boost_1_45_0/libs/unordered/doc/rationale.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) ]

 [def __wang__
     [@http://www.concentric.net/~Ttwang/tech/inthash.htm
     Thomas Wang's article on integer hash functions]]

 [section:rationale Implementation Rationale]

 The intent of this library is to implement the unordered
 containers in the draft standard, so the interface was fixed. But there are
 still some implementation decisions to make. The priorities are
 conformance to the standard and portability.

 The [@http://en.wikipedia.org/wiki/Hash_table wikipedia article on hash tables]
 has a good summary of the implementation issues for hash tables in general.

 [h2 Data Structure]

 By specifying an interface for accessing the buckets of the container the
 standard pretty much requires that the hash table uses chained addressing.

 It would be conceivable to write a hash table that uses another method.  For
 example, it could use open addressing, and use the lookup chain to act as a
 bucket but there are a some serious problems with this:

 * The draft standard requires that pointers to elements aren't invalidated, so
   the elements can't be stored in one array, but will need a layer of
   indirection instead - losing the efficiency and most of the memory gain,
   the main advantages of open addressing.

 * Local iterators would be very inefficient and may not be able to
   meet the complexity requirements.

 * There are also the restrictions on when iterators can be invalidated. Since
   open addressing degrades badly when there are a high number of collisions the
   restrictions could prevent a rehash when it's really needed. The maximum load
   factor could be set to a fairly low value to work around this - but the
   standard requires that it is initially set to 1.0.

 * And since the standard is written with a eye towards chained
   addressing, users will be surprised if the performance doesn't reflect that.

 So chained addressing is used.

 For containers with unique keys I store the buckets in a single-linked list.
 There are other possible data structures (such as a double-linked list)
 that allow for some operations to be faster (such as erasing and iteration)
 but the possible gain seems small compared to the extra memory needed.
 The most commonly used operations (insertion and lookup) would not be improved
 at all.

 But for containers with equivalent keys a single-linked list can degrade badly
 when a large number of elements with equivalent keys are inserted. I think it's
 reasonable to assume that users who choose to use `unordered_multiset` or
 `unordered_multimap` do so because they are likely to insert elements with
 equivalent keys. So I have used an alternative data structure that doesn't
 degrade, at the expense of an extra pointer per node.

 This works by adding storing a circular linked list for each group of equivalent
 nodes in reverse order. This allows quick navigation to the end of a group (since
 the first element points to the last) and can be quickly updated when elements
 are inserted or erased. The main disadvantage of this approach is some hairy code
 for erasing elements.

 [h2 Number of Buckets]

 There are two popular methods for choosing the number of buckets in a hash
 table. One is to have a prime number of buckets, another is to use a power
 of 2.

 Using a prime number of buckets, and choosing a bucket by using the modulus
 of the hash function's result will usually give a good result. The downside
 is that the required modulus operation is fairly expensive.

 Using a power of 2 allows for much quicker selection of the bucket
 to use, but at the expense of loosing the upper bits of the hash value.
 For some specially designed hash functions it is possible to do this and
 still get a good result but as the containers can take arbitrary hash
 functions this can't be relied on.

 To avoid this a transformation could be applied to the hash function, for an
 example see __wang__.  Unfortunately, a transformation like Wang's requires
 knowledge of the number of bits in the hash value, so it isn't portable enough.
 This leaves more expensive methods, such as Knuth's Multiplicative Method
 (mentioned in Wang's article). These don't tend to work as well as taking the
 modulus of a prime, and the extra computation required might negate
 efficiency advantage of power of 2 hash tables.

 So, this implementation uses a prime number for the hash table size.

 [h2 Equality operators]

 `operator==` and `operator!=` are not included in the standard, but I've
 added them as I think they could be useful and can be implemented
 fairly efficiently. They are specified differently to the other standard
 containers, comparing keys using the equality predicate rather than
 `operator==`.

 It's also different to the proposal
 [@http://www.open-std.org/jtc1/sc22/wg21/docs/papers/2009/n2944.pdf n2944].
 which uses the equality operators for the whole of `value_type`. This
 implementation just uses the key equality function for the key,
 and `mapped_type`'s equality operator in `unordered_map` and
 `unordered_multimap` for the mapped part of the element.

 Also, in `unordered_multimap`, the mapped values for a group of elements with
 equivalent keys are only considered equal if they are in the same order,
 in n2944 they just need to be a permutation of each other. Since the
 order of elements with equal keys is now defined to be stable, it seems to me
 that their order can be considered part of the container's value.

 [h2 Active Issues and Proposals]

 [h3 C++0x allocators]

 Recent drafts have included an overhaul of the allocators, but this was
 dependent on concepts which are no longer in the standard.
 [@http://www.open-std.org/jtc1/sc22/wg21/docs/papers/2009/n2946.pdf n2946]
 attempts to respecify them without concepts. I'll try to implement this (or
 an appropriate later version) in a future version of boost, possibly changed
 a little to accomodate non-C++0x compilers.

 [h3 Swapping containers with unequal allocators]

 It isn't clear how to swap containers when their allocators aren't equal.
 This is
 [@http://www.open-std.org/jtc1/sc22/wg21/docs/lwg-active.html#431
 Issue 431: Swapping containers with unequal allocators]. This has been resolved
 with the new allocator specification, so this should be fixed when
 support is added.

 [h3 Are insert and erase stable for unordered_multiset and unordered_multimap?]

 It wan't specified if `unordered_multiset` and `unordered_multimap` preserve the order
 of elements with equivalent keys (i.e. if they're stable under `insert` and `erase`).
 Since [@http://www.open-std.org/jtc1/sc22/wg21/docs/papers/2008/n2691.pdf
 n2691] it's been specified that they do and this implementation follows that.

 [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) ]

	[def __wang__
	[@http://www.concentric.net/~Ttwang/tech/inthash.htm
	Thomas Wang's article on integer hash functions]]

	[section:rationale Implementation Rationale]

	The intent of this library is to implement the unordered
	containers in the draft standard, so the interface was fixed. But there are
	still some implementation decisions to make. The priorities are
	conformance to the standard and portability.

	The [@http://en.wikipedia.org/wiki/Hash_table wikipedia article on hash tables]
	has a good summary of the implementation issues for hash tables in general.

	[h2 Data Structure]

	By specifying an interface for accessing the buckets of the container the
	standard pretty much requires that the hash table uses chained addressing.

	It would be conceivable to write a hash table that uses another method. For
	example, it could use open addressing, and use the lookup chain to act as a
	bucket but there are a some serious problems with this:

	* The draft standard requires that pointers to elements aren't invalidated, so
	the elements can't be stored in one array, but will need a layer of
	indirection instead - losing the efficiency and most of the memory gain,
	the main advantages of open addressing.

	* Local iterators would be very inefficient and may not be able to
	meet the complexity requirements.

	* There are also the restrictions on when iterators can be invalidated. Since
	open addressing degrades badly when there are a high number of collisions the
	restrictions could prevent a rehash when it's really needed. The maximum load
	factor could be set to a fairly low value to work around this - but the
	standard requires that it is initially set to 1.0.

	* And since the standard is written with a eye towards chained
	addressing, users will be surprised if the performance doesn't reflect that.

	So chained addressing is used.

	For containers with unique keys I store the buckets in a single-linked list.
	There are other possible data structures (such as a double-linked list)
	that allow for some operations to be faster (such as erasing and iteration)
	but the possible gain seems small compared to the extra memory needed.
	The most commonly used operations (insertion and lookup) would not be improved
	at all.

	But for containers with equivalent keys a single-linked list can degrade badly
	when a large number of elements with equivalent keys are inserted. I think it's
	reasonable to assume that users who choose to use `unordered_multiset` or
	`unordered_multimap` do so because they are likely to insert elements with
	equivalent keys. So I have used an alternative data structure that doesn't
	degrade, at the expense of an extra pointer per node.

	This works by adding storing a circular linked list for each group of equivalent
	nodes in reverse order. This allows quick navigation to the end of a group (since
	the first element points to the last) and can be quickly updated when elements
	are inserted or erased. The main disadvantage of this approach is some hairy code
	for erasing elements.

	[h2 Number of Buckets]

	There are two popular methods for choosing the number of buckets in a hash
	table. One is to have a prime number of buckets, another is to use a power
	of 2.

	Using a prime number of buckets, and choosing a bucket by using the modulus
	of the hash function's result will usually give a good result. The downside
	is that the required modulus operation is fairly expensive.

	Using a power of 2 allows for much quicker selection of the bucket
	to use, but at the expense of loosing the upper bits of the hash value.
	For some specially designed hash functions it is possible to do this and
	still get a good result but as the containers can take arbitrary hash
	functions this can't be relied on.

	To avoid this a transformation could be applied to the hash function, for an
	example see __wang__. Unfortunately, a transformation like Wang's requires
	knowledge of the number of bits in the hash value, so it isn't portable enough.
	This leaves more expensive methods, such as Knuth's Multiplicative Method
	(mentioned in Wang's article). These don't tend to work as well as taking the
	modulus of a prime, and the extra computation required might negate
	efficiency advantage of power of 2 hash tables.

	So, this implementation uses a prime number for the hash table size.

	[h2 Equality operators]

	`operator==` and `operator!=` are not included in the standard, but I've
	added them as I think they could be useful and can be implemented
	fairly efficiently. They are specified differently to the other standard
	containers, comparing keys using the equality predicate rather than
	`operator==`.

	It's also different to the proposal
	[@http://www.open-std.org/jtc1/sc22/wg21/docs/papers/2009/n2944.pdf n2944].
	which uses the equality operators for the whole of `value_type`. This
	implementation just uses the key equality function for the key,
	and `mapped_type`'s equality operator in `unordered_map` and
	`unordered_multimap` for the mapped part of the element.

	Also, in `unordered_multimap`, the mapped values for a group of elements with
	equivalent keys are only considered equal if they are in the same order,
	in n2944 they just need to be a permutation of each other. Since the
	order of elements with equal keys is now defined to be stable, it seems to me
	that their order can be considered part of the container's value.

	[h2 Active Issues and Proposals]

	[h3 C++0x allocators]

	Recent drafts have included an overhaul of the allocators, but this was
	dependent on concepts which are no longer in the standard.
	[@http://www.open-std.org/jtc1/sc22/wg21/docs/papers/2009/n2946.pdf n2946]
	attempts to respecify them without concepts. I'll try to implement this (or
	an appropriate later version) in a future version of boost, possibly changed
	a little to accomodate non-C++0x compilers.

	[h3 Swapping containers with unequal allocators]

	It isn't clear how to swap containers when their allocators aren't equal.
	This is
	[@http://www.open-std.org/jtc1/sc22/wg21/docs/lwg-active.html#431
	Issue 431: Swapping containers with unequal allocators]. This has been resolved
	with the new allocator specification, so this should be fixed when
	support is added.

	[h3 Are insert and erase stable for unordered_multiset and unordered_multimap?]

	It wan't specified if `unordered_multiset` and `unordered_multimap` preserve the order
	of elements with equivalent keys (i.e. if they're stable under `insert` and `erase`).
	Since [@http://www.open-std.org/jtc1/sc22/wg21/docs/papers/2008/n2691.pdf
	n2691] it's been specified that they do and this implementation follows that.

	[endsect]