📄 producer_consumer.cc
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// Copyright (C) 2004 Free Software Foundation, Inc.//// This file is part of the GNU ISO C++ Library. This library is free// software; you can redistribute it and/or modify it under the// terms of the GNU General Public License as published by the// Free Software Foundation; either version 2, or (at your option)// any later version.// This library is distributed in the hope that it will be useful,// but WITHOUT ANY WARRANTY; without even the implied warranty of// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the// GNU General Public License for more details.// You should have received a copy of the GNU General Public License along// with this library; see the file COPYING. If not, write to the Free// Software Foundation, 59 Temple Place - Suite 330, Boston, MA 02111-1307,// USA.// As a special exception, you may use this file as part of a free software// library without restriction. Specifically, if other files instantiate// templates or use macros or inline functions from this file, or you compile// this file and link it with other files to produce an executable, this// file does not by itself cause the resulting executable to be covered by// the GNU General Public License. This exception does not however// invalidate any other reasons why the executable file might be covered by// the GNU General Public License./* * The goal with this application is to compare the performance of * different allocators in a simple producer-consumer scenario. */// 2004-02-04 Felix Yen <fwy@alumni.brown.edu>#include <vector>#include <list>#include <map>#include <typeinfo>#include <sstream>#include <pthread.h>#include <ext/mt_allocator.h>#include <ext/new_allocator.h>#include <ext/malloc_allocator.h>#include <ext/bitmap_allocator.h>#include <ext/pool_allocator.h>#include <cxxabi.h>#include <testsuite_performance.h>using namespace std;using __gnu_cxx::__mt_alloc;using __gnu_cxx::new_allocator;using __gnu_cxx::malloc_allocator;using __gnu_cxx::bitmap_allocator;using __gnu_cxx::__pool_alloc;using abi::__cxa_demangle;typedef int test_type;typedef less<test_type> compare_type;typedef malloc_allocator<test_type> malloc_alloc_type;typedef new_allocator<test_type> new_alloc_type;typedef __mt_alloc<test_type> so_alloc_type;typedef bitmap_allocator<test_type> bit_alloc_type;typedef __pool_alloc<test_type> po_alloc_type;typedef pair<const test_type, test_type> pair_type;typedef malloc_allocator<pair_type> malloc_pair_alloc_type;typedef new_allocator<pair_type> new_pair_alloc_type;typedef __mt_alloc<pair_type> so_pair_alloc_type;typedef bitmap_allocator<pair_type> bit_pair_alloc_type;typedef __pool_alloc<pair_type> po_pair_alloc_type;// The number of iterations to be performed.int iterations = 10000;// TODO - restore Stefan's comment? i don't understand it. -- fwyint insert_values = 128;class Lock{public: Lock() {pthread_mutex_init(&mutex, 0);} ~Lock() {pthread_mutex_destroy(&mutex);}public: inline pthread_mutex_t* operator&() {return &mutex;}public: inline void lock() {pthread_mutex_lock(&mutex);} inline void unlock() {pthread_mutex_unlock(&mutex);}private: Lock(const Lock&); Lock& operator=(Lock&);private: pthread_mutex_t mutex;};class AutoLock{public: AutoLock(Lock& _lock) : lock(_lock) {lock.lock();} ~AutoLock() {lock.unlock();}private: AutoLock(AutoLock&); AutoLock& operator=(AutoLock&);private: Lock& lock;};template<typename Container> class Queue { public: Queue() {pthread_cond_init(&condition, 0);} ~Queue() {pthread_cond_destroy(&condition);} public: void push_back(const typename Container::value_type& x); void swap(Container& container); private: pthread_cond_t condition; Lock lock; Container queue; };template<typename Container> void Queue<Container>::push_back(const typename Container::value_type& value) { AutoLock auto_lock(lock); const bool signal = queue.empty(); queue.insert(queue.end(), value); if (signal) pthread_cond_signal(&condition); }template<typename Container> void Queue<Container>::swap(Container& container) { AutoLock auto_lock(lock); while (queue.empty()) pthread_cond_wait(&condition, &lock); queue.swap(container); }class Thread{ // NB: Make this the last data member of an object defining operator()().public: class Attributes { public: Attributes(int state = PTHREAD_CREATE_JOINABLE); ~Attributes() {pthread_attr_destroy(&attributes);} public: inline pthread_attr_t* operator&() {return &attributes;} private: pthread_attr_t attributes; };public: Thread() {thread = pthread_self();} ~Thread();public: template <typename ThreadOwner> void create(ThreadOwner* owner);private: pthread_t thread;};Thread::Attributes::Attributes(int state){ pthread_attr_init(&attributes); pthread_attr_setdetachstate(&attributes, state);}Thread::~Thread(){ if (!pthread_equal(thread, pthread_self())) pthread_join(thread, 0);}template<typename ThreadOwner> void* create_thread(void* _this) { ThreadOwner* owner = static_cast<ThreadOwner*>(_this); (*owner)(); return 0; }template<typename ThreadOwner> void Thread::create(ThreadOwner* owner) { Thread::Attributes attributes; pthread_create(&thread, &attributes, create_thread<ThreadOwner>, owner); }template<typename Container> class Consumer { public: Consumer(Queue<Container>& _queue) : queue(_queue) {thread.create(this);} public: void operator()(); private: Queue<Container>& queue; Thread thread; };template<typename Container> void Consumer<Container>::operator()() { for (int j = insert_values * iterations; j > 0;) { Container container; queue.swap(container); j -= container.size(); } }template<typename TestType> struct Value : public pair<TestType, TestType> { Value() : pair<TestType, TestType>(0, 0) { } inline Value operator++() {return ++this->first, *this;} inline operator TestType() const {return this->first;} };template<typename Container> class ProducerConsumer : private Queue<Container> { public: ProducerConsumer() {thread.create(this);} public: void operator()(); private: Thread thread; };template<typename Container> void ProducerConsumer<Container>::operator()() { Consumer<Container> consumer(*this); Value<test_type> test_value; for (int j = insert_values * iterations; j-- > 0;) this->push_back(++test_value); }template<typename Container> void test_container(Container obj) { using namespace __gnu_test; int status; time_counter time; resource_counter resource; clear_counters(time, resource); start_counters(time, resource); { ProducerConsumer<Container> pc1; ProducerConsumer<Container> pc2; } stop_counters(time, resource); std::ostringstream comment; comment << "iterations: " << iterations << '\t'; comment << "type: " << __cxa_demangle(typeid(obj).name(), 0, 0, &status); report_header(__FILE__, comment.str()); report_performance(__FILE__, string(), time, resource); }int main(void){#ifdef TEST_T0 test_container(vector<test_type, malloc_alloc_type>());#endif#ifdef TEST_T1 test_container(vector<test_type, new_alloc_type>());#endif#ifdef TEST_T2 test_container(vector<test_type, so_alloc_type>());#endif#ifdef TEST_T3 test_container(vector<test_type, bit_alloc_type>());#endif#ifdef TEST_T4 test_container(vector<test_type, po_alloc_type>());#endif#ifdef TEST_T5 test_container(list<test_type, malloc_alloc_type>());#endif#ifdef TEST_T6 test_container(list<test_type, new_alloc_type>());#endif#ifdef TEST_T7 test_container(list<test_type, so_alloc_type>());#endif#ifdef TEST_T8 test_container(list<test_type, bit_alloc_type>());#endif#ifdef TEST_T9 test_container(list<test_type, po_alloc_type>());#endif#ifdef TEST_T10 test_container(map<test_type, test_type, compare_type, malloc_pair_alloc_type>());#endif#ifdef TEST_T11 test_container(map<test_type, test_type, compare_type, new_pair_alloc_type>());#endif#ifdef TEST_T12 test_container(map<test_type, test_type, compare_type, so_pair_alloc_type>());#endif#ifdef TEST_T13 test_container(map<test_type, test_type, compare_type, bit_pair_alloc_type>());#endif#ifdef TEST_T14 test_container(map<test_type, test_type, compare_type, po_pair_alloc_type>());#endif return 0;}⌨️ 快捷键说明
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