blob: 437384a727715e17ed7208dc25fc76137f3050f4 (
plain) (
tree)
|
|
//
// 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 <immer/experimental/dvektor.hpp>
#include <boost/range/adaptors.hpp>
#include <algorithm>
#include <numeric>
#include <vector>
#include <iostream>
#include <doctest.h>
using namespace immer;
TEST_CASE("instantiation")
{
auto v = dvektor<int>{};
CHECK(v.size() == 0u);
}
TEST_CASE("push back one element")
{
SUBCASE("one element")
{
const auto v1 = dvektor<int>{};
auto v2 = v1.push_back(42);
CHECK(v1.size() == 0u);
CHECK(v2.size() == 1u);
CHECK(v2[0] == 42);
}
SUBCASE("many elements")
{
const auto n = 666u;
auto v = dvektor<unsigned>{};
for (auto i = 0u; i < n; ++i) {
v = v.push_back(i * 10);
CHECK(v.size() == i + 1);
for (auto j = 0u; j < v.size(); ++j)
CHECK(i + v[j] == i + j * 10);
}
}
}
TEST_CASE("update")
{
const auto n = 42u;
auto v = dvektor<unsigned>{};
for (auto i = 0u; i < n; ++i)
v = v.push_back(i);
SUBCASE("assoc")
{
const auto u = v.assoc(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);
}
SUBCASE("assoc further")
{
for (auto i = n; i < 666; ++i)
v = v.push_back(i);
auto u = v.assoc(3u, 13u);
u = u.assoc(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);
}
SUBCASE("assoc further more")
{
auto v = immer::dvektor<unsigned, 4>{};
for (auto i = n; i < 1000u; ++i)
v = v.push_back(i);
for (auto i = 0u; i < v.size(); ++i) {
v = v.assoc(i, i + 1);
CHECK(v[i] == i + 1);
}
}
SUBCASE("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);
}
}
#if IMMER_SLOW_TESTS
TEST_CASE("big")
{
const auto n = 1000000;
auto v = dvektor<unsigned>{};
for (auto i = 0u; i < n; ++i)
v = v.push_back(i);
SUBCASE("read")
{
for (auto i = 0u; i < n; ++i)
CHECK(v[i] == i);
}
SUBCASE("assoc")
{
for (auto i = 0u; i < n; ++i) {
v = v.assoc(i, i + 1);
CHECK(v[i] == i + 1);
}
}
}
#endif // IMMER_SLOW_TESTS
TEST_CASE("iterator")
{
const auto n = 666u;
auto v = dvektor<unsigned>{};
for (auto i = 0u; i < n; ++i)
v = v.push_back(i);
SUBCASE("works with range loop")
{
auto i = 0u;
for (const auto& x : v)
CHECK(x == i++);
CHECK(i == v.size());
}
SUBCASE("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());
}
SUBCASE("can go back from end") { CHECK(n - 1 == *--v.end()); }
SUBCASE("works with reversed range adaptor")
{
auto r = v | boost::adaptors::reversed;
auto i = n;
for (const auto& x : r)
CHECK(x == --i);
}
SUBCASE("works with strided range adaptor")
{
auto r = v | boost::adaptors::strided(5);
auto i = 0u;
for (const auto& x : r)
CHECK(x == 5 * i++);
}
SUBCASE("works reversed")
{
auto i = n;
for (auto iter = v.rbegin(), last = v.rend(); iter != last; ++iter)
CHECK(*iter == --i);
}
SUBCASE("advance and distance")
{
auto i1 = v.begin();
auto i2 = i1 + 100;
CHECK(*i2 == 100u);
CHECK(i2 - i1 == 100);
CHECK(*(i2 - 50) == 50u);
CHECK((i2 - 30) - i2 == -30);
}
}
|