boost_1_45_0/libs/unordered/doc/buckets.qbk - nest-learning-thermostat/5.0/boost - Git at Google

 [/ Copyright 2006-2008 Daniel James.
  / 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) ]

 [section:buckets The Data Structure]

 The containers are made up of a number of 'buckets', each of which can contain
 any number of elements. For example, the following diagram shows an [classref
 boost::unordered_set unordered_set] with 7 buckets containing 5 elements, `A`,
 `B`, `C`, `D` and `E` (this is just for illustration, containers will typically
 have more buckets).

 [diagram buckets]

 In order to decide which bucket to place an element in, the container applies
 the hash function, `Hash`, to the element's key (for `unordered_set` and
 `unordered_multiset` the key is the whole element, but is referred to as the key
 so that the same terminology can be used for sets and maps). This returns a
 value of type `std::size_t`.  `std::size_t` has a much greater range of values
 then the number of buckets, so that container applies another transformation to
 that value to choose a bucket to place the element in.

 Retrieving the elements for a given key is simple. The same process is applied
 to the key to find the correct bucket. Then the key is compared with the
 elements in the bucket to find any elements that match (using the equality
 predicate `Pred`).  If the hash function has worked well the elements will be
 evenly distributed amongst the buckets so only a small number of elements will
 need to be examined.

 There is [link unordered.hash_equality more information on hash functions and
 equality predicates in the next section].

 You can see in the diagram that `A` & `D` have been placed in the same bucket.
 When looking for elements in this bucket up to 2 comparisons are made, making
 the search slower. This is known as a collision. To keep things fast we try to
 keep collisions to a minimum.

 '''
 <table frame="all"><title>Methods for Accessing Buckets</title>
   <tgroup cols="2">
     <thead><row>
       <entry><para>Method</para></entry>
       <entry><para>Description</para></entry>
     </row></thead>
     <tbody>
       <row>
        <entry>'''`size_type bucket_count() const`'''</entry>
        <entry>'''The number of buckets.'''</entry>
       </row>
       <row>
         <entry>'''`size_type max_bucket_count() const`'''</entry>
         <entry>'''An upper bound on the number of buckets.'''</entry>
       </row>
       <row>
         <entry>'''`size_type bucket_size(size_type n) const`'''</entry>
         <entry>'''The number of elements in bucket `n`.'''</entry>
       </row>
       <row>
         <entry>'''`size_type bucket(key_type const& k) const`'''</entry>
         <entry>'''Returns the index of the bucket which would contain k'''</entry>
       </row>
       <row>
         <entry>'''`local_iterator begin(size_type n);`'''</entry>
         <entry morerows='5'>'''Return begin and end iterators for bucket `n`.'''</entry>
       </row>
       <row>
         <entry>'''`local_iterator end(size_type n);`'''</entry>
       </row>
       <row>
         <entry>'''`const_local_iterator begin(size_type n) const;`'''</entry>
       </row>
       <row>
         <entry>'''`const_local_iterator end(size_type n) const;`'''</entry>
       </row>
       <row>
         <entry>'''`const_local_iterator cbegin(size_type n) const;`'''</entry>
       </row>
       <row>
         <entry>'''`const_local_iterator cend(size_type n) const;`'''</entry>
       </row>
     </tbody>
   </tgroup>
 </table>
 '''

 [h2 Controlling the number of buckets]

 As more elements are added to an unordered associative container, the number
 of elements in the buckets will increase causing performance to degrade.
 To combat this the containers increase the bucket count as elements are inserted.
 You can also tell the container to change the bucket count (if required) by
 calling `rehash`.

 The standard leaves a lot of freedom to the implementer to decide how the
 number of buckets are chosen, but it does make some requirements based on the
 container's 'load factor', the average number of elements per bucket.
 Containers also have a 'maximum load factor' which they should try to keep the
 load factor below.

 You can't control the bucket count directly but there are two ways to
 influence it:

 * Specify the minimum number of buckets when constructing a container or
   when calling `rehash`.
 * Suggest a maximum load factor by calling `max_load_factor`.

 `max_load_factor` doesn't let you set the maximum load factor yourself, it just
 lets you give a /hint/.  And even then, the draft standard doesn't actually
 require the container to pay much attention to this value. The only time the
 load factor is /required/ to be less than the maximum is following a call to
 `rehash`. But most implementations will try to keep the number of elements
 below the max load factor, and set the maximum load factor to be the same as
 or close to the hint - unless your hint is unreasonably small or large.

 [table Methods for Controlling Bucket Size
     [[Method] [Description]]

     [
         [`X(size_type n)`]
         [Construct an empty container with at least `n` buckets (`X` is the container type).]
     ]
     [
         [`X(InputIterator i, InputIterator j, size_type n)`]
         [Construct an empty container with at least `n` buckets and insert elements
          from the range \[`i`, `j`) (`X` is the container type).]
     ]
     [
         [`float load_factor() const`]
         [The average number of elements per bucket.]
     ]
     [
         [`float max_load_factor() const`]
         [Returns the current maximum load factor.]
     ]
     [
         [`float max_load_factor(float z)`]
         [Changes the container's maximum load factor, using `z` as a hint.]
     ]
     [
         [`void rehash(size_type n)`]
         [Changes the number of buckets so that there at least n buckets, and
         so that the load factor is less than the maximum load factor.]
     ]

 ]

 [h2 Iterator Invalidation]

 It is not specified how member functions other than `rehash` affect
 the bucket count, although `insert` is only allowed to invalidate iterators
 when the insertion causes the load factor to be greater than or equal to the
 maximum load factor. For most implementations this means that insert will only
 change the number of buckets when this happens. While iterators can be
 invalidated by calls to `insert` and `rehash`, pointers and references to the
 container's elements are never invalidated.

 In a similar manner to using `reserve` for `vector`s, it can be a good idea
 to call `rehash` before inserting a large number of elements. This will get
 the expensive rehashing out of the way and let you store iterators, safe in
 the knowledge that they won't be invalidated. If you are inserting `n`
 elements into container `x`, you could first call:

     x.rehash((x.size() + n) / x.max_load_factor() + 1);

 [blurb Note: `rehash`'s argument is the minimum number of buckets, not the
 number of elements, which is why the new size is divided by the maximum load factor.  The
 `+ 1` guarantees there is no invalidation; without it, reallocation could occur
 if the number of bucket exactly divides the target size, since the container is
 allowed to rehash when the load factor is equal to the maximum load factor.]

 [endsect]
	[/ Copyright 2006-2008 Daniel James.
	/ 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) ]

	[section:buckets The Data Structure]

	The containers are made up of a number of 'buckets', each of which can contain
	any number of elements. For example, the following diagram shows an [classref
	boost::unordered_set unordered_set] with 7 buckets containing 5 elements, `A`,
	`B`, `C`, `D` and `E` (this is just for illustration, containers will typically
	have more buckets).

	[diagram buckets]

	In order to decide which bucket to place an element in, the container applies
	the hash function, `Hash`, to the element's key (for `unordered_set` and
	`unordered_multiset` the key is the whole element, but is referred to as the key
	so that the same terminology can be used for sets and maps). This returns a
	value of type `std::size_t`. `std::size_t` has a much greater range of values
	then the number of buckets, so that container applies another transformation to
	that value to choose a bucket to place the element in.

	Retrieving the elements for a given key is simple. The same process is applied
	to the key to find the correct bucket. Then the key is compared with the
	elements in the bucket to find any elements that match (using the equality
	predicate `Pred`). If the hash function has worked well the elements will be
	evenly distributed amongst the buckets so only a small number of elements will
	need to be examined.

	There is [link unordered.hash_equality more information on hash functions and
	equality predicates in the next section].

	You can see in the diagram that `A` & `D` have been placed in the same bucket.
	When looking for elements in this bucket up to 2 comparisons are made, making
	the search slower. This is known as a collision. To keep things fast we try to
	keep collisions to a minimum.

	'''
	<table frame="all"><title>Methods for Accessing Buckets</title>
	<tgroup cols="2">
	<thead><row>
	<entry><para>Method</para></entry>
	<entry><para>Description</para></entry>
	</row></thead>
	<tbody>
	<row>
	<entry>'''`size_type bucket_count() const`'''</entry>
	<entry>'''The number of buckets.'''</entry>
	</row>
	<row>
	<entry>'''`size_type max_bucket_count() const`'''</entry>
	<entry>'''An upper bound on the number of buckets.'''</entry>
	</row>
	<row>
	<entry>'''`size_type bucket_size(size_type n) const`'''</entry>
	<entry>'''The number of elements in bucket `n`.'''</entry>
	</row>
	<row>
	<entry>'''`size_type bucket(key_type const& k) const`'''</entry>
	<entry>'''Returns the index of the bucket which would contain k'''</entry>
	</row>
	<row>
	<entry>'''`local_iterator begin(size_type n);`'''</entry>
	<entry morerows='5'>'''Return begin and end iterators for bucket `n`.'''</entry>
	</row>
	<row>
	<entry>'''`local_iterator end(size_type n);`'''</entry>
	</row>
	<row>
	<entry>'''`const_local_iterator begin(size_type n) const;`'''</entry>
	</row>
	<row>
	<entry>'''`const_local_iterator end(size_type n) const;`'''</entry>
	</row>
	<row>
	<entry>'''`const_local_iterator cbegin(size_type n) const;`'''</entry>
	</row>
	<row>
	<entry>'''`const_local_iterator cend(size_type n) const;`'''</entry>
	</row>
	</tbody>
	</tgroup>
	</table>
	'''

	[h2 Controlling the number of buckets]

	As more elements are added to an unordered associative container, the number
	of elements in the buckets will increase causing performance to degrade.
	To combat this the containers increase the bucket count as elements are inserted.
	You can also tell the container to change the bucket count (if required) by
	calling `rehash`.

	The standard leaves a lot of freedom to the implementer to decide how the
	number of buckets are chosen, but it does make some requirements based on the
	container's 'load factor', the average number of elements per bucket.
	Containers also have a 'maximum load factor' which they should try to keep the
	load factor below.

	You can't control the bucket count directly but there are two ways to
	influence it:

	* Specify the minimum number of buckets when constructing a container or
	when calling `rehash`.
	* Suggest a maximum load factor by calling `max_load_factor`.

	`max_load_factor` doesn't let you set the maximum load factor yourself, it just
	lets you give a /hint/. And even then, the draft standard doesn't actually
	require the container to pay much attention to this value. The only time the
	load factor is /required/ to be less than the maximum is following a call to
	`rehash`. But most implementations will try to keep the number of elements
	below the max load factor, and set the maximum load factor to be the same as
	or close to the hint - unless your hint is unreasonably small or large.

	[table Methods for Controlling Bucket Size
	[[Method] [Description]]

	[
	[`X(size_type n)`]
	[Construct an empty container with at least `n` buckets (`X` is the container type).]
	]
	[
	[`X(InputIterator i, InputIterator j, size_type n)`]
	[Construct an empty container with at least `n` buckets and insert elements
	from the range \[`i`, `j`) (`X` is the container type).]
	]
	[
	[`float load_factor() const`]
	[The average number of elements per bucket.]
	]
	[
	[`float max_load_factor() const`]
	[Returns the current maximum load factor.]
	]
	[
	[`float max_load_factor(float z)`]
	[Changes the container's maximum load factor, using `z` as a hint.]
	]
	[
	[`void rehash(size_type n)`]
	[Changes the number of buckets so that there at least n buckets, and
	so that the load factor is less than the maximum load factor.]
	]

	]

	[h2 Iterator Invalidation]

	It is not specified how member functions other than `rehash` affect
	the bucket count, although `insert` is only allowed to invalidate iterators
	when the insertion causes the load factor to be greater than or equal to the
	maximum load factor. For most implementations this means that insert will only
	change the number of buckets when this happens. While iterators can be
	invalidated by calls to `insert` and `rehash`, pointers and references to the
	container's elements are never invalidated.

	In a similar manner to using `reserve` for `vector`s, it can be a good idea
	to call `rehash` before inserting a large number of elements. This will get
	the expensive rehashing out of the way and let you store iterators, safe in
	the knowledge that they won't be invalidated. If you are inserting `n`
	elements into container `x`, you could first call:

	x.rehash((x.size() + n) / x.max_load_factor() + 1);

	[blurb Note: `rehash`'s argument is the minimum number of buckets, not the
	number of elements, which is why the new size is divided by the maximum load factor. The
	`+ 1` guarantees there is no invalidation; without it, reallocation could occur
	if the number of bucket exactly divides the target size, since the container is
	allowed to rehash when the load factor is equal to the maximum load factor.]

	[endsect]