boost_1_45_0/libs/circular_buffer/test/bounded_buffer_comparison.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 // Comparison of bounded buffers based on different containers.

 // Copyright (c) 2003-2008 Jan Gaspar

 // Use, modification, and distribution is subject to the Boost Software
 // License, Version 1.0. (See accompanying file LICENSE_1_0.txt or copy at
 // http://www.boost.org/LICENSE_1_0.txt)

 #define BOOST_CB_DISABLE_DEBUG

 #include <boost/circular_buffer.hpp>
 #include <boost/thread/mutex.hpp>
 #include <boost/thread/condition.hpp>
 #include <boost/thread/thread.hpp>
 #include <boost/call_traits.hpp>
 #include <boost/progress.hpp>
 #include <boost/bind.hpp>
 #include <deque>
 #include <list>
 #include <string>
 #include <iostream>

 const unsigned long QUEUE_SIZE     = 1000L;
 const unsigned long TOTAL_ELEMENTS = QUEUE_SIZE * 1000L;

 template <class T>
 class bounded_buffer {
 public:

     typedef boost::circular_buffer<T> container_type;
     typedef typename container_type::size_type size_type;
     typedef typename container_type::value_type value_type;
     typedef typename boost::call_traits<value_type>::param_type param_type;

     explicit bounded_buffer(size_type capacity) : m_unread(0), m_container(capacity) {}

     void push_front(param_type item) {
         boost::mutex::scoped_lock lock(m_mutex);
         m_not_full.wait(lock, boost::bind(&bounded_buffer<value_type>::is_not_full, this));
         m_container.push_front(item);
         ++m_unread;
         lock.unlock();
         m_not_empty.notify_one();
     }

     void pop_back(value_type* pItem) {
         boost::mutex::scoped_lock lock(m_mutex);
         m_not_empty.wait(lock, boost::bind(&bounded_buffer<value_type>::is_not_empty, this));
         *pItem = m_container[--m_unread];
         lock.unlock();
         m_not_full.notify_one();
     }

 private:
     bounded_buffer(const bounded_buffer&);              // Disabled copy constructor
     bounded_buffer& operator = (const bounded_buffer&); // Disabled assign operator

     bool is_not_empty() const { return m_unread > 0; }
     bool is_not_full() const { return m_unread < m_container.capacity(); }

     size_type m_unread;
     container_type m_container;
     boost::mutex m_mutex;
     boost::condition m_not_empty;
     boost::condition m_not_full;
 };

 template <class T>
 class bounded_buffer_space_optimized {
 public:

     typedef boost::circular_buffer_space_optimized<T> container_type;
     typedef typename container_type::size_type size_type;
     typedef typename container_type::value_type value_type;
     typedef typename boost::call_traits<value_type>::param_type param_type;

     explicit bounded_buffer_space_optimized(size_type capacity) : m_container(capacity) {}

     void push_front(param_type item) {
         boost::mutex::scoped_lock lock(m_mutex);
         m_not_full.wait(lock, boost::bind(&bounded_buffer_space_optimized<value_type>::is_not_full, this));
         m_container.push_front(item);
         lock.unlock();
         m_not_empty.notify_one();
     }

     void pop_back(value_type* pItem) {
         boost::mutex::scoped_lock lock(m_mutex);
         m_not_empty.wait(lock, boost::bind(&bounded_buffer_space_optimized<value_type>::is_not_empty, this));
         *pItem = m_container.back();
         m_container.pop_back();
         lock.unlock();
         m_not_full.notify_one();
     }

 private:

     bounded_buffer_space_optimized(const bounded_buffer_space_optimized&);              // Disabled copy constructor
     bounded_buffer_space_optimized& operator = (const bounded_buffer_space_optimized&); // Disabled assign operator

     bool is_not_empty() const { return m_container.size() > 0; }
     bool is_not_full() const { return m_container.size() < m_container.capacity(); }

     container_type m_container;
     boost::mutex m_mutex;
     boost::condition m_not_empty;
     boost::condition m_not_full;
 };

 template <class T>
 class bounded_buffer_deque_based {
 public:

     typedef std::deque<T> container_type;
     typedef typename container_type::size_type size_type;
     typedef typename container_type::value_type value_type;
     typedef typename boost::call_traits<value_type>::param_type param_type;

     explicit bounded_buffer_deque_based(size_type capacity) : m_capacity(capacity) {}

     void push_front(param_type item) {
         boost::mutex::scoped_lock lock(m_mutex);
         m_not_full.wait(lock, boost::bind(&bounded_buffer_deque_based<value_type>::is_not_full, this));
         m_container.push_front(item);
         lock.unlock();
         m_not_empty.notify_one();
     }

     void pop_back(value_type* pItem) {
         boost::mutex::scoped_lock lock(m_mutex);
         m_not_empty.wait(lock, boost::bind(&bounded_buffer_deque_based<value_type>::is_not_empty, this));
         *pItem = m_container.back();
         m_container.pop_back();
         lock.unlock();
         m_not_full.notify_one();
     }

 private:

     bounded_buffer_deque_based(const bounded_buffer_deque_based&);              // Disabled copy constructor
     bounded_buffer_deque_based& operator = (const bounded_buffer_deque_based&); // Disabled assign operator

     bool is_not_empty() const { return m_container.size() > 0; }
     bool is_not_full() const { return m_container.size() < m_capacity; }

     const size_type m_capacity;
     container_type m_container;
     boost::mutex m_mutex;
     boost::condition m_not_empty;
     boost::condition m_not_full;
 };

 template <class T>
 class bounded_buffer_list_based {
 public:

     typedef std::list<T> container_type;
     typedef typename container_type::size_type size_type;
     typedef typename container_type::value_type value_type;
     typedef typename boost::call_traits<value_type>::param_type param_type;

     explicit bounded_buffer_list_based(size_type capacity) : m_capacity(capacity) {}

     void push_front(param_type item) {
         boost::mutex::scoped_lock lock(m_mutex);
         m_not_full.wait(lock, boost::bind(&bounded_buffer_list_based<value_type>::is_not_full, this));
         m_container.push_front(item);
         lock.unlock();
         m_not_empty.notify_one();
     }

     void pop_back(value_type* pItem) {
         boost::mutex::scoped_lock lock(m_mutex);
         m_not_empty.wait(lock, boost::bind(&bounded_buffer_list_based<value_type>::is_not_empty, this));
         *pItem = m_container.back();
         m_container.pop_back();
         lock.unlock();
         m_not_full.notify_one();
     }

 private:

     bounded_buffer_list_based(const bounded_buffer_list_based&);              // Disabled copy constructor
     bounded_buffer_list_based& operator = (const bounded_buffer_list_based&); // Disabled assign operator

     bool is_not_empty() const { return m_container.size() > 0; }
     bool is_not_full() const { return m_container.size() < m_capacity; }

     const size_type m_capacity;
     container_type m_container;
     boost::mutex m_mutex;
     boost::condition m_not_empty;
     boost::condition m_not_full;
 };

 template<class Buffer>
 class Consumer {

     typedef typename Buffer::value_type value_type;
     Buffer* m_container;
     value_type m_item;

 public:
     Consumer(Buffer* buffer) : m_container(buffer) {}

     void operator()() {
         for (unsigned long i = 0L; i < TOTAL_ELEMENTS; ++i) {
             m_container->pop_back(&m_item);
         }
     }
 };

 template<class Buffer>
 class Producer {

     typedef typename Buffer::value_type value_type;
     Buffer* m_container;

 public:
     Producer(Buffer* buffer) : m_container(buffer) {}

     void operator()() {
         for (unsigned long i = 0L; i < TOTAL_ELEMENTS; ++i) {
             m_container->push_front(value_type());
         }
     }
 };

 template<class Buffer>
 void fifo_test(Buffer* buffer) {

     // Start of measurement
     boost::progress_timer progress;

     // Initialize the buffer with some values before launching producer and consumer threads.
     for (unsigned long i = QUEUE_SIZE / 2L; i > 0; --i) {
 #if BOOST_WORKAROUND(__BORLANDC__, BOOST_TESTED_AT(0x581))
         buffer->push_front(Buffer::value_type());
 #else
         buffer->push_front(BOOST_DEDUCED_TYPENAME Buffer::value_type());
 #endif
     }

     Consumer<Buffer> consumer(buffer);
     Producer<Buffer> producer(buffer);

     // Start the threads.
     boost::thread consume(consumer);
     boost::thread produce(producer);

     // Wait for completion.
     consume.join();
     produce.join();

     // End of measurement
 }

 int main(int /*argc*/, char* /*argv*/[]) {

     bounded_buffer<int> bb_int(QUEUE_SIZE);
     std::cout << "bounded_buffer<int> ";
     fifo_test(&bb_int);

     bounded_buffer_space_optimized<int> bb_space_optimized_int(QUEUE_SIZE);
     std::cout << "bounded_buffer_space_optimized<int> ";
     fifo_test(&bb_space_optimized_int);

     bounded_buffer_deque_based<int> bb_deque_based_int(QUEUE_SIZE);
     std::cout << "bounded_buffer_deque_based<int> ";
     fifo_test(&bb_deque_based_int);

     bounded_buffer_list_based<int> bb_list_based_int(QUEUE_SIZE);
     std::cout << "bounded_buffer_list_based<int> ";
     fifo_test(&bb_list_based_int);

     bounded_buffer<std::string> bb_string(QUEUE_SIZE);
     std::cout << "bounded_buffer<std::string> ";
     fifo_test(&bb_string);

     bounded_buffer_space_optimized<std::string> bb_space_optimized_string(QUEUE_SIZE);
     std::cout << "bounded_buffer_space_optimized<std::string> ";
     fifo_test(&bb_space_optimized_string);

     bounded_buffer_deque_based<std::string> bb_deque_based_string(QUEUE_SIZE);
     std::cout << "bounded_buffer_deque_based<std::string> ";
     fifo_test(&bb_deque_based_string);

     bounded_buffer_list_based<std::string> bb_list_based_string(QUEUE_SIZE);
     std::cout << "bounded_buffer_list_based<std::string> ";
     fifo_test(&bb_list_based_string);

     return 0;
 }
	// Comparison of bounded buffers based on different containers.

	// Copyright (c) 2003-2008 Jan Gaspar

	// Use, modification, and distribution is subject to the Boost Software
	// License, Version 1.0. (See accompanying file LICENSE_1_0.txt or copy at
	// http://www.boost.org/LICENSE_1_0.txt)

	#define BOOST_CB_DISABLE_DEBUG

	#include <boost/circular_buffer.hpp>
	#include <boost/thread/mutex.hpp>
	#include <boost/thread/condition.hpp>
	#include <boost/thread/thread.hpp>
	#include <boost/call_traits.hpp>
	#include <boost/progress.hpp>
	#include <boost/bind.hpp>
	#include <deque>
	#include <list>
	#include <string>
	#include <iostream>

	const unsigned long QUEUE_SIZE = 1000L;
	const unsigned long TOTAL_ELEMENTS = QUEUE_SIZE * 1000L;

	template <class T>
	class bounded_buffer {
	public:

	typedef boost::circular_buffer<T> container_type;
	typedef typename container_type::size_type size_type;
	typedef typename container_type::value_type value_type;
	typedef typename boost::call_traits<value_type>::param_type param_type;

	explicit bounded_buffer(size_type capacity) : m_unread(0), m_container(capacity) {}

	void push_front(param_type item) {
	boost::mutex::scoped_lock lock(m_mutex);
	m_not_full.wait(lock, boost::bind(&bounded_buffer<value_type>::is_not_full, this));
	m_container.push_front(item);
	++m_unread;
	lock.unlock();
	m_not_empty.notify_one();
	}

	void pop_back(value_type* pItem) {
	boost::mutex::scoped_lock lock(m_mutex);
	m_not_empty.wait(lock, boost::bind(&bounded_buffer<value_type>::is_not_empty, this));
	*pItem = m_container[--m_unread];
	lock.unlock();
	m_not_full.notify_one();
	}

	private:
	bounded_buffer(const bounded_buffer&); // Disabled copy constructor
	bounded_buffer& operator = (const bounded_buffer&); // Disabled assign operator

	bool is_not_empty() const { return m_unread > 0; }
	bool is_not_full() const { return m_unread < m_container.capacity(); }

	size_type m_unread;
	container_type m_container;
	boost::mutex m_mutex;
	boost::condition m_not_empty;
	boost::condition m_not_full;
	};

	template <class T>
	class bounded_buffer_space_optimized {
	public:

	typedef boost::circular_buffer_space_optimized<T> container_type;
	typedef typename container_type::size_type size_type;
	typedef typename container_type::value_type value_type;
	typedef typename boost::call_traits<value_type>::param_type param_type;

	explicit bounded_buffer_space_optimized(size_type capacity) : m_container(capacity) {}

	void push_front(param_type item) {
	boost::mutex::scoped_lock lock(m_mutex);
	m_not_full.wait(lock, boost::bind(&bounded_buffer_space_optimized<value_type>::is_not_full, this));
	m_container.push_front(item);
	lock.unlock();
	m_not_empty.notify_one();
	}

	void pop_back(value_type* pItem) {
	boost::mutex::scoped_lock lock(m_mutex);
	m_not_empty.wait(lock, boost::bind(&bounded_buffer_space_optimized<value_type>::is_not_empty, this));
	*pItem = m_container.back();
	m_container.pop_back();
	lock.unlock();
	m_not_full.notify_one();
	}

	private:

	bounded_buffer_space_optimized(const bounded_buffer_space_optimized&); // Disabled copy constructor
	bounded_buffer_space_optimized& operator = (const bounded_buffer_space_optimized&); // Disabled assign operator

	bool is_not_empty() const { return m_container.size() > 0; }
	bool is_not_full() const { return m_container.size() < m_container.capacity(); }

	container_type m_container;
	boost::mutex m_mutex;
	boost::condition m_not_empty;
	boost::condition m_not_full;
	};

	template <class T>
	class bounded_buffer_deque_based {
	public:

	typedef std::deque<T> container_type;
	typedef typename container_type::size_type size_type;
	typedef typename container_type::value_type value_type;
	typedef typename boost::call_traits<value_type>::param_type param_type;

	explicit bounded_buffer_deque_based(size_type capacity) : m_capacity(capacity) {}

	void push_front(param_type item) {
	boost::mutex::scoped_lock lock(m_mutex);
	m_not_full.wait(lock, boost::bind(&bounded_buffer_deque_based<value_type>::is_not_full, this));
	m_container.push_front(item);
	lock.unlock();
	m_not_empty.notify_one();
	}

	void pop_back(value_type* pItem) {
	boost::mutex::scoped_lock lock(m_mutex);
	m_not_empty.wait(lock, boost::bind(&bounded_buffer_deque_based<value_type>::is_not_empty, this));
	*pItem = m_container.back();
	m_container.pop_back();
	lock.unlock();
	m_not_full.notify_one();
	}

	private:

	bounded_buffer_deque_based(const bounded_buffer_deque_based&); // Disabled copy constructor
	bounded_buffer_deque_based& operator = (const bounded_buffer_deque_based&); // Disabled assign operator

	bool is_not_empty() const { return m_container.size() > 0; }
	bool is_not_full() const { return m_container.size() < m_capacity; }

	const size_type m_capacity;
	container_type m_container;
	boost::mutex m_mutex;
	boost::condition m_not_empty;
	boost::condition m_not_full;
	};

	template <class T>
	class bounded_buffer_list_based {
	public:

	typedef std::list<T> container_type;
	typedef typename container_type::size_type size_type;
	typedef typename container_type::value_type value_type;
	typedef typename boost::call_traits<value_type>::param_type param_type;

	explicit bounded_buffer_list_based(size_type capacity) : m_capacity(capacity) {}

	void push_front(param_type item) {
	boost::mutex::scoped_lock lock(m_mutex);
	m_not_full.wait(lock, boost::bind(&bounded_buffer_list_based<value_type>::is_not_full, this));
	m_container.push_front(item);
	lock.unlock();
	m_not_empty.notify_one();
	}

	void pop_back(value_type* pItem) {
	boost::mutex::scoped_lock lock(m_mutex);
	m_not_empty.wait(lock, boost::bind(&bounded_buffer_list_based<value_type>::is_not_empty, this));
	*pItem = m_container.back();
	m_container.pop_back();
	lock.unlock();
	m_not_full.notify_one();
	}

	private:

	bounded_buffer_list_based(const bounded_buffer_list_based&); // Disabled copy constructor
	bounded_buffer_list_based& operator = (const bounded_buffer_list_based&); // Disabled assign operator

	bool is_not_empty() const { return m_container.size() > 0; }
	bool is_not_full() const { return m_container.size() < m_capacity; }

	const size_type m_capacity;
	container_type m_container;
	boost::mutex m_mutex;
	boost::condition m_not_empty;
	boost::condition m_not_full;
	};

	template<class Buffer>
	class Consumer {

	typedef typename Buffer::value_type value_type;
	Buffer* m_container;
	value_type m_item;

	public:
	Consumer(Buffer* buffer) : m_container(buffer) {}

	void operator()() {
	for (unsigned long i = 0L; i < TOTAL_ELEMENTS; ++i) {
	m_container->pop_back(&m_item);
	}
	}
	};

	template<class Buffer>
	class Producer {

	typedef typename Buffer::value_type value_type;
	Buffer* m_container;

	public:
	Producer(Buffer* buffer) : m_container(buffer) {}

	void operator()() {
	for (unsigned long i = 0L; i < TOTAL_ELEMENTS; ++i) {
	m_container->push_front(value_type());
	}
	}
	};

	template<class Buffer>
	void fifo_test(Buffer* buffer) {

	// Start of measurement
	boost::progress_timer progress;

	// Initialize the buffer with some values before launching producer and consumer threads.
	for (unsigned long i = QUEUE_SIZE / 2L; i > 0; --i) {
	#if BOOST_WORKAROUND(__BORLANDC__, BOOST_TESTED_AT(0x581))
	buffer->push_front(Buffer::value_type());
	#else
	buffer->push_front(BOOST_DEDUCED_TYPENAME Buffer::value_type());
	#endif
	}

	Consumer<Buffer> consumer(buffer);
	Producer<Buffer> producer(buffer);

	// Start the threads.
	boost::thread consume(consumer);
	boost::thread produce(producer);

	// Wait for completion.
	consume.join();
	produce.join();

	// End of measurement
	}

	int main(int /argc/, char* /argv/[]) {

	bounded_buffer<int> bb_int(QUEUE_SIZE);
	std::cout << "bounded_buffer<int> ";
	fifo_test(&bb_int);

	bounded_buffer_space_optimized<int> bb_space_optimized_int(QUEUE_SIZE);
	std::cout << "bounded_buffer_space_optimized<int> ";
	fifo_test(&bb_space_optimized_int);

	bounded_buffer_deque_based<int> bb_deque_based_int(QUEUE_SIZE);
	std::cout << "bounded_buffer_deque_based<int> ";
	fifo_test(&bb_deque_based_int);

	bounded_buffer_list_based<int> bb_list_based_int(QUEUE_SIZE);
	std::cout << "bounded_buffer_list_based<int> ";
	fifo_test(&bb_list_based_int);

	bounded_buffer<std::string> bb_string(QUEUE_SIZE);
	std::cout << "bounded_buffer<std::string> ";
	fifo_test(&bb_string);

	bounded_buffer_space_optimized<std::string> bb_space_optimized_string(QUEUE_SIZE);
	std::cout << "bounded_buffer_space_optimized<std::string> ";
	fifo_test(&bb_space_optimized_string);

	bounded_buffer_deque_based<std::string> bb_deque_based_string(QUEUE_SIZE);
	std::cout << "bounded_buffer_deque_based<std::string> ";
	fifo_test(&bb_deque_based_string);

	bounded_buffer_list_based<std::string> bb_list_based_string(QUEUE_SIZE);
	std::cout << "bounded_buffer_list_based<std::string> ";
	fifo_test(&bb_list_based_string);

	return 0;
	}