// // 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/transient_tester.hpp" #include "test/util.hpp" #include #include #include #include #include #include #include #include #ifndef FLEX_VECTOR_T #error "define the vector template to use in FLEX_VECTOR_T" #endif #ifndef VECTOR_T #error "define the vector template to use in VECTOR_T" #endif template > auto make_test_flex_vector(unsigned min, unsigned max) { auto v = V{}; for (auto i = min; i < max; ++i) v = v.push_back({i}); return v; } template > auto make_test_flex_vector_front(unsigned min, unsigned max) { auto v = V{}; for (auto i = max; i > min;) v = v.push_front({--i}); return v; } template auto make_many_test_flex_vector() { using vektor_t = FLEX_VECTOR_T; auto many = std::array{}; std::generate_n(many.begin(), N, [v = vektor_t{}, i = 0u]() mutable { auto r = v; v = v.push_back(i++); return r; }); return many; } template auto make_many_test_flex_vector_front() { using vektor_t = FLEX_VECTOR_T; auto many = std::array{}; std::generate_n(many.begin(), N, [i = 0u]() mutable { return make_test_flex_vector_front(0, i++); }); return many; } template auto make_many_test_flex_vector_front_remainder() { using vektor_t = FLEX_VECTOR_T; auto many = std::array{}; std::generate_n(many.begin(), N, [v = vektor_t{}, i = N - 1]() mutable { auto r = v; v = v.push_front(--i); return r; }); return many; } TEST_CASE("set relaxed") { auto v = make_test_flex_vector_front(0, 666u); for (decltype(v.size()) i = 0; i < v.size(); ++i) { v = v.set(i, i + 1); CHECK(v[i] == i + 1); } } TEST_CASE("push_front") { const auto n = 666u; auto v = FLEX_VECTOR_T{}; for (auto i = 0u; i < n; ++i) { v = v.push_front(i); CHECK(v.size() == i + 1); for (decltype(v.size()) j = 0; j < v.size(); ++j) CHECK(v[v.size() - j - 1] == j); } } TEST_CASE("concat") { #if IMMER_SLOW_TESTS constexpr auto n = 666u; #else constexpr auto n = 101u; #endif auto all_lhs = make_many_test_flex_vector(); auto all_rhs = make_many_test_flex_vector_front_remainder(); SECTION("regular plus regular") { for (auto i : test_irange(0u, n)) { auto c = all_lhs[i] + all_lhs[i]; CHECK_VECTOR_EQUALS( c, boost::join(boost::irange(0u, i), boost::irange(0u, i))); } } SECTION("regular plus relaxed") { for (auto i : test_irange(0u, n)) { auto c = all_lhs[i] + all_rhs[n - i - 1]; CHECK_VECTOR_EQUALS(c, boost::irange(0u, n - 1)); } } } auto make_flex_vector_concat(std::size_t min, std::size_t max) { using vektor_t = FLEX_VECTOR_T; if (max == min) return vektor_t{}; else if (max == min + 1) return vektor_t{}.push_back(min); else { auto mid = min + (max - min) / 2; return make_flex_vector_concat(min, mid) + make_flex_vector_concat(mid, max); } } TEST_CASE("concat recursive") { const auto n = 666u; auto v = make_flex_vector_concat(0, n); CHECK_VECTOR_EQUALS(v, boost::irange(0u, n)); } TEST_CASE("insert") { SECTION("normal") { const auto n = 666u; auto v = make_test_flex_vector(0, n); v = v.insert(42, 100); CHECK_VECTOR_EQUALS(v, boost::join(boost::irange(0u, 42u), boost::join(boost::irange(100u, 101u), boost::irange(42u, n)))); } SECTION("move") { const auto n = 666u; auto v = make_test_flex_vector(0, n); v = std::move(v).insert(42, 100); CHECK_VECTOR_EQUALS(v, boost::join(boost::irange(0u, 42u), boost::join(boost::irange(100u, 101u), boost::irange(42u, n)))); } SECTION("vec") { const auto n = 666u; auto v = make_test_flex_vector(0, n); v = std::move(v).insert(42, {100, 101, 102}); CHECK_VECTOR_EQUALS(v, boost::join(boost::irange(0u, 42u), boost::join(boost::irange(100u, 103u), boost::irange(42u, n)))); } SECTION("vec move") { const auto n = 666u; auto v = make_test_flex_vector(0, n); v = std::move(v).insert(42, {100, 101, 102}); CHECK_VECTOR_EQUALS(v, boost::join(boost::irange(0u, 42u), boost::join(boost::irange(100u, 103u), boost::irange(42u, n)))); } } TEST_CASE("erase") { const auto n = 666u; auto v = make_test_flex_vector(0, n); auto vv = v.erase(0); CHECK_VECTOR_EQUALS(vv, boost::irange(1u, n)); CHECK_VECTOR_EQUALS(v.erase(v.size() - 1), boost::irange(0u, n - 1)); CHECK_VECTOR_EQUALS(v.erase(v.size() - 1), boost::irange(0u, n - 1)); CHECK_VECTOR_EQUALS( v.erase(42), boost::join(boost::irange(0u, 42u), boost::irange(43u, n))); CHECK_VECTOR_EQUALS(v.erase(v.size() - 1, v.size()), boost::irange(0u, n - 1)); CHECK_VECTOR_EQUALS(v.erase(0, 0), boost::irange(0u, n)); CHECK_VECTOR_EQUALS( v.erase(42, 50), boost::join(boost::irange(0u, 42u), boost::irange(50u, n))); } TEST_CASE("accumulate relaxed") { 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") { const auto n = 666u; auto v = make_test_flex_vector_front(0, n); auto sum = immer::accumulate(v, 0u); auto expected = v.size() * (v.size() - 1) / 2; CHECK(sum == expected); } SECTION("sum complex") { const auto n = 20u; auto v = FLEX_VECTOR_T{}; for (auto i = 0u; i < n; ++i) v = v.push_front(i) + v; auto sum = immer::accumulate(v, 0u); auto expected = (1 << n) - n - 1; CHECK(sum == expected); } SECTION("sum range") { using namespace std; const auto n = 666u; auto v = make_test_flex_vector_front(0, n); { 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("equals") { const auto n = 666u; auto v = make_test_flex_vector_front(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])); CHECK(v == v.insert(42, 12).erase(42)); CHECK(v == v.insert(0, 12).erase(0)); } TEST_CASE("equals bugs") { { const auto n = 666u; auto v = make_test_flex_vector(0, n); CHECK(v == v.insert(42, 12).erase(42)); CHECK(v == v.insert(0, 12).erase(0)); } { const auto n = 30u; auto v = make_test_flex_vector(0, n); CHECK(v == v.insert(10, 12).erase(10)); CHECK(v == v.insert(0, 12).erase(0)); } { const auto n = 666u; auto v = make_test_flex_vector(0, n); for (auto i : test_irange(0u, n)) CHECK(v == v.insert(i, 42).erase(i)); } { const auto n = 666u; auto v = make_test_flex_vector_front(0, n); for (auto i : test_irange(0u, n)) CHECK(v == v.insert(i, 42).erase(i)); } { const auto n = 666u; auto v = FLEX_VECTOR_T{}; using size_t = decltype(v.size()); for (auto i : test_irange(0u, n)) { while (v.size() < i) v = std::move(v).push_back(i); auto vv = v; for (auto j : test_irange(size_t{}, v.size())) { auto vz = vv.insert(j, 42).erase(j); CHECK(v == vz); CHECK(vv == vz); vv = vz; } } } } TEST_CASE("take relaxed") { const auto n = 666u; auto v = make_test_flex_vector_front(0, n); for (auto i : test_irange(0u, n)) { auto vv = v.take(i); CHECK_VECTOR_EQUALS_RANGE(vv, v.begin(), v.begin() + i); } } TEST_CASE("drop") { const auto n = 666u; SECTION("regular") { auto v = make_test_flex_vector(0, n); for (auto i : test_irange(0u, n)) { auto vv = v.drop(i); CHECK_VECTOR_EQUALS_RANGE(vv, v.begin() + i, v.end()); } } SECTION("relaxed") { auto v = make_test_flex_vector_front(0, n); for (auto i : test_irange(0u, n)) { auto vv = v.drop(i); CHECK_VECTOR_EQUALS_RANGE(vv, v.begin() + i, v.end()); } } } #if IMMER_SLOW_TESTS TEST_CASE("reconcat") { constexpr auto n = 666u; auto v = make_test_flex_vector_front(0, n); auto all_lhs = make_many_test_flex_vector_front(); auto all_rhs = make_many_test_flex_vector_front_remainder(); for (auto i = 0u; i < n; ++i) { auto vv = all_lhs[i] + all_rhs[n - i]; CHECK_VECTOR_EQUALS(vv, v); CHECK_SLOW(vv == v); } } TEST_CASE("reconcat drop") { constexpr auto n = 666u; auto v = make_test_flex_vector_front(0, n); auto all_lhs = make_many_test_flex_vector_front(); for (auto i = 0u; i < n; ++i) { auto vv = all_lhs[i] + v.drop(i); CHECK_VECTOR_EQUALS(vv, v); CHECK_SLOW(vv == v); } } TEST_CASE("reconcat take") { constexpr auto n = 666u; auto v = make_test_flex_vector_front(0, n); auto all_rhs = make_many_test_flex_vector_front_remainder(); for (auto i = 0u; i < n; ++i) { auto vv = v.take(i) + all_rhs[n - i]; CHECK_VECTOR_EQUALS(vv, v); CHECK_SLOW(vv == v); } } #endif TEST_CASE("reconcat take drop") { const auto n = 666u; auto v = make_test_flex_vector_front(0, n); for (auto i : test_irange(0u, n)) { auto vv = v.take(i) + v.drop(i); CHECK_VECTOR_EQUALS(vv, v); CHECK_SLOW(vv == v); } } TEST_CASE("reconcat take drop feedback") { const auto n = 666u; auto v = make_test_flex_vector_front(0, n); auto vv = v; for (auto i : test_irange(0u, n)) { vv = vv.take(i) + vv.drop(i); CHECK_VECTOR_EQUALS(vv, v); CHECK_SLOW(vv == v); } } TEST_CASE("iterator relaxed") { const auto n = 666u; auto v = make_test_flex_vector_front(0, n); 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(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; CHECK(expected == *--v.end()); } 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("adopt regular vector contents") { const auto n = 666u; auto v = VECTOR_T{}; for (auto i = 0u; i < n; ++i) { v = v.push_back(i); auto fv = FLEX_VECTOR_T{v}; CHECK_VECTOR_EQUALS_AUX(v, fv, [](auto&& v) { return &v; }); } } TEST_CASE("exception safety relaxed") { using dadaist_vector_t = typename dadaist_wrapper>::type; constexpr auto n = 666u; SECTION("push back") { auto half = n / 2; auto v = make_test_flex_vector_front(0, half); auto d = dadaism{}; for (auto i = half; v.size() < static_cast(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_flex_vector_front(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_flex_vector_front(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); } SECTION("concat") { auto v = make_test_flex_vector(0, n); auto d = dadaism{}; for (auto i = 0u; i < n;) { auto lhs = v.take(i); auto rhs = v.drop(i); auto s = d.next(); try { v = lhs + rhs; ++i; } catch (dada_error) {} CHECK_VECTOR_EQUALS(v, boost::irange(0u, n)); } CHECK(d.happenings > 0); IMMER_TRACE_E(d.happenings); } }