//
// immer: immutable data structures for C++
// Copyright (C) 2016, 2017, 2018 Juan Pedro Bolivar Puente
//
// This software is distributed under the Boost Software License, Version 1.0.
// See accompanying file LICENSE or copy at http://boost.org/LICENSE_1_0.txt
//
#ifndef MAP_T
#error "define the map template to use in MAP_T"
#include <immer/map.hpp>
#define MAP_T ::immer::map
#endif
#include <immer/algorithm.hpp>
#include "test/dada.hpp"
#include "test/util.hpp"
#include <catch.hpp>
#include <random>
#include <unordered_set>
template <typename T = unsigned>
auto make_generator()
{
auto engine = std::default_random_engine{42};
auto dist = std::uniform_int_distribution<T>{};
return std::bind(dist, engine);
}
struct conflictor
{
unsigned v1;
unsigned v2;
bool operator==(const conflictor& x) const
{
return v1 == x.v1 && v2 == x.v2;
}
};
struct hash_conflictor
{
std::size_t operator()(const conflictor& x) const { return x.v1; }
};
auto make_values_with_collisions(unsigned n)
{
auto gen = make_generator();
auto vals = std::vector<std::pair<conflictor, unsigned>>{};
auto vals_ = std::unordered_set<conflictor, hash_conflictor>{};
auto i = 0u;
generate_n(back_inserter(vals), n, [&] {
auto newv = conflictor{};
do {
newv = {unsigned(gen() % (n / 2)), gen()};
} while (!vals_.insert(newv).second);
return std::pair<conflictor, unsigned>{newv, i++};
});
return vals;
}
auto make_test_map(unsigned n)
{
auto s = MAP_T<unsigned, unsigned>{};
for (auto i = 0u; i < n; ++i)
s = s.insert({i, i});
return s;
}
auto make_test_map(const std::vector<std::pair<conflictor, unsigned>>& vals)
{
auto s = MAP_T<conflictor, unsigned, hash_conflictor>{};
for (auto&& v : vals)
s = s.insert(v);
return s;
}
TEST_CASE("instantiation")
{
SECTION("default")
{
auto v = MAP_T<int, int>{};
CHECK(v.size() == 0u);
}
}
TEST_CASE("basic insertion")
{
auto v1 = MAP_T<int, int>{};
CHECK(v1.count(42) == 0);
auto v2 = v1.insert({42, {}});
CHECK(v1.count(42) == 0);
CHECK(v2.count(42) == 1);
auto v3 = v2.insert({42, {}});
CHECK(v1.count(42) == 0);
CHECK(v2.count(42) == 1);
CHECK(v3.count(42) == 1);
}
TEST_CASE("accessor")
{
const auto n = 666u;
auto v = make_test_map(n);
CHECK(v[0] == 0);
CHECK(v[42] == 42);
CHECK(v[665] == 665);
CHECK(v[666] == 0);
CHECK(v[1234] == 0);
}
TEST_CASE("at")
{
const auto n = 666u;
auto v = make_test_map(n);
CHECK(v.at(0) == 0);
CHECK(v.at(42) == 42);
CHECK(v.at(665) == 665);
CHECK_THROWS_AS(v.at(666), std::out_of_range&);
CHECK_THROWS_AS(v.at(1234), std::out_of_range&);
}
TEST_CASE("find")
{
const auto n = 666u;
auto v = make_test_map(n);
CHECK(*v.find(0) == 0);
CHECK(*v.find(42) == 42);
CHECK(*v.find(665) == 665);
CHECK(v.find(666) == nullptr);
CHECK(v.find(1234) == nullptr);
}
TEST_CASE("equals and setting")
{
const auto n = 666u;
auto v = make_test_map(n);
CHECK(v == v);
CHECK(v != v.insert({1234, 42}));
CHECK(v != v.erase(32));
CHECK(v == v.insert({1234, 42}).erase(1234));
CHECK(v == v.erase(32).insert({32, 32}));
CHECK(v.set(1234, 42) == v.insert({1234, 42}));
CHECK(v.update(1234, [](auto&& x) { return x + 1; }) == v.set(1234, 1));
CHECK(v.update(42, [](auto&& x) { return x + 1; }) == v.set(42, 43));
}
TEST_CASE("iterator")
{
const auto N = 666u;
auto v = make_test_map(N);
SECTION("empty set")
{
auto s = MAP_T<unsigned, unsigned>{};
CHECK(s.begin() == s.end());
}
SECTION("works with range loop")
{
auto seen = std::unordered_set<unsigned>{};
for (const auto& x : v)
CHECK(seen.insert(x.first).second);
CHECK(seen.size() == v.size());
}
SECTION("iterator and collisions")
{
auto vals = make_values_with_collisions(N);
auto s = make_test_map(vals);
auto seen = std::unordered_set<conflictor, hash_conflictor>{};
for (const auto& x : s)
CHECK(seen.insert(x.first).second);
CHECK(seen.size() == s.size());
}
}
TEST_CASE("accumulate")
{
const auto n = 666u;
auto v = make_test_map(n);
auto expected_n = [](auto n) { return n * (n - 1) / 2; };
SECTION("sum collection")
{
auto acc = [](unsigned acc, const std::pair<unsigned, unsigned>& x) {
return acc + x.first + x.second;
};
auto sum = immer::accumulate(v, 0u, acc);
CHECK(sum == 2 * expected_n(v.size()));
}
SECTION("sum collisions")
{
auto vals = make_values_with_collisions(n);
auto s = make_test_map(vals);
auto acc = [](unsigned r, std::pair<conflictor, unsigned> x) {
return r + x.first.v1 + x.first.v2 + x.second;
};
auto sum1 = std::accumulate(vals.begin(), vals.end(), 0u, acc);
auto sum2 = immer::accumulate(s, 0u, acc);
CHECK(sum1 == sum2);
}
}
TEST_CASE("update a lot")
{
auto v = make_test_map(666u);
for (decltype(v.size()) i = 0; i < v.size(); ++i) {
v = v.update(i, [](auto&& x) { return x + 1; });
CHECK(v[i] == i + 1);
}
}
TEST_CASE("exception safety")
{
constexpr auto n = 2666u;
using dadaist_map_t =
typename dadaist_wrapper<MAP_T<unsigned, unsigned>>::type;
using dadaist_conflictor_map_t = typename dadaist_wrapper<
MAP_T<conflictor, unsigned, hash_conflictor>>::type;
SECTION("update collisions")
{
auto v = dadaist_map_t{};
auto d = dadaism{};
for (auto i = 0u; i < n; ++i)
v = v.set(i, i);
for (auto i = 0u; i < v.size();) {
try {
auto s = d.next();
v = v.update(i, [](auto x) { return x + 1; });
++i;
} catch (dada_error) {}
for (auto i : test_irange(0u, i))
CHECK(v.at(i) == i + 1);
for (auto i : test_irange(i, n))
CHECK(v.at(i) == i);
}
CHECK(d.happenings > 0);
IMMER_TRACE_E(d.happenings);
}
SECTION("update collisisions")
{
auto vals = make_values_with_collisions(n);
auto v = dadaist_conflictor_map_t{};
auto d = dadaism{};
for (auto i = 0u; i < n; ++i)
v = v.insert(vals[i]);
for (auto i = 0u; i < v.size();) {
try {
auto s = d.next();
v = v.update(vals[i].first, [](auto x) { return x + 1; });
++i;
} catch (dada_error) {}
for (auto i : test_irange(0u, i))
CHECK(v.at(vals[i].first) == vals[i].second + 1);
for (auto i : test_irange(i, n))
CHECK(v.at(vals[i].first) == vals[i].second);
}
CHECK(d.happenings > 0);
IMMER_TRACE_E(d.happenings);
}
}
namespace {
class KElem
{
public:
KElem(int* elem) { this->elem = elem; }
bool operator==(const KElem& other) const
{
return this->elem == other.elem;
}
bool operator!=(const KElem& other) const { return !(*this == other); }
int* elem;
};
struct HashBlock
{
size_t operator()(const KElem& block) const noexcept
{
return (uintptr_t) block.elem & 0xffffffff00000000;
}
};
using map = immer::map<KElem, KElem, HashBlock, std::equal_to<KElem>>;
TEST_CASE("issue 134")
{
int a[100];
map m;
for (int i = 0; i < 100; i++) {
m = m.set(KElem(a + i), KElem(a + i));
}
}
} // namespace
