/root/doris/be/src/pipeline/task_queue.cpp

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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 "task_queue.h"

// IWYU pragma: no_include <bits/chrono.h>
#include <chrono> // IWYU pragma: keep
#include <string>

#include "common/logging.h"
#include "pipeline/pipeline_task.h"

namespace doris {
namespace pipeline {

TaskQueue::~TaskQueue() = default;

PipelineTask* SubTaskQueue::try_take(bool is_steal) {
    if (_queue.empty()) {
        return nullptr;
    }
    auto task = _queue.front();
    _queue.pop();
    return task;
}

////////////////////  PriorityTaskQueue ////////////////////

PriorityTaskQueue::PriorityTaskQueue() : _closed(false) {
    double factor = 1;
    for (int i = SUB_QUEUE_LEVEL - 1; i >= 0; i--) {
        _sub_queues[i].set_level_factor(factor);
        factor *= LEVEL_QUEUE_TIME_FACTOR;
    }
}

void PriorityTaskQueue::close() {
    std::unique_lock<std::mutex> lock(_work_size_mutex);
    _closed = true;
    _wait_task.notify_all();
    DorisMetrics::instance()->pipeline_task_queue_size->increment(-_total_task_size);
}

PipelineTask* PriorityTaskQueue::_try_take_unprotected(bool is_steal) {
    if (_total_task_size == 0 || _closed) {
        return nullptr;
    }

    double min_vruntime = 0;
    int level = -1;
    for (int i = 0; i < SUB_QUEUE_LEVEL; ++i) {
        double cur_queue_vruntime = _sub_queues[i].get_vruntime();
        if (!_sub_queues[i].empty()) {
            if (level == -1 || cur_queue_vruntime < min_vruntime) {
                level = i;
                min_vruntime = cur_queue_vruntime;
            }
        }
    }
    DCHECK(level != -1);
    _queue_level_min_vruntime = uint64_t(min_vruntime);

    auto task = _sub_queues[level].try_take(is_steal);
    if (task) {
        task->update_queue_level(level);
        _total_task_size--;
        DorisMetrics::instance()->pipeline_task_queue_size->increment(-1);
    }
    return task;
}

int PriorityTaskQueue::_compute_level(uint64_t runtime) {
    for (int i = 0; i < SUB_QUEUE_LEVEL - 1; ++i) {
        if (runtime <= _queue_level_limit[i]) {
            return i;
        }
    }
    return SUB_QUEUE_LEVEL - 1;
}

PipelineTask* PriorityTaskQueue::try_take(bool is_steal) {
    // TODO other efficient lock? e.g. if get lock fail, return null_ptr
    std::unique_lock<std::mutex> lock(_work_size_mutex);
    return _try_take_unprotected(is_steal);
}

PipelineTask* PriorityTaskQueue::take(uint32_t timeout_ms) {
    std::unique_lock<std::mutex> lock(_work_size_mutex);
    auto task = _try_take_unprotected(false);
    if (task) {
        return task;
    } else {
        if (timeout_ms > 0) {
            _wait_task.wait_for(lock, std::chrono::milliseconds(timeout_ms));
        } else {
            _wait_task.wait(lock);
        }
        return _try_take_unprotected(false);
    }
}

Status PriorityTaskQueue::push(PipelineTask* task) {
    if (_closed) {
        return Status::InternalError("WorkTaskQueue closed");
    }
    auto level = _compute_level(task->get_runtime_ns());
    std::unique_lock<std::mutex> lock(_work_size_mutex);

    // update empty queue's  runtime, to avoid too high priority
    if (_sub_queues[level].empty() &&
        _queue_level_min_vruntime > _sub_queues[level].get_vruntime()) {
        _sub_queues[level].adjust_runtime(_queue_level_min_vruntime);
    }

    _sub_queues[level].push_back(task);
    _total_task_size++;
    DorisMetrics::instance()->pipeline_task_queue_size->increment(1);
    _wait_task.notify_one();
    return Status::OK();
}

MultiCoreTaskQueue::~MultiCoreTaskQueue() = default;

MultiCoreTaskQueue::MultiCoreTaskQueue(int core_size)
        : TaskQueue(core_size), _prio_task_queue_list(core_size), _closed(false) {}

void MultiCoreTaskQueue::close() {
    if (_closed) {
        return;
    }
    _closed = true;
    // close all priority task queue
    std::ranges::for_each(_prio_task_queue_list,
                          [](auto& prio_task_queue) { prio_task_queue.close(); });
}

PipelineTask* MultiCoreTaskQueue::take(int core_id) {
    PipelineTask* task = nullptr;
    while (!_closed) {
        DCHECK(_prio_task_queue_list.size() > core_id)
                << " list size: " << _prio_task_queue_list.size() << " core_id: " << core_id
                << " _core_size: " << _core_size << " _next_core: " << _next_core.load();
        task = _prio_task_queue_list[core_id].try_take(false);
        if (task) {
            task->set_core_id(core_id);
            break;
        }
        task = _steal_take(core_id);
        if (task) {
            break;
        }
        task = _prio_task_queue_list[core_id].take(WAIT_CORE_TASK_TIMEOUT_MS /* timeout_ms */);
        if (task) {
            task->set_core_id(core_id);
            break;
        }
    }
    if (task) {
        task->pop_out_runnable_queue();
    }
    return task;
}

PipelineTask* MultiCoreTaskQueue::_steal_take(int core_id) {
    DCHECK(core_id < _core_size);
    int next_id = core_id;
    for (int i = 1; i < _core_size; ++i) {
        ++next_id;
        if (next_id == _core_size) {
            next_id = 0;
        }
        DCHECK(next_id < _core_size);
        auto task = _prio_task_queue_list[next_id].try_take(true);
        if (task) {
            task->set_core_id(next_id);
            return task;
        }
    }
    return nullptr;
}

Status MultiCoreTaskQueue::push_back(PipelineTask* task) {
    int core_id = task->get_previous_core_id();
    if (core_id < 0) {
        core_id = _next_core.fetch_add(1) % _core_size;
    }
    return push_back(task, core_id);
}

Status MultiCoreTaskQueue::push_back(PipelineTask* task, int core_id) {
    DCHECK(core_id < _core_size);
    task->put_in_runnable_queue();
    return _prio_task_queue_list[core_id].push(task);
}

} // namespace pipeline
} // namespace doris

Coverage Report

Created: 2026-02-06 15:21

Line	Count	Source (jump to first uncovered line)
1		// Licensed to the Apache Software Foundation (ASF) under one
2		// or more contributor license agreements. See the NOTICE file
3		// distributed with this work for additional information
4		// regarding copyright ownership. The ASF licenses this file
5		// to you under the Apache License, Version 2.0 (the
6		// "License"); you may not use this file except in compliance
7		// with the License. You may obtain a copy of the License at
8		//
9		// http://www.apache.org/licenses/LICENSE-2.0
10		//
11		// Unless required by applicable law or agreed to in writing,
12		// software distributed under the License is distributed on an
13		// "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
14		// KIND, either express or implied. See the License for the
15		// specific language governing permissions and limitations
16		// under the License.
17
18		#include "task_queue.h"
19
20		// IWYU pragma: no_include <bits/chrono.h>
21		#include <chrono> // IWYU pragma: keep
22		#include <string>
23
24		#include "common/logging.h"
25		#include "pipeline/pipeline_task.h"
26
27		namespace doris {
28		namespace pipeline {
29
30	0	TaskQueue::~TaskQueue() = default;
31
32	0	PipelineTask* SubTaskQueue::try_take(bool is_steal) {
33	0	if (_queue.empty()) {
34	0	return nullptr;
35	0	}
36	0	auto task = _queue.front();
37	0	_queue.pop();
38	0	return task;
39	0	}
40
41		//////////////////// PriorityTaskQueue ////////////////////
42
43	0	PriorityTaskQueue::PriorityTaskQueue() : _closed(false) {
44	0	double factor = 1;
45	0	for (int i = SUB_QUEUE_LEVEL - 1; i >= 0; i--) {
46	0	_sub_queues[i].set_level_factor(factor);
47	0	factor *= LEVEL_QUEUE_TIME_FACTOR;
48	0	}
49	0	}
50
51	0	void PriorityTaskQueue::close() {
52	0	std::unique_lock<std::mutex> lock(_work_size_mutex);
53	0	_closed = true;
54	0	_wait_task.notify_all();
55	0	DorisMetrics::instance()->pipeline_task_queue_size->increment(-_total_task_size);
56	0	}
57
58	0	PipelineTask* PriorityTaskQueue::_try_take_unprotected(bool is_steal) {
59	0	if (_total_task_size == 0 \|\| _closed) {
60	0	return nullptr;
61	0	}
62
63	0	double min_vruntime = 0;
64	0	int level = -1;
65	0	for (int i = 0; i < SUB_QUEUE_LEVEL; ++i) {
66	0	double cur_queue_vruntime = _sub_queues[i].get_vruntime();
67	0	if (!_sub_queues[i].empty()) {
68	0	if (level == -1 \|\| cur_queue_vruntime < min_vruntime) {
69	0	level = i;
70	0	min_vruntime = cur_queue_vruntime;
71	0	}
72	0	}
73	0	}
74	0	DCHECK(level != -1);
75	0	_queue_level_min_vruntime = uint64_t(min_vruntime);
76
77	0	auto task = _sub_queues[level].try_take(is_steal);
78	0	if (task) {
79	0	task->update_queue_level(level);
80	0	_total_task_size--;
81	0	DorisMetrics::instance()->pipeline_task_queue_size->increment(-1);
82	0	}
83	0	return task;
84	0	}
85
86	0	int PriorityTaskQueue::_compute_level(uint64_t runtime) {
87	0	for (int i = 0; i < SUB_QUEUE_LEVEL - 1; ++i) {
88	0	if (runtime <= _queue_level_limit[i]) {
89	0	return i;
90	0	}
91	0	}
92	0	return SUB_QUEUE_LEVEL - 1;
93	0	}
94
95	0	PipelineTask* PriorityTaskQueue::try_take(bool is_steal) {
96		// TODO other efficient lock? e.g. if get lock fail, return null_ptr
97	0	std::unique_lock<std::mutex> lock(_work_size_mutex);
98	0	return _try_take_unprotected(is_steal);
99	0	}
100
101	0	PipelineTask* PriorityTaskQueue::take(uint32_t timeout_ms) {
102	0	std::unique_lock<std::mutex> lock(_work_size_mutex);
103	0	auto task = _try_take_unprotected(false);
104	0	if (task) {
105	0	return task;
106	0	} else {
107	0	if (timeout_ms > 0) {
108	0	_wait_task.wait_for(lock, std::chrono::milliseconds(timeout_ms));
109	0	} else {
110	0	_wait_task.wait(lock);
111	0	}
112	0	return _try_take_unprotected(false);
113	0	}
114	0	}
115
116	0	Status PriorityTaskQueue::push(PipelineTask* task) {
117	0	if (_closed) {
118	0	return Status::InternalError("WorkTaskQueue closed");
119	0	}
120	0	auto level = _compute_level(task->get_runtime_ns());
121	0	std::unique_lock<std::mutex> lock(_work_size_mutex);
122
123		// update empty queue's runtime, to avoid too high priority
124	0	if (_sub_queues[level].empty() &&
125	0	_queue_level_min_vruntime > _sub_queues[level].get_vruntime()) {
126	0	_sub_queues[level].adjust_runtime(_queue_level_min_vruntime);
127	0	}
128
129	0	_sub_queues[level].push_back(task);
130	0	_total_task_size++;
131	0	DorisMetrics::instance()->pipeline_task_queue_size->increment(1);
132	0	_wait_task.notify_one();
133	0	return Status::OK();
134	0	}
135
136	0	MultiCoreTaskQueue::~MultiCoreTaskQueue() = default;
137
138		MultiCoreTaskQueue::MultiCoreTaskQueue(int core_size)
139	0	: TaskQueue(core_size), _prio_task_queue_list(core_size), _closed(false) {}
140
141	0	void MultiCoreTaskQueue::close() {
142	0	if (_closed) {
143	0	return;
144	0	}
145	0	_closed = true;
146		// close all priority task queue
147	0	std::ranges::for_each(_prio_task_queue_list,
148	0	[](auto& prio_task_queue) { prio_task_queue.close(); });
149	0	}
150
151	0	PipelineTask* MultiCoreTaskQueue::take(int core_id) {
152	0	PipelineTask* task = nullptr;
153	0	while (!_closed) {
154	0	DCHECK(_prio_task_queue_list.size() > core_id)
155	0	<< " list size: " << _prio_task_queue_list.size() << " core_id: " << core_id
156	0	<< " _core_size: " << _core_size << " _next_core: " << _next_core.load();
157	0	task = _prio_task_queue_list[core_id].try_take(false);
158	0	if (task) {
159	0	task->set_core_id(core_id);
160	0	break;
161	0	}
162	0	task = _steal_take(core_id);
163	0	if (task) {
164	0	break;
165	0	}
166	0	task = _prio_task_queue_list[core_id].take(WAIT_CORE_TASK_TIMEOUT_MS /* timeout_ms */);
167	0	if (task) {
168	0	task->set_core_id(core_id);
169	0	break;
170	0	}
171	0	}
172	0	if (task) {
173	0	task->pop_out_runnable_queue();
174	0	}
175	0	return task;
176	0	}
177
178	0	PipelineTask* MultiCoreTaskQueue::_steal_take(int core_id) {
179	0	DCHECK(core_id < _core_size);
180	0	int next_id = core_id;
181	0	for (int i = 1; i < _core_size; ++i) {
182	0	++next_id;
183	0	if (next_id == _core_size) {
184	0	next_id = 0;
185	0	}
186	0	DCHECK(next_id < _core_size);
187	0	auto task = _prio_task_queue_list[next_id].try_take(true);
188	0	if (task) {
189	0	task->set_core_id(next_id);
190	0	return task;
191	0	}
192	0	}
193	0	return nullptr;
194	0	}
195
196	0	Status MultiCoreTaskQueue::push_back(PipelineTask* task) {
197	0	int core_id = task->get_previous_core_id();
198	0	if (core_id < 0) {
199	0	core_id = _next_core.fetch_add(1) % _core_size;
200	0	}
201	0	return push_back(task, core_id);
202	0	}
203
204	0	Status MultiCoreTaskQueue::push_back(PipelineTask* task, int core_id) {
205	0	DCHECK(core_id < _core_size);
206	0	task->put_in_runnable_queue();
207	0	return _prio_task_queue_list[core_id].push(task);
208	0	}
209
210		} // namespace pipeline
211		} // namespace doris