set

Container

Summary
Data Type and Member Function Indexes
Synopsis
Description
Interface
Constructors
Destructors
Assignment Operators
Allocators
Iterators
Member Functions
Non-member Operators
Specialized Algorithms
Example
Warnings
See Also

Summary

An associative container that supports unique keys. A set supports bidirectional iterators.

Data Type and Member Function Indexes
(exclusive of constructors and destructors)

Member Functions
begin() clear() count() empty() end() equal_range()	erase() find() get_allocator() insert() key_comp() lower_bound()	max_size() operator!=() operator>() operator>=() operator<() operator<=()	operator=() operator==() rbegin() rend() size() swap() upper_bound() value_comp()

Synopsis

#include <set>
template <class Key, class Compare = less<Key>,
class Allocator = allocator<Key> >
class set ;

Description

set<Key, Compare, Allocator> is an associative container that supports unique keys and allows for fast retrieval of the keys. A set contains, at most, one of any key value. The keys are sorted using Compare.

Since a set maintains a total order on its elements, you cannot alter the key values directly. Instead, you must insert new elements with an insert_iterator.

Any type used for the template parameter Key must include the following (where T is the type, t is a value of T and u is a const value of T):

Copy constructors	`T(t)` and `T(u)`
Destructor	`t.~T()`
Address of	`&t` and `&u` yielding `T` and `const T` respectively
Assignment	`t = a` where `a` is a (possibly `const`) value of `T`

The type used for the Compare template parameter must satisfy the requirements for binary functions.

Interface

template <class Key, class Compare = less<Key>,
class Allocator = allocator<Key> >
class set {
public:
// types
typedef Key key_type;
typedef Key value_type;
typedef Compare key_compare;
typedef Compare value_compare;
typedef Allocator allocator_type;
typedef typename Allocator::reference reference;
typedef typename Allocator::const_reference const_reference;
class iterator;
class const_iterator;
typedef typename Allocator::size_type size_type;
typedef typename Allocator::difference_type difference_type;
typedef typename std::reverse_iterator<iterator>
                      reverse_iterator;
typedef typename std::reverse_iterator<const_iterator>
                      const_reverse_iterator;

// Construct/Copy/Destroy
explicit set (const Compare& = Compare(), 
              const Allocator& = Allocator ());
template <class InputIterator>
set (InputIterator, InputIterator, 
     const Compare& = Compare(),
     const Allocator& = Allocator ());
set (const set<Key, Compare, Allocator>&);
~set ();
set<Key, Compare, Allocator>& operator= 
   (const set <Key, Compare, Allocator>&);
allocator_type get_allocator () const;

// Iterators
iterator begin ();
const_iterator begin () const;
iterator end ();
const_iterator end () const;
reverse_iterator rbegin ();
const_reverse_iterator rbegin () const;
reverse_iterator rend ();
const_reverse_iterator rend () const;

// Capacity
bool empty () const;
size_type size () const;
size_type max_size () const;

// Modifiers
pair<iterator, bool> insert (const value_type&);
iterator insert (iterator, const value_type&);
template <class InputIterator>
void insert (InputIterator, InputIterator);
void erase (iterator);
size_type erase (const key_type&);
void erase (iterator, iterator);
void swap (set<Key, Compare, Allocator>&);
void clear ();


// Observers
key_compare key_comp () const;
value_compare value_comp () const;

// Set operations
size_type count (const key_type&) const;
pair<iterator, iterator> equal_range (const  key_type&) const;
iterator find (const key_type&) const;
iterator lower_bound (const key_type&) const;
iterator upper_bound (const key_type&) const
};

// Non-member Operators
template <class Key, class Compare, class Allocator>
bool operator== (const set<Key, Compare, Allocator>&,
const set<Key, Compare, Allocator>&);
template <class Key, class Compare, class Allocator>
bool operator!= (const set<Key, Compare, Allocator>&,
const set<Key, Compare, Allocator>&);
template <class Key, class Compare, class Allocator>
bool operator< (const set<Key, Compare, Allocator>&,
const set<Key, Compare, Allocator>&);
template <class Key, class Compare, class Allocator>
bool operator> (const set<Key, Compare, Allocator>&,
const set<Key, Compare, Allocator>&);
template <class Key, class Compare, class Allocator>
bool operator<= (const set<Key, Compare, Allocator>&,
const set<Key, Compare, Allocator>&);
template <class Key, class Compare, class Allocator>
bool operator>= (const set<Key, Compare, Allocator>&,
const set<Key, Compare, Allocator>&);

// Specialized Algorithms
template <class Key, class Compare, class Allocator>
void swap (set <Key, Compare, Allocator>&,
set <Key, Compare, Allocator>&);

Constructors

explicit 
set(const Compare& comp = Compare(),
const Allocator& alloc = Allocator());

Creates a set of zero elements. If the function object comp is supplied, it is used to compare elements of the set. Otherwise, the default function object in the template argument is used. The template argument defaults to less (<). The allocator alloc is used for all storage management.

template <class InputIterator>
set(InputIterator first, InputIterator last, 
const Compare& comp = Compare()
const Allocator& alloc = Allocator());

Creates a set of length last - first, filled with all values obtained by dereferencing the InputIterators on the range [first, last). If the function object comp is supplied, it is used to compare elements of the set. Otherwise, the default function object in the template argument is used. The template argument defaults to less (<). Uses the allocator Allocator() for all storage management.

set(const set<Key, Compare, Allocator>& x);

Copy constructor. Creates a copy of x.

Destructors

~set();

Releases any allocated memory for self.

Assignment Operators

set<Key, Compare, Allocator>& 
operator=(const set<Key, Compare, Allocator>& x);

Returns a reference to self. Self shares an implementation with x.

Allocators

allocator_type 
get_allocator() const;

Returns a copy of the allocator used by self for storage management.

Iterators

iterator 
begin();

Returns an iterator that points to the first element in self.

const_iterator 
begin() const;

Returns a const_iterator that points to the first element in self.

iterator 
end();

Returns an iterator that points to the past-the-end value.

const_iterator 
end() const;

Returns a const_iterator that points to the past-the-end value.

reverse_iterator 
rbegin();

Returns a reverse_iterator that points to the past-the-end value.

const_reverse_iterator 
rbegin() const;

Returns a const_reverse_iterator that points to the past-the-end value.

reverse_iterator 
rend();

Returns a reverse_iterator that points to the first element.

const_reverse_iterator 
rend() const;

Returns a const_reverse_iterator that points to the first element.

Member Functions

void
clear();

Erases all elements from the set.

size_type 
count(const key_type& x) const;

Returns the number of elements equal to x. Since a set supports unique keys, count always returns 1 or 0.

bool 
empty() const;

Returns true if the size is zero.

pair<iterator, iterator> 
equal_range(const key_type&  x) const;

Returns pair(lower_bound(x),upper_bound(x)). The equal_range function indicates the valid range for insertion of x into the set.

size_type 
erase(const key_type& x);

Deletes all the elements matching x. Returns the number of elements erased. Since a set supports unique keys, erase always returns 1 or 0.

void
erase(iterator position);

Deletes the map element pointed to by the iterator position. Returns an iterator pointing to the element following the deleted element, or end() if the deleted item was the last one in this list.

void
erase(iterator first, iterator last);

Deletes the elements in the range (first, last). Returns an iterator pointing to the element following the last deleted element, or end() if there were no elements after the deleted range.

iterator 
find(const key_value& x) const;

Returns an iterator that points to the element equal to x. If there is no such element, the iterator points to the past-the-end value.

pair<iterator, bool> 
insert(const value_type& x);

Inserts x into self according to the comparison function object. The template's default comparison function object is less (<). If the insertion succeeds, it returns a pair composed of the iterator position where the insertion took place and true. Otherwise, the pair contains the end value and false.

iterator 
insert(iterator position, const value_type& x);

x is inserted into the set. A position may be supplied as a hint regarding where to do the insertion. If the insertion is done right after position, then it takes amortized constant time. Otherwise it takes 0 (log N) time. The return value points to the inserted x.

template <class InputIterator>
void 
insert(InputIterator first, InputIterator last);

Inserts copies of the elements in the range [first, last].

key_compare 
key_comp() const;

Returns the comparison function object for the set.

iterator 
lower_bound(const key_type& x) const;

Returns an iterator that points to the first element that is greater than or equal to x. If there is no such element, the iterator points to the past-the-end value.

size_type 
max_size() const;

Returns the size of the largest possible set.

size_type 
size() const;

Returns the number of elements.

void 
swap(set<Key, Compare, Allocator>& x);

Exchanges self with x.

iterator 
upper_bound(const key_type& x) const

Returns an iterator that points to the first element that is greater than or equal to x. If there is no such element, the iterator points to the past-the-end value.

value_compare 
value_comp() const;

Returns the set's comparison object. This is identical to the function key_comp().

Non-member Operators

template <class Key, class Compare, class Allocator>
bool operator==(const set<Key, Compare, Allocator>& x,
const set<Key, Compare, Allocator>& y);

Returns true if x is the same as y.

template <class Key, class Compare, class Allocator>
bool operator!=(const set<Key, Compare, Allocator>& x,
const set<Key, Compare, Allocator>& y);

Returns !(x==y).

template <class Key, class Compare, class Allocator>
bool operator<(const set <Key, Compare, Allocator>& x,
const set <Key, Compare, Allocator>& y);

Returns true if the elements contained in x are lexicographically less than the elements contained in y.

template <class Key, class Compare, class Allocator>
bool operator>(const set <Key, Compare, Allocator>& x,
const set <Key, Compare, Allocator>& y);

Returns y < x.

template <class Key, class Compare, class Allocator>
bool operator<=(const set <Key, Compare, Allocator>& x,
const set <Key, Compare, Allocator>& y);

Returns !(y < x).

template <class Key, class Compare, class Allocator>
bool operator>=(const set <Key, Compare, Allocator>& x,
const set <Key, Compare, Allocator>& y);

Returns !(x < y).

Specialized Algorithms

template <class Key, class Compare, class Allocator>
void swap(set <Key, Compare, Allocator>& a,
set <Key, Compare, Allocator>& b);

Swaps the contents of a and b.

Example

//
// setex.cpp
//
#include <set>
#include <iostream>
 using namespace std;

typedef set<double, less<double>, allocator<double> >
        set_type;
ostream& operator<<(ostream& out, const set_type& s)
 {
copy(s.begin(), s.end(), 
     ostream_iterator<set_type::value_type,char>(cout," "));
return out;
 }

int main(void)
 {
// create a set of doubles
   set_type   sd;
   int         i;

for(i = 0; i < 10; ++i) {
// insert values
sd.insert(i);
   }

// print out the set
cout << sd << endl << endl;

// now let's erase half of the elements in the set
int half = sd.size() >> 1;
set_type::iterator sdi = sd.begin();
advance(sdi,half);
sd.erase(sd.begin(),sdi);
// print it out again
cout << sd << endl << endl;

// Make another set and an empty result set
set_type sd2, sdResult;
for (i = 1; i < 9; i++)
  sd2.insert(i+5);
cout << sd2 << endl;
// Try a couple of set algorithms
set_union(sd.begin(),sd.end(),sd2.begin(),sd2.end(),
          inserter(sdResult,sdResult.begin()));
cout << "Union:" << endl << sdResult << endl;
sdResult.erase(sdResult.begin(),sdResult.end());
set_intersection(sd.begin(),sd.end(),
                 sd2.begin(),sd2.end(),
                 inserter(sdResult,sdResult.begin()));
cout << "Intersection:" << endl << sdResult << endl;
return 0;
 }

Program Output

0 1 2 3 4 5 6 7 8 9

5 6 7 8 9

6 7 8 9 10 11 12 13
Union:
5 6 7 8 9 10 11 12 13
Intersection:
6 7 8 9

Warnings

Member function templates are used in all containers included in the Standard Template Library. An example of this feature is the constructor for set <Key, Compare, Allocator> that takes two templatized iterators:

template <class InputIterator>
set (InputIterator, InputIterator,
const Compare& = Compare(),
const Allocator& = Allocator());

set also has an insert function of this type. These functions, when not restricted by compiler limitations, allow you to use any type of input iterator as arguments. For compilers that do not support this feature, substitute functions allow you to use an iterator obtained from the same type of container as the one you are constructing (or calling a member function on), or you can use a pointer to the type of element you have in the container.

For example, if your compiler does not support member function templates, you can construct a set in the following two ways:

int intarray[10];
set<int> first_set(intarray, intarray + 10);
set<int> second_set(first_set.begin(),
first_set.end());

but not this way:

set<long> long_set(first_set.begin(),
first_set.end());

since the long_set and first_set are not the same type.

Also, many compilers do not support default template arguments. If your compiler is one of these you always need to supply the Compare template argument and the Allocator template argument. For instance, you need to write:

set<int, less<int>, allocator<int> >

instead of:

set<int>

If your compiler does not support namespaces, then you do not need the using declaration for std.

set