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annotate thread/AsynchronousTask.h @ 209:ccd2019190bf msvc

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Some MSVC fixes, including (temporarily, probably) renaming the FFT source file to avoid getting it mixed up with the Vamp SDK one in our object dir
author Chris Cannam
date Thu, 01 Feb 2018 16:34:08 +0000
parents 6afa0e011f74
children 701233f8ed41
rev   line source
cannam@67 1 /* -*- c-basic-offset: 4 indent-tabs-mode: nil -*- vi:set ts=8 sts=4 sw=4: */
cannam@67 2
cannam@67 3 /*
cannam@67 4 QM DSP Library
cannam@67 5
cannam@67 6 Centre for Digital Music, Queen Mary, University of London.
cannam@67 7 This file Copyright 2009 QMUL.
cannam@67 8 */
cannam@67 9
cannam@67 10 #ifndef _ASYNCHRONOUS_TASK_H_
cannam@67 11 #define _ASYNCHRONOUS_TASK_H_
cannam@67 12
cannam@67 13 #include "Thread.h"
cannam@67 14
cannam@69 15 #include <iostream>
cannam@69 16
cannam@67 17 /**
cannam@67 18 * AsynchronousTask provides a thread pattern implementation for
cannam@67 19 * threads which are used to perform a series of similar operations in
cannam@67 20 * parallel with other threads of the same type.
cannam@67 21 *
cannam@67 22 * For example, a thread used to calculate FFTs of a particular block
cannam@67 23 * size in the context of a class that needs to calculate many block
cannam@67 24 * sizes of FFT at once may be a candidate for an AsynchronousTask.
cannam@67 25 *
cannam@67 26 * The general use pattern is:
cannam@67 27 *
cannam@67 28 * caller -> request thread A calculate something
cannam@67 29 * caller -> request thread B calculate something
cannam@67 30 * caller -> request thread C calculate something
cannam@67 31 * caller -> wait for threads A, B, and C
cannam@67 32 *
cannam@67 33 * Here threads A, B, and C may be AsynchronousTasks. An important
cannam@67 34 * point is that the caller must be prepared to block when waiting for
cannam@67 35 * these threads to complete (i.e. they are started asynchronously,
cannam@67 36 * but testing for completion is synchronous).
cannam@67 37 */
cannam@67 38 class AsynchronousTask : public Thread
cannam@67 39 {
cannam@67 40 public:
cannam@67 41 AsynchronousTask() :
cannam@67 42 m_todo("AsynchronousTask: task to perform"),
cannam@67 43 m_done("AsynchronousTask: task complete"),
cannam@67 44 m_inTask(false),
cannam@67 45 m_finishing(false)
cannam@67 46 {
cannam@67 47 start();
cannam@67 48 }
cannam@67 49 virtual ~AsynchronousTask()
cannam@67 50 {
cannam@69 51 m_todo.lock();
cannam@67 52 m_finishing = true;
cannam@67 53 m_todo.signal();
cannam@69 54 m_todo.unlock();
cannam@67 55 wait();
cannam@67 56 }
cannam@67 57
cannam@67 58 // Subclass must provide methods to request task and obtain
cannam@67 59 // results, which the caller calls. The method that requests a
cannam@67 60 // new task should set up any internal state and call startTask(),
cannam@67 61 // which then calls back on the subclass implementation of
cannam@67 62 // performTask from within its work thread. The method that
cannam@67 63 // obtains results should call awaitTask() and then return any
cannam@67 64 // results from internal state.
cannam@67 65
cannam@67 66 protected:
cannam@67 67 void startTask() {
cannam@69 68 m_done.lock();
cannam@67 69 m_todo.lock();
cannam@67 70 m_inTask = true;
cannam@67 71 m_todo.signal();
cannam@67 72 m_todo.unlock();
cannam@67 73 }
cannam@67 74 void awaitTask() {
cannam@69 75 m_done.wait();
cannam@67 76 m_done.unlock();
cannam@67 77 }
cannam@67 78
cannam@67 79 virtual void performTask() = 0;
cannam@67 80
cannam@67 81 private:
cannam@67 82 virtual void run() {
cannam@67 83 m_todo.lock();
cannam@69 84 while (1) {
cannam@67 85 while (!m_inTask && !m_finishing) {
cannam@67 86 m_todo.wait();
cannam@67 87 }
cannam@67 88 if (m_finishing) {
cannam@69 89 m_done.lock();
cannam@68 90 m_inTask = false;
cannam@68 91 m_done.signal();
cannam@69 92 m_done.unlock();
cannam@67 93 break;
cannam@67 94 }
cannam@69 95 performTask();
cannam@69 96 m_done.lock();
cannam@69 97 m_inTask = false;
cannam@69 98 m_done.signal();
cannam@69 99 m_done.unlock();
cannam@67 100 }
cannam@67 101 m_todo.unlock();
cannam@67 102 }
cannam@67 103
cannam@67 104 Condition m_todo;
cannam@67 105 Condition m_done;
cannam@67 106 bool m_inTask;
cannam@67 107 bool m_finishing;
cannam@67 108 };
cannam@67 109
cannam@67 110 #endif