Table of Contents
find
with Small Secondary-to-Primary Key Ratios
find
with Large Secondary-to-Primary Key Ratios
insert
with Small
Secondary-to-Primary Key Ratios
insert
with Small
Secondary-to-Primary Key Ratios
insert
with Small
Secondary-to-Primary Key Ratios Memory Use
insert
with Small
Secondary-to-Primary Key Ratios Memory Use
This is a library of policy-based elementary data structures:
associative containers and priority queues. It is designed for
high-performance, flexibility, semantic safety, and conformance to
the corresponding containers in std
and
std::tr1
(except for some points where it differs
by design).
An attempt is made to categorize the wide variety of possible container designs in terms of performance-impacting factors. These performance factors are translated into design policies and incorporated into container design.
There is tension between unravelling factors into a coherent set of policies. Every attempt is made to make a minimal set of factors. However, in many cases multiple factors make for long template names. Every attempt is made to alias and use typedefs in the source files, but the generated names for external symbols can be large for binary files or debuggers.
In many cases, the longer names allow capabilities and behaviours controlled by macros to also be unamibiguously emitted as distinct generated names.
Specific issues found while unraveling performance factors in the design of associative containers and priority queues follow.
Associative containers depend on their composite policies to a very large extent. Implicitly hard-wiring policies can hamper their performance and limit their functionality. An efficient hash-based container, for example, requires policies for testing key equivalence, hashing keys, translating hash values into positions within the hash table, and determining when and how to resize the table internally. A tree-based container can efficiently support order statistics, i.e. the ability to query what is the order of each key within the sequence of keys in the container, but only if the container is supplied with a policy to internally update meta-data. There are many other such examples.
Ideally, all associative containers would share the same interface. Unfortunately, underlying data structures and mapping semantics differentiate between different containers. For example, suppose one writes a generic function manipulating an associative container.
template<typename Cntnr> void some_op_sequence(Cntnr& r_cnt) { ... }
Given this, then what can one assume about the instantiating
container? The answer varies according to its underlying data
structure. If the underlying data structure of
Cntnr
is based on a tree or trie, then the order
of elements is well defined; otherwise, it is not, in general. If
the underlying data structure of Cntnr
is based
on a collision-chaining hash table, then modifying
r_Cntnr
will not invalidate its iterators' order;
if the underlying data structure is a probing hash table, then this
is not the case. If the underlying data structure is based on a tree
or trie, then a reference to the container can efficiently be split;
otherwise, it cannot, in general. If the underlying data structure
is a red-black tree, then splitting a reference to the container is
exception-free; if it is an ordered-vector tree, exceptions can be
thrown.
Priority queues are useful when one needs to efficiently access a minimum (or maximum) value as the set of values changes.
Most useful data structures for priority queues have a relatively simple structure, as they are geared toward relatively simple requirements. Unfortunately, these structures do not support access to an arbitrary value, which turns out to be necessary in many algorithms. Say, decreasing an arbitrary value in a graph algorithm. Therefore, some extra mechanism is necessary and must be invented for accessing arbitrary values. There are at least two alternatives: embedding an associative container in a priority queue, or allowing cross-referencing through iterators. The first solution adds significant overhead; the second solution requires a precise definition of iterator invalidation. Which is the next point...
Priority queues, like hash-based containers, store values in an
order that is meaningless and undefined externally. For example, a
push
operation can internally reorganize the
values. Because of this characteristic, describing a priority
queues' iterator is difficult: on one hand, the values to which
iterators point can remain valid, but on the other, the logical
order of iterators can change unpredictably.
Roughly speaking, any element that is both inserted to a priority
queue (e.g. through push
) and removed
from it (e.g., through pop
), incurs a
logarithmic overhead (in the amortized sense). Different underlying
data structures place the actual cost differently: some are
optimized for amortized complexity, whereas others guarantee that
specific operations only have a constant cost. One underlying data
structure might be chosen if modifying a value is frequent
(Dijkstra's shortest-path algorithm), whereas a different one might
be chosen otherwise. Unfortunately, an array-based binary heap - an
underlying data structure that optimizes (in the amortized sense)
push
and pop
operations, differs from the
others in terms of its invalidation guarantees. Other design
decisions also impact the cost and placement of the overhead, at the
expense of more difference in the kinds of operations that the
underlying data structure can support. These differences pose a
challenge when creating a uniform interface for priority queues.
Many fine associative-container libraries were already written, most notably, the C++ standard's associative containers. Why then write another library? This section shows some possible advantages of this library, when considering the challenges in the introduction. Many of these points stem from the fact that the ISO C++ process introduced associative-containers in a two-step process (first standardizing tree-based containers, only then adding hash-based containers, which are fundamentally different), did not standardize priority queues as containers, and (in our opinion) overloads the iterator concept.
Associative containers require a relatively large number of policies to function efficiently in various settings. In some cases this is needed for making their common operations more efficient, and in other cases this allows them to support a larger set of operations
Hash-based containers, for example, support look-up and
insertion methods (find
and
insert
). In order to locate elements
quickly, they are supplied a hash functor, which instruct
how to transform a key object into some size type; a hash
functor might transform "hello"
into 1123002298
. A hash table, though,
requires transforming each key object into some size-type
type in some specific domain; a hash table with a 128-long
table might transform "hello"
into
position 63
. The policy by which the
hash value is transformed into a position within the table
can dramatically affect performance. Hash-based containers
also do not resize naturally (as opposed to tree-based
containers, for example). The appropriate resize policy is
unfortunately intertwined with the policy that transforms
hash value into a position within the table.
Tree-based containers, for example, also support look-up and insertion methods, and are primarily useful when maintaining order between elements is important. In some cases, though, one can utilize their balancing algorithms for completely different purposes.
Figure A shows a tree whose each node contains two entries: a floating-point key, and some size-type metadata (in bold beneath it) that is the number of nodes in the sub-tree. (The root has key 0.99, and has 5 nodes (including itself) in its sub-tree.) A container based on this data structure can obviously answer efficiently whether 0.3 is in the container object, but it can also answer what is the order of 0.3 among all those in the container object: see [biblio.clrs2001].
As another example, Figure B shows a tree whose each node
contains two entries: a half-open geometric line interval,
and a number metadata (in bold beneath
it) that is the largest endpoint of all intervals in its
sub-tree. (The root describes the interval [20,
36)
, and the largest endpoint in its sub-tree is
99.) A container based on this data structure can obviously
answer efficiently whether [3, 41)
is
in the container object, but it can also answer efficiently
whether the container object has intervals that intersect
[3, 41)
. These types of queries are
very useful in geometric algorithms and lease-management
algorithms.
It is important to note, however, that as the trees are modified, their internal structure changes. To maintain these invariants, one must supply some policy that is aware of these changes. Without this, it would be better to use a linked list (in itself very efficient for these purposes).
The standard C++ library contains associative containers based on red-black trees and collision-chaining hash tables. These are very useful, but they are not ideal for all types of settings.
The figure below shows the different underlying data structures currently supported in this library.
A shows a collision-chaining hash-table, B shows a probing hash-table, C shows a red-black tree, D shows a splay tree, E shows a tree based on an ordered vector(implicit in the order of the elements), F shows a PATRICIA trie, and G shows a list-based container with update policies.
Each of these data structures has some performance benefits, in terms of speed, size or both. For now, note that vector-based trees and probing hash tables manipulate memory more efficiently than red-black trees and collision-chaining hash tables, and that list-based associative containers are very useful for constructing "multimaps".
Now consider a function manipulating a generic associative container,
template<class Cntnr> int some_op_sequence(Cntnr &r_cnt) { ... }
Ideally, the underlying data structure
of Cntnr
would not affect what can be
done with r_cnt
. Unfortunately, this is not
the case.
For example, if Cntnr
is std::map
, then the function can
use
std::for_each(r_cnt.find(foo), r_cnt.find(bar), foobar)
in order to apply foobar
to all
elements between foo
and
bar
. If
Cntnr
is a hash-based container,
then this call's results are undefined.
Also, if Cntnr
is tree-based, the type
and object of the comparison functor can be
accessed. If Cntnr
is hash based, these
queries are nonsensical.
There are various other differences based on the container's underlying data structure. For one, they can be constructed by, and queried for, different policies. Furthermore:
Containers based on C, D, E and F store elements in a
meaningful order; the others store elements in a meaningless
(and probably time-varying) order. By implication, only
containers based on C, D, E and F can
support erase
operations taking an
iterator and returning an iterator to the following element
without performance loss.
Containers based on C, D, E, and F can be split and joined efficiently, while the others cannot. Containers based on C and D, furthermore, can guarantee that this is exception-free; containers based on E cannot guarantee this.
Containers based on all but E can guarantee that erasing an element is exception free; containers based on E cannot guarantee this. Containers based on all but B and E can guarantee that modifying an object of their type does not invalidate iterators or references to their elements, while containers based on B and E cannot. Containers based on C, D, and E can furthermore make a stronger guarantee, namely that modifying an object of their type does not affect the order of iterators.
A unified tag and traits system (as used for the C++ standard library iterators, for example) can ease generic manipulation of associative containers based on different underlying data structures.
Iterators are centric to the design of the standard library
containers, because of the container/algorithm/iterator
decomposition that allows an algorithm to operate on a range
through iterators of some sequence. Iterators, then, are useful
because they allow going over a
specific sequence. The standard library
also uses iterators for accessing a
specific element: when an associative
container returns one through find
. The
standard library consistently uses the same types of iterators
for both purposes: going over a range, and accessing a specific
found element. Before the introduction of hash-based containers
to the standard library, this made sense (with the exception of
priority queues, which are discussed later).
Using the standard associative containers together with non-order-preserving associative containers (and also because of priority-queues container), there is a possible need for different types of iterators for self-organizing containers: the iterator concept seems overloaded to mean two different things (in some cases).
Suppose cntnr
is some associative
container, and say c
is an object of
type cntnr
. Then what will be the outcome
of
std::for_each(c.find(1), c.find(5), foo);
If cntnr
is a tree-based container
object, then an in-order walk will
apply foo
to the relevant elements,
as in the graphic below, label A. If c
is
a hash-based container, then the order of elements between any
two elements is undefined (and probably time-varying); there is
no guarantee that the elements traversed will coincide with the
logical elements between 1 and 5, as in
label B.
In our opinion, this problem is not caused just because
red-black trees are order preserving while
collision-chaining hash tables are (generally) not - it
is more fundamental. Most of the standard's containers
order sequences in a well-defined manner that is
determined by their interface:
calling insert
on a tree-based
container modifies its sequence in a predictable way, as
does calling push_back
on a list or
a vector. Conversely, collision-chaining hash tables,
probing hash tables, priority queues, and list-based
containers (which are very useful for "multimaps") are
self-organizing data structures; the effect of each
operation modifies their sequences in a manner that is
(practically) determined by their
implementation.
Consequently, applying an algorithm to a sequence obtained from most containers may or may not make sense, but applying it to a sub-sequence of a self-organizing container does not.
Suppose c
is some collision-chaining
hash-based container object, and one calls
c.find(3)
Then what composes the returned iterator?
In the graphic below, label A shows the simplest (and
most efficient) implementation of a collision-chaining
hash table. The little box marked
point_iterator
shows an object
that contains a pointer to the element's node. Note that
this "iterator" has no way to move to the next element (
it cannot support
operator++
). Conversely, the little
box marked iterator
stores both a
pointer to the element, as well as some other
information (the bucket number of the element). the
second iterator, then, is "heavier" than the first one-
it requires more time and space. If we were to use a
different container to cross-reference into this
hash-table using these iterators - it would take much
more space. As noted above, nothing much can be done by
incrementing these iterators, so why is this extra
information needed?
Alternatively, one might create a collision-chaining hash-table where the lists might be linked, forming a monolithic total-element list, as in the graphic below, label B. Here the iterators are as light as can be, but the hash-table's operations are more complicated.
It should be noted that containers based on collision-chaining hash-tables are not the only ones with this type of behavior; many other self-organizing data structures display it as well.
Consider the following snippet:
it = c.find(3); c.erase(5);
Following the call to erase
, what is the
validity of it
: can it be de-referenced?
can it be incremented?
The answer depends on the underlying data structure of the container. The graphic below shows three cases: A1 and A2 show a red-black tree; B1 and B2 show a probing hash-table; C1 and C2 show a collision-chaining hash table.
Erasing 5 from A1 yields A2. Clearly, an iterator to 3 can be de-referenced and incremented. The sequence of iterators changed, but in a way that is well-defined by the interface.
Erasing 5 from B1 yields B2. Clearly, an iterator to 3 is not valid at all - it cannot be de-referenced or incremented; the order of iterators changed in a way that is (practically) determined by the implementation and not by the interface.
Erasing 5 from C1 yields C2. Here the situation is more
complicated. On the one hand, there is no problem in
de-referencing it
. On the other hand,
the order of iterators changed in a way that is
(practically) determined by the implementation and not by
the interface.
So in the standard library containers, it is not always possible
to express whether it
is valid or not. This
is true also for insert
. Again, the
iterator concept seems overloaded.
The design of the functional overlay to the underlying data structures differs slightly from some of the conventions used in the C++ standard. A strict public interface of methods that comprise only operations which depend on the class's internal structure; other operations are best designed as external functions. (See [biblio.meyers02both]).With this rubric, the standard associative containers lack some useful methods, and provide other methods which would be better removed.
Order-preserving standard associative containers provide the method
iterator erase(iterator it)
which takes an iterator, erases the corresponding element, and returns an iterator to the following element. Also standardd hash-based associative containers provide this method. This seemingly increasesgenericity between associative containers, since it is possible to use
typename C::iterator it = c.begin(); typename C::iterator e_it = c.end(); while(it != e_it) it = pred(*it)? c.erase(it) : ++it;
in order to erase from a container object
c
all element which match a
predicate pred
. However, in a
different sense this actually decreases genericity: an
integral implication of this method is that tree-based
associative containers' memory use is linear in the total
number of elements they store, while hash-based
containers' memory use is unbounded in the total number of
elements they store. Assume a hash-based container is
allowed to decrease its size when an element is
erased. Then the elements might be rehashed, which means
that there is no "next" element - it is simply
undefined. Consequently, it is possible to infer from the
fact that the standard library's hash-based containers
provide this method that they cannot downsize when
elements are erased. As a consequence, different code is
needed to manipulate different containers, assuming that
memory should be conserved. Therefor, this library's
non-order preserving associative containers omit this
method.
All associative containers include a conditional-erase method
template< class Pred> size_type erase_if (Pred pred)
which erases all elements matching a predicate. This is probably the only way to ensure linear-time multiple-item erase which can actually downsize a container.
The standard associative containers provide methods for multiple-item erase of the form
size_type erase(It b, It e)
erasing a range of elements given by a pair of
iterators. For tree-based or trie-based containers, this can
implemented more efficiently as a (small) sequence of split
and join operations. For other, unordered, containers, this
method isn't much better than an external loop. Moreover,
if c
is a hash-based container,
then
c.erase(c.find(2), c.find(5))
is almost certain to do something different than erasing all elements whose keys are between 2 and 5, and is likely to produce other undefined behavior.
It is well-known that tree-based and trie-based container objects can be efficiently split or joined (See [biblio.clrs2001]). Externally splitting or joining trees is super-linear, and, furthermore, can throw exceptions. Split and join methods, consequently, seem good choices for tree-based container methods, especially, since as noted just before, they are efficient replacements for erasing sub-sequences.
The standard associative containers provide methods of the form
template<class It> size_type insert(It b, It e);
for inserting a range of elements given by a pair of iterators. At best, this can be implemented as an external loop, or, even more efficiently, as a join operation (for the case of tree-based or trie-based containers). Moreover, these methods seem similar to constructors taking a range given by a pair of iterators; the constructors, however, are transactional, whereas the insert methods are not; this is possibly confusing.
Associative containers are parametrized by policies allowing to
test key equivalence: a hash-based container can do this through
its equivalence functor, and a tree-based container can do this
through its comparison functor. In addition, some standard
associative containers have global function operators, like
operator==
and operator<=
,
that allow comparing entire associative containers.
In our opinion, these functions are better left out. To begin
with, they do not significantly improve over an external
loop. More importantly, however, they are possibly misleading -
operator==
, for example, usually checks for
equivalence, or interchangeability, but the associative
container cannot check for values' equivalence, only keys'
equivalence; also, are two containers considered equivalent if
they store the same values in different order? this is an
arbitrary decision.
Priority queues are containers that allow efficiently inserting
values and accessing the maximal value (in the sense of the
container's comparison functor). Their interface
supports push
and pop
. The standard
container std::priorityqueue
indeed support
these methods, but little else. For algorithmic and
software-engineering purposes, other methods are needed:
Many graph algorithms (see [biblio.clrs2001]) require increasing a value in a priority queue (again, in the sense of the container's comparison functor), or joining two priority-queue objects.
The return type of priority_queue
's
push
method is a point-type iterator, which can
be used for modifying or erasing arbitrary values. For
example:
priority_queue<int> p; priority_queue<int>::point_iterator it = p.push(3); p.modify(it, 4);
These types of cross-referencing operations are necessary for making priority queues useful for different applications, especially graph applications.
It is sometimes necessary to erase an arbitrary value in a
priority queue. For example, consider
the select
function for monitoring
file descriptors:
int select(int nfds, fd_set *readfds, fd_set *writefds, fd_set *errorfds, struct timeval *timeout);
then, as the select documentation states:
“ The nfds argument specifies the range of file descriptors to be tested. The select() function tests file descriptors in the range of 0 to nfds-1.”
It stands to reason, therefore, that we might wish to
maintain a minimal value for nfds
, and
priority queues immediately come to mind. Note, though, that
when a socket is closed, the minimal file description might
change; in the absence of an efficient means to erase an
arbitrary value from a priority queue, we might as well
avoid its use altogether.
The standard containers typically support iterators. It is
somewhat unusual
for std::priority_queue
to omit them
(See [biblio.meyers01stl]). One might
ask why do priority queues need to support iterators, since
they are self-organizing containers with a different purpose
than abstracting sequences. There are several reasons:
Iterators (even in self-organizing containers) are useful for many purposes: cross-referencing containers, serialization, and debugging code that uses these containers.
The standard library's hash-based containers support iterators, even though they too are self-organizing containers with a different purpose than abstracting sequences.
In standard-library-like containers, it is natural to specify the
interface of operations for modifying a value or erasing
a value (discussed previously) in terms of a iterators.
It should be noted that the standard
containers also use iterators for accessing and
manipulating a specific value. In hash-based
containers, one checks the existence of a key by
comparing the iterator returned by find
to the
iterator returned by end
, and not by comparing a
pointer returned by find
to NULL.
There are three main implementations of priority queues: the first employs a binary heap, typically one which uses a sequence; the second uses a tree (or forest of trees), which is typically less structured than an associative container's tree; the third simply uses an associative container. These are shown in the figure below with labels A1 and A2, B, and C.
No single implementation can completely replace any of the
others. Some have better push
and pop
amortized performance, some have
better bounded (worst case) response time than others, some
optimize a single method at the expense of others, etc. In
general the "best" implementation is dictated by the specific
problem.
As with associative containers, the more implementations co-exist, the more necessary a traits mechanism is for handling generic containers safely and efficiently. This is especially important for priority queues, since the invalidation guarantees of one of the most useful data structures - binary heaps - is markedly different than those of most of the others.
Binary heaps are one of the most useful underlying
data structures for priority queues. They are very efficient in
terms of memory (since they don't require per-value structure
metadata), and have the best amortized push
and
pop
performance for primitive types like
int.
The standard library's priority_queue
implements this data structure as an adapter over a sequence,
typically
std::vector
or std::deque
, which correspond to labels
A1 and A2 respectively in the graphic above.
This is indeed an elegant example of the adapter concept and the algorithm/container/iterator decomposition. (See [biblio.nelson96stlpq]). There are several reasons why a binary-heap priority queue may be better implemented as a container instead of a sequence adapter:
std::priority_queue
cannot erase values
from its adapted sequence (irrespective of the sequence
type). This means that the memory use of
an std::priority_queue
object is always
proportional to the maximal number of values it ever contained,
and not to the number of values that it currently
contains. (See performance/priority_queue_text_pop_mem_usage.cc
.)
This implementation of binary heaps acts very differently than
other underlying data structures (See also pairing heaps).
Some combinations of adapted sequences and value types
are very inefficient or just don't make sense. If one uses
std::priority_queue<std::vector<std::string>
> >
, for example, then not only will each
operation perform a logarithmic number of
std::string
assignments, but, furthermore, any
operation (including pop
) can render the container
useless due to exceptions. Conversely, if one uses
std::priority_queue<std::deque<int> >
>
, then each operation uses incurs a logarithmic
number of indirect accesses (through pointers) unnecessarily.
It might be better to let the container make a conservative
deduction whether to use the structure in the graphic above, labels A1 or A2.
There does not seem to be a systematic way to determine what exactly can be done with the priority queue.
If p
is a priority queue adapting an
std::vector
, then it is possible to iterate over
all values by using &p.top()
and
&p.top() + p.size()
, but this will not work
if p
is adapting an std::deque
; in any
case, one cannot use p.begin()
and
p.end()
. If a different sequence is adapted, it
is even more difficult to determine what can be
done.
If p
is a priority queue adapting an
std::deque
, then the reference return by
p.top()
will remain valid until it is popped,
but if p
adapts an std::vector
, the
next push
will invalidate it. If a different
sequence is adapted, it is even more difficult to
determine what can be done.
Sequence-based binary heaps can still implement
linear-time erase
and modify
operations.
This means that if one needs to erase a small
(say logarithmic) number of values, then one might still
choose this underlying data structure. Using
std::priority_queue
, however, this will generally
change the order of growth of the entire sequence of
operations.
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