libcxx/test/std/numerics/numeric.ops/numeric.ops.midpoint/midpoint.float.pass.cpp

//===----------------------------------------------------------------------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
//
// UNSUPPORTED: c++98, c++03, c++11, c++14, c++17
// <numeric>

// template <class _Float>
// _Tp midpoint(_Float __a, _Float __b) noexcept
//

#include <numeric>
#include <cassert>

#include "test_macros.h"
#include "fp_compare.h"

//  Totally arbitrary picks for precision
template <typename T>
constexpr T fp_error_pct();

template <>
constexpr float fp_error_pct<float>() { return 1.0e-4f; }

template <>
constexpr double fp_error_pct<double>() { return 1.0e-12; }

template <>
constexpr long double fp_error_pct<long double>() { return 1.0e-13l; }


template <typename T>
void fp_test()
{
    ASSERT_SAME_TYPE(T, decltype(std::midpoint(T(), T())));
    ASSERT_NOEXCEPT(             std::midpoint(T(), T()));

    constexpr T maxV = std::numeric_limits<T>::max();
    constexpr T minV = std::numeric_limits<T>::min();
    
//  Things that can be compared exactly
    assert((std::midpoint(T(0), T(0)) == T(0)));
    assert((std::midpoint(T(2), T(4)) == T(3)));
    assert((std::midpoint(T(4), T(2)) == T(3)));
    assert((std::midpoint(T(3), T(4)) == T(3.5)));
    assert((std::midpoint(T(0), T(0.4)) == T(0.2)));

//  Things that can't be compared exactly
    constexpr T pct = fp_error_pct<T>();
    assert((fptest_close_pct(std::midpoint(T( 1.3), T(11.4)), T( 6.35),    pct)));
    assert((fptest_close_pct(std::midpoint(T(11.33), T(31.45)), T(21.39),  pct)));
    assert((fptest_close_pct(std::midpoint(T(-1.3), T(11.4)), T( 5.05),    pct)));
    assert((fptest_close_pct(std::midpoint(T(11.4), T(-1.3)), T( 5.05),    pct)));
    assert((fptest_close_pct(std::midpoint(T(0.1),  T(0.4)),  T(0.25),     pct)));

    assert((fptest_close_pct(std::midpoint(T(11.2345), T(14.5432)), T(12.88885),  pct)));
    
//  From e to pi
    assert((fptest_close_pct(std::midpoint(T(2.71828182845904523536028747135266249775724709369995),
                                      T(3.14159265358979323846264338327950288419716939937510)),
                                      T(2.92993724102441923691146542731608269097720824653752),  pct)));

    assert((fptest_close_pct(std::midpoint(maxV, T(0)), maxV/2, pct)));
    assert((fptest_close_pct(std::midpoint(T(0), maxV), maxV/2, pct)));
    assert((fptest_close_pct(std::midpoint(minV, T(0)), minV/2, pct)));
    assert((fptest_close_pct(std::midpoint(T(0), minV), minV/2, pct)));
    assert((fptest_close_pct(std::midpoint(maxV, maxV), maxV,   pct)));
    assert((fptest_close_pct(std::midpoint(minV, minV), minV,   pct)));

//  Denormalized values
//  TODO

//  Check two values "close to each other"
    T d1 = 3.14;
    T d0 = std::nexttoward(d1, T(2));
    T d2 = std::nexttoward(d1, T(5));
    assert(d0 < d1);  // sanity checking
    assert(d1 < d2);  // sanity checking

//  Since there's nothing in between, the midpoint has to be one or the other
    T res;
    res = std::midpoint(d0, d1);
    assert(res == d0 || res == d1);
    assert(d0 <= res);
    assert(res <= d1);
    res = std::midpoint(d1, d0);
    assert(res == d0 || res == d1);
    assert(d0 <= res);
    assert(res <= d1);

    res = std::midpoint(d1, d2);
    assert(res == d1 || res == d2);
    assert(d1 <= res);
    assert(res <= d2);
    res = std::midpoint(d2, d1);
    assert(res == d1 || res == d2);
    assert(d1 <= res);
    assert(res <= d2);
}


int main (int, char**)
{
    fp_test<float>();
    fp_test<double>();
    fp_test<long double>();

    return 0;
}