
     auto state = _scanner_scheduler->submit(this);
     //todo(wb) rethinking is it better to mark current scan_context failed when submit failed many times?
     if (state.ok()) {
         _num_scheduling_ctx++;
     } else {
         set_status_on_error(state, false);
     }
 }

 void ScannerContext::push_back_scanner_and_reschedule(VScannerSPtr scanner) {
     {
         std::unique_lock l(_scanners_lock);
         _scanners.push_front(scanner);
     }
     std::lock_guard l(_transfer_lock);
     if (has_enough_space_in_blocks_queue()) {
         auto state = _scanner_scheduler->submit(this);
         if (state.ok()) {
             _num_scheduling_ctx++;
         } else {
             set_status_on_error(state, false);
         }
     }

     // Notice that after calling "_scanners.push_front(scanner)", there may be other ctx in scheduler
     // to schedule that scanner right away, and in that schedule run, the scanner may be marked as closed
     // before we call the following if() block.
     // So we need "scanner->set_counted_down()" to avoid "_num_unfinished_scanners" being decreased twice by
     // same scanner.
     if (scanner->need_to_close() && scanner->set_counted_down() &&
         (--_num_unfinished_scanners) == 0) {
         _dispose_coloate_blocks_not_in_queue();
         _is_finished = true;
         _blocks_queue_added_cv.notify_one();
     }
     // In pipeline engine, doris will close scanners when `no_schedule`.
     _num_running_scanners--;
     _ctx_finish_cv.notify_one();
 }

 void ScannerContext::get_next_batch_of_scanners(std::list<VScannerSPtr>* current_run) {
     // 1. Calculate how many scanners should be scheduled at this run.
     int thread_slot_num = 0;
     {
         // If there are enough space in blocks queue,
         // the scanner number depends on the _free_blocks numbers
         thread_slot_num = cal_thread_slot_num_by_free_block_num();
     }

     // 2. get #thread_slot_num scanners from ctx->scanners
     // and put them into "this_run".
     {
         std::unique_lock l(_scanners_lock);
         for (int i = 0; i < thread_slot_num && !_scanners.empty();) {
             VScannerSPtr scanner = _scanners.front();
             _scanners.pop_front();
             if (scanner->need_to_close()) {
                 _finished_scanner_runtime.push_back(scanner->get_time_cost_ns());
                 _finished_scanner_rows_read.push_back(scanner->get_rows_read());
                 _finished_scanner_wait_worker_time.push_back(
                         scanner->get_scanner_wait_worker_timer());
                 scanner->close(_state);
             } else {
                 current_run->push_back(scanner);
                 i++;
             }
         }
     }
 }

 taskgroup::TaskGroup* ScannerContext::get_task_group() const {
     return _state->get_query_ctx()->get_task_group();
 }

 } // namespace doris::vectorized
	// 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 "scanner_context.h"

	#include <bthread/bthread.h>
	#include <fmt/format.h>
	#include <gen_cpp/Metrics_types.h>
	#include <glog/logging.h>

	#include <algorithm>
	#include <mutex>
	#include <ostream>
	#include <utility>

	#include "common/config.h"
	#include "common/status.h"
	#include "runtime/descriptors.h"
	#include "runtime/exec_env.h"
	#include "runtime/query_context.h"
	#include "runtime/runtime_state.h"
	#include "util/pretty_printer.h"
	#include "util/uid_util.h"
	#include "vec/core/block.h"
	#include "vec/exec/scan/scanner_scheduler.h"
	#include "vec/exec/scan/vscan_node.h"
	#include "vec/exec/scan/vscanner.h"

	namespace doris::vectorized {

	ScannerContext::ScannerContext(doris::RuntimeState* state_, doris::vectorized::VScanNode* parent,
	const doris::TupleDescriptor* output_tuple_desc,
	const std::list<VScannerSPtr>& scanners_, int64_t limit_,
	int64_t max_bytes_in_blocks_queue_, const int num_parallel_instances)
	: _state(state_),
	_parent(parent),
	_output_tuple_desc(output_tuple_desc),
	_process_status(Status::OK()),
	_batch_size(state_->batch_size()),
	limit(limit_),
	_max_bytes_in_queue(max_bytes_in_blocks_queue_),
	_scanner_scheduler(state_->exec_env()->scanner_scheduler()),
	_scanners(scanners_),
	_scanners_ref(scanners_.begin(), scanners_.end()),
	_num_parallel_instances(num_parallel_instances) {
	ctx_id = UniqueId::gen_uid().to_string();
	if (_scanners.empty()) {
	_is_finished = true;
	}
	if (limit < 0) {
	limit = -1;
	}
	}

	// After init function call, should not access _parent
	Status ScannerContext::init() {
	// 1. Calculate max concurrency
	// TODO: now the max thread num <= config::doris_scanner_thread_pool_thread_num / 4
	// should find a more reasonable value.
	_max_thread_num = config::doris_scanner_thread_pool_thread_num / 4;
	if (_parent->_shared_scan_opt) {
	DCHECK(_num_parallel_instances > 0);
	_max_thread_num *= _num_parallel_instances;
	}
	_max_thread_num = _max_thread_num == 0 ? 1 : _max_thread_num;
	DCHECK(_max_thread_num > 0);
	_max_thread_num = std::min(_max_thread_num, (int32_t)_scanners.size());
	// For select * from table limit 10; should just use one thread.
	if (_parent->should_run_serial()) {
	_max_thread_num = 1;
	}

	_scanner_profile = _parent->_scanner_profile;
	_scanner_sched_counter = _parent->_scanner_sched_counter;
	_scanner_ctx_sched_counter = _parent->_scanner_ctx_sched_counter;
	_scanner_ctx_sched_time = _parent->_scanner_ctx_sched_time;
	_free_blocks_memory_usage = _parent->_free_blocks_memory_usage;
	_newly_create_free_blocks_num = _parent->_newly_create_free_blocks_num;
	_queued_blocks_memory_usage = _parent->_queued_blocks_memory_usage;
	_scanner_wait_batch_timer = _parent->_scanner_wait_batch_timer;
	// 2. Calculate the number of free blocks that all scanners can use.
	// The calculation logic is as follows:
	// 1. Assuming that at most M rows can be scanned in one scan(config::doris_scanner_row_num),
	// then figure out how many blocks are required for one scan(_block_per_scanner).
	// 2. The maximum number of concurrency * the blocks required for one scan,
	// that is, the number of blocks that all scanners can use.
	auto doris_scanner_row_num =
	limit == -1 ? config::doris_scanner_row_num
	: std::min(static_cast<int64_t>(config::doris_scanner_row_num), limit);
	int real_block_size =
	limit == -1 ? _batch_size : std::min(static_cast<int64_t>(_batch_size), limit);
	_block_per_scanner = (doris_scanner_row_num + (real_block_size - 1)) / real_block_size;
	_free_blocks_capacity = _max_thread_num * _block_per_scanner;

	#ifndef BE_TEST
	// 3. get thread token
	thread_token = _state->get_query_ctx()->get_token();
	#endif

	// 4. This ctx will be submitted to the scanner scheduler right after init.
	// So set _num_scheduling_ctx to 1 here.
	_num_scheduling_ctx = 1;

	_num_unfinished_scanners = _scanners.size();

	COUNTER_SET(_parent->_max_scanner_thread_num, (int64_t)_max_thread_num);
	_parent->_runtime_profile->add_info_string("UseSpecificThreadToken",
	thread_token == nullptr ? "False" : "True");

	return Status::OK();
	}

	vectorized::BlockUPtr ScannerContext::get_free_block(bool* has_free_block,
	bool get_block_not_empty) {
	vectorized::BlockUPtr block;
	if (_free_blocks.try_dequeue(block)) {
	if (!get_block_not_empty \|\| block->mem_reuse()) {
	_free_blocks_capacity--;
	_free_blocks_memory_usage->add(-block->allocated_bytes());
	return block;
	}
	}

	COUNTER_UPDATE(_newly_create_free_blocks_num, 1);
	return vectorized::Block::create_unique(_output_tuple_desc->slots(), _batch_size,
	true /ignore invalid slots/);
	}

	void ScannerContext::return_free_block(std::unique_ptr<vectorized::Block> block) {
	block->clear_column_data();
	_free_blocks_memory_usage->add(block->allocated_bytes());
	_free_blocks.enqueue(std::move(block));
	++_free_blocks_capacity;
	}

	void ScannerContext::append_blocks_to_queue(std::vector<vectorized::BlockUPtr>& blocks) {
	std::lock_guard l(_transfer_lock);
	auto old_bytes_in_queue = _cur_bytes_in_queue;
	for (auto& b : blocks) {
	auto st = validate_block_schema(b.get());
	if (!st.ok()) {
	set_status_on_error(st, false);
	}
	_cur_bytes_in_queue += b->allocated_bytes();
	_blocks_queue.push_back(std::move(b));
	}
	blocks.clear();
	_blocks_queue_added_cv.notify_one();
	_queued_blocks_memory_usage->add(_cur_bytes_in_queue - old_bytes_in_queue);
	}

	bool ScannerContext::empty_in_queue(int id) {
	std::unique_lock l(_transfer_lock);
	return _blocks_queue.empty();
	}

	Status ScannerContext::get_block_from_queue(RuntimeState* state, vectorized::BlockUPtr* block,
	bool* eos, int id, bool wait) {
	std::unique_lock l(_transfer_lock);
	// Normally, the scanner scheduler will schedule ctx.
	// But when the amount of data in the blocks queue exceeds the upper limit,
	// the scheduler will stop scheduling.
	// (if the scheduler continues to schedule, it will cause a lot of busy running).
	// At this point, consumers are required to trigger new scheduling to ensure that
	// data can be continuously fetched.
	if (has_enough_space_in_blocks_queue() && _num_running_scanners == 0) {
	auto state = _scanner_scheduler->submit(this);
	if (state.ok()) {
	_num_scheduling_ctx++;
	} else {
	set_status_on_error(state, false);
	}
	}
	// Wait for block from queue
	if (wait) {
	SCOPED_TIMER(_scanner_wait_batch_timer);
	while (!(!_blocks_queue.empty() \|\| _is_finished \|\| !status().ok() \|\|
	state->is_cancelled())) {
	_blocks_queue_added_cv.wait(l);
	}
	}

	if (state->is_cancelled()) {
	set_status_on_error(Status::Cancelled("cancelled"), false);
	}

	if (!status().ok()) {
	return status();
	}

	if (!_blocks_queue.empty()) {
	*block = std::move(_blocks_queue.front());
	_blocks_queue.pop_front();

	auto block_bytes = (*block)->allocated_bytes();
	_cur_bytes_in_queue -= block_bytes;
	_queued_blocks_memory_usage->add(-block_bytes);
	return Status::OK();
	} else {
	*eos = _is_finished;
	}
	return Status::OK();
	}

	Status ScannerContext::validate_block_schema(Block* block) {
	size_t index = 0;
	for (auto& slot : _output_tuple_desc->slots()) {
	if (!slot->need_materialize()) {
	continue;
	}
	auto& data = block->get_by_position(index++);
	if (data.column->is_nullable() != data.type->is_nullable()) {
	return Status::Error<ErrorCode::INVALID_SCHEMA>(
	"column(name: {}) nullable({}) does not match type nullable({}), slot(id: {}, "
	"name:{})",
	data.name, data.column->is_nullable(), data.type->is_nullable(), slot->id(),
	slot->col_name());
	}

	if (data.column->is_nullable() != slot->is_nullable()) {
	return Status::Error<ErrorCode::INVALID_SCHEMA>(
	"column(name: {}) nullable({}) does not match slot(id: {}, name: {}) "
	"nullable({})",
	data.name, data.column->is_nullable(), slot->id(), slot->col_name(),
	slot->is_nullable());
	}
	}
	return Status::OK();
	}

	bool ScannerContext::set_status_on_error(const Status& status, bool need_lock) {
	std::unique_lock l(_transfer_lock, std::defer_lock);
	if (need_lock) {
	l.lock();
	}
	if (this->status().ok()) {
	_process_status = status;
	_status_error = true;
	_blocks_queue_added_cv.notify_one();
	_should_stop = true;
	return true;
	}
	return false;
	}

	Status ScannerContext::_close_and_clear_scanners(VScanNode* node, RuntimeState* state) {
	std::unique_lock l(_scanners_lock);
	if (state->enable_profile()) {
	std::stringstream scanner_statistics;
	std::stringstream scanner_rows_read;
	std::stringstream scanner_wait_worker_time;
	scanner_statistics << "[";
	scanner_rows_read << "[";
	scanner_wait_worker_time << "[";
	for (auto finished_scanner_time : _finished_scanner_runtime) {
	scanner_statistics << PrettyPrinter::print(finished_scanner_time, TUnit::TIME_NS)
	<< ", ";
	}
	for (auto finished_scanner_rows : _finished_scanner_rows_read) {
	scanner_rows_read << PrettyPrinter::print(finished_scanner_rows, TUnit::UNIT) << ", ";
	}
	for (auto finished_scanner_wait_time : _finished_scanner_wait_worker_time) {
	scanner_wait_worker_time
	<< PrettyPrinter::print(finished_scanner_wait_time, TUnit::TIME_NS) << ", ";
	}
	// Only unfinished scanners here
	for (auto& scanner : _scanners) {
	// Scanners are in ObjPool in ScanNode,
	// so no need to delete them here.
	// Add per scanner running time before close them
	scanner_statistics << PrettyPrinter::print(scanner->get_time_cost_ns(), TUnit::TIME_NS)
	<< ", ";
	scanner_rows_read << PrettyPrinter::print(scanner->get_rows_read(), TUnit::UNIT)
	<< ", ";
	scanner_wait_worker_time
	<< PrettyPrinter::print(scanner->get_scanner_wait_worker_timer(),
	TUnit::TIME_NS)
	<< ", ";
	}
	scanner_statistics << "]";
	scanner_rows_read << "]";
	scanner_wait_worker_time << "]";
	node->_scanner_profile->add_info_string("PerScannerRunningTime", scanner_statistics.str());
	node->_scanner_profile->add_info_string("PerScannerRowsRead", scanner_rows_read.str());
	node->_scanner_profile->add_info_string("PerScannerWaitTime",
	scanner_wait_worker_time.str());
	}
	// Only unfinished scanners here
	for (auto& scanner : _scanners) {
	scanner->close(state);
	// Scanners are in ObjPool in ScanNode,
	// so no need to delete them here.
	}
	_scanners.clear();
	return Status::OK();
	}

	void ScannerContext::clear_and_join(VScanNode* node, RuntimeState* state) {
	std::unique_lock l(_transfer_lock);
	do {
	if (_num_running_scanners == 0 && _num_scheduling_ctx == 0) {
	break;
	} else {
	DCHECK(!state->enable_pipeline_exec());
	while (!(_num_running_scanners == 0 && _num_scheduling_ctx == 0)) {
	_ctx_finish_cv.wait(l);
	}
	break;
	}
	} while (false);

	for (const auto& tid : _btids) {
	bthread_join(tid, nullptr);
	}
	// Must wait all running scanners stop running.
	// So that we can make sure to close all scanners.
	_close_and_clear_scanners(node, state);

	_blocks_queue.clear();
	}

	bool ScannerContext::no_schedule() {
	std::unique_lock l(_transfer_lock);
	return _num_running_scanners == 0 && _num_scheduling_ctx == 0;
	}

	std::string ScannerContext::debug_string() {
	return fmt::format(
	"id: {}, sacnners: {}, blocks in queue: {},"
	" status: {}, _should_stop: {}, _is_finished: {}, free blocks: {},"
	" limit: {}, _num_running_scanners: {}, _num_scheduling_ctx: {}, _max_thread_num: {},"
	" _block_per_scanner: {}, _cur_bytes_in_queue: {}, MAX_BYTE_OF_QUEUE: {}",
	ctx_id, _scanners.size(), _blocks_queue.size(), status().ok(), _should_stop,
	_is_finished, _free_blocks.size_approx(), limit, _num_running_scanners,
	_num_scheduling_ctx, _max_thread_num, _block_per_scanner, _cur_bytes_in_queue,
	_max_bytes_in_queue);
	}

	void ScannerContext::reschedule_scanner_ctx() {
	std::lock_guard l(_transfer_lock);
	auto state = _scanner_scheduler->submit(this);
	//todo(wb) rethinking is it better to mark current scan_context failed when submit failed many times?
	if (state.ok()) {
	_num_scheduling_ctx++;
	} else {
	set_status_on_error(state, false);
	}
	}

	void ScannerContext::push_back_scanner_and_reschedule(VScannerSPtr scanner) {
	{
	std::unique_lock l(_scanners_lock);
	_scanners.push_front(scanner);
	}
	std::lock_guard l(_transfer_lock);
	if (has_enough_space_in_blocks_queue()) {
	auto state = _scanner_scheduler->submit(this);
	if (state.ok()) {
	_num_scheduling_ctx++;
	} else {
	set_status_on_error(state, false);
	}
	}

	// Notice that after calling "_scanners.push_front(scanner)", there may be other ctx in scheduler
	// to schedule that scanner right away, and in that schedule run, the scanner may be marked as closed
	// before we call the following if() block.
	// So we need "scanner->set_counted_down()" to avoid "_num_unfinished_scanners" being decreased twice by
	// same scanner.
	if (scanner->need_to_close() && scanner->set_counted_down() &&
	(--_num_unfinished_scanners) == 0) {
	_dispose_coloate_blocks_not_in_queue();
	_is_finished = true;
	_blocks_queue_added_cv.notify_one();
	}
	// In pipeline engine, doris will close scanners when `no_schedule`.
	_num_running_scanners--;
	_ctx_finish_cv.notify_one();
	}

	void ScannerContext::get_next_batch_of_scanners(std::list<VScannerSPtr>* current_run) {
	// 1. Calculate how many scanners should be scheduled at this run.
	int thread_slot_num = 0;
	{
	// If there are enough space in blocks queue,
	// the scanner number depends on the _free_blocks numbers
	thread_slot_num = cal_thread_slot_num_by_free_block_num();
	}

	// 2. get #thread_slot_num scanners from ctx->scanners
	// and put them into "this_run".
	{
	std::unique_lock l(_scanners_lock);
	for (int i = 0; i < thread_slot_num && !_scanners.empty();) {
	VScannerSPtr scanner = _scanners.front();
	_scanners.pop_front();
	if (scanner->need_to_close()) {
	_finished_scanner_runtime.push_back(scanner->get_time_cost_ns());
	_finished_scanner_rows_read.push_back(scanner->get_rows_read());
	_finished_scanner_wait_worker_time.push_back(
	scanner->get_scanner_wait_worker_timer());
	scanner->close(_state);
	} else {
	current_run->push_back(scanner);
	i++;
	}
	}
	}
	}

	taskgroup::TaskGroup* ScannerContext::get_task_group() const {
	return _state->get_query_ctx()->get_task_group();
	}

	} // namespace doris::vectorized