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Comparison operators

Compares the arguments.

Operator name Syntax Over​load​able Prototype examples (for class T)
As member function As free (namespace) function
equal to a == b Yes bool T::operator ==(const T2 &b) const; bool operator ==(const T &a, const T2 &b);
not equal to a != b Yes bool T::operator !=(const T2 &b) const; bool operator !=(const T &a, const T2 &b);
less than a < b Yes bool T::operator <(const T2 &b) const; bool operator <(const T &a, const T2 &b);
greater than a > b Yes bool T::operator >(const T2 &b) const; bool operator >(const T &a, const T2 &b);
less than or equal to a <= b Yes bool T::operator <=(const T2 &b) const; bool operator <=(const T &a, const T2 &b);
greater than or equal to a >= b Yes bool T::operator >=(const T2 &b) const; bool operator >=(const T &a, const T2 &b);
three-way comparison (C++20) a <=> b Yes /*see description*/ T::operator <=>(const T2 &b) const; /*see description*/ operator <=>(const T &a, const T2 &b);
Notes
  • Where built-in operators return bool, most user-defined overloads also return bool so that the user-defined operators can be used in the same manner as the built-ins. However, in a user-defined operator overload, any type can be used as return type (including void).
  • T2 can be any type including T

Two-way comparison

The two-way comparison operator expressions have the form.

lhs < rhs (1)
lhs > rhs (2)
lhs <= rhs (3)
lhs >= rhs (4)
lhs == rhs (5)
lhs != rhs (6)
1) Returns true if lhs is less than rhs, false otherwise.
2) Returns true if lhs is greater than rhs, false otherwise.
3) Returns true if lhs is less than or equal to rhs, false otherwise.
4) Returns true if lhs is greater than or equal to rhs, false otherwise.
5) Returns true if lhs is equal to rhs, false otherwise.
6) Returns true if lhs is not equal to rhs, false otherwise.

In all cases, for the built-in operators, lhs and rhs must have either.

  • arithmetic or enumeration type (see arithmetic comparison operators below)
  • pointer type (see pointer comparison operators below)

after the application of the lvalue-to-rvalue, array-to-pointer and function-to-pointer standard conversions. The comparison is deprecated if both operands have array type prior to the application of these conversions. (since C++20).

In any case, the result is a bool prvalue.

Arithmetic comparison operators

If the operands has arithmetic or enumeration type (scoped or unscoped), usual arithmetic conversions are performed on both operands following the rules for arithmetic operators. The values are compared after conversions:

Example

#include <iostream>
int main()
{
    std::cout << std::boolalpha;
    int n = -1;
 
    int n2 = 1;
    std::cout << " -1 == 1? " << (n == n2) << '\n'
              << "Comparing two signed values:\n"
              << " -1  < 1? " << (n < n2) << '\n'
              << " -1  > 1? " << (n > n2) << '\n';
 
    unsigned int u = 1;
    std::cout << "Comparing signed and unsigned:\n"
              << " -1  < 1? " << (n < u) << '\n'
              << " -1  > 1? " << (n > u) << '\n';
 
    unsigned char uc = 1;
    std::cout << "Comparing signed and smaller unsigned:\n"
              << " -1  < 1? " << (n < uc) << '\n'
              << " -1  > 1? " << (n > uc) << '\n';
}

Output:

 -1 == 1? false
Comparing two signed values:
 -1  < 1? true
 -1  > 1? false
Comparing signed and unsigned:
 -1  < 1? false
 -1  > 1? true
Comparing signed and smaller unsigned:
 -1  < 1? true
 -1  > 1? false

Pointer comparison operators

Comparison operators can be used to compare two pointers (or pointers-to-members, for operator== and operator!= only), or a pointer to member (since C++14) and a null pointer constant, or two null pointer constants (but only as long as at least one of them is std::nullptr_t: comparison of NULL and NULL follows arithmetic comparison rules) (until C++14).

First, Pointer conversions (pointer to member conversions if the arguments are pointers to members), function pointer conversions, (since C++17) and qualification conversions are applied to both operands to obtain the composite pointer type, as follows.

1) If both operands are null pointer constants, the composite pointer type is std::nullptr_t
2) If one operand is a null pointer constant, and the other is a pointer, the composite type is exactly the pointer type
3) If one operand is pointer to cv1 void and the other is a pointer to cv2 T for some type T, where T is an object type or void, the composite type is "pointer to cv12 void", where cv12 is the union of cv1 and cv2
4) If both operands are pointers to the same type, with different cv-qualification, the composite is pointer to the same type with cv-qualification that is a union of the cv-qualifications of the arguments. (until C++14)
4) If the types of the operands are P1, a pointer to (possibly cv-qualified) T1, and P2, a pointer to (possibly cv-qualified) T2, and if T1 is the same as T2 or is a base class of T2, then the composite pointer type is the cv-combined type of P1 and P2. Otherwise, if T2 is a base class of T1, then the composite pointer type is the cv-combined type of P2 and P1. 5) If the types of the operands are MP1, pointer to member of T1 of type (possibly cv-qualified) U1 and MP2, pointer to member of T2 of type (possibly cv-qualified) U2, and if T1 is the same as or derived from T2, then the composite pointer type is the cv-combined type of MP1 and MP2. Otherwise, if T2 is derived from T1, then the composite pointer type is the cv-combined type of MP2 and MP1. 6) if the types of the operands P1 and P2 are multi-level mixed pointer and pointer to member types with the same number of levels that only differ by cv-qualifications at any of the levels, the composite pointer type is the cv-combined type of P1 and P2

In the definition above, cv-combined type of two pointer types P1 and P2 is a type P3 that has the same number of levels and type at every level as P1, except that cv-qualifications at every level are set as follows:

a) at every level other than top level, the union of the cv-qualifications of P1 and P2 at that level b) if the resulting cv-qualification at any level is different from P1's or P2's cv-qualification at the same level, then const is added to every level between the top level and this one.

For example, the composite pointer type of void* and const int* is const void*. The composite pointer type of int** and const int** is const int* const*. Note that until C++14, int** and const int** could not be compared.

(since C++14)

In addition to the above, the composite pointer type between pointer to function and pointer to noexcept function (as long as the function type is the same) is pointer to function.

(since C++17)

Note that this implies that any pointer can be compared with void*.

The result of comparing two pointers to objects (after conversions) is defined as follows:

1) If two pointers point to different elements of the same array, or to subobjects within different elements of the same array, the pointer to the element with the higher subscript compares greater. In other words, they results of comparing the pointers is the same as the result of comparing the indexes of the elements they point to.
2) If one pointer points to an element of an array, or to a subobject of the element of the array, and another pointer points one past the last element of the array, the latter pointer compares greater. Pointers to single objects are treated as pointers to arrays of one: &obj+1 compares greater than &obj (since C++17)
3) If, within an object of non-union class type, two pointers point to different non-static data members with the same member access, or to subobjects or array elements of such members, recursively, the pointer to the later declared member compares greater. In other words, class members in each of the three member access modes are positioned in memory in order of declaration.

The result of equality comparison of two pointers (after conversions) is defined as follows:

1) If the pointers are both null pointer values, they compare equal
2) If the pointers are pointers to function and point to the same function, then compare equal
3) If the pointers are pointers to object and represent the same address, they compare equal (this includes two pointers to non-static members of the same union, pointers to standard-layout struct and to its first member, pointers related by reinterpret_cast, etc)
4) All other pointers compare unequal

The result of comparing two pointers to members (after conversions) is defined as follows:

1) If both pointers to member are null member pointer values, they compare equal.
2) Otherwise, if only one of two pointers to member is the null member pointer value, they compare unequal.
3) Otherwise, if either is a pointer to a virtual member function, the result is unspecified.
4) Otherwise, two pointers to member compare equal if and only if they would refer to the same member of the same most derived object or the same subobject if they were dereferenced with a hypothetical object of the associated class type
5) Otherwise they compare unequal.

If a pointer p compare equal to pointer q, p<=q and p>=q both yield true and p<q and p>q both yield false.

If a pointer p compares greater than a pointer q, then p>=q, p>q, q<=p, and q<p all yield true and p<=q, p<q, q>=p, and q>p all yield false.

If two pointers are not specified to compare greater or compare equal, the result of the comparison is unspecified. The result may be nondeterministic, and need not be consistent even for multiple evaluations of the same expression with the same operands in the same execution of the program:

int x, y;
 
bool f(int* p, int* q) { return p < q; }
 
assert(f(&x, &y) == f(&x, &y)); // may fire in a conforming implementation

In overload resolution against user-defined operators, for every pair of promoted arithmetic types L and R, including enumeration types, the following function signatures participate in overload resolution:

bool operator<(L, R);
bool operator>(L, R);
bool operator<=(L, R);
bool operator>=(L, R);
bool operator==(L, R);
bool operator!=(L, R);

For every type P which is either pointer to object or pointer to function or std::nullptr_t (until C++14), the following function signatures participate in overload resolution:

bool operator<(P, P);
bool operator>(P, P);
bool operator<=(P, P);
bool operator>=(P, P);
bool operator==(P, P);
bool operator!=(P, P);

For every type MP that is a pointer to member object or pointer to member function or std::nullptr_t, the following function signatures participate in overload resolution:

bool operator==(MP, MP);
bool operator!=(MP, MP);

Example

#include <iostream>
struct Foo  { int n1; int n2; };
union Union { int n; double d; };
int main()
{
    std::cout << std::boolalpha;
 
    char a[4] = "abc";
 
    char* p1 = &a[1];
    char* p2 = &a[2];
    std::cout << "Pointers to array elements: p1 == p2 " << (p1 == p2)
              << ", p1 < p2 "  << (p1 < p2) << '\n';
 
    Foo f;
    int* p3 = &f.n1;
    int* p4 = &f.n2;
    std::cout << "Pointers to members of a class: p3 == p4 " << (p3 == p4)
              << ", p3 < p4 "  << (p3 < p4) << '\n';
 
    Union u;
    int* p5 = &u.n;
    double* p6 = &u.d;
    std::cout << "Pointers to members of a union: p5 == (void*)p6 " << (p5 == (void*)p6)
              << ", p5 < p6 "  << (p5 < (void*)p6) << '\n';
}

Output:

Pointers to array elements: p1 == p2 false, p1 < p2 true
Pointers to members of a class: p3 == p4 false, p3 < p4 true
Pointers to members of a union: p5 == (void*)p6 true, p5 < p6 false

Notes

Because these operators group left-to-right, the expression a<b<c is parsed (a<b)<c, and not a<(b<c) or (a<b)&&(b<c).

A common requirement for user-defined operator< is strict weak ordering. In particular, this is required by the standard algorithms and containers that work with Compare types: std::sort, std::max_element, std::map, etc.

Although the results of comparing pointers of random origin (e.g. not all pointing to members of the same array) is unspecified, many implementations provide strict total ordering of pointers, e.g. if they are implemented as addresses within continuous virtual address space. Those implementations that do not (e.g. where not all bits of the pointer are part of a memory address and have to be ignored for comparison, or an additional calculation is required or otherwise pointer and integer is not a 1 to 1 relationship), provide a specialization of std::less for pointers that has that guarantee. This makes it possible to use all pointers of random origin as keys in standard associative containers such as std::set or std::map.

For the types that are both EqualityComparable and LessThanComparable, the C++ standard library makes a distinction between equality, which is the value of the expression a == b and equivalence, which is the value of the expression !(a < b) && !(b < a).

Comparison between pointers and null pointer constants was removed in C++14.

void f(char * p)
{
  if (p > 0) { ... } // OK in C++98..C++11, does not compile in C++14
  if (p > nullptr) { ... } // OK in C++11, does not compile in C++14
}

Three-way comparison

The three-way comparison operator expressions have the form.

lhs <=> rhs (1)

The expression returns an object such that.

  • (a <=> b) < 0 if lhs < rhs
  • (a <=> b) > 0 if lhs > rhs
  • (a <=> b) == 0 if lhs and rhs are equal/equivalent.

If one of the operands is of type bool and the other is not, the program is ill-formed.

If both operands have arithmetic types, or if one operand has unscoped enumeration type and the other has integral type, the usual arithmetic conversions are applied to the operands, and then.

  • If a narrowing conversion is required, other than from an integral type to a floating point type, the program is ill-formed.
  • Otherwise, if the operands have integral type, the operator yields a prvalue of type std::strong_ordering:
    • std::strong_ordering::equal if both operands are arithmetically equal,
    • std::strong_ordering::less if the first operand is arithmetically less than the second
    • std::strong_ordering::greater otherwise.
  • Otherwise, the operands have floating-point type, and the operator yields a prvalue of type std::partial_ordering. The expression a <=> b yields
    • std::partial_ordering::less if a is less than b
    • std::partial_ordering::greater if a is greater than b
    • std::partial_ordering::equivalent if a is equivalent to b (-0 <=> +0 is equivalent)
    • std::partial_ordering::unordered (NaN <=> anything is unordered)

If both operands have the same enumeration type E, the operator yields the result of converting the operands to the underlying type of E and applying <=> to the converted operands.

If at least one of the operands is a pointer or pointer-to-member, array-to-pointer conversions, derived-to-base pointer conversions, function pointer conversions, and qualification conversions are applied as necessary to convert both operands to the same pointer type.

If the resulting pointer type is a function pointer, a pointer to member, or std::nullptr_t, p <=> q returns a prvalue of type std::strong_equality:

  • std::strong_equality::equal if p == q
  • std::strong_equality::unequal if p != q
  • unspecified result if the equality comparison is unspecified for these pointer values

If the resulting pointer type is an object pointer type, p <=> q returns a prvalue of type strong_ordering:

  • std::strong_ordering::equal if p == q
  • std::strong_ordering::less if q > p
  • std::strong_ordering::greater if p > q.
  • unspecified result if comparison is unspecified for these pointer values (such as when they do not point into the same object or array)

In overload resolution against user-defined operators, for pointer or enumeration type T, the following function signature participates in overload resolution:

R operator<=>(T, T);

Where R is the ordering category type defined above.

For every T that is a pointer-to-member type or the type std::nullptr_t, the following function signature participates in overload resolution:

std::strong_equality operator<=>(T, T);

Notes

Three-way comparison can be automatically generated for class types, see default comparisons.

If both of the operands are arrays, three-way comparison is ill-formed except when comparing class members of array type.

unsigned int i = 1;
auto r = -1 < i; // existing pitfall: returns ‘false’
auto r2 = -1 <=> i; // Error: narrowing conversion required
(since C++20)

Standard library

Comparison operators are overloaded for many classes in the standard library.

checks whether the objects refer to the same type
(public member function of std::type_info)
compares two error_codes
(function)
compares error_conditions and error_codes
(function)
lexicographically compares the values in the pair
(function template)
lexicographically compares the values in the tuple
(function template)
compares the contents
(public member function of std::bitset<N>)
compares two allocator instances
(public member function of std::allocator<T>)
compares to another unique_ptr or with nullptr
(function template)
compares with another shared_ptr or with nullptr
(function template)
compares a std::function with nullptr
(function template)
compares two durations
(function template)
compares two time points
(function template)
compares two scoped_allocator_adaptor instances
(public member function of std::scoped_allocator_adaptor<OuterAlloc,InnerAlloc...>)
compares the underlying std::type_info objects
(public member function of std::type_index)
lexicographically compares two strings
(function template)
equality comparison between locale objects
(public member function of std::locale)
lexicographically compares the values in the array
(function template)
lexicographically compares the values in the deque
(function template)
lexicographically compares the values in the forward_list
(function template)
lexicographically compares the values in the list
(function template)
lexicographically compares the values in the vector
(function template)
lexicographically compares the values in the map
(function template)
lexicographically compares the values in the multimap
(function template)
lexicographically compares the values in the set
(function template)
lexicographically compares the values in the multiset
(function template)
compares the values in the unordered_map
(function template)
compares the values in the unordered_multimap
(function template)
compares the values in the unordered_set
(function template)
compares the values in the unordered_multiset
(function template)
lexicographically compares the values in the queue
(function template)
lexicographically compares the values in the stack
(function template)
compares the underlying iterators
(function template)
compares the underlying iterators
(function template)
compares two istream_iterators
(function template)
compares two istreambuf_iterators
(function template)
compares two complex numbers or a complex and a scalar
(function template)
compares two valarrays or a valarray with a value
(function template)
compares the internal states of two pseudo-random number engines
(function template)
compares two distribution objects
(function)
compares two sub_match objects
(function template)
lexicographically compares the values in the two match result
(function template)
compares two regex_iterators
(public member function of std::regex_iterator<BidirIt,CharT,Traits>)
compares two regex_token_iterators
(public member function of std::regex_token_iterator<BidirIt,CharT,Traits>)
compares two thread::id objects
(function)

The namespace rel_ops provides generic operators !=, >, <=, and >=

Defined in header <utility>
Defined in namespace std::rel_ops
(deprecated in C++20)
automatically generates comparison operators based on user-defined operator== and operator<
(function template)

See also

Operator precedence.

Operator overloading.

Common operators
assignment increment
decrement
arithmetic logical comparison member
access
other

a = b a += b a -= b a *= b a /= b a %= b a &= b a |= b a ^= b a <<= b a >>= b.

++a --a a++ a--

+a -a a + b a - b a * b a / b a % b ~a a & b a | b a ^ b a << b a >> b.

!a a && b a || b.

a == b a != b a < b a > b a <= b a >= b a <=> b.

a[b] *a &a a->b a.b a->*b a.*b.

a(...) a, b ? :

Special operators

static_cast converts one type to another related type
dynamic_cast converts within inheritance hierarchies
const_cast adds or removes cv qualifiers
reinterpret_cast converts type to unrelated type
C-style cast converts one type to another by a mix of static_cast, const_cast, and reinterpret_cast
new creates objects with dynamic storage duration
delete destructs objects previously created by the new expression and releases obtained memory area
sizeof queries the size of a type
sizeof... queries the size of a parameter pack (since C++11)
typeid queries the type information of a type
noexcept checks if an expression can throw an exception (since C++11)
alignof queries alignment requirements of a type (since C++11).

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