//
// 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
//
#include "test/dada.hpp"
#include "test/util.hpp"
#include <immer/algorithm.hpp>
#include <boost/range/adaptors.hpp>
#include <catch.hpp>
#include <algorithm>
#include <numeric>
#include <string>
#include <vector>
using namespace std::string_literals;
#ifndef VECTOR_T
#error "define the vector template to use in VECTOR_T"
#endif
template <typename V = VECTOR_T<unsigned>>
auto make_test_vector(unsigned min, unsigned max)
{
auto v = V{};
for (auto i = min; i < max; ++i)
v = v.push_back({i});
return v;
}
struct big_object
{
std::array<std::size_t, 42> v;
};
struct string_sentinel
{};
bool operator==(const char16_t* i, string_sentinel) { return *i == '\0'; }
bool operator!=(const char16_t* i, string_sentinel) { return *i != '\0'; }
TEST_CASE("instantiation")
{
SECTION("default")
{
auto v = VECTOR_T<int>{};
CHECK(v.size() == 0u);
CHECK(v.empty());
}
SECTION("initializer list")
{
auto v = VECTOR_T<unsigned>{0, 1, 2, 3, 4, 5, 6, 7, 8, 9};
CHECK_VECTOR_EQUALS(v, boost::irange(0u, 10u));
CHECK(!v.empty());
}
SECTION("big object")
{
auto v = VECTOR_T<big_object>{{}, {}, {}, {}};
CHECK(v.size() == 4);
}
SECTION("range")
{
auto r = std::vector<int>{{0, 1, 2, 3, 4, 5, 6, 7, 8, 9}};
auto v = VECTOR_T<unsigned>{r.begin(), r.end()};
CHECK_VECTOR_EQUALS(v, boost::irange(0u, 10u));
}
SECTION("empty range")
{
auto r = std::vector<int>{};
auto v = VECTOR_T<unsigned>{r.begin(), r.end()};
CHECK(v.size() == 0);
}
SECTION("iterator/sentinel")
{
auto r = u"012345678";
string_sentinel s;
auto v = VECTOR_T<unsigned>{r, s};
CHECK_VECTOR_EQUALS(v, boost::irange(u'0', u'9'));
}
SECTION("fill")
{
auto v1 = VECTOR_T<int>(4);
CHECK(v1.size() == 4);
auto v2 = VECTOR_T<int>(4, 42);
CHECK(v2.size() == 4);
CHECK(v2[2] == 42);
}
}
TEST_CASE("back and front")
{
auto v = VECTOR_T<unsigned>{0, 1, 2, 3, 4, 5, 6, 7, 8, 9};
CHECK(v.front() == 0);
CHECK(v.back() == 9);
}
TEST_CASE("at")
{
auto v = VECTOR_T<unsigned>{0, 1, 2, 3, 4, 5, 6, 7, 8, 9};
CHECK(v.at(0) == 0);
CHECK(v.at(5) == 5);
CHECK_THROWS_AS(v.at(10), const std::out_of_range&);
CHECK_THROWS_AS(v.at(11), const std::out_of_range&);
}
TEST_CASE("push back one element")
{
SECTION("one element")
{
const auto v1 = VECTOR_T<int>{};
auto v2 = v1.push_back(42);
CHECK(v1.size() == 0u);
CHECK(v2.size() == 1u);
CHECK(v2[0] == 42);
}
SECTION("many elements")
{
const auto n = 666u;
auto v = VECTOR_T<unsigned>{};
for (auto i = 0u; i < n; ++i) {
v = v.push_back(i * 42);
CHECK(v.size() == i + 1);
for (decltype(v.size()) j = 0; j < v.size(); ++j)
CHECK(v[j] == j * 42);
}
}
}
TEST_CASE("update")
{
const auto n = 42u;
auto v = make_test_vector(0, n);
SECTION("set")
{
const auto u = v.set(3u, 13u);
CHECK(u.size() == v.size());
CHECK(u[2u] == 2u);
CHECK(u[3u] == 13u);
CHECK(u[4u] == 4u);
CHECK(u[40u] == 40u);
CHECK(v[3u] == 3u);
}
SECTION("set further")
{
auto v = make_test_vector(0, 666);
auto u = v.set(3u, 13u);
u = u.set(200u, 7u);
CHECK(u.size() == v.size());
CHECK(u[2u] == 2u);
CHECK(u[4u] == 4u);
CHECK(u[40u] == 40u);
CHECK(u[600u] == 600u);
CHECK(u[3u] == 13u);
CHECK(u[200u] == 7u);
CHECK(v[3u] == 3u);
CHECK(v[200u] == 200u);
}
SECTION("set further more")
{
auto v = make_test_vector(0, 666u);
for (decltype(v.size()) i = 0; i < v.size(); ++i) {
v = v.set(i, i + 1);
CHECK(v[i] == i + 1);
}
}
SECTION("update")
{
const auto u = v.update(10u, [](auto x) { return x + 10; });
CHECK(u.size() == v.size());
CHECK(u[10u] == 20u);
CHECK(v[40u] == 40u);
const auto w = v.update(40u, [](auto x) { return x - 10; });
CHECK(w.size() == v.size());
CHECK(w[40u] == 30u);
CHECK(v[40u] == 40u);
}
}
TEST_CASE("iterator")
{
const auto n = 666u;
auto v = make_test_vector(0, n);
SECTION("empty vector")
{
auto v = VECTOR_T<unsigned>{};
CHECK(v.begin() == v.end());
}
SECTION("works with range loop")
{
auto i = 0u;
for (const auto& x : v)
CHECK(x == i++);
CHECK(i == v.size());
}
SECTION("works with standard algorithms")
{
auto s = std::vector<unsigned>(n);
std::iota(s.begin(), s.end(), 0u);
std::equal(v.begin(), v.end(), s.begin(), s.end());
}
SECTION("can go back from end")
{
auto expected = n - 1;
auto last = v.end();
CHECK(expected == *--last);
}
SECTION("works with reversed range adaptor")
{
auto r = v | boost::adaptors::reversed;
auto i = n;
for (const auto& x : r)
CHECK(x == --i);
}
SECTION("works with strided range adaptor")
{
auto r = v | boost::adaptors::strided(5);
auto i = 0u;
for (const auto& x : r)
CHECK(x == 5 * i++);
}
SECTION("works reversed")
{
auto i = n;
for (auto iter = v.rbegin(), last = v.rend(); iter != last; ++iter)
CHECK(*iter == --i);
}
SECTION("advance and distance")
{
auto i1 = v.begin();
auto i2 = i1 + 100;
CHECK(100u == *i2);
CHECK(100 == i2 - i1);
CHECK(50u == *(i2 - 50));
CHECK(-30 == (i2 - 30) - i2);
}
}
TEST_CASE("equals")
{
const auto n = 666u;
auto v = make_test_vector(0, n);
CHECK(v == v);
CHECK(v == v.set(42, 42));
CHECK(v != v.set(42, 24));
CHECK(v == v.set(42, 24).set(42, 42));
CHECK(v.set(42, 24) == v.set(42, 24));
CHECK(v != v.push_back(7));
CHECK(v.push_back(7) == v.push_back(7));
CHECK(v.push_back(5) != v.push_back(7));
CHECK(v != v.set(v.size() - 2, 24));
CHECK(v == v.set(v.size() - 2, 24).set(v.size() - 2, v[v.size() - 2]));
}
TEST_CASE("all of")
{
const auto n = 666u;
auto v = make_test_vector(0, n);
SECTION("false")
{
auto res = immer::all_of(v, [](auto x) { return x < 100; });
CHECK(res == false);
}
SECTION("true")
{
auto res = immer::all_of(v, [](auto x) { return x < 1000; });
CHECK(res == true);
}
SECTION("bounded, true")
{
auto res = immer::all_of(
v.begin() + 101, v.end() - 10, [](auto x) { return x > 100; });
CHECK(res == true);
}
SECTION("bounded, false")
{
auto res = immer::all_of(
v.begin() + 101, v.end() - 10, [](auto x) { return x < 600; });
CHECK(res == false);
}
}
TEST_CASE("accumulate")
{
const auto n = 666u;
auto v = make_test_vector(0, n);
auto expected_n = [](auto n) { return n * (n - 1) / 2; };
auto expected_i = [&](auto i, auto n) {
return expected_n(n) - expected_n(i);
};
SECTION("sum collection")
{
auto sum = immer::accumulate(v, 0u);
CHECK(sum == expected_n(v.size()));
}
SECTION("sum range")
{
using namespace std;
{
auto sum = immer::accumulate(begin(v) + 100, begin(v) + 300, 0u);
CHECK(sum == expected_i(100, 300));
}
{
auto sum = immer::accumulate(begin(v) + 31, begin(v) + 300, 0u);
CHECK(sum == expected_i(31, 300));
}
{
auto sum = immer::accumulate(begin(v), begin(v) + 33, 0u);
CHECK(sum == expected_i(0, 33));
}
{
auto sum = immer::accumulate(begin(v) + 100, begin(v) + 660, 0u);
CHECK(sum == expected_i(100, 660));
}
{
auto sum = immer::accumulate(begin(v) + 100, begin(v) + 105, 0u);
CHECK(sum == expected_i(100, 105));
}
{
auto sum = immer::accumulate(begin(v) + 660, begin(v) + 664, 0u);
CHECK(sum == expected_i(660, 664));
}
}
}
TEST_CASE("vector of strings")
{
const auto n = 666u;
auto v = VECTOR_T<std::string>{};
for (auto i = 0u; i < n; ++i)
v = v.push_back(std::to_string(i));
for (decltype(v.size()) i = 0; i < v.size(); ++i)
CHECK(v[i] == std::to_string(i));
SECTION("set")
{
for (auto i = 0u; i < n; ++i)
v = v.set(i, "foo " + std::to_string(i));
for (auto i = 0u; i < n; ++i)
CHECK(v[i] == "foo " + std::to_string(i));
}
}
struct non_default
{
unsigned value;
non_default() = delete;
operator unsigned() const { return value; }
#if IMMER_DEBUG_PRINT
friend std::ostream& operator<<(std::ostream& os, non_default x)
{
os << "ND{" << x.value << "}";
return os;
}
#endif
};
TEST_CASE("non default")
{
const auto n = 666u;
auto v = VECTOR_T<non_default>{};
for (auto i = 0u; i < n; ++i)
v = v.push_back({i});
CHECK_VECTOR_EQUALS(v, boost::irange(0u, n));
SECTION("set")
{
for (auto i = 0u; i < n; ++i)
v = v.set(i, {i + 1});
CHECK_VECTOR_EQUALS(v, boost::irange(1u, n + 1u));
}
}
TEST_CASE("take")
{
const auto n = 666u;
SECTION("anywhere")
{
auto v = make_test_vector(0, n);
for (auto i : test_irange(0u, n)) {
auto vv = v.take(i);
CHECK(vv.size() == i);
CHECK_VECTOR_EQUALS_RANGE(vv, v.begin(), v.begin() + i);
}
}
}
TEST_CASE("exception safety")
{
constexpr auto n = 666u;
using dadaist_vector_t = typename dadaist_wrapper<VECTOR_T<unsigned>>::type;
SECTION("push back")
{
auto v = dadaist_vector_t{};
auto d = dadaism{};
for (auto i = 0u; v.size() < static_cast<decltype(v.size())>(n);) {
auto s = d.next();
try {
v = v.push_back({i});
++i;
} catch (dada_error) {}
CHECK_VECTOR_EQUALS(v, boost::irange(0u, i));
}
CHECK(d.happenings > 0);
IMMER_TRACE_E(d.happenings);
}
SECTION("update")
{
auto v = make_test_vector<dadaist_vector_t>(0, n);
auto d = dadaism{};
for (auto i = 0u; i < n;) {
auto s = d.next();
try {
v = v.update(i, [](auto x) { return dada(), x + 1; });
++i;
} catch (dada_error) {}
CHECK_VECTOR_EQUALS(
v, boost::join(boost::irange(1u, 1u + i), boost::irange(i, n)));
}
CHECK(d.happenings > 0);
IMMER_TRACE_E(d.happenings);
}
SECTION("take")
{
auto v = make_test_vector<dadaist_vector_t>(0, n);
auto d = dadaism{};
for (auto i = 0u; i < n;) {
auto s = d.next();
auto r = dadaist_vector_t{};
try {
r = v.take(i);
CHECK_VECTOR_EQUALS(r, boost::irange(0u, i++));
} catch (dada_error) {
CHECK_VECTOR_EQUALS(r, boost::irange(0u, 0u));
}
}
CHECK(d.happenings > 0);
IMMER_TRACE_E(d.happenings);
}
}
