// Copyright (c) 2014-2021 The Bitcoin Core developers // Distributed under the MIT software license, see the accompanying // file COPYING or http://www.opensource.org/licenses/mit-license.php. #include #include #include #include #include #include #include #include #include BOOST_FIXTURE_TEST_SUITE(serfloat_tests, BasicTestingSetup) namespace { uint64_t TestDouble(double f) { uint64_t i = EncodeDouble(f); double f2 = DecodeDouble(i); if (std::isnan(f)) { // NaN is not guaranteed to round-trip exactly. BOOST_CHECK(std::isnan(f2)); } else { // Everything else is. BOOST_CHECK(!std::isnan(f2)); uint64_t i2 = EncodeDouble(f2); BOOST_CHECK_EQUAL(f, f2); BOOST_CHECK_EQUAL(i, i2); } return i; } } // namespace BOOST_AUTO_TEST_CASE(double_serfloat_tests) { // Test specific values against their expected encoding. BOOST_CHECK_EQUAL(TestDouble(0.0), 0U); BOOST_CHECK_EQUAL(TestDouble(-0.0), 0x8000000000000000); BOOST_CHECK_EQUAL(TestDouble(std::numeric_limits::infinity()), 0x7ff0000000000000U); BOOST_CHECK_EQUAL(TestDouble(-std::numeric_limits::infinity()), 0xfff0000000000000); BOOST_CHECK_EQUAL(TestDouble(0.5), 0x3fe0000000000000ULL); BOOST_CHECK_EQUAL(TestDouble(1.0), 0x3ff0000000000000ULL); BOOST_CHECK_EQUAL(TestDouble(2.0), 0x4000000000000000ULL); BOOST_CHECK_EQUAL(TestDouble(4.0), 0x4010000000000000ULL); BOOST_CHECK_EQUAL(TestDouble(785.066650390625), 0x4088888880000000ULL); BOOST_CHECK_EQUAL(TestDouble(3.7243058682384174), 0x400dcb60e0031440); BOOST_CHECK_EQUAL(TestDouble(91.64070592566159), 0x4056e901536d447a); BOOST_CHECK_EQUAL(TestDouble(-98.63087668642575), 0xc058a860489c007a); BOOST_CHECK_EQUAL(TestDouble(4.908737756962054), 0x4013a28c268b2b70); BOOST_CHECK_EQUAL(TestDouble(77.9247330021754), 0x40537b2ed3547804); BOOST_CHECK_EQUAL(TestDouble(40.24732825357566), 0x40441fa873c43dfc); BOOST_CHECK_EQUAL(TestDouble(71.39395607929222), 0x4051d936938f27b6); BOOST_CHECK_EQUAL(TestDouble(58.80100710817612), 0x404d668766a2bd70); BOOST_CHECK_EQUAL(TestDouble(-30.10665786964975), 0xc03e1b4dee1e01b8); BOOST_CHECK_EQUAL(TestDouble(60.15231509068704), 0x404e137f0f969814); BOOST_CHECK_EQUAL(TestDouble(-48.15848711335961), 0xc04814494e445bc6); BOOST_CHECK_EQUAL(TestDouble(26.68450101125353), 0x403aaf3b755169b0); BOOST_CHECK_EQUAL(TestDouble(-65.72071986604303), 0xc0506e2046378ede); BOOST_CHECK_EQUAL(TestDouble(17.95575825512381), 0x4031f4ac92b0a388); BOOST_CHECK_EQUAL(TestDouble(-35.27171863226279), 0xc041a2c7ad17a42a); BOOST_CHECK_EQUAL(TestDouble(-8.58810329425124), 0xc0212d1bdffef538); BOOST_CHECK_EQUAL(TestDouble(88.51393044338977), 0x405620e43c83b1c8); BOOST_CHECK_EQUAL(TestDouble(48.07224932612732), 0x4048093f77466ffc); BOOST_CHECK_EQUAL(TestDouble(9.867348871395659e+117), 0x586f4daeb2459b9f); BOOST_CHECK_EQUAL(TestDouble(-1.5166424385129721e+206), 0xeabe3bbc484bd458); BOOST_CHECK_EQUAL(TestDouble(-8.585156555624594e-275), 0x8707c76eee012429); BOOST_CHECK_EQUAL(TestDouble(2.2794371091628822e+113), 0x5777b2184458f4ee); BOOST_CHECK_EQUAL(TestDouble(-1.1290476594131867e+163), 0xe1c91893d3488bb0); BOOST_CHECK_EQUAL(TestDouble(9.143848423979275e-246), 0x0d0ff76e5f2620a3); BOOST_CHECK_EQUAL(TestDouble(-2.8366718125941117e+81), 0xd0d7ec7e754b394a); BOOST_CHECK_EQUAL(TestDouble(-1.2754409481684012e+229), 0xef80d32f8ec55342); BOOST_CHECK_EQUAL(TestDouble(6.000577060053642e-186), 0x197a1be7c8209b6a); BOOST_CHECK_EQUAL(TestDouble(2.0839423284378986e-302), 0x014c94f8689cb0a5); BOOST_CHECK_EQUAL(TestDouble(-1.422140051483753e+259), 0xf5bd99271d04bb35); BOOST_CHECK_EQUAL(TestDouble(-1.0593973991188853e+46), 0xc97db0cdb72d1046); BOOST_CHECK_EQUAL(TestDouble(2.62945125875249e+190), 0x67779b36366c993b); BOOST_CHECK_EQUAL(TestDouble(-2.920377657275094e+115), 0xd7e7b7b45908e23b); BOOST_CHECK_EQUAL(TestDouble(9.790289014855851e-118), 0x27a3c031cc428bcc); BOOST_CHECK_EQUAL(TestDouble(-4.629317182034961e-114), 0xa866ccf0b753705a); BOOST_CHECK_EQUAL(TestDouble(-1.7674605603846528e+279), 0xf9e8ed383ffc3e25); BOOST_CHECK_EQUAL(TestDouble(2.5308171727712605e+120), 0x58ef5cd55f0ec997); BOOST_CHECK_EQUAL(TestDouble(-1.05034156412799e+54), 0xcb25eea1b9350fa0); // Test extreme values BOOST_CHECK_EQUAL(TestDouble(std::numeric_limits::min()), 0x10000000000000); BOOST_CHECK_EQUAL(TestDouble(-std::numeric_limits::min()), 0x8010000000000000); BOOST_CHECK_EQUAL(TestDouble(std::numeric_limits::max()), 0x7fefffffffffffff); BOOST_CHECK_EQUAL(TestDouble(-std::numeric_limits::max()), 0xffefffffffffffff); BOOST_CHECK_EQUAL(TestDouble(std::numeric_limits::lowest()), 0xffefffffffffffff); BOOST_CHECK_EQUAL(TestDouble(-std::numeric_limits::lowest()), 0x7fefffffffffffff); BOOST_CHECK_EQUAL(TestDouble(std::numeric_limits::denorm_min()), 0x1); BOOST_CHECK_EQUAL(TestDouble(-std::numeric_limits::denorm_min()), 0x8000000000000001); // Note that all NaNs are encoded the same way. BOOST_CHECK_EQUAL(TestDouble(std::numeric_limits::quiet_NaN()), 0x7ff8000000000000); BOOST_CHECK_EQUAL(TestDouble(-std::numeric_limits::quiet_NaN()), 0x7ff8000000000000); BOOST_CHECK_EQUAL(TestDouble(std::numeric_limits::signaling_NaN()), 0x7ff8000000000000); BOOST_CHECK_EQUAL(TestDouble(-std::numeric_limits::signaling_NaN()), 0x7ff8000000000000); // Construct doubles to test from the encoding. static_assert(sizeof(double) == 8); static_assert(sizeof(uint64_t) == 8); for (int j = 0; j < 1000; ++j) { // Iterate over 9 specific bits exhaustively; the others are chosen randomly. // These specific bits are the sign bit, and the 2 top and bottom bits of // exponent and mantissa in the IEEE754 binary64 format. for (int x = 0; x < 512; ++x) { uint64_t v = m_rng.randbits(64); int x_pos = 0; for (int v_pos : {0, 1, 50, 51, 52, 53, 61, 62, 63}) { v &= ~(uint64_t{1} << v_pos); if ((x >> (x_pos++)) & 1) v |= (uint64_t{1} << v_pos); } double f; memcpy(&f, &v, 8); TestDouble(f); } } } /* Python code to generate the below hashes: def reversed_hex(x): return bytes(reversed(x)).hex() def dsha256(x): return hashlib.sha256(hashlib.sha256(x).digest()).digest() reversed_hex(dsha256(b''.join(struct.pack('> val; double j = DecodeDouble(val); BOOST_CHECK_MESSAGE(i == j, "decoded:" << j << " expected:" << i); } } BOOST_AUTO_TEST_SUITE_END()