boost_1_45_0/libs/type_traits/examples/copy_example.cpp - nest-learning-thermostat/5.0/boost - Git at Google


 /*
  *
  * (C) Copyright John Maddock 1999-2005.
  * Use, modification and distribution are 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)
  *
  * This file provides some example of type_traits usage -
  * by "optimising" various algorithms:
  *
  * opt::copy - optimised for trivial copy (cf std::copy)
  *
  */

 #include <iostream>
 #include <typeinfo>
 #include <algorithm>
 #include <iterator>
 #include <memory>

 #include <boost/test/included/prg_exec_monitor.hpp>
 #include <boost/timer.hpp>
 #include <boost/type_traits.hpp>

 using std::cout;
 using std::endl;
 using std::cin;

 namespace opt{

 //
 // opt::copy
 // same semantics as std::copy
 // calls memcpy where appropiate.
 //

 namespace detail{

 template<typename I1, typename I2, bool b>
 I2 copy_imp(I1 first, I1 last, I2 out, const boost::integral_constant<bool, b>&)
 {
    while(first != last)
    {
       *out = *first;
       ++out;
       ++first;
    }
    return out;
 }

 template<typename T>
 T* copy_imp(const T* first, const T* last, T* out, const boost::true_type&)
 {
    memmove(out, first, (last-first)*sizeof(T));
    return out+(last-first);
 }


 }

 template<typename I1, typename I2>
 inline I2 copy(I1 first, I1 last, I2 out)
 {
    //
    // We can copy with memcpy if T has a trivial assignment operator,
    // and if the iterator arguments are actually pointers (this last
    // requirement we detect with overload resolution):
    //
    typedef typename std::iterator_traits<I1>::value_type value_type;
    return detail::copy_imp(first, last, out, boost::has_trivial_assign<value_type>());
 }

 }   // namespace opt

 namespace non_opt
 {

 template<typename I1, typename I2>
 inline I2 copy(I1 first, I1 last, I2 out)
 {
    return opt::detail::copy_imp(first, last, out, boost::false_type());
 }

 }

 //
 // define some global data:
 //
 const int array_size = 1000;
 int i_array_[array_size] = {0,};
 const int ci_array_[array_size] = {0,};
 char c_array_[array_size] = {0,};
 const char cc_array_[array_size] = { 0,};
 //
 // since arrays aren't iterators we define a set of pointer
 // aliases into the arrays (otherwise the compiler is entitled
 // to deduce the type passed to the template functions as
 // T (&)[N] rather than T*).
 int* i_array = i_array_;
 const int* ci_array = ci_array_;
 char* c_array = c_array_;
 const char* cc_array = cc_array_;

 const int iter_count = 1000000;

 int cpp_main(int argc, char* argv[])
 {
    boost::timer t;
    double result;
    int i;
    cout << "Measuring times in micro-seconds per 1000 elements processed" << endl << endl;
    cout << "testing copy...\n"
    "[Some standard library versions may already perform this optimisation.]" << endl;

    // cache load:
    opt::copy(ci_array, ci_array + array_size, i_array);

    // time optimised version:
    t.restart();
    for(i = 0; i < iter_count; ++i)
    {
       opt::copy(ci_array, ci_array + array_size, i_array);
    }
    result = t.elapsed();
    cout << "opt::copy<const int*, int*>: " << result << endl;

    // cache load:
    non_opt::copy(ci_array, ci_array + array_size, i_array);

    // time non-optimised version:
    t.restart();
    for(i = 0; i < iter_count; ++i)
    {
       non_opt::copy(ci_array, ci_array + array_size, i_array);
    }
    result = t.elapsed();
    cout << "non_opt::copy<const int*, int*>: " << result << endl;

    // cache load:
    std::copy(ci_array, ci_array + array_size, i_array);

    // time standard version:
    t.restart();
    for(i = 0; i < iter_count; ++i)
    {
       std::copy(ci_array, ci_array + array_size, i_array);
    }
    result = t.elapsed();
    cout << "std::copy<const int*, int*>: " << result << endl;

    // cache load:
    opt::copy(cc_array, cc_array + array_size, c_array);

    // time optimised version:
    t.restart();
    for(i = 0; i < iter_count; ++i)
    {
       opt::copy(cc_array, cc_array + array_size, c_array);
    }
    result = t.elapsed();
    cout << "opt::copy<const char*, char*>: " << result << endl;

    // cache load:
    non_opt::copy(cc_array, cc_array + array_size, c_array);

    // time optimised version:
    t.restart();
    for(i = 0; i < iter_count; ++i)
    {
       non_opt::copy(cc_array, cc_array + array_size, c_array);
    }
    result = t.elapsed();
    cout << "non_opt::copy<const char*, char*>: " << result << endl;

    // cache load:
    std::copy(cc_array, cc_array + array_size, c_array);

    // time standard version:
    t.restart();
    for(i = 0; i < iter_count; ++i)
    {
       std::copy(cc_array, cc_array + array_size, c_array);
    }
    result = t.elapsed();
    cout << "std::copy<const char*, char*>: " << result << endl;

    return 0;
 }

	/*
	*
	* (C) Copyright John Maddock 1999-2005.
	* Use, modification and distribution are 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)
	*
	* This file provides some example of type_traits usage -
	* by "optimising" various algorithms:
	*
	* opt::copy - optimised for trivial copy (cf std::copy)
	*
	*/

	#include <iostream>
	#include <typeinfo>
	#include <algorithm>
	#include <iterator>
	#include <memory>

	#include <boost/test/included/prg_exec_monitor.hpp>
	#include <boost/timer.hpp>
	#include <boost/type_traits.hpp>

	using std::cout;
	using std::endl;
	using std::cin;

	namespace opt{

	//
	// opt::copy
	// same semantics as std::copy
	// calls memcpy where appropiate.
	//

	namespace detail{

	template<typename I1, typename I2, bool b>
	I2 copy_imp(I1 first, I1 last, I2 out, const boost::integral_constant<bool, b>&)
	{
	while(first != last)
	{
	out = first;
	++out;
	++first;
	}
	return out;
	}

	template<typename T>
	T* copy_imp(const T* first, const T* last, T* out, const boost::true_type&)
	{
	memmove(out, first, (last-first)*sizeof(T));
	return out+(last-first);
	}


	}

	template<typename I1, typename I2>
	inline I2 copy(I1 first, I1 last, I2 out)
	{
	//
	// We can copy with memcpy if T has a trivial assignment operator,
	// and if the iterator arguments are actually pointers (this last
	// requirement we detect with overload resolution):
	//
	typedef typename std::iterator_traits<I1>::value_type value_type;
	return detail::copy_imp(first, last, out, boost::has_trivial_assign<value_type>());
	}

	} // namespace opt

	namespace non_opt
	{

	template<typename I1, typename I2>
	inline I2 copy(I1 first, I1 last, I2 out)
	{
	return opt::detail::copy_imp(first, last, out, boost::false_type());
	}

	}

	//
	// define some global data:
	//
	const int array_size = 1000;
	int i_array_[array_size] = {0,};
	const int ci_array_[array_size] = {0,};
	char c_array_[array_size] = {0,};
	const char cc_array_[array_size] = { 0,};
	//
	// since arrays aren't iterators we define a set of pointer
	// aliases into the arrays (otherwise the compiler is entitled
	// to deduce the type passed to the template functions as
	// T (&)[N] rather than T*).
	int* i_array = i_array_;
	const int* ci_array = ci_array_;
	char* c_array = c_array_;
	const char* cc_array = cc_array_;

	const int iter_count = 1000000;

	int cpp_main(int argc, char* argv[])
	{
	boost::timer t;
	double result;
	int i;
	cout << "Measuring times in micro-seconds per 1000 elements processed" << endl << endl;
	cout << "testing copy...\n"
	"[Some standard library versions may already perform this optimisation.]" << endl;

	// cache load:
	opt::copy(ci_array, ci_array + array_size, i_array);

	// time optimised version:
	t.restart();
	for(i = 0; i < iter_count; ++i)
	{
	opt::copy(ci_array, ci_array + array_size, i_array);
	}
	result = t.elapsed();
	cout << "opt::copy<const int, int>: " << result << endl;

	// cache load:
	non_opt::copy(ci_array, ci_array + array_size, i_array);

	// time non-optimised version:
	t.restart();
	for(i = 0; i < iter_count; ++i)
	{
	non_opt::copy(ci_array, ci_array + array_size, i_array);
	}
	result = t.elapsed();
	cout << "non_opt::copy<const int, int>: " << result << endl;

	// cache load:
	std::copy(ci_array, ci_array + array_size, i_array);

	// time standard version:
	t.restart();
	for(i = 0; i < iter_count; ++i)
	{
	std::copy(ci_array, ci_array + array_size, i_array);
	}
	result = t.elapsed();
	cout << "std::copy<const int, int>: " << result << endl;

	// cache load:
	opt::copy(cc_array, cc_array + array_size, c_array);

	// time optimised version:
	t.restart();
	for(i = 0; i < iter_count; ++i)
	{
	opt::copy(cc_array, cc_array + array_size, c_array);
	}
	result = t.elapsed();
	cout << "opt::copy<const char, char>: " << result << endl;

	// cache load:
	non_opt::copy(cc_array, cc_array + array_size, c_array);

	// time optimised version:
	t.restart();
	for(i = 0; i < iter_count; ++i)
	{
	non_opt::copy(cc_array, cc_array + array_size, c_array);
	}
	result = t.elapsed();
	cout << "non_opt::copy<const char, char>: " << result << endl;

	// cache load:
	std::copy(cc_array, cc_array + array_size, c_array);

	// time standard version:
	t.restart();
	for(i = 0; i < iter_count; ++i)
	{
	std::copy(cc_array, cc_array + array_size, c_array);
	}
	result = t.elapsed();
	cout << "std::copy<const char, char>: " << result << endl;

	return 0;
	}