effective STL给出的Lock框架
template<typename Container> //一个为容器获取和释放互斥体的模板 class Lock { //框架;其中的很多细节被省略了 public: Lock(const Container& container) :c(container) { getMutexFor(c); //在构造函数中获取互斥体 } ~Lock() { releaseMutexFor(c); //在析构函数中释放它 } private: const Container& c; };
// parallel-fibonacci.cpp // compile with: /EHsc #include <windows.h> #include <ppl.h> #include <concurrent_vector.h> #include <array> #include <vector> #include <tuple> #include <algorithm> #include <iostream> using namespace Concurrency; using namespace std; // Calls the provided work function and returns the number of milliseconds // that it takes to call that function. template <class Function> __int64 time_call(Function&& f) { __int64 begin = GetTickCount(); f(); return GetTickCount() - begin; } // Computes the nth Fibonacci number. int fibonacci(int n) { if(n < 2) return n; return fibonacci(n-1) + fibonacci(n-2); } int wmain() { __int64 elapsed; // An array of Fibonacci numbers to compute. array<int, 4> a = { 24, 26, 41, 42 }; // The results of the serial computation. vector<tuple<int,int>> results1; // The results of the parallel computation. concurrent_vector<tuple<int,int>> results2; // Use the for_each algorithm to compute the results serially. elapsed = time_call([&] { for_each (a.begin(), a.end(), [&](int n) { results1.push_back(make_tuple(n, fibonacci(n))); }); }); wcout << L"serial time: " << elapsed << L" ms" << endl; // Use the parallel_for_each algorithm to perform the same task. elapsed = time_call([&] { parallel_for_each (a.begin(), a.end(), [&](int n) { results2.push_back(make_tuple(n, fibonacci(n))); }); // Because parallel_for_each acts concurrently, the results do not // have a pre-determined order. Sort the concurrent_vector object // so that the results match the serial version. sort(results2.begin(), results2.end()); }); wcout << L"parallel time: " << elapsed << L" ms" << endl << endl; // Print the results. for_each (results2.begin(), results2.end(), [](tuple<int,int>& pair) { wcout << L"fib(" << get<0>(pair) << L"): " << get<1>(pair) << endl; }); }
#include "stdafx.h" #include <ppl.h> #include <array> #include <iostream> using namespace Concurrency; using namespace std; using namespace std::tr1; // Function object (functor) class that computes the square of its input. template<class Ty> class SquareFunctor { public: void operator()(Ty& n) const { n *= n; } }; // Function that computes the square of its input. template<class Ty> void square_function(Ty& n) { n *= n; } int _tmain(int argc, _TCHAR* argv[]) { // Create an array object that contains 5 values. array<int, 5> values = { 1, 2, 3, 4, 5 }; // Use a lambda function, a function object, and a function pointer to // compute the square of each element of the array in parallel. // Use a lambda function to square each element. parallel_for_each(values.begin(), values.end(), [](int& n){n *= n;}); // Use a function object (functor) to square each element. parallel_for_each(values.begin(), values.end(), SquareFunctor<int>()); // Use a function pointer to square each element. parallel_for_each(values.begin(), values.end(), &square_function<int>); // Print each element of the array to the console. for_each(values.begin(), values.end(), [](int& n) { wcout << n << endl; }); return 0; }
#include <boost/thread/thread.hpp> #include <boost/lockfree/queue.hpp> #include <iostream> #include <boost/atomic.hpp> boost::atomic_int producer_count(0); boost::atomic_int consumer_count(0); boost::lockfree::queue<int> queue(128); const int iterations = 10000000; const int producer_thread_count = 4; const int consumer_thread_count = 4; void producer(void) { for (int i = 0; i != iterations; ++i) { int value = ++producer_count; while (!queue.push(value)) ; } } boost::atomic<bool> done (false); void consumer(void) { int value; while (!done) { while (queue.pop(value)) ++consumer_count; } while (queue.pop(value)) ++consumer_count; } int main(int argc, char* argv[]) { using namespace std; cout << "boost::lockfree::queue is "; if (!queue.is_lock_free()) cout << "not "; cout << "lockfree" << endl; boost::thread_group producer_threads, consumer_threads; for (int i = 0; i != producer_thread_count; ++i) producer_threads.create_thread(producer); for (int i = 0; i != consumer_thread_count; ++i) consumer_threads.create_thread(consumer); producer_threads.join_all(); done = true; consumer_threads.join_all(); cout << "produced " << producer_count << " objects." << endl; cout << "consumed " << consumer_count << " objects." << endl; }