ParallelHelperPool.h source code [webcore/Source/WTF/wtf/ParallelHelperPool.h]

1	/*
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25
26	#pragma once
27
28	#include <wtf/Box.h>
29	#include <wtf/Condition.h>
30	#include <wtf/Lock.h>
31	#include <wtf/RefPtr.h>
32	#include <wtf/SharedTask.h>
33	#include <wtf/ThreadSafeRefCounted.h>
34	#include <wtf/Threading.h>
35	#include <wtf/Vector.h>
36	#include <wtf/WeakRandom.h>
37	#include <wtf/text/CString.h>
38
39	namespace WTF {
40
41	class AutomaticThread;
42	class AutomaticThreadCondition;
43
44	// A ParallelHelperPool is a shared pool of threads that can be asked to help with some finite-time
45	// parallel activity. It's designed to work well when there are multiple concurrent tasks that may
46	// all want parallel help. In that case, we don't want each task to start its own thread pool. It's
47	// also designed to work well for tasks that do their own load balancing and do not wish to
48	// participate in microtask-style load balancing.
49	//
50	// A pool can have many clients, and each client may have zero or one tasks. The pool will have up
51	// to some number of threads, configurable with ParallelHelperPool::addThreads(); usually you bound
52	// this by the number of CPUs. Whenever a thread is idle and it notices that some client has a
53	// task, it will run the task. A task may be run on anywhere between zero and N threads, where N is
54	// the number of threads in the pool. Tasks run to completion. It's expected that a task will have
55	// its own custom ideas about how to participate in some parallel activity's load balancing, and it
56	// will return when the parallel activity is done. For example, a parallel marking task will return
57	// when the mark phase is done.
58	//
59	// Threads may have a choice between many tasks, since there may be many clients and each client
60	// may have a task. For the marking example, that may happen if there are multiple VM instances and
61	// each instance decides to start parallel marking at the same time. In that case, threads choose
62	// a task at random. So long as any client has a task, all threads in the pool will continue
63	// running the available tasks. Threads go idle when no client has tasks to run.
64
65	class ParallelHelperPool;
66
67	// A client is a placeholder for a parallel algorithm. A parallel algorithm will have a task that
68	// can be run concurrently. Whenever a client has a task set (you have called setTask() or
69	// setFunction()), threads in the pool may run that task. If a task returns on any thread, the
70	// client will assume that the task is done and will clear the task. If the task is cleared (the
71	// task runs to completion on any thread or you call finish()), any threads in the pool already
72	// running the last set task(s) will continue to run them. You can wait for all of them to finish
73	// by calling finish(). That method will clear the task and wait for any threads running the last
74	// set task to finish. There are two known-good patterns for using a client:
75	//
76	// 1) Tasks intrinsically know when the algorithm reaches termination, and simply returns when
77	// this happens. The main thread runs the task by doing:
78	//
79	// client->setFunction(
80	// [=] () {
81	// do things;
82	// });
83	// client->doSomeHelping();
84	// client->finish();
85	//
86	// Calling doSomeHelping() ensures that the algorithm runs on at least one thread (this one).
87	// Tasks will know when to complete, and will return when they are done. This will clear the
88	// task to ensure that no new threads will run the task. Then, finish() clears the current task
89	// and waits for any parallel tasks to finish after the main thread has finished. It's possible
90	// for threads to still be running the last set task (i.e. the one set by setFunction()) even
91	// after the task has been cleared. Waiting for idle ensures that no old tasks are running
92	// anymore.
93	//
94	// You can do this more easily by using the runFunctionInParallel() helper:
95	//
96	// clients->runFunctionInParallel(
97	// [=] () {
98	// do things;
99	// });
100	//
101	// 2) Tasks keep doing things until they are told to quit using some custom notification mechanism.
102	// The main thread runs the task by doing:
103	//
104	// bool keepGoing = true;
105	// client->setFunction(
106	// [=] () {
107	// while (keepGoing) {
108	// do things;
109	// }
110	// });
111	//
112	// When work runs out, the main thread will inform tasks that there is no more work, and then
113	// wait until no more tasks are running:
114	//
115	// keepGoing = false;
116	// client->finish();
117	//
118	// This works best when the main thread doesn't actually want to run the task that it set in the
119	// client. This happens for example in parallel marking. The main thread uses a somewhat
120	// different marking algorithm than the helpers. The main thread may provide work that the
121	// helpers steal. The main thread knows when termination is reached, and simply tells the
122	// helpers to stop upon termination.
123	//
124	// The known-good styles of using ParallelHelperClient all involve a parallel algorithm that has
125	// its own work distribution and load balancing.
126	//
127	// Note that it is not valid to use the same ParallelHelperClient instance from multiple threads.
128	// Each thread should have its own ParallelHelperClient in that case. Failure to follow this advice
129	// will lead to RELEASE_ASSERT's or worse.
130	class ParallelHelperClient {
131	WTF_MAKE_NONCOPYABLE(ParallelHelperClient);
132	WTF_MAKE_FAST_ALLOCATED;
133	public:
134	WTF_EXPORT_PRIVATE ParallelHelperClient(RefPtr<ParallelHelperPool>&&);
135	WTF_EXPORT_PRIVATE ~ParallelHelperClient();
136
137	WTF_EXPORT_PRIVATE void setTask(RefPtr<SharedTask<void ()>>&&);
138
139	template<typename Functor>
140	void setFunction(const Functor& functor)
141	{
142	setTask(createSharedTask<void ()>(functor));
143	}
144
145	WTF_EXPORT_PRIVATE void finish();
146
147	WTF_EXPORT_PRIVATE void doSomeHelping();
148
149	// Equivalent to:
150	// client->setTask(task);
151	// client->doSomeHelping();
152	// client->finish();
153	WTF_EXPORT_PRIVATE void runTaskInParallel(RefPtr<SharedTask<void ()>>&&);
154
155	// Equivalent to:
156	// client->setFunction(functor);
157	// client->doSomeHelping();
158	// client->finish();
159	template<typename Functor>
160	void runFunctionInParallel(const Functor& functor)
161	{
162	runTaskInParallel(createSharedTask<void ()>(functor));
163	}
164
165	ParallelHelperPool& pool() { return *m_pool; }
166	unsigned numberOfActiveThreads() const { return m_numActive; }
167
168	private:
169	friend class ParallelHelperPool;
170
171	void finish(const AbstractLocker&);
172	RefPtr<SharedTask<void ()>> claimTask(const AbstractLocker&);
173	void runTask(const RefPtr<SharedTask<void ()>>&);
174
175	RefPtr<ParallelHelperPool> m_pool;
176	RefPtr<SharedTask<void ()>> m_task;
177	unsigned m_numActive { `0` };
178	};
179
180	class ParallelHelperPool : public ThreadSafeRefCounted<ParallelHelperPool> {
181	public:
182	WTF_EXPORT_PRIVATE ParallelHelperPool(CString&& threadName);
183	WTF_EXPORT_PRIVATE ~ParallelHelperPool();
184
185	WTF_EXPORT_PRIVATE void ensureThreads(unsigned numThreads);
186
187	unsigned numberOfThreads() const { return m_numThreads; }
188
189	WTF_EXPORT_PRIVATE void doSomeHelping();
190
191	private:
192	friend class ParallelHelperClient;
193	class Thread;
194	friend class Thread;
195
196	void didMakeWorkAvailable(const AbstractLocker&);
197
198	bool hasClientWithTask(const AbstractLocker&);
199	ParallelHelperClient* getClientWithTask(const AbstractLocker&);
200	ParallelHelperClient* waitForClientWithTask(const AbstractLocker&);
201
202	Box<Lock> m_lock; // AutomaticThread wants this in a box for safety.
203	Ref<AutomaticThreadCondition> m_workAvailableCondition;
204	Condition m_workCompleteCondition;
205
206	WeakRandom m_random;
207
208	Vector<ParallelHelperClient*> m_clients;
209	Vector<RefPtr<AutomaticThread>> m_threads;
210	CString m_threadName;
211	unsigned m_numThreads { `0` }; // This can be larger than m_threads.size() because we start threads only once there is work.
212	bool m_isDying { false };
213	};
214
215	} // namespace WTF
216
217	using WTF::ParallelHelperClient;
218	using WTF::ParallelHelperPool;
219

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