63802395c7
Keeps the library up to date.
456 lines
15 KiB
C++
456 lines
15 KiB
C++
// Formatting library for C++ - formatting library implementation tests
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//
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// Copyright (c) 2012 - present, Victor Zverovich
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// All rights reserved.
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//
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// For the license information refer to format.h.
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#define FMT_NOEXCEPT
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#undef FMT_SHARED
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#include "test-assert.h"
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// Include format.cc instead of format.h to test implementation.
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#include <algorithm>
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#include <cstring>
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#include "../src/format.cc"
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#include "fmt/printf.h"
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#include "gmock.h"
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#include "gtest-extra.h"
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#include "util.h"
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#undef max
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using fmt::detail::bigint;
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using fmt::detail::fp;
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using fmt::detail::max_value;
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static_assert(!std::is_copy_constructible<bigint>::value, "");
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static_assert(!std::is_copy_assignable<bigint>::value, "");
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TEST(BigIntTest, Construct) {
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EXPECT_EQ("", fmt::format("{}", bigint()));
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EXPECT_EQ("42", fmt::format("{}", bigint(0x42)));
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EXPECT_EQ("123456789abcedf0", fmt::format("{}", bigint(0x123456789abcedf0)));
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}
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TEST(BigIntTest, Compare) {
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bigint n1(42);
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bigint n2(42);
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EXPECT_EQ(compare(n1, n2), 0);
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n2 <<= 32;
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EXPECT_LT(compare(n1, n2), 0);
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bigint n3(43);
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EXPECT_LT(compare(n1, n3), 0);
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EXPECT_GT(compare(n3, n1), 0);
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bigint n4(42 * 0x100000001);
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EXPECT_LT(compare(n2, n4), 0);
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EXPECT_GT(compare(n4, n2), 0);
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}
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TEST(BigIntTest, AddCompare) {
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EXPECT_LT(
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add_compare(bigint(0xffffffff), bigint(0xffffffff), bigint(1) <<= 64), 0);
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EXPECT_LT(add_compare(bigint(1) <<= 32, bigint(1), bigint(1) <<= 96), 0);
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EXPECT_GT(add_compare(bigint(1) <<= 32, bigint(0), bigint(0xffffffff)), 0);
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EXPECT_GT(add_compare(bigint(0), bigint(1) <<= 32, bigint(0xffffffff)), 0);
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EXPECT_GT(add_compare(bigint(42), bigint(1), bigint(42)), 0);
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EXPECT_GT(add_compare(bigint(0xffffffff), bigint(1), bigint(0xffffffff)), 0);
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EXPECT_LT(add_compare(bigint(10), bigint(10), bigint(22)), 0);
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EXPECT_LT(add_compare(bigint(0x100000010), bigint(0x100000010),
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bigint(0x300000010)),
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0);
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EXPECT_GT(add_compare(bigint(0x1ffffffff), bigint(0x100000002),
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bigint(0x300000000)),
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0);
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EXPECT_EQ(add_compare(bigint(0x1ffffffff), bigint(0x100000002),
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bigint(0x300000001)),
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0);
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EXPECT_LT(add_compare(bigint(0x1ffffffff), bigint(0x100000002),
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bigint(0x300000002)),
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0);
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EXPECT_LT(add_compare(bigint(0x1ffffffff), bigint(0x100000002),
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bigint(0x300000003)),
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0);
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}
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TEST(BigIntTest, ShiftLeft) {
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bigint n(0x42);
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n <<= 0;
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EXPECT_EQ("42", fmt::format("{}", n));
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n <<= 1;
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EXPECT_EQ("84", fmt::format("{}", n));
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n <<= 25;
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EXPECT_EQ("108000000", fmt::format("{}", n));
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}
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TEST(BigIntTest, Multiply) {
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bigint n(0x42);
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EXPECT_THROW(n *= 0, assertion_failure);
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n *= 1;
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EXPECT_EQ("42", fmt::format("{}", n));
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n *= 2;
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EXPECT_EQ("84", fmt::format("{}", n));
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n *= 0x12345678;
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EXPECT_EQ("962fc95e0", fmt::format("{}", n));
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bigint bigmax(max_value<uint32_t>());
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bigmax *= max_value<uint32_t>();
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EXPECT_EQ("fffffffe00000001", fmt::format("{}", bigmax));
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bigmax.assign(max_value<uint64_t>());
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bigmax *= max_value<uint64_t>();
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EXPECT_EQ("fffffffffffffffe0000000000000001", fmt::format("{}", bigmax));
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}
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TEST(BigIntTest, Accumulator) {
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fmt::detail::accumulator acc;
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EXPECT_EQ(acc.lower, 0);
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EXPECT_EQ(acc.upper, 0);
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acc.upper = 12;
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acc.lower = 34;
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EXPECT_EQ(static_cast<uint32_t>(acc), 34);
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acc += 56;
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EXPECT_EQ(acc.lower, 90);
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acc += fmt::detail::max_value<uint64_t>();
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EXPECT_EQ(acc.upper, 13);
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EXPECT_EQ(acc.lower, 89);
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acc >>= 32;
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EXPECT_EQ(acc.upper, 0);
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EXPECT_EQ(acc.lower, 13 * 0x100000000);
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}
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TEST(BigIntTest, Square) {
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bigint n0(0);
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n0.square();
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EXPECT_EQ("0", fmt::format("{}", n0));
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bigint n1(0x100);
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n1.square();
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EXPECT_EQ("10000", fmt::format("{}", n1));
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bigint n2(0xfffffffff);
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n2.square();
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EXPECT_EQ("ffffffffe000000001", fmt::format("{}", n2));
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bigint n3(max_value<uint64_t>());
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n3.square();
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EXPECT_EQ("fffffffffffffffe0000000000000001", fmt::format("{}", n3));
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bigint n4;
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n4.assign_pow10(10);
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EXPECT_EQ("2540be400", fmt::format("{}", n4));
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}
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TEST(BigIntTest, DivModAssignZeroDivisor) {
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bigint zero(0);
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EXPECT_THROW(bigint(0).divmod_assign(zero), assertion_failure);
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EXPECT_THROW(bigint(42).divmod_assign(zero), assertion_failure);
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}
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TEST(BigIntTest, DivModAssignSelf) {
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bigint n(100);
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EXPECT_THROW(n.divmod_assign(n), assertion_failure);
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}
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TEST(BigIntTest, DivModAssignUnaligned) {
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// (42 << 340) / pow(10, 100):
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bigint n1(42);
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n1 <<= 340;
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bigint n2;
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n2.assign_pow10(100);
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int result = n1.divmod_assign(n2);
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EXPECT_EQ(result, 9406);
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EXPECT_EQ("10f8353019583bfc29ffc8f564e1b9f9d819dbb4cf783e4507eca1539220p96",
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fmt::format("{}", n1));
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}
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TEST(BigIntTest, DivModAssign) {
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// 100 / 10:
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bigint n1(100);
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int result = n1.divmod_assign(bigint(10));
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EXPECT_EQ(result, 10);
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EXPECT_EQ("0", fmt::format("{}", n1));
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// pow(10, 100) / (42 << 320):
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n1.assign_pow10(100);
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result = n1.divmod_assign(bigint(42) <<= 320);
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EXPECT_EQ(result, 111);
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EXPECT_EQ("13ad2594c37ceb0b2784c4ce0bf38ace408e211a7caab24308a82e8f10p96",
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fmt::format("{}", n1));
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// 42 / 100:
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bigint n2(42);
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n1.assign_pow10(2);
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result = n2.divmod_assign(n1);
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EXPECT_EQ(result, 0);
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EXPECT_EQ("2a", fmt::format("{}", n2));
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}
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template <bool is_iec559> void run_double_tests() {
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fmt::print("warning: double is not IEC559, skipping FP tests\n");
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}
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template <> void run_double_tests<true>() {
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// Construct from double.
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EXPECT_EQ(fp(1.23), fp(0x13ae147ae147aeu, -52));
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// Compute boundaries:
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fp value;
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// Normalized & not power of 2 - equidistant boundaries:
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auto b = value.assign_with_boundaries(1.23);
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EXPECT_EQ(value, fp(0x0013ae147ae147ae, -52));
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EXPECT_EQ(b.lower, 0x9d70a3d70a3d6c00);
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EXPECT_EQ(b.upper, 0x9d70a3d70a3d7400);
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// Normalized power of 2 - lower boundary is closer:
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b = value.assign_with_boundaries(1.9807040628566084e+28); // 2**94
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EXPECT_EQ(value, fp(0x0010000000000000, 42));
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EXPECT_EQ(b.lower, 0x7ffffffffffffe00);
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EXPECT_EQ(b.upper, 0x8000000000000400);
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// Smallest normalized double - equidistant boundaries:
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b = value.assign_with_boundaries(2.2250738585072014e-308);
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EXPECT_EQ(value, fp(0x0010000000000000, -1074));
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EXPECT_EQ(b.lower, 0x7ffffffffffffc00);
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EXPECT_EQ(b.upper, 0x8000000000000400);
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// Subnormal - equidistant boundaries:
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b = value.assign_with_boundaries(4.9406564584124654e-324);
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EXPECT_EQ(value, fp(0x0000000000000001, -1074));
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EXPECT_EQ(b.lower, 0x4000000000000000);
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EXPECT_EQ(b.upper, 0xc000000000000000);
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}
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TEST(FPTest, DoubleTests) {
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run_double_tests<std::numeric_limits<double>::is_iec559>();
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}
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TEST(FPTest, Normalize) {
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const auto v = fp(0xbeef, 42);
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auto normalized = normalize(v);
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EXPECT_EQ(0xbeef000000000000, normalized.f);
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EXPECT_EQ(-6, normalized.e);
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}
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TEST(FPTest, ComputeFloatBoundaries) {
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struct {
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double x, lower, upper;
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} tests[] = {
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// regular
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{1.5f, 1.4999999403953552, 1.5000000596046448},
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// boundary
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{1.0f, 0.9999999701976776, 1.0000000596046448},
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// min normal
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{1.1754944e-38f, 1.1754942807573643e-38, 1.1754944208872107e-38},
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// max subnormal
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{1.1754942e-38f, 1.1754941406275179e-38, 1.1754942807573643e-38},
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// min subnormal
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{1e-45f, 7.006492321624085e-46, 2.1019476964872256e-45},
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};
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for (auto test : tests) {
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fp vlower = normalize(fp(test.lower));
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fp vupper = normalize(fp(test.upper));
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vlower.f >>= vupper.e - vlower.e;
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vlower.e = vupper.e;
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fp value;
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auto b = value.assign_float_with_boundaries(test.x);
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EXPECT_EQ(vlower.f, b.lower);
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EXPECT_EQ(vupper.f, b.upper);
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}
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}
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TEST(FPTest, Multiply) {
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auto v = fp(123ULL << 32, 4) * fp(56ULL << 32, 7);
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EXPECT_EQ(v.f, 123u * 56u);
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EXPECT_EQ(v.e, 4 + 7 + 64);
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v = fp(123ULL << 32, 4) * fp(567ULL << 31, 8);
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EXPECT_EQ(v.f, (123 * 567 + 1u) / 2);
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EXPECT_EQ(v.e, 4 + 8 + 64);
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}
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TEST(FPTest, GetCachedPower) {
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typedef std::numeric_limits<double> limits;
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for (auto exp = limits::min_exponent; exp <= limits::max_exponent; ++exp) {
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int dec_exp = 0;
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auto fp = fmt::detail::get_cached_power(exp, dec_exp);
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EXPECT_LE(exp, fp.e);
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int dec_exp_step = 8;
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EXPECT_LE(fp.e, exp + dec_exp_step * log2(10));
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EXPECT_DOUBLE_EQ(pow(10, dec_exp), ldexp(static_cast<double>(fp.f), fp.e));
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}
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}
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TEST(FPTest, GetRoundDirection) {
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using fmt::detail::get_round_direction;
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using fmt::detail::round_direction;
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EXPECT_EQ(round_direction::down, get_round_direction(100, 50, 0));
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EXPECT_EQ(round_direction::up, get_round_direction(100, 51, 0));
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EXPECT_EQ(round_direction::down, get_round_direction(100, 40, 10));
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EXPECT_EQ(round_direction::up, get_round_direction(100, 60, 10));
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for (size_t i = 41; i < 60; ++i)
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EXPECT_EQ(round_direction::unknown, get_round_direction(100, i, 10));
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uint64_t max = max_value<uint64_t>();
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EXPECT_THROW(get_round_direction(100, 100, 0), assertion_failure);
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EXPECT_THROW(get_round_direction(100, 0, 100), assertion_failure);
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EXPECT_THROW(get_round_direction(100, 0, 50), assertion_failure);
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// Check that remainder + error doesn't overflow.
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EXPECT_EQ(round_direction::up, get_round_direction(max, max - 1, 2));
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// Check that 2 * (remainder + error) doesn't overflow.
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EXPECT_EQ(round_direction::unknown,
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get_round_direction(max, max / 2 + 1, max / 2));
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// Check that remainder - error doesn't overflow.
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EXPECT_EQ(round_direction::unknown, get_round_direction(100, 40, 41));
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// Check that 2 * (remainder - error) doesn't overflow.
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EXPECT_EQ(round_direction::up, get_round_direction(max, max - 1, 1));
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}
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TEST(FPTest, FixedHandler) {
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struct handler : fmt::detail::fixed_handler {
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char buffer[10];
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handler(int prec = 0) : fmt::detail::fixed_handler() {
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buf = buffer;
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precision = prec;
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}
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};
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int exp = 0;
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handler().on_digit('0', 100, 99, 0, exp, false);
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EXPECT_THROW(handler().on_digit('0', 100, 100, 0, exp, false),
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assertion_failure);
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namespace digits = fmt::detail::digits;
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EXPECT_EQ(handler(1).on_digit('0', 100, 10, 10, exp, false), digits::done);
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// Check that divisor - error doesn't overflow.
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EXPECT_EQ(handler(1).on_digit('0', 100, 10, 101, exp, false), digits::error);
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// Check that 2 * error doesn't overflow.
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uint64_t max = max_value<uint64_t>();
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EXPECT_EQ(handler(1).on_digit('0', max, 10, max - 1, exp, false),
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digits::error);
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}
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TEST(FPTest, GrisuFormatCompilesWithNonIEEEDouble) {
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fmt::memory_buffer buf;
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format_float(0.42, -1, fmt::detail::float_specs(), buf);
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}
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template <typename T> struct value_extractor {
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T operator()(T value) { return value; }
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template <typename U> FMT_NORETURN T operator()(U) {
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throw std::runtime_error(fmt::format("invalid type {}", typeid(U).name()));
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}
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#if FMT_USE_INT128
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// Apple Clang does not define typeid for __int128_t and __uint128_t.
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FMT_NORETURN T operator()(fmt::detail::int128_t) {
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throw std::runtime_error("invalid type __int128_t");
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}
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FMT_NORETURN T operator()(fmt::detail::uint128_t) {
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throw std::runtime_error("invalid type __uint128_t");
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}
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#endif
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};
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TEST(FormatTest, ArgConverter) {
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long long value = max_value<long long>();
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auto arg = fmt::detail::make_arg<fmt::format_context>(value);
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fmt::visit_format_arg(
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fmt::detail::arg_converter<long long, fmt::format_context>(arg, 'd'),
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arg);
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EXPECT_EQ(value, fmt::visit_format_arg(value_extractor<long long>(), arg));
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}
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TEST(FormatTest, FormatNegativeNaN) {
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double nan = std::numeric_limits<double>::quiet_NaN();
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if (std::signbit(-nan))
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EXPECT_EQ("-nan", fmt::format("{}", -nan));
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else
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fmt::print("Warning: compiler doesn't handle negative NaN correctly");
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}
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TEST(FormatTest, StrError) {
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char* message = nullptr;
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char buffer[BUFFER_SIZE];
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EXPECT_ASSERT(fmt::detail::safe_strerror(EDOM, message = nullptr, 0),
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"invalid buffer");
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EXPECT_ASSERT(fmt::detail::safe_strerror(EDOM, message = buffer, 0),
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"invalid buffer");
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buffer[0] = 'x';
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#if defined(_GNU_SOURCE) && !defined(__COVERITY__)
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// Use invalid error code to make sure that safe_strerror returns an error
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// message in the buffer rather than a pointer to a static string.
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int error_code = -1;
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#else
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int error_code = EDOM;
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#endif
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int result =
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fmt::detail::safe_strerror(error_code, message = buffer, BUFFER_SIZE);
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EXPECT_EQ(result, 0);
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size_t message_size = std::strlen(message);
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EXPECT_GE(BUFFER_SIZE - 1u, message_size);
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EXPECT_EQ(get_system_error(error_code), message);
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// safe_strerror never uses buffer on MinGW.
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#if !defined(__MINGW32__) && !defined(__sun)
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result =
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fmt::detail::safe_strerror(error_code, message = buffer, message_size);
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EXPECT_EQ(ERANGE, result);
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result = fmt::detail::safe_strerror(error_code, message = buffer, 1);
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EXPECT_EQ(buffer, message); // Message should point to buffer.
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EXPECT_EQ(ERANGE, result);
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EXPECT_STREQ("", message);
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#endif
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}
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TEST(FormatTest, FormatErrorCode) {
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std::string msg = "error 42", sep = ": ";
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{
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fmt::memory_buffer buffer;
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format_to(buffer, "garbage");
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fmt::detail::format_error_code(buffer, 42, "test");
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EXPECT_EQ("test: " + msg, to_string(buffer));
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}
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{
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fmt::memory_buffer buffer;
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std::string prefix(fmt::inline_buffer_size - msg.size() - sep.size() + 1,
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'x');
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fmt::detail::format_error_code(buffer, 42, prefix);
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EXPECT_EQ(msg, to_string(buffer));
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}
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int codes[] = {42, -1};
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for (size_t i = 0, n = sizeof(codes) / sizeof(*codes); i < n; ++i) {
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// Test maximum buffer size.
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msg = fmt::format("error {}", codes[i]);
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fmt::memory_buffer buffer;
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std::string prefix(fmt::inline_buffer_size - msg.size() - sep.size(), 'x');
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fmt::detail::format_error_code(buffer, codes[i], prefix);
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EXPECT_EQ(prefix + sep + msg, to_string(buffer));
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size_t size = fmt::inline_buffer_size;
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EXPECT_EQ(size, buffer.size());
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buffer.resize(0);
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// Test with a message that doesn't fit into the buffer.
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prefix += 'x';
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fmt::detail::format_error_code(buffer, codes[i], prefix);
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EXPECT_EQ(msg, to_string(buffer));
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}
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}
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TEST(FormatTest, CountCodePoints) {
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EXPECT_EQ(4,
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fmt::detail::count_code_points(
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fmt::basic_string_view<fmt::detail::char8_type>(
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reinterpret_cast<const fmt::detail::char8_type*>("ёжик"))));
|
|
}
|
|
|
|
// Tests fmt::detail::count_digits for integer type Int.
|
|
template <typename Int> void test_count_digits() {
|
|
for (Int i = 0; i < 10; ++i) EXPECT_EQ(1u, fmt::detail::count_digits(i));
|
|
for (Int i = 1, n = 1, end = max_value<Int>() / 10; n <= end; ++i) {
|
|
n *= 10;
|
|
EXPECT_EQ(i, fmt::detail::count_digits(n - 1));
|
|
EXPECT_EQ(i + 1, fmt::detail::count_digits(n));
|
|
}
|
|
}
|
|
|
|
TEST(UtilTest, CountDigits) {
|
|
test_count_digits<uint32_t>();
|
|
test_count_digits<uint64_t>();
|
|
}
|
|
|
|
TEST(UtilTest, WriteFallbackUIntPtr) {
|
|
std::string s;
|
|
fmt::detail::write_ptr<char>(
|
|
std::back_inserter(s),
|
|
fmt::detail::fallback_uintptr(reinterpret_cast<void*>(0xface)), nullptr);
|
|
EXPECT_EQ(s, "0xface");
|
|
}
|