boost_1_45_0/libs/fusion/example/cookbook/fill_em_up.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 /*=============================================================================
     Copyright (c) 2006 Joel de Guzman

     Distributed under 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)

     Problem:

     So... you have an input sequence I and a target vector R. You want to
     copy I into R. But, I may have less elements than the result vector R.
     For those elements not in R, you want them to be default constructed.

     Here's a case:

         I: list<double, std::string>
         R: vector<double, std::string, int, short>

     You want the elements at the right of I not in R (i.e. int, short)
     default constructed. Those at the left, found in both I and R, you want
     to simply copy from I.

     Of course you want to be able to handle any type of I and R.

 ==============================================================================*/

 // We'll use these containers as examples
 #include <boost/fusion/container/list.hpp>
 #include <boost/fusion/container/vector.hpp>

 // For doing I/O
 #include <boost/fusion/sequence/io.hpp>

 // We'll use join and advance for processing
 #include <boost/fusion/algorithm/transformation/join.hpp>
 #include <boost/fusion/iterator/advance.hpp>

 // The fusion <--> MPL link header
 #include <boost/fusion/mpl.hpp>

 // Same-o same-o
 #include <iostream>
 #include <string>

 int
 main()
 {
     using namespace boost::fusion;
     using namespace boost;

     // Let's specify our own tuple delimeters for nicer printing
     std::cout << tuple_open('[');
     std::cout << tuple_close(']');
     std::cout << tuple_delimiter(", ");

     // Here's your input sequence
     typedef list<double, std::string> I;
     I i(123.456, "Hello");

     // Here's your output sequence. For now, it is just a typedef
     typedef vector<double, std::string, int, short> R;

     // Let's get the sizes of the sequences. Yeah, you already know that.
     // But with templates, you are simply given, say, R and I, corresponding
     // to the types of the sequences. You'll have to deal with it generically.
     static int const r_size = result_of::size<R>::value;
     static int const i_size = result_of::size<I>::value;

     // Make sure that I has no more elements than R
     // Be nice and catch obvious errors earlier rather than later.
     // Without this assert, the mistake will still be caught by Fusion,
     // but the error will point to somewhere really obscure.
     BOOST_STATIC_ASSERT(i_size <= r_size);

     // Let's get the begin and end iterator types of the output sequence
     // There's no actual vector yet. We just want to know the types.
     typedef result_of::begin<R>::type r_begin;
     typedef result_of::end<R>::type r_end;

     // Let's skip i_size elements from r_begin. Again, we just want to know the type.
     typedef result_of::advance_c<r_begin, i_size>::type r_advance;

     // Now, make MPL iterators from r_advance and r_end. Ditto, just types.
     typedef mpl::fusion_iterator<r_advance> mpl_r_advance;
     typedef mpl::fusion_iterator<r_end> mpl_r_end;

     // Make an mpl::iterator_range from the MPL iterators we just created
     // You guessed it! --just a type.
     typedef mpl::iterator_range<mpl_r_advance, mpl_r_end> tail;

     // Use join to join the input sequence and our mpl::iterator_range
     // Our mpl::iterator_range is 'tail'. Here, we'll actually instantiate
     // 'tail'. Notice that this is a flyweight object, typically just 1 byte
     // in size -- it doesn't really hold any data, but is a fully conforming
     // sequence nonetheless. When asked to return its elements, 'tail' returns
     // each element default constructed. Breeds like a rabbit!

     // Construct R from the joined sequences:
     R r(join(i, tail()));

     // Then finally, print the result:
     std::cout << r << std::endl;

     return 0;
 }
	/*=============================================================================
	Copyright (c) 2006 Joel de Guzman

	Distributed under 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)

	Problem:

	So... you have an input sequence I and a target vector R. You want to
	copy I into R. But, I may have less elements than the result vector R.
	For those elements not in R, you want them to be default constructed.

	Here's a case:

	I: list<double, std::string>
	R: vector<double, std::string, int, short>

	You want the elements at the right of I not in R (i.e. int, short)
	default constructed. Those at the left, found in both I and R, you want
	to simply copy from I.

	Of course you want to be able to handle any type of I and R.

	==============================================================================*/

	// We'll use these containers as examples
	#include <boost/fusion/container/list.hpp>
	#include <boost/fusion/container/vector.hpp>

	// For doing I/O
	#include <boost/fusion/sequence/io.hpp>

	// We'll use join and advance for processing
	#include <boost/fusion/algorithm/transformation/join.hpp>
	#include <boost/fusion/iterator/advance.hpp>

	// The fusion <--> MPL link header
	#include <boost/fusion/mpl.hpp>

	// Same-o same-o
	#include <iostream>
	#include <string>

	int
	main()
	{
	using namespace boost::fusion;
	using namespace boost;

	// Let's specify our own tuple delimeters for nicer printing
	std::cout << tuple_open('[');
	std::cout << tuple_close(']');
	std::cout << tuple_delimiter(", ");

	// Here's your input sequence
	typedef list<double, std::string> I;
	I i(123.456, "Hello");

	// Here's your output sequence. For now, it is just a typedef
	typedef vector<double, std::string, int, short> R;

	// Let's get the sizes of the sequences. Yeah, you already know that.
	// But with templates, you are simply given, say, R and I, corresponding
	// to the types of the sequences. You'll have to deal with it generically.
	static int const r_size = result_of::size<R>::value;
	static int const i_size = result_of::size<I>::value;

	// Make sure that I has no more elements than R
	// Be nice and catch obvious errors earlier rather than later.
	// Without this assert, the mistake will still be caught by Fusion,
	// but the error will point to somewhere really obscure.
	BOOST_STATIC_ASSERT(i_size <= r_size);

	// Let's get the begin and end iterator types of the output sequence
	// There's no actual vector yet. We just want to know the types.
	typedef result_of::begin<R>::type r_begin;
	typedef result_of::end<R>::type r_end;

	// Let's skip i_size elements from r_begin. Again, we just want to know the type.
	typedef result_of::advance_c<r_begin, i_size>::type r_advance;

	// Now, make MPL iterators from r_advance and r_end. Ditto, just types.
	typedef mpl::fusion_iterator<r_advance> mpl_r_advance;
	typedef mpl::fusion_iterator<r_end> mpl_r_end;

	// Make an mpl::iterator_range from the MPL iterators we just created
	// You guessed it! --just a type.
	typedef mpl::iterator_range<mpl_r_advance, mpl_r_end> tail;

	// Use join to join the input sequence and our mpl::iterator_range
	// Our mpl::iterator_range is 'tail'. Here, we'll actually instantiate
	// 'tail'. Notice that this is a flyweight object, typically just 1 byte
	// in size -- it doesn't really hold any data, but is a fully conforming
	// sequence nonetheless. When asked to return its elements, 'tail' returns
	// each element default constructed. Breeds like a rabbit!

	// Construct R from the joined sequences:
	R r(join(i, tail()));

	// Then finally, print the result:
	std::cout << r << std::endl;

	return 0;
	}