WSJT-X/boost/libs/iterator/doc/quickbook/zip_iterator.qbk


[section:zip Zip Iterator]

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. 

The tuple of iterators is now implemented in terms of a Boost fusion sequence. 
Because of this the 'tuple' may be any Boost fusion sequence and, for backwards
compatibility through a Boost fusion sequence adapter, a Boost tuple. Because the 
'tuple' may be any boost::fusion sequence the 'tuple' may also be any type for which a 
Boost fusion adapter exists. This includes, among others, a std::tuple and a std::pair.
Just remember to include the appropriate Boost fusion adapter header files for these
other Boost fusion adapters. The zip_iterator header file already includes the
Boost fusion adapter header file for Boost tuple, so you need not include it yourself
to use a Boost tuple as your 'tuple'.

[section:zip_example Example]

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>()
      );

[endsect]

[section:zip_reference Reference]

[h2 Synopsis]

  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`.

[h2 Requirements]

All iterator types in the argument `IteratorTuple` shall model Readable Iterator.  

[h2 Concepts]

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`.

[h2 Operations]

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.


  zip_iterator(IteratorTuple iterator_tuple);

[*Returns:] An instance of `zip_iterator` with `m_iterator_tuple`
  initialized to `iterator_tuple`.


    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`.[br]
[*Requires:] `OtherIteratorTuple` is implicitly convertible to `IteratorTuple`.


  const IteratorTuple& get_iterator_tuple() const;

[*Returns:] `m_iterator_tuple`


  reference operator*() const;

[*Returns:] A tuple consisting of the results of dereferencing all iterators in
  `m_iterator_tuple`.


  zip_iterator& operator++();

[*Effects:] Increments each iterator in `m_iterator_tuple`.[br]
[*Returns:] `*this`


  zip_iterator& operator--();

[*Effects:] Decrements each iterator in `m_iterator_tuple`.[br]
[*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`.

[endsect]

[endsect]
Squashed 'boost/' content from commit b4feb19f2 git-subtree-dir: boost git-subtree-split: b4feb19f287ee92d87a9624b5d36b7cf46aeadeb 2018-06-09 21:48:32 +01:00
			`[section:zip Zip Iterator]`

			`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.`

			`The tuple of iterators is now implemented in terms of a Boost fusion sequence.`
			`Because of this the 'tuple' may be any Boost fusion sequence and, for backwards`
			`compatibility through a Boost fusion sequence adapter, a Boost tuple. Because the`
			`'tuple' may be any boost::fusion sequence the 'tuple' may also be any type for which a`
			`Boost fusion adapter exists. This includes, among others, a std::tuple and a std::pair.`
			`Just remember to include the appropriate Boost fusion adapter header files for these`
			`other Boost fusion adapters. The zip_iterator header file already includes the`
			`Boost fusion adapter header file for Boost tuple, so you need not include it yourself`
			`to use a Boost tuple as your 'tuple'.`

			`[section:zip_example Example]`

			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>()`
			`);`

			`[endsect]`

			`[section:zip_reference Reference]`

			`[h2 Synopsis]`

			`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`.

			`[h2 Requirements]`

			All iterator types in the argument `IteratorTuple` shall model Readable Iterator.

			`[h2 Concepts]`

			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`.

			`[h2 Operations]`

			`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.`


			`zip_iterator(IteratorTuple iterator_tuple);`

			[*Returns:] An instance of `zip_iterator` with `m_iterator_tuple`
			initialized to `iterator_tuple`.


			`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`.[br]
			[*Requires:] `OtherIteratorTuple` is implicitly convertible to `IteratorTuple`.


			`const IteratorTuple& get_iterator_tuple() const;`

			[*Returns:] `m_iterator_tuple`


			`reference operator*() const;`

			`[*Returns:] A tuple consisting of the results of dereferencing all iterators in`
			`m_iterator_tuple`.


			`zip_iterator& operator++();`

			[*Effects:] Increments each iterator in `m_iterator_tuple`.[br]
			[Returns:] `this`


			`zip_iterator& operator--();`

			[*Effects:] Decrements each iterator in `m_iterator_tuple`.[br]
			[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`.

			`[endsect]`

			`[endsect]`