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#include <frozen/unordered_map.h>
#include <frozen/string.h>
#include <frozen/bits/elsa_std.h>
#include <iostream>
#include <unordered_map>
#include <string>
#include "bench.hpp"
#include "catch.hpp"
TEST_CASE("singleton frozen unordered map", "[unordered map]") {
constexpr frozen::unordered_map<int, double, 1> ze_map{{1, 2.}};
constexpr auto empty = ze_map.empty();
REQUIRE(!empty);
constexpr auto size = ze_map.size();
REQUIRE(size == 1);
constexpr auto max_size = ze_map.max_size();
REQUIRE(max_size == 1);
constexpr auto nocount = ze_map.count(3);
REQUIRE(nocount == 0);
constexpr auto count = ze_map.count(1);
REQUIRE(count == 1);
constexpr auto find = ze_map.at(1);
REQUIRE(find == 2.);
auto notfound = ze_map.find(3);
REQUIRE(notfound == ze_map.end());
auto found = ze_map.find(1);
REQUIRE(found == ze_map.begin());
auto range = ze_map.equal_range(1);
REQUIRE(std::get<0>(range) == ze_map.begin());
REQUIRE(std::get<1>(range) == ze_map.end());
auto begin = ze_map.begin(), end = ze_map.end();
REQUIRE(begin != end);
// auto constexpr key_hash = ze_map.hash_function();
// auto constexpr key_hashed = key_hash(1);
// REQUIRE(key_hashed);
auto constexpr key_eq = ze_map.key_eq();
auto constexpr value_comparison = key_eq(11, 11);
REQUIRE(value_comparison);
auto cbegin = ze_map.cbegin(), cend = ze_map.cend();
REQUIRE(cbegin < cend);
std::for_each(ze_map.begin(), ze_map.end(), [](std::tuple<int, double>) {});
static_assert(std::is_same<typename decltype(ze_map)::key_type, int>::value, "");
static_assert(std::is_same<typename decltype(ze_map)::mapped_type, double>::value, "");
}
// This is mainly a test that construction does not time out
TEST_CASE("frozen::unordered_map powers of two", "[unordered_map]") {
constexpr frozen::unordered_map<int, int, 14> frozen_map = {
{1, 0}, {2, 1}, {4, 2}, {8, 3}, {16, 4}, {32, 5}, {64, 6}, {128, 7},
{256, 8}, {512, 9}, {1024, 10}, {2048, 11}, {4096, 12}, {8192, 13}
};
for (const auto & pair : frozen_map) {
REQUIRE(pair.first == (1 << pair.second));
}
}
// This is also mainly a test that construction does not time out
#define M64(X) { X * 64, X }
TEST_CASE("frozen::unordered_map multiples of 64", "[unordered_map]") {
constexpr frozen::unordered_map<int, int, 57> frozen_map = {
M64(0), M64(1), M64(2), M64(3), M64(4), M64(5), M64(6), M64(7), M64(8),
M64(9), M64(10), M64(11), M64(12), M64(13), M64(14), M64(15), M64(16),
M64(17), M64(18), M64(19), M64(20), M64(21), M64(22), M64(23), M64(24),
M64(25), M64(26), M64(27), M64(28), M64(29), M64(30), M64(31), M64(32),
M64(33), M64(34), M64(35), M64(36), M64(37), M64(38), M64(39), M64(40),
M64(41), M64(42), M64(43), M64(44), M64(45), M64(46), M64(47), M64(48),
M64(49), M64(50), M64(51), M64(52), M64(53), M64(54), M64(55), M64(56),
};
# undef M64
for (const auto & pair : frozen_map) {
REQUIRE(pair.first == 64 * pair.second);
}
}
TEST_CASE("frozen::unordered_map <> std::unordered_map", "[unordered_map]") {
#define INIT_SEQ \
{19, 12}, {1, 12}, {2, 12}, {4, 12}, {5, 12}, {6, 12}, {7, 12}, {8, 12}, \
{9, 12}, {10, 12}, {11, 12}, {111, 12}, {1112, 12}, {1115, 12}, \
{1118, 12}, {1110, 12}, {1977, 12}, {177, 12}, {277, 12}, {477, 12}, \
{577, 12}, {677, 12}, {777, 12}, {877, 12}, {977, 12}, {1077, 12}, \
{1177, 12}, {11177, 12}, {111277, 12}, {111577, 12}, {111877, 12}, \
{111077, 12}, {1999, 12}, {199, 12}, {299, 12}, {499, 12}, {599, 12}, \
{699, 12}, {799, 12}, {899, 12}, {999, 12}, {1099, 12}, {1199, 12}, \
{11199, 12}, {111299, 12}, {111599, 12}, {111899, 12}, {111099, 12}, \
{197799, 12}, {17799, 12}, {27799, 12}, {47799, 12}, {57799, 12}, \
{67799, 12}, {77799, 12}, {87799, 12}, {97799, 12}, {107799, 12}, \
{117799, 12}, {1117799, 12}, {11127799, 12}, {11157799, 12}, \
{11187799, 12}, {11107799, 12}, {1988, 12}, {188, 12}, {288, 12}, \
{488, 12}, {588, 12}, {688, 12}, {788, 12}, {888, 12}, {988, 12}, \
{1088, 12}, {1188, 12}, {11188, 12}, {111288, 12}, {111588, 12}, \
{111888, 12}, {111088, 12}, {197788, 12}, {17788, 12}, {27788, 12}, \
{47788, 12}, {57788, 12}, {67788, 12}, {77788, 12}, {87788, 12}, \
{97788, 12}, {107788, 12}, {117788, 12}, {1117788, 12}, \
{11127788, 12}, {11157788, 12}, {11187788, 12}, {11107788, 12}, \
{199988, 12}, {19988, 12}, {29988, 12}, {49988, 12}, {59988, 12}, \
{69988, 12}, {79988, 12}, {89988, 12}, {99988, 12}, {109988, 12}, \
{119988, 12}, {1119988, 12}, {11129988, 12}, {11159988, 12}, \
{11189988, 12}, {11109988, 12}, {19779988, 12}, {1779988, 12}, \
{2779988, 12}, {4779988, 12}, {5779988, 12}, {6779988, 12}, \
{7779988, 12}, {8779988, 12}, {9779988, 12}, {10779988, 12}, \
{11779988, 12}, {111779988, 12}, {1112779988, 12}, {1115779988, 12}, \
{1118779988, 12}, { \
1110779988, 13 \
}
const std::unordered_map<int, int> std_map = { INIT_SEQ };
constexpr frozen::unordered_map<int, int, 128> frozen_map = { INIT_SEQ };
SECTION("checking size and content") {
REQUIRE(std_map.size() == frozen_map.size());
for (auto v : std_map)
REQUIRE(frozen_map.count(std::get<0>(v)));
for (auto v : frozen_map)
REQUIRE(std_map.count(std::get<0>(v)));
}
static_assert(std::is_same<typename decltype(std_map)::key_type,
typename decltype(frozen_map)::key_type>::value, "");
static_assert(std::is_same<typename decltype(std_map)::mapped_type,
typename decltype(frozen_map)::mapped_type>::value, "");
}
TEST_CASE("frozen::unordered_map <> frozen::make_unordered_map", "[unordered_map]") {
constexpr frozen::unordered_map<int, int, 128> frozen_map = { INIT_SEQ };
constexpr auto frozen_map2 = frozen::make_unordered_map<int, int>({INIT_SEQ});
constexpr auto frozen_map3 = frozen::make_unordered_map(std::array<std::pair<int, int>, 128>{{INIT_SEQ}});
REQUIRE(std::equal(frozen_map2.begin(), frozen_map2.end(), frozen_map3.begin()));
SECTION("checking size and content") {
REQUIRE(frozen_map.size() == frozen_map2.size());
for (auto v : frozen_map2)
REQUIRE(frozen_map.count(std::get<0>(v)));
for (auto v : frozen_map)
REQUIRE(frozen_map2.count(std::get<0>(v)));
}
}
TEST_CASE("frozen::unordered_map <> std::unordered_map /small", "[unordered_map]") {
#define INIT_SEQ_SMALL \
{"0", 0},{"1", 1},{"2", 2},{"3", 3},{"5", 4},{"8", 5},{"9", 6},{"A", 7},{"W", 8},{"X", 9},{"r", 10},{"y", 11},{"BF", 12},{"AP", 13}
const std::unordered_map<frozen::string, int> std_map = { INIT_SEQ_SMALL };
constexpr frozen::unordered_map<frozen::string, int, 14> frozen_map = { INIT_SEQ_SMALL };
SECTION("checking size and content") {
REQUIRE(std_map.size() == frozen_map.size());
for (auto v : std_map)
REQUIRE(frozen_map.count(std::get<0>(v)));
for (auto v : frozen_map)
REQUIRE(std_map.count(std::get<0>(v)));
}
static_assert(std::is_same<typename decltype(std_map)::key_type,
typename decltype(frozen_map)::key_type>::value, "");
static_assert(std::is_same<typename decltype(std_map)::mapped_type,
typename decltype(frozen_map)::mapped_type>::value, "");
}
TEST_CASE("frozen::unordered_map constexpr", "[unordered_map]") {
constexpr frozen::unordered_map<unsigned, unsigned, 2> ce = {{3,4}, {11,12}};
static_assert(ce.begin() +2 == ce.end(), "");
static_assert(ce.size() == 2, "");
static_assert(ce.count(3), "");
static_assert(!ce.count(0), "");
static_assert(ce.find(0) == ce.end(), "");
}
TEST_CASE("access", "[unordered_map]") {
constexpr frozen::unordered_map<unsigned, unsigned, 2> ce = {{3,4}, {11,12}};
REQUIRE(4 == ce.at(3));
REQUIRE_THROWS(ce.at(33));
}
TEST_CASE("Modifiable frozen::unordered_map", "[unordered_map]") {
frozen::unordered_map<int, int, 3> frozen_map = {{0, 1}, {2, 3}, {4, 5}};
SECTION("Lookup existing values") {
REQUIRE(frozen_map.at(0) == 1);
REQUIRE(frozen_map.find(0)->second == 1);
REQUIRE(frozen_map.equal_range(0).first->second == 1);
REQUIRE(frozen_map.at(2) == 3);
REQUIRE(frozen_map.find(2)->second == 3);
REQUIRE(frozen_map.equal_range(2).first->second == 3);
REQUIRE(frozen_map.at(4) == 5);
REQUIRE(frozen_map.find(4)->second == 5);
REQUIRE(frozen_map.equal_range(4).first->second == 5);
}
SECTION("Lookup failure") {
REQUIRE(frozen_map.find(5) == frozen_map.end());
REQUIRE_THROWS_AS(frozen_map.at(5), std::out_of_range);
}
SECTION("Modify value") {
frozen_map.at(0) = -1;
REQUIRE(frozen_map.at(0) == -1);
frozen_map.begin()->second = -2;
REQUIRE(frozen_map.begin()->second == -2);
(frozen_map.end() - 1)->second = -3;
REQUIRE((frozen_map.end() - 1)->second == -3);
frozen_map.equal_range(4).first->second = -5;
REQUIRE(frozen_map.at(4) == -5);
}
}
TEST_CASE("frozen::unordered_map heterogeneous lookup", "[unordered_map]") {
constexpr auto map = frozen::make_unordered_map<frozen::string, int>({{"one", 1}, {"two", 2}, {"three", 3}});
const auto eq = [](const frozen::string& frozen, const std::string& std) {
return frozen == frozen::string{std.data(), std.size()};
};
REQUIRE(map.find(std::string{"two"}, frozen::elsa<std::string>{}, eq)->second == 2);
}
TEST_CASE("frozen::unordered_map heterogeneous container", "[unordered_map]") {
const auto eq = [](const frozen::string& frozen, const auto& str) {
return frozen == frozen::string{str.data(), str.size()};
};
constexpr auto map = frozen::make_unordered_map<frozen::string, int>(
{{"one", 1}, {"two", 2}, {"three", 3}},
frozen::elsa<>{}, eq);
REQUIRE(map.find(std::string{"two"})->second == 2);
REQUIRE(map.find(frozen::string{"two"})->second == 2);
}
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