boost_1_45_0/libs/range/doc/reference/semantics.qbk - nest-learning-thermostat/5.0/boost - Git at Google

 [section Semantics]

 [heading notation]

 [table
   [[Type   ] [Object] [Describes                                ]]
   [[`X`    ] [`x`   ] [any type                                 ]]
   [[`T`    ] [`t`   ] [denotes behavior of the primary templates]]
   [[`P`    ] [`p`   ] [denotes `std::pair<iterator,iterator>`   ]]
   [[`A[sz]`] [`a`   ] [denotes an array of type `A` of size `sz`]]
   [[`Char*`] [`s`   ] [denotes either `char*` or `wchar_t*`     ]]
 ]

 [section Metafunctions]

 [table
     [[Expression] [Return type] [Complexity]]
     [
         [`range_iterator<X>::type`]
         [``
             T::iterator
             P::first_type
             A*
         ``]
         [compile time]
     ]
     [
         [`range_iterator<const X>::type`]
         [``
             T::const_iterator
             P::first_type
             const A*
         ``]
         [compile time]
     ]
     [
         [`range_value<X>::type`]
         [`boost::iterator_value<range_iterator<X>::type>::type`]
         [compile time]
     ]
     [
         [`range_reference<X>::type`]
         [`boost::iterator_reference<range_iterator<X>::type>::type`]
         [compile time]
     ]
     [
         [`range_pointer<X>::type`]
         [`boost::iterator_pointer<range_iterator<X>::type>::type`]
         [compile time]
     ]
     [
         [`range_category<X>::type`]
         [`boost::iterator_category<range_iterator<X>::type>::type`]
         [compile time]
     ]
     [
         [`range_difference<X>::type`]
         [`boost::iterator_category<range_iterator<X>::type>::type`]
         [compile time]
     ]
     [
         [`range_reverse_iterator<X>::type`]
         [`boost::reverse_iterator<range_iterator<X>::type>`]
         [compile time]
     ]
     [
         [`range_reverse_iterator<const X>::type`]
         [`boost::reverse_iterator<range_iterator<const X>::type`]
         [compile time]
     ]
 ]

 [endsect]

 [section Functions]

 [table
     [[Expression] [Return type] [Returns] [Complexity]]

     [
         [`begin(x)`]
         [`range_iterator<X>::type`]
         [
             `p.first` if `p` is of type `std::pair<T>`
             `a` if `a` is an array
             `range_begin(x)` if that expression would invoke a function found by ADL
             `t.begin()` otherwise
         ]
         [constant time]
     ]
     [
         [`end(x)`]
         [`range_iterator<X>::type`]
         [
             `p.second` if `p` is of type `std::pair<T>`
             `a + sz` if `a` is an array of size `sz`
             `range_end(x)` if that expression would invoke a function found by ADL
             `t.end()` otherwise
         ]
         [constant time]
     ]
     [
         [`empty(x)`]
         [`bool`]
         [`boost::begin(x) == boost::end(x)`]
         [constant time]
     ]
     [
         [`distance(x)`]
         [`range_difference<X>::type`]
         [`std::distance(boost::begin(x),boost::end(x))`]
         [-]
     ]
     [
         [`size(x)`]
         [`range_difference<X>::type`]
         [`boost::end(x) - boost::begin(x)`]
         [constant time]
     ]
     [
         [`rbegin(x)`]
         [`range_reverse_iterator<X>::type`]
         [`range_reverse_iterator<X>::type(boost::end(x))`]
         [constant time]
     ]
     [
         [`rend(x)`]
         [`range_reverse_iterator<X>::type`]
         [`range_reverse_iterator<X>::type(boost::begin(x))`]
         [constant time]
     ]
     [
         [`const_begin(x)`]
         [`range_iterator<const X>::type`]
         [`range_iterator<const X>::type(boost::begin(x))`]
         [constant time]
     ]
     [
         [`const_end(x)`]
         [`range_iterator<const X>::type`]
         [`range_iterator<const X>::type(boost::end(x))`]
         [constant time]
     ]
     [
         [`const_rbegin(x)`]
         [`range_reverse_iterator<const X>::type`]
         [`range_reverse_iterator<const X>::type(boost::rbegin(x))`]
         [constant time]
     ]
     [
         [`const_rend(x)`]
         [`range_reverse_iterator<const X>::type`]
         [`range_reverse_iterator<const X>::type(boost::rend(x))`]
         [constant time]
     ]
     [
         [`as_literal(x)`]
         [`iterator_range<U>` where `U` is `Char*` if `x` is a pointer to a string and `U` is `range_iterator<X>::type` otherwise]
         [
             `[s,s + std::char_traits<X>::length(s))` if `s` is a `Char*` or an array of `Char` `[boost::begin(x),boost::end(x))` otherwise
         ]
         [
             linear time for pointers to a string or arrays of `Char`, constant time otherwise
         ]
     ]
     [
         [`as_array(x)`]
         [`iterator_range<X>`]
         [`[boost::begin(x),boost::end(x))`]
     ]
 ]

 The special `const_`-named functions are useful when you want to document clearly that your code is read-only.

 `as_literal()` can be used ['*internally*] in string algorithm libraries such that arrays of characters are handled correctly.

 `as_array()` can be used with string algorithm libraries to make it clear that arrays of characters are handled like an array and not like a string.

 Notice that the above functions should always be called with qualification (`boost::`) to prevent ['*unintended*] Argument Dependent Lookup (ADL).

 [endsect]

 [endsect]
	[section Semantics]

	[heading notation]

	[table
	[[Type ] [Object] [Describes ]]
	[[`X` ] [`x` ] [any type ]]
	[[`T` ] [`t` ] [denotes behavior of the primary templates]]
	[[`P` ] [`p` ] [denotes `std::pair<iterator,iterator>` ]]
	[[`A[sz]`] [`a` ] [denotes an array of type `A` of size `sz`]]
	[[`Char`] [`s` ] [denotes either `char` or `wchar_t*` ]]
	]

	[section Metafunctions]

	[table
	[[Expression] [Return type] [Complexity]]
	[
	[`range_iterator<X>::type`]
	[``
	T::iterator
	P::first_type
	A*
	``]
	[compile time]
	]
	[
	[`range_iterator<const X>::type`]
	[``
	T::const_iterator
	P::first_type
	const A*
	``]
	[compile time]
	]
	[
	[`range_value<X>::type`]
	[`boost::iterator_value<range_iterator<X>::type>::type`]
	[compile time]
	]
	[
	[`range_reference<X>::type`]
	[`boost::iterator_reference<range_iterator<X>::type>::type`]
	[compile time]
	]
	[
	[`range_pointer<X>::type`]
	[`boost::iterator_pointer<range_iterator<X>::type>::type`]
	[compile time]
	]
	[
	[`range_category<X>::type`]
	[`boost::iterator_category<range_iterator<X>::type>::type`]
	[compile time]
	]
	[
	[`range_difference<X>::type`]
	[`boost::iterator_category<range_iterator<X>::type>::type`]
	[compile time]
	]
	[
	[`range_reverse_iterator<X>::type`]
	[`boost::reverse_iterator<range_iterator<X>::type>`]
	[compile time]
	]
	[
	[`range_reverse_iterator<const X>::type`]
	[`boost::reverse_iterator<range_iterator<const X>::type`]
	[compile time]
	]
	]

	[endsect]

	[section Functions]

	[table
	[[Expression] [Return type] [Returns] [Complexity]]

	[
	[`begin(x)`]
	[`range_iterator<X>::type`]
	[
	`p.first` if `p` is of type `std::pair<T>`
	`a` if `a` is an array
	`range_begin(x)` if that expression would invoke a function found by ADL
	`t.begin()` otherwise
	]
	[constant time]
	]
	[
	[`end(x)`]
	[`range_iterator<X>::type`]
	[
	`p.second` if `p` is of type `std::pair<T>`
	`a + sz` if `a` is an array of size `sz`
	`range_end(x)` if that expression would invoke a function found by ADL
	`t.end()` otherwise
	]
	[constant time]
	]
	[
	[`empty(x)`]
	[`bool`]
	[`boost::begin(x) == boost::end(x)`]
	[constant time]
	]
	[
	[`distance(x)`]
	[`range_difference<X>::type`]
	[`std::distance(boost::begin(x),boost::end(x))`]
	[-]
	]
	[
	[`size(x)`]
	[`range_difference<X>::type`]
	[`boost::end(x) - boost::begin(x)`]
	[constant time]
	]
	[
	[`rbegin(x)`]
	[`range_reverse_iterator<X>::type`]
	[`range_reverse_iterator<X>::type(boost::end(x))`]
	[constant time]
	]
	[
	[`rend(x)`]
	[`range_reverse_iterator<X>::type`]
	[`range_reverse_iterator<X>::type(boost::begin(x))`]
	[constant time]
	]
	[
	[`const_begin(x)`]
	[`range_iterator<const X>::type`]
	[`range_iterator<const X>::type(boost::begin(x))`]
	[constant time]
	]
	[
	[`const_end(x)`]
	[`range_iterator<const X>::type`]
	[`range_iterator<const X>::type(boost::end(x))`]
	[constant time]
	]
	[
	[`const_rbegin(x)`]
	[`range_reverse_iterator<const X>::type`]
	[`range_reverse_iterator<const X>::type(boost::rbegin(x))`]
	[constant time]
	]
	[
	[`const_rend(x)`]
	[`range_reverse_iterator<const X>::type`]
	[`range_reverse_iterator<const X>::type(boost::rend(x))`]
	[constant time]
	]
	[
	[`as_literal(x)`]
	[`iterator_range<U>` where `U` is `Char*` if `x` is a pointer to a string and `U` is `range_iterator<X>::type` otherwise]
	[
	`[s,s + std::char_traits<X>::length(s))` if `s` is a `Char*` or an array of `Char` `[boost::begin(x),boost::end(x))` otherwise
	]
	[
	linear time for pointers to a string or arrays of `Char`, constant time otherwise
	]
	]
	[
	[`as_array(x)`]
	[`iterator_range<X>`]
	[`[boost::begin(x),boost::end(x))`]
	]
	]

	The special `const_`-named functions are useful when you want to document clearly that your code is read-only.

	`as_literal()` can be used ['internally] in string algorithm libraries such that arrays of characters are handled correctly.

	`as_array()` can be used with string algorithm libraries to make it clear that arrays of characters are handled like an array and not like a string.

	Notice that the above functions should always be called with qualification (`boost::`) to prevent ['unintended] Argument Dependent Lookup (ADL).

	[endsect]

	[endsect]