boost_1_45_0/libs/fusion/doc/notes.qbk - nest-learning-thermostat/5.1.5/boost - Git at Google

 [/==============================================================================
     Copyright (C) 2001-2007 Joel de Guzman, Dan Marsden, Tobias Schwinger
     Copyright (C) 2010 Christopher Schmidt

     Use, modification and distribution is 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)
 ===============================================================================/]
 [section Notes]

 [heading Recursive Inlined Functions]

 An interesting peculiarity of functions like __at__ when applied to a
 __forward_sequence__ like __list__ is that what could have been linear
 runtime complexity effectively becomes constant O(1) due to compiler
 optimization of C++ inlined functions, however deeply recursive (up to a
 certain compiler limit of course). Compile time complexity remains linear.

 [heading Overloaded Functions]

 Associative sequences use function overloading to implement membership
 testing and type associated key lookup. This amounts to constant runtime
 and amortized constant compile time complexities. There is an overloaded
 function, `f(k)`, for each key /type/ `k`. The compiler chooses the
 appropriate function given a key, `k`.

 [heading Tag Dispatching]

 Tag dispatching is a generic programming technique for selecting template
 specializations. There are typically 3 components involved in the tag
 dispatching mechanism:

 # A type for which an appropriate template specialization is required
 # A metafunction that associates the type with a tag type
 # A template that is specialized for the tag type

 For example, the fusion `result_of::begin` metafunction is implemented
 as follows:

     template <typename Sequence>
     struct begin
     {
         typedef typename
             result_of::begin_impl<typename traits::tag_of<Sequence>::type>::
             template apply<Sequence>::type
         type;
     };

 In the case:

 # `Sequence` is the type for which a suitable implementation of
    `result_of::begin_impl` is required
 # `traits::tag_of` is the metafunction that associates `Sequence`
    with an appropriate tag
 # `result_of::begin_impl` is the template which is specialized to provide
    an implementation for each tag type

 [heading Extensibility]

 Unlike __mpl__, there is no extensibe sequence concept in fusion. This does
 not mean that Fusion sequences are not extensible. In fact, all Fusion
 sequences are inherently extensible. It is just that the manner of sequence
 extension in Fusion is diferent from both __stl__ and __mpl__ on account of
 the lazy nature of fusion __algorithms__. __stl__ containers extend
 themselves in place though member functions such as __push_back__ and
 __insert__. __mpl__ sequences, on the other hand, are extended through
 "intrinsic" functions that actually return whole sequences. __mpl__ is
 purely functional and can not have side effects. For example, __mpl__'s
 `push_back` does not actually mutate an `mpl::vector`. It can't do that.
 Instead, it returns an extended `mpl::vector`.

 Like __mpl__, Fusion too is purely functional and can not have side
 effects. With runtime efficiency in mind, Fusion sequences are extended
 through generic functions that return __views__. __views__ are sequences
 that do not actually contain data, but instead impart an alternative
 presentation over the data from one or more underlying sequences. __views__
 are proxies. They provide an efficient yet purely functional way to work on
 potentially expensive sequence operations. For example, given a __vector__,
 Fusion's __push_back__ returns a __joint_view__, instead of an actual
 extended __vector__. A __joint_view__ holds a reference to the original
 sequence plus the appended data --making it very cheap to pass around.

 [heading Element Conversion]

 Functions that take in elemental values to form sequences (e.g.
 __make_list__) convert their arguments to something suitable to be stored
 as a sequence element. In general, the element types are stored as plain
 values. Example:

     __make_list__(1, 'x')

 returns a __list__`<int, char>`.

 There are a few exceptions, however.

 [*Arrays:]

 Array arguments are deduced to reference to const types. For example
 [footnote Note that the type of a string literal is an array of const
 characters, not `const char*`. To get __make_list__ to create a __list__
 with an element of a non-const array type one must use the `ref` wrapper
 (see __note_boost_ref__).]:

     __make_list__("Donald", "Daisy")

 creates a __list__ of type

     __list__<const char (&)[7], const char (&)[6]>

 [*Function pointers:]

 Function pointers are deduced to the plain non-reference type (i.e. to
 plain function pointer). Example:

     void f(int i);
       ...
     __make_list__(&f);

 creates a __list__ of type

     __list__<void (*)(int)>

 [heading boost::ref]

 Fusion's generation functions (e.g. __make_list__) by default stores the
 element types as plain non-reference types. Example:

     void foo(const A& a, B& b) {
         ...
         __make_list__(a, b)

 creates a __list__ of type

     __list__<A, B>

 Sometimes the plain non-reference type is not desired. You can use
 `boost::ref` and `boost::cref` to store references or const references
 (respectively) instead. The mechanism does not compromise const correctness
 since a const object wrapped with ref results in a tuple element with const
 reference type (see the fifth code line below). Examples:

 For example:

     A a; B b; const A ca = a;
     __make_list__(cref(a), b);          // creates list<const A&, B>
     __make_list__(ref(a), b);           // creates list<A&, B>
     __make_list__(ref(a), cref(b));     // creates list<A&, const B&>
     __make_list__(cref(ca));            // creates list<const A&>
     __make_list__(ref(ca));             // creates list<const A&>

 See __boost_ref__ for details.

 [heading adt_attribute_proxy]

 To adapt arbitrary data types that do not allow direct access to their members,
 but allow indirect access via expressions (such as invocations of get- and
 set-methods), fusion's [^BOOST\_FUSION\_ADAPT\_['xxx]ADT['xxx]]-family (e.g.
 __adapt_adt__) may be used.
 To bypass the restriction of not having actual lvalues that
 represent the elements of the fusion sequence, but rather a sequence of paired
 expressions that access the elements, the actual return type of fusion's
 intrinsic sequence access functions (__at__, __at_c__, __at_key__, __deref__,
 and __deref_data__) is a proxy type, an instance of
 `adt_attribute_proxy`, that encapsulates these expressions.

 `adt_attribute_proxy` is defined in the namespace `boost::fusion::extension` and
 has three template arguments:

     namespace boost { namespace fusion { namespace extension
     {
         template<
             typename Type
           , int Index
           , bool Const
         >
         struct adt_attribute_proxy;
     }}}

 When adapting a class type, `adt_attribute_proxy` is specialized for every
 element of the adapted sequence, with `Type` being the class type that is
 adapted, `Index` the 0-based indices of the elements, and `Const` both `true`
 and `false`. The return type of fusion's intrinsic sequence access functions
 for the ['N]th element of an adapted class type `type_name` is
 [^adt_attribute_proxy<type_name, ['N], ['Const]>], with [^['Const]] being `true`
 for constant instances of `type_name` and `false` for non-constant ones.

 [variablelist Notation
     [[`type_name`]
         [The type to be adapted, with M attributes]]
     [[`inst`]
         [Object of type `type_name`]]
     [[`const_inst`]
         [Object of type `type_name const`]]
     [[[^(attribute_type['N], attribute_const_type['N], get_expr['N], set_expr['N])]]
         [Attribute descriptor of the ['N]th attribute of `type_name` as passed to the adaption macro, 0\u2264['N]<M]]
     [[[^proxy_type['N]]]
         [[^adt_attribute_proxy<type_name, ['N], `false`>] with ['N] being an integral constant, 0\u2264['N]<M]]
     [[[^const_proxy_type['N]]]
         [[^adt_attribute_proxy<type_name, ['N], `true`>] with ['N] being an integral constant, 0\u2264['N]<M]]
     [[[^proxy['N]]]
         [Object of type [^proxy_type['N]]]]
     [[[^const_proxy['N]]]
         [Object of type [^const_proxy_type['N]]]]
 ]

 [*Expression Semantics]

 [table
     [[Expression]                     [Semantics]]
     [[[^proxy_type['N](inst)]]             [Creates an instance of [^proxy_type['N]] with underlying object `inst`]]
     [[[^const_proxy_type['N](const_inst)]] [Creates an instance of [^const_proxy_type['N]] with underlying object `const_inst`]]
     [[[^proxy_type['N]::type]]             [Another name for [^attribute_type['N]]]]
     [[[^const_proxy_type['N]::type]]       [Another name for [^const_attribute_type['N]]]]
     [[[^proxy['N]=t]]                 [Invokes [^set_expr['N]], with `t` being an arbitrary object. [^set_expr['N]] may access the variables named `obj` of type `type_name&`, which represent the corresponding instance of `type_name`, and `val` of an arbitrary const-qualified reference template type parameter `Val`, which represents `t`.]]
     [[[^proxy['N].get()]]             [Invokes [^get_expr['N]] and forwards its return value. [^get_expr['N]] may access the variable named `obj` of type `type_name&` which represents the underlying instance of `type_name`. [^attribute_type['N]] may specify the type that [^get_expr['N]] denotes to.]]
     [[[^const_proxy['N].get()]]       [Invokes [^get_expr['N]] and forwards its return value. [^get_expr['N]] may access the variable named `obj` of type `type_name const&` which represents the underlying instance of `type_name`. [^attribute_const_type['N]] may specify the type that [^get_expr['N]] denotes to.]]
 ]

 Additionally, [^proxy_type['N]] and [^const_proxy_type['N]] are copy
 constructible, copy assignable and implicitly convertible to
 [^proxy_type['N]::type] or [^const_proxy_type['N]::type].

 [tip To avoid the pitfalls of the proxy type, an arbitrary class type may also
 be adapted directly using fusion's [link fusion.extension intrinsic extension
 mechanism].]

 [endsect]
	[/==============================================================================
	Copyright (C) 2001-2007 Joel de Guzman, Dan Marsden, Tobias Schwinger
	Copyright (C) 2010 Christopher Schmidt

	Use, modification and distribution is 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)
	===============================================================================/]
	[section Notes]

	[heading Recursive Inlined Functions]

	An interesting peculiarity of functions like __at__ when applied to a
	__forward_sequence__ like __list__ is that what could have been linear
	runtime complexity effectively becomes constant O(1) due to compiler
	optimization of C++ inlined functions, however deeply recursive (up to a
	certain compiler limit of course). Compile time complexity remains linear.

	[heading Overloaded Functions]

	Associative sequences use function overloading to implement membership
	testing and type associated key lookup. This amounts to constant runtime
	and amortized constant compile time complexities. There is an overloaded
	function, `f(k)`, for each key /type/ `k`. The compiler chooses the
	appropriate function given a key, `k`.

	[heading Tag Dispatching]

	Tag dispatching is a generic programming technique for selecting template
	specializations. There are typically 3 components involved in the tag
	dispatching mechanism:

	# A type for which an appropriate template specialization is required
	# A metafunction that associates the type with a tag type
	# A template that is specialized for the tag type

	For example, the fusion `result_of::begin` metafunction is implemented
	as follows:

	template <typename Sequence>
	struct begin
	{
	typedef typename
	result_of::begin_impl<typename traits::tag_of<Sequence>::type>::
	template apply<Sequence>::type
	type;
	};

	In the case:

	# `Sequence` is the type for which a suitable implementation of
	`result_of::begin_impl` is required
	# `traits::tag_of` is the metafunction that associates `Sequence`
	with an appropriate tag
	# `result_of::begin_impl` is the template which is specialized to provide
	an implementation for each tag type

	[heading Extensibility]

	Unlike __mpl__, there is no extensibe sequence concept in fusion. This does
	not mean that Fusion sequences are not extensible. In fact, all Fusion
	sequences are inherently extensible. It is just that the manner of sequence
	extension in Fusion is diferent from both __stl__ and __mpl__ on account of
	the lazy nature of fusion __algorithms__. __stl__ containers extend
	themselves in place though member functions such as __push_back__ and
	__insert__. __mpl__ sequences, on the other hand, are extended through
	"intrinsic" functions that actually return whole sequences. __mpl__ is
	purely functional and can not have side effects. For example, __mpl__'s
	`push_back` does not actually mutate an `mpl::vector`. It can't do that.
	Instead, it returns an extended `mpl::vector`.

	Like __mpl__, Fusion too is purely functional and can not have side
	effects. With runtime efficiency in mind, Fusion sequences are extended
	through generic functions that return __views__. __views__ are sequences
	that do not actually contain data, but instead impart an alternative
	presentation over the data from one or more underlying sequences. __views__
	are proxies. They provide an efficient yet purely functional way to work on
	potentially expensive sequence operations. For example, given a __vector__,
	Fusion's __push_back__ returns a __joint_view__, instead of an actual
	extended __vector__. A __joint_view__ holds a reference to the original
	sequence plus the appended data --making it very cheap to pass around.

	[heading Element Conversion]

	Functions that take in elemental values to form sequences (e.g.
	__make_list__) convert their arguments to something suitable to be stored
	as a sequence element. In general, the element types are stored as plain
	values. Example:

	__make_list__(1, 'x')

	returns a __list__`<int, char>`.

	There are a few exceptions, however.

	[*Arrays:]

	Array arguments are deduced to reference to const types. For example
	[footnote Note that the type of a string literal is an array of const
	characters, not `const char*`. To get __make_list__ to create a __list__
	with an element of a non-const array type one must use the `ref` wrapper
	(see __note_boost_ref__).]:

	__make_list__("Donald", "Daisy")

	creates a __list__ of type

	__list__<const char (&)[7], const char (&)[6]>

	[*Function pointers:]

	Function pointers are deduced to the plain non-reference type (i.e. to
	plain function pointer). Example:

	void f(int i);
	...
	__make_list__(&f);

	creates a __list__ of type

	__list__<void (*)(int)>

	[heading boost::ref]

	Fusion's generation functions (e.g. __make_list__) by default stores the
	element types as plain non-reference types. Example:

	void foo(const A& a, B& b) {
	...
	__make_list__(a, b)

	creates a __list__ of type

	__list__<A, B>

	Sometimes the plain non-reference type is not desired. You can use
	`boost::ref` and `boost::cref` to store references or const references
	(respectively) instead. The mechanism does not compromise const correctness
	since a const object wrapped with ref results in a tuple element with const
	reference type (see the fifth code line below). Examples:

	For example:

	A a; B b; const A ca = a;
	__make_list__(cref(a), b); // creates list<const A&, B>
	__make_list__(ref(a), b); // creates list<A&, B>
	__make_list__(ref(a), cref(b)); // creates list<A&, const B&>
	__make_list__(cref(ca)); // creates list<const A&>
	__make_list__(ref(ca)); // creates list<const A&>

	See __boost_ref__ for details.

	[heading adt_attribute_proxy]

	To adapt arbitrary data types that do not allow direct access to their members,
	but allow indirect access via expressions (such as invocations of get- and
	set-methods), fusion's [^BOOST\_FUSION\_ADAPT\_['xxx]ADT['xxx]]-family (e.g.
	__adapt_adt__) may be used.
	To bypass the restriction of not having actual lvalues that
	represent the elements of the fusion sequence, but rather a sequence of paired
	expressions that access the elements, the actual return type of fusion's
	intrinsic sequence access functions (__at__, __at_c__, __at_key__, __deref__,
	and __deref_data__) is a proxy type, an instance of
	`adt_attribute_proxy`, that encapsulates these expressions.

	`adt_attribute_proxy` is defined in the namespace `boost::fusion::extension` and
	has three template arguments:

	namespace boost { namespace fusion { namespace extension
	{
	template<
	typename Type
	, int Index
	, bool Const
	>
	struct adt_attribute_proxy;
	}}}

	When adapting a class type, `adt_attribute_proxy` is specialized for every
	element of the adapted sequence, with `Type` being the class type that is
	adapted, `Index` the 0-based indices of the elements, and `Const` both `true`
	and `false`. The return type of fusion's intrinsic sequence access functions
	for the ['N]th element of an adapted class type `type_name` is
	[^adt_attribute_proxy<type_name, ['N], ['Const]>], with [^['Const]] being `true`
	for constant instances of `type_name` and `false` for non-constant ones.

	[variablelist Notation
	[[`type_name`]
	[The type to be adapted, with M attributes]]
	[[`inst`]
	[Object of type `type_name`]]
	[[`const_inst`]
	[Object of type `type_name const`]]
	[[[^(attribute_type['N], attribute_const_type['N], get_expr['N], set_expr['N])]]
	[Attribute descriptor of the ['N]th attribute of `type_name` as passed to the adaption macro, 0\u2264['N]<M]]
	[[[^proxy_type['N]]]
	[[^adt_attribute_proxy<type_name, ['N], `false`>] with ['N] being an integral constant, 0\u2264['N]<M]]
	[[[^const_proxy_type['N]]]
	[[^adt_attribute_proxy<type_name, ['N], `true`>] with ['N] being an integral constant, 0\u2264['N]<M]]
	[[[^proxy['N]]]
	[Object of type [^proxy_type['N]]]]
	[[[^const_proxy['N]]]
	[Object of type [^const_proxy_type['N]]]]
	]

	[*Expression Semantics]

	[table
	[[Expression] [Semantics]]
	[[[^proxy_type['N](inst)]] [Creates an instance of [^proxy_type['N]] with underlying object `inst`]]
	[[[^const_proxy_type['N](const_inst)]] [Creates an instance of [^const_proxy_type['N]] with underlying object `const_inst`]]
	[[[^proxy_type['N]::type]] [Another name for [^attribute_type['N]]]]
	[[[^const_proxy_type['N]::type]] [Another name for [^const_attribute_type['N]]]]
	[[[^proxy['N]=t]] [Invokes [^set_expr['N]], with `t` being an arbitrary object. [^set_expr['N]] may access the variables named `obj` of type `type_name&`, which represent the corresponding instance of `type_name`, and `val` of an arbitrary const-qualified reference template type parameter `Val`, which represents `t`.]]
	[[[^proxy['N].get()]] [Invokes [^get_expr['N]] and forwards its return value. [^get_expr['N]] may access the variable named `obj` of type `type_name&` which represents the underlying instance of `type_name`. [^attribute_type['N]] may specify the type that [^get_expr['N]] denotes to.]]
	[[[^const_proxy['N].get()]] [Invokes [^get_expr['N]] and forwards its return value. [^get_expr['N]] may access the variable named `obj` of type `type_name const&` which represents the underlying instance of `type_name`. [^attribute_const_type['N]] may specify the type that [^get_expr['N]] denotes to.]]
	]

	Additionally, [^proxy_type['N]] and [^const_proxy_type['N]] are copy
	constructible, copy assignable and implicitly convertible to
	[^proxy_type['N]::type] or [^const_proxy_type['N]::type].

	[tip To avoid the pitfalls of the proxy type, an arbitrary class type may also
	be adapted directly using fusion's [link fusion.extension intrinsic extension
	mechanism].]

	[endsect]