//===----------------------------------------------------------------------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
// <map>
// class map
// map& operator=(const map& m);
#include <map>
#include <algorithm>
#include <cassert>
#include <cstdio>
#include <iterator>
#include <vector>
#include "test_macros.h"
#include "../../../test_compare.h"
#include "test_allocator.h"
#include "min_allocator.h"
#if TEST_STD_VER >= 11
std::vector<int> ca_allocs;
std::vector<int> ca_deallocs;
template <class T>
class counting_allocatorT {
public:
typedef T value_type;
int foo{0};
counting_allocatorT(int f) noexcept : foo(f) {}
using propagate_on_container_copy_assignment = std::true_type;
template <class U> counting_allocatorT(const counting_allocatorT<U>& other) noexcept {foo = other.foo;}
template <class U> bool operator==(const counting_allocatorT<U>& other) const noexcept { return foo == other.foo; }
template <class U> bool operator!=(const counting_allocatorT<U>& other) const noexcept { return foo != other.foo; }
T* allocate(std::size_t n) const {
ca_allocs.push_back(foo);
void * const pv = ::malloc(n * sizeof(T));
return static_cast<T *>(pv);
}
void deallocate(T* p, std::size_t) const noexcept {
ca_deallocs.push_back(foo);
free(p);
}
};
template <class T>
class counting_allocatorF {
public:
typedef T value_type;
int foo{0};
counting_allocatorF(int f) noexcept : foo(f) {}
using propagate_on_container_copy_assignment = std::false_type;
template <class U> counting_allocatorF(const counting_allocatorF<U>& other) noexcept {foo = other.foo;}
template <class U> bool operator==(const counting_allocatorF<U>& other) const noexcept { return foo == other.foo; }
template <class U> bool operator!=(const counting_allocatorF<U>& other) const noexcept { return foo != other.foo; }
T* allocate(std::size_t n) const {
ca_allocs.push_back(foo);
void * const pv = ::malloc(n * sizeof(T));
return static_cast<T *>(pv);
}
void deallocate(T* p, std::size_t) const noexcept {
ca_deallocs.push_back(foo);
free(p);
}
};
bool balanced_allocs() {
std::vector<int> temp1, temp2;
std::printf("Allocations = %zu, deallocations = %zu\n", ca_allocs.size(),
ca_deallocs.size());
if (ca_allocs.size() != ca_deallocs.size())
return false;
temp1 = ca_allocs;
std::sort(temp1.begin(), temp1.end());
temp2.clear();
std::unique_copy(temp1.begin(), temp1.end(), std::back_inserter<std::vector<int>>(temp2));
std::printf("There were %zu different allocators\n", temp2.size());
for (std::vector<int>::const_iterator it = temp2.begin(); it != temp2.end(); ++it ) {
std::ptrdiff_t const allocs = std::count(ca_allocs.begin(), ca_allocs.end(), *it);
std::ptrdiff_t const deallocs = std::count(ca_deallocs.begin(), ca_deallocs.end(), *it);
std::printf("%d: %td vs %td\n", *it, allocs, deallocs);
if (allocs != deallocs)
return false;
}
temp1 = ca_allocs;
std::sort(temp1.begin(), temp1.end());
temp2.clear();
std::unique_copy(temp1.begin(), temp1.end(), std::back_inserter<std::vector<int>>(temp2));
std::printf("There were %zu different (de)allocators\n", temp2.size());
for (std::vector<int>::const_iterator it = ca_deallocs.begin(); it != ca_deallocs.end(); ++it ) {
std::ptrdiff_t const allocs = std::count(ca_allocs.begin(), ca_allocs.end(), *it);
std::ptrdiff_t const deallocs = std::count(ca_deallocs.begin(), ca_deallocs.end(), *it);
std::printf("%d: %td vs %td\n", *it, allocs, deallocs);
if (allocs != deallocs)
return false;
}
return true;
}
#endif
int main(int, char**)
{
{
typedef std::pair<const int, double> V;
V ar[] =
{
V(1, 1),
V(1, 1.5),
V(1, 2),
V(2, 1),
V(2, 1.5),
V(2, 2),
V(3, 1),
V(3, 1.5),
V(3, 2)
};
typedef test_less<int> C;
typedef test_allocator<V> A;
std::map<int, double, C, A> mo(ar, ar+sizeof(ar)/sizeof(ar[0]), C(5), A(2));
std::map<int, double, C, A> m(ar, ar+sizeof(ar)/sizeof(ar[0])/2, C(3), A(7));
m = mo;
assert(m.get_allocator() == A(7));
assert(m.key_comp() == C(5));
assert(m.size() == 3);
assert(std::distance(m.begin(), m.end()) == 3);
assert(*m.begin() == V(1, 1));
assert(*std::next(m.begin()) == V(2, 1));
assert(*std::next(m.begin(), 2) == V(3, 1));
assert(mo.get_allocator() == A(2));
assert(mo.key_comp() == C(5));
assert(mo.size() == 3);
assert(std::distance(mo.begin(), mo.end()) == 3);
assert(*mo.begin() == V(1, 1));
assert(*std::next(mo.begin()) == V(2, 1));
assert(*std::next(mo.begin(), 2) == V(3, 1));
}
{
typedef std::pair<const int, double> V;
const V ar[] =
{
V(1, 1),
V(2, 1),
V(3, 1),
};
std::map<int, double> m(ar, ar+sizeof(ar)/sizeof(ar[0]));
std::map<int, double> *p = &m;
m = *p;
assert(m.size() == 3);
assert(std::equal(m.begin(), m.end(), ar));
}
{
typedef std::pair<const int, double> V;
V ar[] =
{
V(1, 1),
V(1, 1.5),
V(1, 2),
V(2, 1),
V(2, 1.5),
V(2, 2),
V(3, 1),
V(3, 1.5),
V(3, 2)
};
typedef test_less<int> C;
typedef other_allocator<V> A;
std::map<int, double, C, A> mo(ar, ar+sizeof(ar)/sizeof(ar[0]), C(5), A(2));
std::map<int, double, C, A> m(ar, ar+sizeof(ar)/sizeof(ar[0])/2, C(3), A(7));
m = mo;
assert(m.get_allocator() == A(2));
assert(m.key_comp() == C(5));
assert(m.size() == 3);
assert(std::distance(m.begin(), m.end()) == 3);
assert(*m.begin() == V(1, 1));
assert(*std::next(m.begin()) == V(2, 1));
assert(*std::next(m.begin(), 2) == V(3, 1));
assert(mo.get_allocator() == A(2));
assert(mo.key_comp() == C(5));
assert(mo.size() == 3);
assert(std::distance(mo.begin(), mo.end()) == 3);
assert(*mo.begin() == V(1, 1));
assert(*std::next(mo.begin()) == V(2, 1));
assert(*std::next(mo.begin(), 2) == V(3, 1));
}
#if TEST_STD_VER >= 11
{
typedef std::pair<const int, double> V;
V ar[] =
{
V(1, 1),
V(1, 1.5),
V(1, 2),
V(2, 1),
V(2, 1.5),
V(2, 2),
V(3, 1),
V(3, 1.5),
V(3, 2)
};
typedef test_less<int> C;
typedef min_allocator<V> A;
std::map<int, double, C, A> mo(ar, ar+sizeof(ar)/sizeof(ar[0]), C(5), A());
std::map<int, double, C, A> m(ar, ar+sizeof(ar)/sizeof(ar[0])/2, C(3), A());
m = mo;
assert(m.get_allocator() == A());
assert(m.key_comp() == C(5));
assert(m.size() == 3);
assert(std::distance(m.begin(), m.end()) == 3);
assert(*m.begin() == V(1, 1));
assert(*std::next(m.begin()) == V(2, 1));
assert(*std::next(m.begin(), 2) == V(3, 1));
assert(mo.get_allocator() == A());
assert(mo.key_comp() == C(5));
assert(mo.size() == 3);
assert(std::distance(mo.begin(), mo.end()) == 3);
assert(*mo.begin() == V(1, 1));
assert(*std::next(mo.begin()) == V(2, 1));
assert(*std::next(mo.begin(), 2) == V(3, 1));
}
{
typedef std::pair<const int, double> V;
V ar[] =
{
V(1, 1),
V(1, 1.5),
V(1, 2),
V(2, 1),
V(2, 1.5),
V(2, 2),
V(3, 1),
V(3, 1.5),
V(3, 2)
};
typedef test_less<int> C;
typedef min_allocator<V> A;
std::map<int, double, C, A> mo(ar, ar+sizeof(ar)/sizeof(ar[0]), C(5), A());
std::map<int, double, C, A> m(ar, ar+sizeof(ar)/sizeof(ar[0])/2, C(3), A());
m = mo;
assert(m.get_allocator() == A());
assert(m.key_comp() == C(5));
assert(m.size() == 3);
assert(std::distance(m.begin(), m.end()) == 3);
assert(*m.begin() == V(1, 1));
assert(*std::next(m.begin()) == V(2, 1));
assert(*std::next(m.begin(), 2) == V(3, 1));
assert(mo.get_allocator() == A());
assert(mo.key_comp() == C(5));
assert(mo.size() == 3);
assert(std::distance(mo.begin(), mo.end()) == 3);
assert(*mo.begin() == V(1, 1));
assert(*std::next(mo.begin()) == V(2, 1));
assert(*std::next(mo.begin(), 2) == V(3, 1));
}
assert(balanced_allocs());
{
typedef std::pair<const int, double> V;
V ar[] =
{
V(1, 1),
V(1, 1.5),
V(1, 2),
V(2, 1),
V(2, 1.5),
V(2, 2),
V(3, 1),
V(3, 1.5),
V(3, 2)
};
typedef test_less<int> C;
typedef counting_allocatorT<V> A;
std::map<int, double, C, A> mo(ar, ar+sizeof(ar)/sizeof(ar[0]), C(5), A(1));
std::map<int, double, C, A> m(ar, ar+sizeof(ar)/sizeof(ar[0])/2, C(3), A(2));
m = mo;
assert(m.key_comp() == C(5));
assert(m.size() == 3);
assert(std::distance(m.begin(), m.end()) == 3);
assert(*m.begin() == V(1, 1));
assert(*std::next(m.begin()) == V(2, 1));
assert(*std::next(m.begin(), 2) == V(3, 1));
assert(mo.key_comp() == C(5));
assert(mo.size() == 3);
assert(std::distance(mo.begin(), mo.end()) == 3);
assert(*mo.begin() == V(1, 1));
assert(*std::next(mo.begin()) == V(2, 1));
assert(*std::next(mo.begin(), 2) == V(3, 1));
}
assert(balanced_allocs());
{
typedef std::pair<const int, double> V;
V ar[] =
{
V(1, 1),
V(1, 1.5),
V(1, 2),
V(2, 1),
V(2, 1.5),
V(2, 2),
V(3, 1),
V(3, 1.5),
V(3, 2)
};
typedef test_less<int> C;
typedef counting_allocatorF<V> A;
std::map<int, double, C, A> mo(ar, ar+sizeof(ar)/sizeof(ar[0]), C(5), A(100));
std::map<int, double, C, A> m(ar, ar+sizeof(ar)/sizeof(ar[0])/2, C(3), A(200));
m = mo;
assert(m.key_comp() == C(5));
assert(m.size() == 3);
assert(std::distance(m.begin(), m.end()) == 3);
assert(*m.begin() == V(1, 1));
assert(*std::next(m.begin()) == V(2, 1));
assert(*std::next(m.begin(), 2) == V(3, 1));
assert(mo.key_comp() == C(5));
assert(mo.size() == 3);
assert(std::distance(mo.begin(), mo.end()) == 3);
assert(*mo.begin() == V(1, 1));
assert(*std::next(mo.begin()) == V(2, 1));
assert(*std::next(mo.begin(), 2) == V(3, 1));
}
assert(balanced_allocs());
#endif
return 0;
}