...one of the most highly
regarded and expertly designed C++ library projects in the
world.
— Herb Sutter and Andrei
Alexandrescu, C++
Coding Standards
Author: | David Abrahams, Thomas Becker |
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Contact: | dave@boost-consulting.com, thomas@styleadvisor.com |
Organization: | Boost Consulting, Zephyr Associates, Inc. |
Date: | 2006-09-11 |
Copyright: | Copyright David Abrahams and Thomas Becker 2003. |
abstract: | The zip iterator provides the ability to parallel-iterate over several controlled sequences simultaneously. A zip iterator is constructed from a tuple of iterators. Moving the zip iterator moves all the iterators in parallel. Dereferencing the zip iterator returns a tuple that contains the results of dereferencing the individual iterators. |
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Table of Contents
template<typename IteratorTuple> class zip_iterator { public: typedef /* see below */ reference; typedef reference value_type; typedef value_type* pointer; typedef /* see below */ difference_type; typedef /* see below */ iterator_category; zip_iterator(); zip_iterator(IteratorTuple iterator_tuple); template<typename OtherIteratorTuple> zip_iterator( const zip_iterator<OtherIteratorTuple>& other , typename enable_if_convertible< OtherIteratorTuple , IteratorTuple>::type* = 0 // exposition only ); const IteratorTuple& get_iterator_tuple() const; private: IteratorTuple m_iterator_tuple; // exposition only }; template<typename IteratorTuple> zip_iterator<IteratorTuple> make_zip_iterator(IteratorTuple t);
The reference member of zip_iterator is the type of the tuple made of the reference types of the iterator types in the IteratorTuple argument.
The difference_type member of zip_iterator is the difference_type of the first of the iterator types in the IteratorTuple argument.
The iterator_category member of zip_iterator is convertible to the minimum of the traversal categories of the iterator types in the IteratorTuple argument. For example, if the zip_iterator holds only vector iterators, then iterator_category is convertible to boost::random_access_traversal_tag. If you add a list iterator, then iterator_category will be convertible to boost::bidirectional_traversal_tag, but no longer to boost::random_access_traversal_tag.
All iterator types in the argument IteratorTuple shall model Readable Iterator.
The resulting zip_iterator models Readable Iterator.
The fact that the zip_iterator models only Readable Iterator does not prevent you from modifying the values that the individual iterators point to. The tuple returned by the zip_iterator's operator* is a tuple constructed from the reference types of the individual iterators, not their value types. For example, if zip_it is a zip_iterator whose first member iterator is an std::vector<double>::iterator, then the following line will modify the value which the first member iterator of zip_it currently points to:
zip_it->get<0>() = 42.0;
Consider the set of standard traversal concepts obtained by taking the most refined standard traversal concept modeled by each individual iterator type in the IteratorTuple argument.The zip_iterator models the least refined standard traversal concept in this set.
zip_iterator<IteratorTuple1> is interoperable with zip_iterator<IteratorTuple2> if and only if IteratorTuple1 is interoperable with IteratorTuple2.
In addition to the operations required by the concepts modeled by zip_iterator, zip_iterator provides the following operations.
zip_iterator();
Returns: | An instance of zip_iterator with m_iterator_tuple default constructed. |
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zip_iterator(IteratorTuple iterator_tuple);
Returns: | An instance of zip_iterator with m_iterator_tuple initialized to iterator_tuple. |
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template<typename OtherIteratorTuple> zip_iterator( const zip_iterator<OtherIteratorTuple>& other , typename enable_if_convertible< OtherIteratorTuple , IteratorTuple>::type* = 0 // exposition only );
Returns: | An instance of zip_iterator that is a copy of other. |
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Requires: | OtherIteratorTuple is implicitly convertible to IteratorTuple. |
const IteratorTuple& get_iterator_tuple() const;
Returns: | m_iterator_tuple |
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reference operator*() const;
Returns: | A tuple consisting of the results of dereferencing all iterators in m_iterator_tuple. |
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zip_iterator& operator++();
Effects: | Increments each iterator in m_iterator_tuple. |
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Returns: | *this |
zip_iterator& operator--();
Effects: | Decrements each iterator in m_iterator_tuple. |
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Returns: | *this |
template<typename IteratorTuple> zip_iterator<IteratorTuple> make_zip_iterator(IteratorTuple t);
Returns: | An instance of zip_iterator<IteratorTuple> with m_iterator_tuple initialized to t. |
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template<typename IteratorTuple> zip_iterator<IteratorTuple> make_zip_iterator(IteratorTuple t);
Returns: | An instance of zip_iterator<IteratorTuple> with m_iterator_tuple initialized to t. |
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There are two main types of applications of the zip_iterator. The first one concerns runtime efficiency: If one has several controlled sequences of the same length that must be somehow processed, e.g., with the for_each algorithm, then it is more efficient to perform just one parallel-iteration rather than several individual iterations. For an example, assume that vect_of_doubles and vect_of_ints are two vectors of equal length containing doubles and ints, respectively, and consider the following two iterations:
std::vector<double>::const_iterator beg1 = vect_of_doubles.begin(); std::vector<double>::const_iterator end1 = vect_of_doubles.end(); std::vector<int>::const_iterator beg2 = vect_of_ints.begin(); std::vector<int>::const_iterator end2 = vect_of_ints.end(); std::for_each(beg1, end1, func_0()); std::for_each(beg2, end2, func_1());
These two iterations can now be replaced with a single one as follows:
std::for_each( boost::make_zip_iterator( boost::make_tuple(beg1, beg2) ), boost::make_zip_iterator( boost::make_tuple(end1, end2) ), zip_func() );
A non-generic implementation of zip_func could look as follows:
struct zip_func : public std::unary_function<const boost::tuple<const double&, const int&>&, void> { void operator()(const boost::tuple<const double&, const int&>& t) const { m_f0(t.get<0>()); m_f1(t.get<1>()); } private: func_0 m_f0; func_1 m_f1; };
The second important application of the zip_iterator is as a building block to make combining iterators. A combining iterator is an iterator that parallel-iterates over several controlled sequences and, upon dereferencing, returns the result of applying a functor to the values of the sequences at the respective positions. This can now be achieved by using the zip_iterator in conjunction with the transform_iterator.
Suppose, for example, that you have two vectors of doubles, say vect_1 and vect_2, and you need to expose to a client a controlled sequence containing the products of the elements of vect_1 and vect_2. Rather than placing these products in a third vector, you can use a combining iterator that calculates the products on the fly. Let us assume that tuple_multiplies is a functor that works like std::multiplies, except that it takes its two arguments packaged in a tuple. Then the two iterators it_begin and it_end defined below delimit a controlled sequence containing the products of the elements of vect_1 and vect_2:
typedef boost::tuple< std::vector<double>::const_iterator, std::vector<double>::const_iterator > the_iterator_tuple; typedef boost::zip_iterator< the_iterator_tuple > the_zip_iterator; typedef boost::transform_iterator< tuple_multiplies<double>, the_zip_iterator > the_transform_iterator; the_transform_iterator it_begin( the_zip_iterator( the_iterator_tuple( vect_1.begin(), vect_2.begin() ) ), tuple_multiplies<double>() ); the_transform_iterator it_end( the_zip_iterator( the_iterator_tuple( vect_1.end(), vect_2.end() ) ), tuple_multiplies<double>() );