// Copyright 2015-2017 Hans Dembinski // // Distributed under the Boost Software License, Version 1.0. // (See accompanying file LICENSE_1_0.txt // or copy at http://www.boost.org/LICENSE_1_0.txt) #include #include #include #include #include #include #include #include #include #include #include #include #include #include "allocator.hpp" #include "is_close.hpp" #include "throw_exception.hpp" using namespace boost::histogram; using namespace std::literals; template auto str(const T& t) { std::ostringstream os; os << t; return os.str(); } template void tests() { using Storage = storage_adaptor; // ctor, copy, move { Storage a; a.reset(2); Storage b(a); Storage c; c = a; BOOST_TEST_EQ(std::distance(a.begin(), a.end()), 2); BOOST_TEST_EQ(a.size(), 2); BOOST_TEST_EQ(b.size(), 2); BOOST_TEST_EQ(c.size(), 2); Storage d(std::move(a)); BOOST_TEST_EQ(d.size(), 2); Storage e; e = std::move(d); BOOST_TEST_EQ(e.size(), 2); const auto t = T(); storage_adaptor g(t); // tests converting ctor BOOST_TEST_EQ(g.size(), 0); const auto u = std::vector(3, 1); Storage h(u); // tests converting ctor BOOST_TEST_EQ(h.size(), 3); BOOST_TEST_EQ(h[0], 1); BOOST_TEST_EQ(h[1], 1); BOOST_TEST_EQ(h[2], 1); } // increment, add, sub, set, reset, compare { Storage a; a.reset(1); ++a[0]; const auto save = a[0]++; BOOST_TEST_EQ(save, 1); BOOST_TEST_EQ(a[0], 2); a.reset(2); BOOST_TEST_EQ(a.size(), 2); ++a[0]; a[0] += 2; a[1] += 5; BOOST_TEST_EQ(a[0], 3); BOOST_TEST_EQ(a[1], 5); a[0] -= 2; a[1] -= 5; BOOST_TEST_EQ(a[0], 1); BOOST_TEST_EQ(a[1], 0); a[1] = 9; BOOST_TEST_EQ(a[0], 1); BOOST_TEST_EQ(a[1], 9); BOOST_TEST_LT(a[0], 2); BOOST_TEST_LT(0, a[1]); BOOST_TEST_GT(a[1], 4); BOOST_TEST_GT(3, a[0]); a[1] = a[0]; BOOST_TEST_EQ(a[0], 1); BOOST_TEST_EQ(a[1], 1); a.reset(0); BOOST_TEST_EQ(a.size(), 0); } // copy { Storage a; a.reset(1); ++a[0]; Storage b; b.reset(2); BOOST_TEST(!(a == b)); b = a; BOOST_TEST(a == b); BOOST_TEST_EQ(b.size(), 1); BOOST_TEST_EQ(b[0], 1); Storage c(a); BOOST_TEST(a == c); BOOST_TEST_EQ(c.size(), 1); BOOST_TEST_EQ(c[0], 1); } // move { Storage a; a.reset(1); ++a[0]; Storage b; BOOST_TEST(!(a == b)); b = std::move(a); BOOST_TEST_EQ(b.size(), 1); BOOST_TEST_EQ(b[0], 1); Storage c(std::move(b)); BOOST_TEST_EQ(c.size(), 1); BOOST_TEST_EQ(c[0], 1); } { Storage a; a.reset(1); a[0] += 2; BOOST_TEST_EQ(str(a[0]), "2"s); } } template void mixed_tests() { // comparison { A a, b; a.reset(1); b.reset(1); B c, d; c.reset(1); d.reset(2); ++a[0]; ++b[0]; c[0] += 2; d[0] = 3; d[1] = 5; BOOST_TEST_EQ(a[0], 1); BOOST_TEST_EQ(b[0], 1); BOOST_TEST_EQ(c[0], 2); BOOST_TEST_EQ(d[0], 3); BOOST_TEST_EQ(d[1], 5); BOOST_TEST(a == a); BOOST_TEST(a == b); BOOST_TEST(!(a == c)); BOOST_TEST(!(a == d)); } // ctor, copy, move, assign { A a; a.reset(2); ++a[1]; B b(a); B c; c = a; BOOST_TEST_EQ(c[0], 0); BOOST_TEST_EQ(c[1], 1); c = A(); BOOST_TEST_EQ(c.size(), 0); B d(std::move(a)); B e; e = std::move(d); BOOST_TEST_EQ(e[0], 0); BOOST_TEST_EQ(e[1], 1); } } int main() { tests>(); tests>(); tests>(); tests>(); tests>(); mixed_tests>, storage_adaptor>>(); mixed_tests, storage_adaptor>>(); mixed_tests>, unlimited_storage<>>(); mixed_tests>, storage_adaptor>>(); // special case for division of map-based storage_adaptor { auto a = storage_adaptor>(); a.reset(2); a[0] /= 2; BOOST_TEST_EQ(a[0], 0); a[0] = 2; a[0] /= 2; BOOST_TEST_EQ(a[0], 1); a[1] /= std::numeric_limits::quiet_NaN(); BOOST_TEST(std::isnan(static_cast(a[1]))); } // with accumulators::weighted_sum { auto a = storage_adaptor>>(); a.reset(1); ++a[0]; a[0] += 1; a[0] += 2; a[0] += accumulators::weighted_sum(1, 2); BOOST_TEST_EQ(a[0].value(), 5); BOOST_TEST_EQ(a[0].variance(), 6); a[0] *= 2; BOOST_TEST_EQ(a[0].value(), 10); BOOST_TEST_EQ(a[0].variance(), 24); } // with accumulators::weighted_mean { auto a = storage_adaptor>>(); a.reset(1); a[0](/* sample */ 1); a[0](weight(2), /* sample */ 2); accumulators::weighted_mean b; b(weight(3), 3); a[0] += b; accumulators::weighted_mean c; c(weight(1), 1); c(weight(2), 2); c(weight(3), 3); BOOST_TEST_EQ(a[0].sum_of_weights(), c.sum_of_weights()); BOOST_TEST_IS_CLOSE(a[0].value(), c.value(), 1e-3); BOOST_TEST_IS_CLOSE(a[0].variance(), c.variance(), 1e-3); } // exceeding array capacity { auto a = storage_adaptor>(); a.reset(10); // should not throw BOOST_TEST_THROWS(a.reset(11), std::length_error); auto b = storage_adaptor>(); b.reset(11); BOOST_TEST_THROWS(a = b, std::length_error); } // test sparsity of map backend { tracing_allocator_db db; tracing_allocator alloc(db); using map_t = std::map, tracing_allocator>>; using A = storage_adaptor; auto a = A(alloc); // MSVC implementation allocates some structures for debugging const auto baseline = db.second; a.reset(10); BOOST_TEST_EQ(db.first, baseline); // nothing allocated yet // queries do not allocate BOOST_TEST_EQ(a[0], 0); BOOST_TEST_EQ(a[9], 0); BOOST_TEST_EQ(db.first, baseline); ++a[5]; // causes one allocation const auto node = db.first - baseline; BOOST_TEST_EQ(a[5], 1); a[4] += 2; // causes one allocation BOOST_TEST_EQ(a[4], 2); BOOST_TEST_EQ(db.first, baseline + 2 * node); a[3] -= 2; // causes one allocation BOOST_TEST_EQ(a[3], -2); BOOST_TEST_EQ(db.first, baseline + 3 * node); a[2] *= 2; // no allocation BOOST_TEST_EQ(db.first, baseline + 3 * node); a[2] /= 2; // no allocation BOOST_TEST_EQ(db.first, baseline + 3 * node); a[4] = 0; // causes one deallocation BOOST_TEST_EQ(db.first, baseline + 2 * node); auto b = storage_adaptor>(); b.reset(5); ++b[2]; a = b; // only one new allocation for non-zero value BOOST_TEST_EQ(db.first, baseline + node); } return boost::report_errors(); }