| //===----------------------------------------------------------------------===// |
| // |
| // The LLVM Compiler Infrastructure |
| // |
| // This file is dual licensed under the MIT and the University of Illinois Open |
| // Source Licenses. See LICENSE.TXT for details. |
| // |
| //===----------------------------------------------------------------------===// |
| |
| // <unordered_set> |
| |
| // template <class Value, class Hash = hash<Value>, class Pred = equal_to<Value>, |
| // class Alloc = allocator<Value>> |
| // class unordered_set |
| |
| // unordered_set& operator=(unordered_set&& u); |
| |
| #include <unordered_set> |
| #include <cassert> |
| #include <cfloat> |
| |
| #include "../../../test_compare.h" |
| #include "../../../test_hash.h" |
| #include "test_allocator.h" |
| #include "min_allocator.h" |
| |
| int main() |
| { |
| #ifndef _LIBCPP_HAS_NO_RVALUE_REFERENCES |
| { |
| typedef test_allocator<int> A; |
| typedef std::unordered_set<int, |
| test_hash<std::hash<int> >, |
| test_compare<std::equal_to<int> >, |
| A |
| > C; |
| typedef int P; |
| P a[] = |
| { |
| P(1), |
| P(2), |
| P(3), |
| P(4), |
| P(1), |
| P(2) |
| }; |
| C c0(a, a + sizeof(a)/sizeof(a[0]), |
| 7, |
| test_hash<std::hash<int> >(8), |
| test_compare<std::equal_to<int> >(9), |
| A(10) |
| ); |
| C c(a, a + 2, |
| 7, |
| test_hash<std::hash<int> >(2), |
| test_compare<std::equal_to<int> >(3), |
| A(4) |
| ); |
| c = std::move(c0); |
| assert(c.bucket_count() == 7); |
| assert(c.size() == 4); |
| assert(c.count(1) == 1); |
| assert(c.count(2) == 1); |
| assert(c.count(3) == 1); |
| assert(c.count(4) == 1); |
| assert(c.hash_function() == test_hash<std::hash<int> >(8)); |
| assert(c.key_eq() == test_compare<std::equal_to<int> >(9)); |
| assert(c.get_allocator() == A(4)); |
| assert(!c.empty()); |
| assert(std::distance(c.begin(), c.end()) == c.size()); |
| assert(std::distance(c.cbegin(), c.cend()) == c.size()); |
| assert(fabs(c.load_factor() - (float)c.size()/c.bucket_count()) < FLT_EPSILON); |
| assert(c.max_load_factor() == 1); |
| } |
| { |
| typedef test_allocator<int> A; |
| typedef std::unordered_set<int, |
| test_hash<std::hash<int> >, |
| test_compare<std::equal_to<int> >, |
| A |
| > C; |
| typedef int P; |
| P a[] = |
| { |
| P(1), |
| P(2), |
| P(3), |
| P(4), |
| P(1), |
| P(2) |
| }; |
| C c0(a, a + sizeof(a)/sizeof(a[0]), |
| 7, |
| test_hash<std::hash<int> >(8), |
| test_compare<std::equal_to<int> >(9), |
| A(10) |
| ); |
| C c(a, a + 2, |
| 7, |
| test_hash<std::hash<int> >(2), |
| test_compare<std::equal_to<int> >(3), |
| A(10) |
| ); |
| c = std::move(c0); |
| assert(c.bucket_count() == 7); |
| assert(c.size() == 4); |
| assert(c.count(1) == 1); |
| assert(c.count(2) == 1); |
| assert(c.count(3) == 1); |
| assert(c.count(4) == 1); |
| assert(c.hash_function() == test_hash<std::hash<int> >(8)); |
| assert(c.key_eq() == test_compare<std::equal_to<int> >(9)); |
| assert(c.get_allocator() == A(10)); |
| assert(!c.empty()); |
| assert(std::distance(c.begin(), c.end()) == c.size()); |
| assert(std::distance(c.cbegin(), c.cend()) == c.size()); |
| assert(fabs(c.load_factor() - (float)c.size()/c.bucket_count()) < FLT_EPSILON); |
| assert(c.max_load_factor() == 1); |
| } |
| { |
| typedef other_allocator<int> A; |
| typedef std::unordered_set<int, |
| test_hash<std::hash<int> >, |
| test_compare<std::equal_to<int> >, |
| A |
| > C; |
| typedef int P; |
| P a[] = |
| { |
| P(1), |
| P(2), |
| P(3), |
| P(4), |
| P(1), |
| P(2) |
| }; |
| C c0(a, a + sizeof(a)/sizeof(a[0]), |
| 7, |
| test_hash<std::hash<int> >(8), |
| test_compare<std::equal_to<int> >(9), |
| A(10) |
| ); |
| C c(a, a + 2, |
| 7, |
| test_hash<std::hash<int> >(2), |
| test_compare<std::equal_to<int> >(3), |
| A(4) |
| ); |
| c = std::move(c0); |
| assert(c.bucket_count() == 7); |
| assert(c.size() == 4); |
| assert(c.count(1) == 1); |
| assert(c.count(2) == 1); |
| assert(c.count(3) == 1); |
| assert(c.count(4) == 1); |
| assert(c.hash_function() == test_hash<std::hash<int> >(8)); |
| assert(c.key_eq() == test_compare<std::equal_to<int> >(9)); |
| assert(c.get_allocator() == A(10)); |
| assert(!c.empty()); |
| assert(std::distance(c.begin(), c.end()) == c.size()); |
| assert(std::distance(c.cbegin(), c.cend()) == c.size()); |
| assert(fabs(c.load_factor() - (float)c.size()/c.bucket_count()) < FLT_EPSILON); |
| assert(c.max_load_factor() == 1); |
| } |
| #if __cplusplus >= 201103L |
| { |
| typedef min_allocator<int> A; |
| typedef std::unordered_set<int, |
| test_hash<std::hash<int> >, |
| test_compare<std::equal_to<int> >, |
| A |
| > C; |
| typedef int P; |
| P a[] = |
| { |
| P(1), |
| P(2), |
| P(3), |
| P(4), |
| P(1), |
| P(2) |
| }; |
| C c0(a, a + sizeof(a)/sizeof(a[0]), |
| 7, |
| test_hash<std::hash<int> >(8), |
| test_compare<std::equal_to<int> >(9), |
| A() |
| ); |
| C c(a, a + 2, |
| 7, |
| test_hash<std::hash<int> >(2), |
| test_compare<std::equal_to<int> >(3), |
| A() |
| ); |
| c = std::move(c0); |
| assert(c.bucket_count() == 7); |
| assert(c.size() == 4); |
| assert(c.count(1) == 1); |
| assert(c.count(2) == 1); |
| assert(c.count(3) == 1); |
| assert(c.count(4) == 1); |
| assert(c.hash_function() == test_hash<std::hash<int> >(8)); |
| assert(c.key_eq() == test_compare<std::equal_to<int> >(9)); |
| assert(c.get_allocator() == A()); |
| assert(!c.empty()); |
| assert(std::distance(c.begin(), c.end()) == c.size()); |
| assert(std::distance(c.cbegin(), c.cend()) == c.size()); |
| assert(fabs(c.load_factor() - (float)c.size()/c.bucket_count()) < FLT_EPSILON); |
| assert(c.max_load_factor() == 1); |
| } |
| #endif |
| #if _LIBCPP_DEBUG >= 1 |
| { |
| std::unordered_set<int> s1 = {1, 2, 3}; |
| std::unordered_set<int>::iterator i = s1.begin(); |
| int k = *i; |
| std::unordered_set<int> s2; |
| s2 = std::move(s1); |
| assert(*i == k); |
| s2.erase(i); |
| assert(s2.size() == 2); |
| } |
| #endif |
| #endif // _LIBCPP_HAS_NO_RVALUE_REFERENCES |
| } |