// Formatting library for C++ - formatting library tests // // Copyright (c) 2012 - present, Victor Zverovich // All rights reserved. // // For the license information refer to format.h. #include #include #include #include #include #include #include #include #include // Check if fmt/format.h compiles with windows.h included before it. #ifdef _WIN32 # include #endif #include "fmt/color.h" #include "fmt/format.h" #include "gmock.h" #include "gtest-extra.h" #include "mock-allocator.h" #include "util.h" #undef ERROR #undef min #undef max using std::size_t; using fmt::basic_memory_buffer; using fmt::basic_writer; using fmt::format; using fmt::format_error; using fmt::memory_buffer; using fmt::string_view; using fmt::wmemory_buffer; using testing::Return; using testing::StrictMock; namespace { #if !FMT_GCC_VERSION || FMT_GCC_VERSION >= 408 template bool check_enabled_formatter() { static_assert(std::is_default_constructible>::value, ""); return true; } template void check_enabled_formatters() { auto dummy = {check_enabled_formatter()...}; (void)dummy; } TEST(FormatterTest, TestFormattersEnabled) { check_enabled_formatters(); check_enabled_formatters(); } #endif // Format value using the standard library. template void std_format(const T& value, std::basic_string& result) { std::basic_ostringstream os; os << value; result = os.str(); } #ifdef __MINGW32__ // Workaround a bug in formatting long double in MinGW. void std_format(long double value, std::string& result) { char buffer[100]; safe_sprintf(buffer, "%Lg", value); result = buffer; } void std_format(long double value, std::wstring& result) { wchar_t buffer[100]; swprintf(buffer, L"%Lg", value); result = buffer; } #endif // Checks if writing value to BasicWriter produces the same result // as writing it to std::basic_ostringstream. template ::testing::AssertionResult check_write(const T& value, const char* type) { fmt::basic_memory_buffer buffer; typedef fmt::back_insert_range> range; fmt::basic_writer writer(buffer); writer.write(value); std::basic_string actual = to_string(buffer); std::basic_string expected; std_format(value, expected); if (expected == actual) return ::testing::AssertionSuccess(); return ::testing::AssertionFailure() << "Value of: (Writer<" << type << ">() << value).str()\n" << " Actual: " << actual << "\n" << "Expected: " << expected << "\n"; } struct AnyWriteChecker { template ::testing::AssertionResult operator()(const char*, const T& value) const { ::testing::AssertionResult result = check_write(value, "char"); return result ? check_write(value, "wchar_t") : result; } }; template struct WriteChecker { template ::testing::AssertionResult operator()(const char*, const T& value) const { return check_write(value, "char"); } }; // Checks if writing value to BasicWriter produces the same result // as writing it to std::ostringstream both for char and wchar_t. #define CHECK_WRITE(value) EXPECT_PRED_FORMAT1(AnyWriteChecker(), value) #define CHECK_WRITE_CHAR(value) EXPECT_PRED_FORMAT1(WriteChecker(), value) #define CHECK_WRITE_WCHAR(value) \ EXPECT_PRED_FORMAT1(WriteChecker(), value) } // namespace struct uint32_pair { uint32_t u[2]; }; TEST(UtilTest, BitCast) { auto s = fmt::internal::bit_cast(uint64_t{42}); EXPECT_EQ(fmt::internal::bit_cast(s), 42ull); s = fmt::internal::bit_cast(uint64_t(~0ull)); EXPECT_EQ(fmt::internal::bit_cast(s), ~0ull); } TEST(UtilTest, Increment) { char s[10] = "123"; increment(s); EXPECT_STREQ("124", s); s[2] = '8'; increment(s); EXPECT_STREQ("129", s); increment(s); EXPECT_STREQ("130", s); s[1] = s[2] = '9'; increment(s); EXPECT_STREQ("200", s); } TEST(UtilTest, ParseNonnegativeInt) { if (std::numeric_limits::max() != static_cast(static_cast(1) << 31)) { fmt::print("Skipping parse_nonnegative_int test\n"); return; } fmt::string_view s = "10000000000"; auto begin = s.begin(), end = s.end(); EXPECT_THROW_MSG( parse_nonnegative_int(begin, end, fmt::internal::error_handler()), fmt::format_error, "number is too big"); s = "2147483649"; begin = s.begin(); end = s.end(); EXPECT_THROW_MSG( parse_nonnegative_int(begin, end, fmt::internal::error_handler()), fmt::format_error, "number is too big"); } TEST(IteratorTest, CountingIterator) { fmt::internal::counting_iterator it; auto prev = it++; EXPECT_EQ(prev.count(), 0); EXPECT_EQ(it.count(), 1); } TEST(IteratorTest, TruncatingIterator) { char* p = nullptr; fmt::internal::truncating_iterator it(p, 3); auto prev = it++; EXPECT_EQ(prev.base(), p); EXPECT_EQ(it.base(), p + 1); } TEST(IteratorTest, TruncatingBackInserter) { std::string buffer; auto bi = std::back_inserter(buffer); fmt::internal::truncating_iterator it(bi, 2); *it++ = '4'; *it++ = '2'; *it++ = '1'; EXPECT_EQ(buffer.size(), 2); EXPECT_EQ(buffer, "42"); } TEST(IteratorTest, IsOutputIterator) { EXPECT_TRUE(fmt::internal::is_output_iterator::value); EXPECT_FALSE(fmt::internal::is_output_iterator::value); EXPECT_FALSE(fmt::internal::is_output_iterator::value); EXPECT_TRUE(fmt::internal::is_output_iterator< std::back_insert_iterator>::value); EXPECT_TRUE(fmt::internal::is_output_iterator::value); EXPECT_FALSE( fmt::internal::is_output_iterator::value); EXPECT_FALSE(fmt::internal::is_output_iterator>::value); EXPECT_TRUE( fmt::internal::is_output_iterator::iterator>::value); EXPECT_FALSE(fmt::internal::is_output_iterator< std::list::const_iterator>::value); EXPECT_FALSE(fmt::internal::is_output_iterator::value); } TEST(MemoryBufferTest, Ctor) { basic_memory_buffer buffer; EXPECT_EQ(static_cast(0), buffer.size()); EXPECT_EQ(123u, buffer.capacity()); } static void check_forwarding(mock_allocator& alloc, allocator_ref>& ref) { int mem; // Check if value_type is properly defined. allocator_ref>::value_type* ptr = &mem; // Check forwarding. EXPECT_CALL(alloc, allocate(42)).WillOnce(testing::Return(ptr)); ref.allocate(42); EXPECT_CALL(alloc, deallocate(ptr, 42)); ref.deallocate(ptr, 42); } TEST(AllocatorTest, allocator_ref) { StrictMock> alloc; typedef allocator_ref> test_allocator_ref; test_allocator_ref ref(&alloc); // Check if allocator_ref forwards to the underlying allocator. check_forwarding(alloc, ref); test_allocator_ref ref2(ref); check_forwarding(alloc, ref2); test_allocator_ref ref3; EXPECT_EQ(nullptr, ref3.get()); ref3 = ref; check_forwarding(alloc, ref3); } typedef allocator_ref> TestAllocator; static void check_move_buffer( const char* str, basic_memory_buffer& buffer) { std::allocator* alloc = buffer.get_allocator().get(); basic_memory_buffer buffer2(std::move(buffer)); // Move shouldn't destroy the inline content of the first buffer. EXPECT_EQ(str, std::string(&buffer[0], buffer.size())); EXPECT_EQ(str, std::string(&buffer2[0], buffer2.size())); EXPECT_EQ(5u, buffer2.capacity()); // Move should transfer allocator. EXPECT_EQ(nullptr, buffer.get_allocator().get()); EXPECT_EQ(alloc, buffer2.get_allocator().get()); } TEST(MemoryBufferTest, MoveCtor) { std::allocator alloc; basic_memory_buffer buffer((TestAllocator(&alloc))); const char test[] = "test"; buffer.append(test, test + 4); check_move_buffer("test", buffer); // Adding one more character fills the inline buffer, but doesn't cause // dynamic allocation. buffer.push_back('a'); check_move_buffer("testa", buffer); const char* inline_buffer_ptr = &buffer[0]; // Adding one more character causes the content to move from the inline to // a dynamically allocated buffer. buffer.push_back('b'); basic_memory_buffer buffer2(std::move(buffer)); // Move should rip the guts of the first buffer. EXPECT_EQ(inline_buffer_ptr, &buffer[0]); EXPECT_EQ("testab", std::string(&buffer2[0], buffer2.size())); EXPECT_GT(buffer2.capacity(), 5u); } static void check_move_assign_buffer(const char* str, basic_memory_buffer& buffer) { basic_memory_buffer buffer2; buffer2 = std::move(buffer); // Move shouldn't destroy the inline content of the first buffer. EXPECT_EQ(str, std::string(&buffer[0], buffer.size())); EXPECT_EQ(str, std::string(&buffer2[0], buffer2.size())); EXPECT_EQ(5u, buffer2.capacity()); } TEST(MemoryBufferTest, MoveAssignment) { basic_memory_buffer buffer; const char test[] = "test"; buffer.append(test, test + 4); check_move_assign_buffer("test", buffer); // Adding one more character fills the inline buffer, but doesn't cause // dynamic allocation. buffer.push_back('a'); check_move_assign_buffer("testa", buffer); const char* inline_buffer_ptr = &buffer[0]; // Adding one more character causes the content to move from the inline to // a dynamically allocated buffer. buffer.push_back('b'); basic_memory_buffer buffer2; buffer2 = std::move(buffer); // Move should rip the guts of the first buffer. EXPECT_EQ(inline_buffer_ptr, &buffer[0]); EXPECT_EQ("testab", std::string(&buffer2[0], buffer2.size())); EXPECT_GT(buffer2.capacity(), 5u); } TEST(MemoryBufferTest, Grow) { typedef allocator_ref> Allocator; typedef basic_memory_buffer Base; mock_allocator alloc; struct TestMemoryBuffer : Base { TestMemoryBuffer(Allocator alloc) : Base(alloc) {} void grow(std::size_t size) { Base::grow(size); } } buffer((Allocator(&alloc))); buffer.resize(7); using fmt::internal::to_unsigned; for (int i = 0; i < 7; ++i) buffer[to_unsigned(i)] = i * i; EXPECT_EQ(10u, buffer.capacity()); int mem[20]; mem[7] = 0xdead; EXPECT_CALL(alloc, allocate(20)).WillOnce(Return(mem)); buffer.grow(20); EXPECT_EQ(20u, buffer.capacity()); // Check if size elements have been copied for (int i = 0; i < 7; ++i) EXPECT_EQ(i * i, buffer[to_unsigned(i)]); // and no more than that. EXPECT_EQ(0xdead, buffer[7]); EXPECT_CALL(alloc, deallocate(mem, 20)); } TEST(MemoryBufferTest, Allocator) { typedef allocator_ref> TestAllocator; basic_memory_buffer buffer; EXPECT_EQ(nullptr, buffer.get_allocator().get()); StrictMock> alloc; char mem; { basic_memory_buffer buffer2( (TestAllocator(&alloc))); EXPECT_EQ(&alloc, buffer2.get_allocator().get()); std::size_t size = 2 * fmt::inline_buffer_size; EXPECT_CALL(alloc, allocate(size)).WillOnce(Return(&mem)); buffer2.reserve(size); EXPECT_CALL(alloc, deallocate(&mem, size)); } } TEST(MemoryBufferTest, ExceptionInDeallocate) { typedef allocator_ref> TestAllocator; StrictMock> alloc; basic_memory_buffer buffer((TestAllocator(&alloc))); std::size_t size = 2 * fmt::inline_buffer_size; std::vector mem(size); { EXPECT_CALL(alloc, allocate(size)).WillOnce(Return(&mem[0])); buffer.resize(size); std::fill(&buffer[0], &buffer[0] + size, 'x'); } std::vector mem2(2 * size); { EXPECT_CALL(alloc, allocate(2 * size)).WillOnce(Return(&mem2[0])); std::exception e; EXPECT_CALL(alloc, deallocate(&mem[0], size)).WillOnce(testing::Throw(e)); EXPECT_THROW(buffer.reserve(2 * size), std::exception); EXPECT_EQ(&mem2[0], &buffer[0]); // Check that the data has been copied. for (std::size_t i = 0; i < size; ++i) EXPECT_EQ('x', buffer[i]); } EXPECT_CALL(alloc, deallocate(&mem2[0], 2 * size)); } #ifdef _WIN32 TEST(UtilTest, UTF16ToUTF8) { std::string s = "ёжик"; fmt::internal::utf16_to_utf8 u(L"\x0451\x0436\x0438\x043A"); EXPECT_EQ(s, u.str()); EXPECT_EQ(s.size(), u.size()); } TEST(UtilTest, UTF16ToUTF8EmptyString) { std::string s = ""; fmt::internal::utf16_to_utf8 u(L""); EXPECT_EQ(s, u.str()); EXPECT_EQ(s.size(), u.size()); } TEST(UtilTest, UTF8ToUTF16) { std::string s = "лошадка"; fmt::internal::utf8_to_utf16 u(s.c_str()); EXPECT_EQ(L"\x043B\x043E\x0448\x0430\x0434\x043A\x0430", u.str()); EXPECT_EQ(7, u.size()); } TEST(UtilTest, UTF8ToUTF16EmptyString) { std::string s = ""; fmt::internal::utf8_to_utf16 u(s.c_str()); EXPECT_EQ(L"", u.str()); EXPECT_EQ(s.size(), u.size()); } template void check_utf_conversion_error( const char* message, fmt::basic_string_view str = fmt::basic_string_view(0, 1)) { fmt::memory_buffer out; fmt::internal::format_windows_error(out, ERROR_INVALID_PARAMETER, message); fmt::system_error error(0, ""); try { (Converter)(str); } catch (const fmt::system_error& e) { error = e; } EXPECT_EQ(ERROR_INVALID_PARAMETER, error.error_code()); EXPECT_EQ(fmt::to_string(out), error.what()); } TEST(UtilTest, UTF16ToUTF8Error) { check_utf_conversion_error( "cannot convert string from UTF-16 to UTF-8"); } TEST(UtilTest, UTF8ToUTF16Error) { const char* message = "cannot convert string from UTF-8 to UTF-16"; check_utf_conversion_error(message); check_utf_conversion_error( message, fmt::string_view("foo", INT_MAX + 1u)); } TEST(UtilTest, UTF16ToUTF8Convert) { fmt::internal::utf16_to_utf8 u; EXPECT_EQ(ERROR_INVALID_PARAMETER, u.convert(fmt::wstring_view(0, 1))); EXPECT_EQ(ERROR_INVALID_PARAMETER, u.convert(fmt::wstring_view(L"foo", INT_MAX + 1u))); } #endif // _WIN32 typedef void (*FormatErrorMessage)(fmt::internal::buffer& out, int error_code, string_view message); template void check_throw_error(int error_code, FormatErrorMessage format) { fmt::system_error error(0, ""); try { throw Error(error_code, "test {}", "error"); } catch (const fmt::system_error& e) { error = e; } fmt::memory_buffer message; format(message, error_code, "test error"); EXPECT_EQ(to_string(message), error.what()); EXPECT_EQ(error_code, error.error_code()); } TEST(UtilTest, FormatSystemError) { fmt::memory_buffer message; fmt::format_system_error(message, EDOM, "test"); EXPECT_EQ(fmt::format("test: {}", get_system_error(EDOM)), to_string(message)); message = fmt::memory_buffer(); // Check if std::allocator throws on allocating max size_t / 2 chars. size_t max_size = std::numeric_limits::max() / 2; bool throws_on_alloc = false; try { std::allocator alloc; alloc.deallocate(alloc.allocate(max_size), max_size); } catch (const std::bad_alloc&) { throws_on_alloc = true; } if (!throws_on_alloc) { fmt::print("warning: std::allocator allocates {} chars", max_size); return; } fmt::format_system_error(message, EDOM, fmt::string_view(nullptr, max_size)); EXPECT_EQ(fmt::format("error {}", EDOM), to_string(message)); } TEST(UtilTest, SystemError) { fmt::system_error e(EDOM, "test"); EXPECT_EQ(fmt::format("test: {}", get_system_error(EDOM)), e.what()); EXPECT_EQ(EDOM, e.error_code()); check_throw_error(EDOM, fmt::format_system_error); } TEST(UtilTest, ReportSystemError) { fmt::memory_buffer out; fmt::format_system_error(out, EDOM, "test error"); out.push_back('\n'); EXPECT_WRITE(stderr, fmt::report_system_error(EDOM, "test error"), to_string(out)); } #ifdef _WIN32 TEST(UtilTest, FormatWindowsError) { LPWSTR message = 0; FormatMessageW(FORMAT_MESSAGE_ALLOCATE_BUFFER | FORMAT_MESSAGE_FROM_SYSTEM | FORMAT_MESSAGE_IGNORE_INSERTS, 0, ERROR_FILE_EXISTS, MAKELANGID(LANG_NEUTRAL, SUBLANG_DEFAULT), reinterpret_cast(&message), 0, 0); fmt::internal::utf16_to_utf8 utf8_message(message); LocalFree(message); fmt::memory_buffer actual_message; fmt::internal::format_windows_error(actual_message, ERROR_FILE_EXISTS, "test"); EXPECT_EQ(fmt::format("test: {}", utf8_message.str()), fmt::to_string(actual_message)); actual_message.resize(0); fmt::internal::format_windows_error( actual_message, ERROR_FILE_EXISTS, fmt::string_view(0, std::numeric_limits::max())); EXPECT_EQ(fmt::format("error {}", ERROR_FILE_EXISTS), fmt::to_string(actual_message)); } TEST(UtilTest, FormatLongWindowsError) { LPWSTR message = 0; // this error code is not available on all Windows platforms and // Windows SDKs, so do not fail the test if the error string cannot // be retrieved. const int provisioning_not_allowed = 0x80284013L /*TBS_E_PROVISIONING_NOT_ALLOWED*/; if (FormatMessageW(FORMAT_MESSAGE_ALLOCATE_BUFFER | FORMAT_MESSAGE_FROM_SYSTEM | FORMAT_MESSAGE_IGNORE_INSERTS, 0, static_cast(provisioning_not_allowed), MAKELANGID(LANG_NEUTRAL, SUBLANG_DEFAULT), reinterpret_cast(&message), 0, 0) == 0) { return; } fmt::internal::utf16_to_utf8 utf8_message(message); LocalFree(message); fmt::memory_buffer actual_message; fmt::internal::format_windows_error(actual_message, provisioning_not_allowed, "test"); EXPECT_EQ(fmt::format("test: {}", utf8_message.str()), fmt::to_string(actual_message)); } TEST(UtilTest, WindowsError) { check_throw_error(ERROR_FILE_EXISTS, fmt::internal::format_windows_error); } TEST(UtilTest, ReportWindowsError) { fmt::memory_buffer out; fmt::internal::format_windows_error(out, ERROR_FILE_EXISTS, "test error"); out.push_back('\n'); EXPECT_WRITE(stderr, fmt::report_windows_error(ERROR_FILE_EXISTS, "test error"), fmt::to_string(out)); } #endif // _WIN32 TEST(StringViewTest, Ctor) { EXPECT_STREQ("abc", string_view("abc").data()); EXPECT_EQ(3u, string_view("abc").size()); EXPECT_STREQ("defg", string_view(std::string("defg")).data()); EXPECT_EQ(4u, string_view(std::string("defg")).size()); } TEST(WriterTest, Data) { memory_buffer buf; fmt::writer w(buf); w.write(42); EXPECT_EQ("42", to_string(buf)); } TEST(WriterTest, WriteInt) { CHECK_WRITE(42); CHECK_WRITE(-42); CHECK_WRITE(static_cast(12)); CHECK_WRITE(34u); CHECK_WRITE(std::numeric_limits::min()); CHECK_WRITE(std::numeric_limits::max()); CHECK_WRITE(std::numeric_limits::max()); } TEST(WriterTest, WriteLong) { CHECK_WRITE(56l); CHECK_WRITE(78ul); CHECK_WRITE(std::numeric_limits::min()); CHECK_WRITE(std::numeric_limits::max()); CHECK_WRITE(std::numeric_limits::max()); } TEST(WriterTest, WriteLongLong) { CHECK_WRITE(56ll); CHECK_WRITE(78ull); CHECK_WRITE(std::numeric_limits::min()); CHECK_WRITE(std::numeric_limits::max()); CHECK_WRITE(std::numeric_limits::max()); } TEST(WriterTest, WriteDouble) { CHECK_WRITE(4.2); CHECK_WRITE(-4.2); auto min = std::numeric_limits::min(); auto max = std::numeric_limits::max(); if (fmt::internal::use_grisu()) { EXPECT_EQ("2.2250738585072014e-308", fmt::format("{}", min)); EXPECT_EQ("1.7976931348623157e+308", fmt::format("{}", max)); } else { CHECK_WRITE(min); CHECK_WRITE(max); } } TEST(WriterTest, WriteLongDouble) { CHECK_WRITE(4.2l); CHECK_WRITE_CHAR(-4.2l); std::wstring str; std_format(4.2l, str); if (str[0] != '-') CHECK_WRITE_WCHAR(-4.2l); else fmt::print("warning: long double formatting with std::swprintf is broken"); auto min = std::numeric_limits::min(); auto max = std::numeric_limits::max(); if (fmt::internal::use_grisu()) { EXPECT_EQ("2.2250738585072014e-308", fmt::format("{}", min)); EXPECT_EQ("1.7976931348623157e+308", fmt::format("{}", max)); } else { CHECK_WRITE(min); CHECK_WRITE(max); } } TEST(WriterTest, WriteDoubleAtBufferBoundary) { memory_buffer buf; fmt::writer writer(buf); for (int i = 0; i < 100; ++i) writer.write(1.23456789); } TEST(WriterTest, WriteDoubleWithFilledBuffer) { memory_buffer buf; fmt::writer writer(buf); // Fill the buffer. for (int i = 0; i < fmt::inline_buffer_size; ++i) writer.write(' '); writer.write(1.2); fmt::string_view sv(buf.data(), buf.size()); sv.remove_prefix(fmt::inline_buffer_size); EXPECT_EQ("1.2", sv); } TEST(WriterTest, WriteChar) { CHECK_WRITE('a'); } TEST(WriterTest, WriteWideChar) { CHECK_WRITE_WCHAR(L'a'); } TEST(WriterTest, WriteString) { CHECK_WRITE_CHAR("abc"); CHECK_WRITE_WCHAR("abc"); // The following line shouldn't compile: // std::declval>().write(L"abc"); } TEST(WriterTest, WriteWideString) { CHECK_WRITE_WCHAR(L"abc"); // The following line shouldn't compile: // std::declval>().write("abc"); } TEST(FormatToTest, FormatWithoutArgs) { std::string s; fmt::format_to(std::back_inserter(s), "test"); EXPECT_EQ("test", s); } TEST(FormatToTest, Format) { std::string s; fmt::format_to(std::back_inserter(s), "part{0}", 1); EXPECT_EQ("part1", s); fmt::format_to(std::back_inserter(s), "part{0}", 2); EXPECT_EQ("part1part2", s); } TEST(FormatToTest, WideString) { std::vector buf; fmt::format_to(std::back_inserter(buf), L"{}{}", 42, L'\0'); EXPECT_STREQ(buf.data(), L"42"); } TEST(FormatToTest, FormatToNonbackInsertIteratorWithSignAndNumericAlignment) { char buffer[16] = {}; fmt::format_to(fmt::internal::make_checked(buffer, 16), "{: =+}", 42.0); EXPECT_STREQ("+42.0", buffer); } TEST(FormatToTest, FormatToMemoryBuffer) { fmt::basic_memory_buffer buffer; fmt::format_to(buffer, "{}", "foo"); EXPECT_EQ("foo", to_string(buffer)); fmt::wmemory_buffer wbuffer; fmt::format_to(wbuffer, L"{}", L"foo"); EXPECT_EQ(L"foo", to_string(wbuffer)); } TEST(FormatterTest, Escape) { EXPECT_EQ("{", format("{{")); EXPECT_EQ("before {", format("before {{")); EXPECT_EQ("{ after", format("{{ after")); EXPECT_EQ("before { after", format("before {{ after")); EXPECT_EQ("}", format("}}")); EXPECT_EQ("before }", format("before }}")); EXPECT_EQ("} after", format("}} after")); EXPECT_EQ("before } after", format("before }} after")); EXPECT_EQ("{}", format("{{}}")); EXPECT_EQ("{42}", format("{{{0}}}", 42)); } TEST(FormatterTest, UnmatchedBraces) { EXPECT_THROW_MSG(format("{"), format_error, "invalid format string"); EXPECT_THROW_MSG(format("}"), format_error, "unmatched '}' in format string"); EXPECT_THROW_MSG(format("{0{}"), format_error, "invalid format string"); } TEST(FormatterTest, NoArgs) { EXPECT_EQ("test", format("test")); } TEST(FormatterTest, ArgsInDifferentPositions) { EXPECT_EQ("42", format("{0}", 42)); EXPECT_EQ("before 42", format("before {0}", 42)); EXPECT_EQ("42 after", format("{0} after", 42)); EXPECT_EQ("before 42 after", format("before {0} after", 42)); EXPECT_EQ("answer = 42", format("{0} = {1}", "answer", 42)); EXPECT_EQ("42 is the answer", format("{1} is the {0}", "answer", 42)); EXPECT_EQ("abracadabra", format("{0}{1}{0}", "abra", "cad")); } TEST(FormatterTest, ArgErrors) { EXPECT_THROW_MSG(format("{"), format_error, "invalid format string"); EXPECT_THROW_MSG(format("{?}"), format_error, "invalid format string"); EXPECT_THROW_MSG(format("{0"), format_error, "invalid format string"); EXPECT_THROW_MSG(format("{0}"), format_error, "argument index out of range"); EXPECT_THROW_MSG(format("{00}", 42), format_error, "invalid format string"); char format_str[BUFFER_SIZE]; safe_sprintf(format_str, "{%u", INT_MAX); EXPECT_THROW_MSG(format(format_str), format_error, "invalid format string"); safe_sprintf(format_str, "{%u}", INT_MAX); EXPECT_THROW_MSG(format(format_str), format_error, "argument index out of range"); safe_sprintf(format_str, "{%u", INT_MAX + 1u); EXPECT_THROW_MSG(format(format_str), format_error, "number is too big"); safe_sprintf(format_str, "{%u}", INT_MAX + 1u); EXPECT_THROW_MSG(format(format_str), format_error, "number is too big"); } template struct TestFormat { template static std::string format(fmt::string_view format_str, const Args&... args) { return TestFormat::format(format_str, N - 1, args...); } }; template <> struct TestFormat<0> { template static std::string format(fmt::string_view format_str, const Args&... args) { return fmt::format(format_str, args...); } }; TEST(FormatterTest, ManyArgs) { EXPECT_EQ("19", TestFormat<20>::format("{19}")); EXPECT_THROW_MSG(TestFormat<20>::format("{20}"), format_error, "argument index out of range"); EXPECT_THROW_MSG(TestFormat<21>::format("{21}"), format_error, "argument index out of range"); enum { max_packed_args = fmt::internal::max_packed_args }; std::string format_str = fmt::format("{{{}}}", max_packed_args + 1); EXPECT_THROW_MSG(TestFormat::format(format_str), format_error, "argument index out of range"); } TEST(FormatterTest, NamedArg) { EXPECT_EQ("1/a/A", format("{_1}/{a_}/{A_}", fmt::arg("a_", 'a'), fmt::arg("A_", "A"), fmt::arg("_1", 1))); EXPECT_THROW_MSG(format("{a}"), format_error, "argument not found"); EXPECT_EQ(" -42", format("{0:{width}}", -42, fmt::arg("width", 4))); EXPECT_EQ("st", format("{0:.{precision}}", "str", fmt::arg("precision", 2))); EXPECT_EQ("1 2", format("{} {two}", 1, fmt::arg("two", 2))); EXPECT_EQ("42", format("{c}", fmt::arg("a", 0), fmt::arg("b", 0), fmt::arg("c", 42), fmt::arg("d", 0), fmt::arg("e", 0), fmt::arg("f", 0), fmt::arg("g", 0), fmt::arg("h", 0), fmt::arg("i", 0), fmt::arg("j", 0), fmt::arg("k", 0), fmt::arg("l", 0), fmt::arg("m", 0), fmt::arg("n", 0), fmt::arg("o", 0), fmt::arg("p", 0))); } TEST(FormatterTest, AutoArgIndex) { EXPECT_EQ("abc", format("{}{}{}", 'a', 'b', 'c')); EXPECT_THROW_MSG(format("{0}{}", 'a', 'b'), format_error, "cannot switch from manual to automatic argument indexing"); EXPECT_THROW_MSG(format("{}{0}", 'a', 'b'), format_error, "cannot switch from automatic to manual argument indexing"); EXPECT_EQ("1.2", format("{:.{}}", 1.2345, 2)); EXPECT_THROW_MSG(format("{0}:.{}", 1.2345, 2), format_error, "cannot switch from manual to automatic argument indexing"); EXPECT_THROW_MSG(format("{:.{0}}", 1.2345, 2), format_error, "cannot switch from automatic to manual argument indexing"); EXPECT_THROW_MSG(format("{}"), format_error, "argument index out of range"); } TEST(FormatterTest, EmptySpecs) { EXPECT_EQ("42", format("{0:}", 42)); } TEST(FormatterTest, LeftAlign) { EXPECT_EQ("42 ", format("{0:<4}", 42)); EXPECT_EQ("42 ", format("{0:<4o}", 042)); EXPECT_EQ("42 ", format("{0:<4x}", 0x42)); EXPECT_EQ("-42 ", format("{0:<5}", -42)); EXPECT_EQ("42 ", format("{0:<5}", 42u)); EXPECT_EQ("-42 ", format("{0:<5}", -42l)); EXPECT_EQ("42 ", format("{0:<5}", 42ul)); EXPECT_EQ("-42 ", format("{0:<5}", -42ll)); EXPECT_EQ("42 ", format("{0:<5}", 42ull)); EXPECT_EQ("-42.0 ", format("{0:<7}", -42.0)); EXPECT_EQ("-42.0 ", format("{0:<7}", -42.0l)); EXPECT_EQ("c ", format("{0:<5}", 'c')); EXPECT_EQ("abc ", format("{0:<5}", "abc")); EXPECT_EQ("0xface ", format("{0:<8}", reinterpret_cast(0xface))); } TEST(FormatterTest, RightAlign) { EXPECT_EQ(" 42", format("{0:>4}", 42)); EXPECT_EQ(" 42", format("{0:>4o}", 042)); EXPECT_EQ(" 42", format("{0:>4x}", 0x42)); EXPECT_EQ(" -42", format("{0:>5}", -42)); EXPECT_EQ(" 42", format("{0:>5}", 42u)); EXPECT_EQ(" -42", format("{0:>5}", -42l)); EXPECT_EQ(" 42", format("{0:>5}", 42ul)); EXPECT_EQ(" -42", format("{0:>5}", -42ll)); EXPECT_EQ(" 42", format("{0:>5}", 42ull)); EXPECT_EQ(" -42.0", format("{0:>7}", -42.0)); EXPECT_EQ(" -42.0", format("{0:>7}", -42.0l)); EXPECT_EQ(" c", format("{0:>5}", 'c')); EXPECT_EQ(" abc", format("{0:>5}", "abc")); EXPECT_EQ(" 0xface", format("{0:>8}", reinterpret_cast(0xface))); } TEST(FormatterTest, NumericAlign) { EXPECT_EQ(" 42", format("{0:=4}", 42)); EXPECT_EQ("+ 42", format("{0:=+4}", 42)); EXPECT_EQ(" 42", format("{0:=4o}", 042)); EXPECT_EQ("+ 42", format("{0:=+4o}", 042)); EXPECT_EQ(" 42", format("{0:=4x}", 0x42)); EXPECT_EQ("+ 42", format("{0:=+4x}", 0x42)); EXPECT_EQ("- 42", format("{0:=5}", -42)); EXPECT_EQ(" 42", format("{0:=5}", 42u)); EXPECT_EQ("- 42", format("{0:=5}", -42l)); EXPECT_EQ(" 42", format("{0:=5}", 42ul)); EXPECT_EQ("- 42", format("{0:=5}", -42ll)); EXPECT_EQ(" 42", format("{0:=5}", 42ull)); EXPECT_EQ("- 42.0", format("{0:=7}", -42.0)); EXPECT_EQ("- 42.0", format("{0:=7}", -42.0l)); EXPECT_THROW_MSG(format("{0:=5", 'c'), format_error, "missing '}' in format string"); EXPECT_THROW_MSG(format("{0:=5}", 'c'), format_error, "invalid format specifier for char"); EXPECT_THROW_MSG(format("{0:=5}", "abc"), format_error, "format specifier requires numeric argument"); EXPECT_THROW_MSG(format("{0:=8}", reinterpret_cast(0xface)), format_error, "format specifier requires numeric argument"); EXPECT_EQ(" 1.0", fmt::format("{:= }", 1.0)); } TEST(FormatterTest, CenterAlign) { EXPECT_EQ(" 42 ", format("{0:^5}", 42)); EXPECT_EQ(" 42 ", format("{0:^5o}", 042)); EXPECT_EQ(" 42 ", format("{0:^5x}", 0x42)); EXPECT_EQ(" -42 ", format("{0:^5}", -42)); EXPECT_EQ(" 42 ", format("{0:^5}", 42u)); EXPECT_EQ(" -42 ", format("{0:^5}", -42l)); EXPECT_EQ(" 42 ", format("{0:^5}", 42ul)); EXPECT_EQ(" -42 ", format("{0:^5}", -42ll)); EXPECT_EQ(" 42 ", format("{0:^5}", 42ull)); EXPECT_EQ(" -42.0 ", format("{0:^7}", -42.0)); EXPECT_EQ(" -42.0 ", format("{0:^7}", -42.0l)); EXPECT_EQ(" c ", format("{0:^5}", 'c')); EXPECT_EQ(" abc ", format("{0:^6}", "abc")); EXPECT_EQ(" 0xface ", format("{0:^8}", reinterpret_cast(0xface))); } TEST(FormatterTest, Fill) { EXPECT_THROW_MSG(format("{0:{<5}", 'c'), format_error, "invalid fill character '{'"); EXPECT_THROW_MSG(format("{0:{<5}}", 'c'), format_error, "invalid fill character '{'"); EXPECT_EQ("**42", format("{0:*>4}", 42)); EXPECT_EQ("**-42", format("{0:*>5}", -42)); EXPECT_EQ("***42", format("{0:*>5}", 42u)); EXPECT_EQ("**-42", format("{0:*>5}", -42l)); EXPECT_EQ("***42", format("{0:*>5}", 42ul)); EXPECT_EQ("**-42", format("{0:*>5}", -42ll)); EXPECT_EQ("***42", format("{0:*>5}", 42ull)); EXPECT_EQ("**-42.0", format("{0:*>7}", -42.0)); EXPECT_EQ("**-42.0", format("{0:*>7}", -42.0l)); EXPECT_EQ("c****", format("{0:*<5}", 'c')); EXPECT_EQ("abc**", format("{0:*<5}", "abc")); EXPECT_EQ("**0xface", format("{0:*>8}", reinterpret_cast(0xface))); EXPECT_EQ("foo=", format("{:}=", "foo")); EXPECT_EQ(std::string("\0\0\0*", 4), format(string_view("{:\0>4}", 6), '*')); } TEST(FormatterTest, PlusSign) { EXPECT_EQ("+42", format("{0:+}", 42)); EXPECT_EQ("-42", format("{0:+}", -42)); EXPECT_EQ("+42", format("{0:+}", 42)); EXPECT_THROW_MSG(format("{0:+}", 42u), format_error, "format specifier requires signed argument"); EXPECT_EQ("+42", format("{0:+}", 42l)); EXPECT_THROW_MSG(format("{0:+}", 42ul), format_error, "format specifier requires signed argument"); EXPECT_EQ("+42", format("{0:+}", 42ll)); EXPECT_THROW_MSG(format("{0:+}", 42ull), format_error, "format specifier requires signed argument"); EXPECT_EQ("+42.0", format("{0:+}", 42.0)); EXPECT_EQ("+42.0", format("{0:+}", 42.0l)); EXPECT_THROW_MSG(format("{0:+", 'c'), format_error, "missing '}' in format string"); EXPECT_THROW_MSG(format("{0:+}", 'c'), format_error, "invalid format specifier for char"); EXPECT_THROW_MSG(format("{0:+}", "abc"), format_error, "format specifier requires numeric argument"); EXPECT_THROW_MSG(format("{0:+}", reinterpret_cast(0x42)), format_error, "format specifier requires numeric argument"); } TEST(FormatterTest, MinusSign) { EXPECT_EQ("42", format("{0:-}", 42)); EXPECT_EQ("-42", format("{0:-}", -42)); EXPECT_EQ("42", format("{0:-}", 42)); EXPECT_THROW_MSG(format("{0:-}", 42u), format_error, "format specifier requires signed argument"); EXPECT_EQ("42", format("{0:-}", 42l)); EXPECT_THROW_MSG(format("{0:-}", 42ul), format_error, "format specifier requires signed argument"); EXPECT_EQ("42", format("{0:-}", 42ll)); EXPECT_THROW_MSG(format("{0:-}", 42ull), format_error, "format specifier requires signed argument"); EXPECT_EQ("42.0", format("{0:-}", 42.0)); EXPECT_EQ("42.0", format("{0:-}", 42.0l)); EXPECT_THROW_MSG(format("{0:-", 'c'), format_error, "missing '}' in format string"); EXPECT_THROW_MSG(format("{0:-}", 'c'), format_error, "invalid format specifier for char"); EXPECT_THROW_MSG(format("{0:-}", "abc"), format_error, "format specifier requires numeric argument"); EXPECT_THROW_MSG(format("{0:-}", reinterpret_cast(0x42)), format_error, "format specifier requires numeric argument"); } TEST(FormatterTest, SpaceSign) { EXPECT_EQ(" 42", format("{0: }", 42)); EXPECT_EQ("-42", format("{0: }", -42)); EXPECT_EQ(" 42", format("{0: }", 42)); EXPECT_THROW_MSG(format("{0: }", 42u), format_error, "format specifier requires signed argument"); EXPECT_EQ(" 42", format("{0: }", 42l)); EXPECT_THROW_MSG(format("{0: }", 42ul), format_error, "format specifier requires signed argument"); EXPECT_EQ(" 42", format("{0: }", 42ll)); EXPECT_THROW_MSG(format("{0: }", 42ull), format_error, "format specifier requires signed argument"); EXPECT_EQ(" 42.0", format("{0: }", 42.0)); EXPECT_EQ(" 42.0", format("{0: }", 42.0l)); EXPECT_THROW_MSG(format("{0: ", 'c'), format_error, "missing '}' in format string"); EXPECT_THROW_MSG(format("{0: }", 'c'), format_error, "invalid format specifier for char"); EXPECT_THROW_MSG(format("{0: }", "abc"), format_error, "format specifier requires numeric argument"); EXPECT_THROW_MSG(format("{0: }", reinterpret_cast(0x42)), format_error, "format specifier requires numeric argument"); } TEST(FormatterTest, HashFlag) { EXPECT_EQ("42", format("{0:#}", 42)); EXPECT_EQ("-42", format("{0:#}", -42)); EXPECT_EQ("0b101010", format("{0:#b}", 42)); EXPECT_EQ("0B101010", format("{0:#B}", 42)); EXPECT_EQ("-0b101010", format("{0:#b}", -42)); EXPECT_EQ("0x42", format("{0:#x}", 0x42)); EXPECT_EQ("0X42", format("{0:#X}", 0x42)); EXPECT_EQ("-0x42", format("{0:#x}", -0x42)); EXPECT_EQ("042", format("{0:#o}", 042)); EXPECT_EQ("-042", format("{0:#o}", -042)); EXPECT_EQ("42", format("{0:#}", 42u)); EXPECT_EQ("0x42", format("{0:#x}", 0x42u)); EXPECT_EQ("042", format("{0:#o}", 042u)); EXPECT_EQ("-42", format("{0:#}", -42l)); EXPECT_EQ("0x42", format("{0:#x}", 0x42l)); EXPECT_EQ("-0x42", format("{0:#x}", -0x42l)); EXPECT_EQ("042", format("{0:#o}", 042l)); EXPECT_EQ("-042", format("{0:#o}", -042l)); EXPECT_EQ("42", format("{0:#}", 42ul)); EXPECT_EQ("0x42", format("{0:#x}", 0x42ul)); EXPECT_EQ("042", format("{0:#o}", 042ul)); EXPECT_EQ("-42", format("{0:#}", -42ll)); EXPECT_EQ("0x42", format("{0:#x}", 0x42ll)); EXPECT_EQ("-0x42", format("{0:#x}", -0x42ll)); EXPECT_EQ("042", format("{0:#o}", 042ll)); EXPECT_EQ("-042", format("{0:#o}", -042ll)); EXPECT_EQ("42", format("{0:#}", 42ull)); EXPECT_EQ("0x42", format("{0:#x}", 0x42ull)); EXPECT_EQ("042", format("{0:#o}", 042ull)); EXPECT_EQ("-42.0", format("{0:#}", -42.0)); EXPECT_EQ("-42.0", format("{0:#}", -42.0l)); EXPECT_THROW_MSG(format("{0:#", 'c'), format_error, "missing '}' in format string"); EXPECT_THROW_MSG(format("{0:#}", 'c'), format_error, "invalid format specifier for char"); EXPECT_THROW_MSG(format("{0:#}", "abc"), format_error, "format specifier requires numeric argument"); EXPECT_THROW_MSG(format("{0:#}", reinterpret_cast(0x42)), format_error, "format specifier requires numeric argument"); } TEST(FormatterTest, ZeroFlag) { EXPECT_EQ("42", format("{0:0}", 42)); EXPECT_EQ("-0042", format("{0:05}", -42)); EXPECT_EQ("00042", format("{0:05}", 42u)); EXPECT_EQ("-0042", format("{0:05}", -42l)); EXPECT_EQ("00042", format("{0:05}", 42ul)); EXPECT_EQ("-0042", format("{0:05}", -42ll)); EXPECT_EQ("00042", format("{0:05}", 42ull)); EXPECT_EQ("-0042.0", format("{0:07}", -42.0)); EXPECT_EQ("-0042.0", format("{0:07}", -42.0l)); EXPECT_THROW_MSG(format("{0:0", 'c'), format_error, "missing '}' in format string"); EXPECT_THROW_MSG(format("{0:05}", 'c'), format_error, "invalid format specifier for char"); EXPECT_THROW_MSG(format("{0:05}", "abc"), format_error, "format specifier requires numeric argument"); EXPECT_THROW_MSG(format("{0:05}", reinterpret_cast(0x42)), format_error, "format specifier requires numeric argument"); } TEST(FormatterTest, Width) { char format_str[BUFFER_SIZE]; safe_sprintf(format_str, "{0:%u", UINT_MAX); increment(format_str + 3); EXPECT_THROW_MSG(format(format_str, 0), format_error, "number is too big"); std::size_t size = std::strlen(format_str); format_str[size] = '}'; format_str[size + 1] = 0; EXPECT_THROW_MSG(format(format_str, 0), format_error, "number is too big"); safe_sprintf(format_str, "{0:%u", INT_MAX + 1u); EXPECT_THROW_MSG(format(format_str, 0), format_error, "number is too big"); safe_sprintf(format_str, "{0:%u}", INT_MAX + 1u); EXPECT_THROW_MSG(format(format_str, 0), format_error, "number is too big"); EXPECT_EQ(" -42", format("{0:4}", -42)); EXPECT_EQ(" 42", format("{0:5}", 42u)); EXPECT_EQ(" -42", format("{0:6}", -42l)); EXPECT_EQ(" 42", format("{0:7}", 42ul)); EXPECT_EQ(" -42", format("{0:6}", -42ll)); EXPECT_EQ(" 42", format("{0:7}", 42ull)); EXPECT_EQ(" -1.23", format("{0:8}", -1.23)); EXPECT_EQ(" -1.23", format("{0:9}", -1.23l)); EXPECT_EQ(" 0xcafe", format("{0:10}", reinterpret_cast(0xcafe))); EXPECT_EQ("x ", format("{0:11}", 'x')); EXPECT_EQ("str ", format("{0:12}", "str")); } template inline T const_check(T value) { return value; } TEST(FormatterTest, RuntimeWidth) { char format_str[BUFFER_SIZE]; safe_sprintf(format_str, "{0:{%u", UINT_MAX); increment(format_str + 4); EXPECT_THROW_MSG(format(format_str, 0), format_error, "number is too big"); std::size_t size = std::strlen(format_str); format_str[size] = '}'; format_str[size + 1] = 0; EXPECT_THROW_MSG(format(format_str, 0), format_error, "number is too big"); format_str[size + 1] = '}'; format_str[size + 2] = 0; EXPECT_THROW_MSG(format(format_str, 0), format_error, "number is too big"); EXPECT_THROW_MSG(format("{0:{", 0), format_error, "invalid format string"); EXPECT_THROW_MSG(format("{0:{}", 0), format_error, "cannot switch from manual to automatic argument indexing"); EXPECT_THROW_MSG(format("{0:{?}}", 0), format_error, "invalid format string"); EXPECT_THROW_MSG(format("{0:{1}}", 0), format_error, "argument index out of range"); EXPECT_THROW_MSG(format("{0:{0:}}", 0), format_error, "invalid format string"); EXPECT_THROW_MSG(format("{0:{1}}", 0, -1), format_error, "negative width"); EXPECT_THROW_MSG(format("{0:{1}}", 0, (INT_MAX + 1u)), format_error, "number is too big"); EXPECT_THROW_MSG(format("{0:{1}}", 0, -1l), format_error, "negative width"); if (const_check(sizeof(long) > sizeof(int))) { long value = INT_MAX; EXPECT_THROW_MSG(format("{0:{1}}", 0, (value + 1)), format_error, "number is too big"); } EXPECT_THROW_MSG(format("{0:{1}}", 0, (INT_MAX + 1ul)), format_error, "number is too big"); EXPECT_THROW_MSG(format("{0:{1}}", 0, '0'), format_error, "width is not integer"); EXPECT_THROW_MSG(format("{0:{1}}", 0, 0.0), format_error, "width is not integer"); EXPECT_EQ(" -42", format("{0:{1}}", -42, 4)); EXPECT_EQ(" 42", format("{0:{1}}", 42u, 5)); EXPECT_EQ(" -42", format("{0:{1}}", -42l, 6)); EXPECT_EQ(" 42", format("{0:{1}}", 42ul, 7)); EXPECT_EQ(" -42", format("{0:{1}}", -42ll, 6)); EXPECT_EQ(" 42", format("{0:{1}}", 42ull, 7)); EXPECT_EQ(" -1.23", format("{0:{1}}", -1.23, 8)); EXPECT_EQ(" -1.23", format("{0:{1}}", -1.23l, 9)); EXPECT_EQ(" 0xcafe", format("{0:{1}}", reinterpret_cast(0xcafe), 10)); EXPECT_EQ("x ", format("{0:{1}}", 'x', 11)); EXPECT_EQ("str ", format("{0:{1}}", "str", 12)); } TEST(FormatterTest, Precision) { char format_str[BUFFER_SIZE]; safe_sprintf(format_str, "{0:.%u", UINT_MAX); increment(format_str + 4); EXPECT_THROW_MSG(format(format_str, 0), format_error, "number is too big"); std::size_t size = std::strlen(format_str); format_str[size] = '}'; format_str[size + 1] = 0; EXPECT_THROW_MSG(format(format_str, 0), format_error, "number is too big"); safe_sprintf(format_str, "{0:.%u", INT_MAX + 1u); EXPECT_THROW_MSG(format(format_str, 0), format_error, "number is too big"); safe_sprintf(format_str, "{0:.%u}", INT_MAX + 1u); EXPECT_THROW_MSG(format(format_str, 0), format_error, "number is too big"); EXPECT_THROW_MSG(format("{0:.", 0), format_error, "missing precision specifier"); EXPECT_THROW_MSG(format("{0:.}", 0), format_error, "missing precision specifier"); EXPECT_THROW_MSG(format("{0:.2", 0), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:.2}", 42), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:.2f}", 42), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:.2}", 42u), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:.2f}", 42u), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:.2}", 42l), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:.2f}", 42l), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:.2}", 42ul), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:.2f}", 42ul), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:.2}", 42ll), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:.2f}", 42ll), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:.2}", 42ull), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:.2f}", 42ull), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:.2%}", 42), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:3.0}", 'x'), format_error, "precision not allowed for this argument type"); EXPECT_EQ("1.2", format("{0:.2}", 1.2345)); EXPECT_EQ("1.2", format("{0:.2}", 1.2345l)); EXPECT_THROW_MSG(format("{0:.2}", reinterpret_cast(0xcafe)), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:.2f}", reinterpret_cast(0xcafe)), format_error, "precision not allowed for this argument type"); EXPECT_EQ("st", format("{0:.2}", "str")); } TEST(FormatterTest, RuntimePrecision) { char format_str[BUFFER_SIZE]; safe_sprintf(format_str, "{0:.{%u", UINT_MAX); increment(format_str + 5); EXPECT_THROW_MSG(format(format_str, 0), format_error, "number is too big"); std::size_t size = std::strlen(format_str); format_str[size] = '}'; format_str[size + 1] = 0; EXPECT_THROW_MSG(format(format_str, 0), format_error, "number is too big"); format_str[size + 1] = '}'; format_str[size + 2] = 0; EXPECT_THROW_MSG(format(format_str, 0), format_error, "number is too big"); EXPECT_THROW_MSG(format("{0:.{", 0), format_error, "invalid format string"); EXPECT_THROW_MSG(format("{0:.{}", 0), format_error, "cannot switch from manual to automatic argument indexing"); EXPECT_THROW_MSG(format("{0:.{?}}", 0), format_error, "invalid format string"); EXPECT_THROW_MSG(format("{0:.{1}", 0, 0), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:.{1}}", 0), format_error, "argument index out of range"); EXPECT_THROW_MSG(format("{0:.{0:}}", 0), format_error, "invalid format string"); EXPECT_THROW_MSG(format("{0:.{1}}", 0, -1), format_error, "negative precision"); EXPECT_THROW_MSG(format("{0:.{1}}", 0, (INT_MAX + 1u)), format_error, "number is too big"); EXPECT_THROW_MSG(format("{0:.{1}}", 0, -1l), format_error, "negative precision"); if (const_check(sizeof(long) > sizeof(int))) { long value = INT_MAX; EXPECT_THROW_MSG(format("{0:.{1}}", 0, (value + 1)), format_error, "number is too big"); } EXPECT_THROW_MSG(format("{0:.{1}}", 0, (INT_MAX + 1ul)), format_error, "number is too big"); EXPECT_THROW_MSG(format("{0:.{1}}", 0, '0'), format_error, "precision is not integer"); EXPECT_THROW_MSG(format("{0:.{1}}", 0, 0.0), format_error, "precision is not integer"); EXPECT_THROW_MSG(format("{0:.{1}}", 42, 2), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:.{1}f}", 42, 2), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:.{1}}", 42u, 2), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:.{1}f}", 42u, 2), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:.{1}}", 42l, 2), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:.{1}f}", 42l, 2), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:.{1}}", 42ul, 2), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:.{1}f}", 42ul, 2), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:.{1}}", 42ll, 2), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:.{1}f}", 42ll, 2), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:.{1}}", 42ull, 2), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:.{1}f}", 42ull, 2), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:3.{1}}", 'x', 0), format_error, "precision not allowed for this argument type"); EXPECT_EQ("1.2", format("{0:.{1}}", 1.2345, 2)); EXPECT_EQ("1.2", format("{1:.{0}}", 2, 1.2345l)); EXPECT_THROW_MSG(format("{0:.{1}}", reinterpret_cast(0xcafe), 2), format_error, "precision not allowed for this argument type"); EXPECT_THROW_MSG(format("{0:.{1}f}", reinterpret_cast(0xcafe), 2), format_error, "precision not allowed for this argument type"); EXPECT_EQ("st", format("{0:.{1}}", "str", 2)); } template void check_unknown_types(const T& value, const char* types, const char*) { char format_str[BUFFER_SIZE]; const char* special = ".0123456789}"; for (int i = CHAR_MIN; i <= CHAR_MAX; ++i) { char c = static_cast(i); if (std::strchr(types, c) || std::strchr(special, c) || !c) continue; safe_sprintf(format_str, "{0:10%c}", c); const char* message = "invalid type specifier"; EXPECT_THROW_MSG(format(format_str, value), format_error, message) << format_str << " " << message; } } TEST(BoolTest, FormatBool) { EXPECT_EQ("true", format("{}", true)); EXPECT_EQ("false", format("{}", false)); EXPECT_EQ("1", format("{:d}", true)); EXPECT_EQ("true ", format("{:5}", true)); EXPECT_EQ(L"true", format(L"{}", true)); } TEST(FormatterTest, FormatShort) { short s = 42; EXPECT_EQ("42", format("{0:d}", s)); unsigned short us = 42; EXPECT_EQ("42", format("{0:d}", us)); } TEST(FormatterTest, FormatInt) { EXPECT_THROW_MSG(format("{0:v", 42), format_error, "missing '}' in format string"); check_unknown_types(42, "bBdoxXn", "integer"); } TEST(FormatterTest, FormatBin) { EXPECT_EQ("0", format("{0:b}", 0)); EXPECT_EQ("101010", format("{0:b}", 42)); EXPECT_EQ("101010", format("{0:b}", 42u)); EXPECT_EQ("-101010", format("{0:b}", -42)); EXPECT_EQ("11000000111001", format("{0:b}", 12345)); EXPECT_EQ("10010001101000101011001111000", format("{0:b}", 0x12345678)); EXPECT_EQ("10010000101010111100110111101111", format("{0:b}", 0x90ABCDEF)); EXPECT_EQ("11111111111111111111111111111111", format("{0:b}", std::numeric_limits::max())); } TEST(FormatterTest, FormatDec) { EXPECT_EQ("0", format("{0}", 0)); EXPECT_EQ("42", format("{0}", 42)); EXPECT_EQ("42", format("{0:d}", 42)); EXPECT_EQ("42", format("{0}", 42u)); EXPECT_EQ("-42", format("{0}", -42)); EXPECT_EQ("12345", format("{0}", 12345)); EXPECT_EQ("67890", format("{0}", 67890)); char buffer[BUFFER_SIZE]; safe_sprintf(buffer, "%d", INT_MIN); EXPECT_EQ(buffer, format("{0}", INT_MIN)); safe_sprintf(buffer, "%d", INT_MAX); EXPECT_EQ(buffer, format("{0}", INT_MAX)); safe_sprintf(buffer, "%u", UINT_MAX); EXPECT_EQ(buffer, format("{0}", UINT_MAX)); safe_sprintf(buffer, "%ld", 0 - static_cast(LONG_MIN)); EXPECT_EQ(buffer, format("{0}", LONG_MIN)); safe_sprintf(buffer, "%ld", LONG_MAX); EXPECT_EQ(buffer, format("{0}", LONG_MAX)); safe_sprintf(buffer, "%lu", ULONG_MAX); EXPECT_EQ(buffer, format("{0}", ULONG_MAX)); } TEST(FormatterTest, FormatHex) { EXPECT_EQ("0", format("{0:x}", 0)); EXPECT_EQ("42", format("{0:x}", 0x42)); EXPECT_EQ("42", format("{0:x}", 0x42u)); EXPECT_EQ("-42", format("{0:x}", -0x42)); EXPECT_EQ("12345678", format("{0:x}", 0x12345678)); EXPECT_EQ("90abcdef", format("{0:x}", 0x90abcdef)); EXPECT_EQ("12345678", format("{0:X}", 0x12345678)); EXPECT_EQ("90ABCDEF", format("{0:X}", 0x90ABCDEF)); char buffer[BUFFER_SIZE]; safe_sprintf(buffer, "-%x", 0 - static_cast(INT_MIN)); EXPECT_EQ(buffer, format("{0:x}", INT_MIN)); safe_sprintf(buffer, "%x", INT_MAX); EXPECT_EQ(buffer, format("{0:x}", INT_MAX)); safe_sprintf(buffer, "%x", UINT_MAX); EXPECT_EQ(buffer, format("{0:x}", UINT_MAX)); safe_sprintf(buffer, "-%lx", 0 - static_cast(LONG_MIN)); EXPECT_EQ(buffer, format("{0:x}", LONG_MIN)); safe_sprintf(buffer, "%lx", LONG_MAX); EXPECT_EQ(buffer, format("{0:x}", LONG_MAX)); safe_sprintf(buffer, "%lx", ULONG_MAX); EXPECT_EQ(buffer, format("{0:x}", ULONG_MAX)); } TEST(FormatterTest, FormatOct) { EXPECT_EQ("0", format("{0:o}", 0)); EXPECT_EQ("42", format("{0:o}", 042)); EXPECT_EQ("42", format("{0:o}", 042u)); EXPECT_EQ("-42", format("{0:o}", -042)); EXPECT_EQ("12345670", format("{0:o}", 012345670)); char buffer[BUFFER_SIZE]; safe_sprintf(buffer, "-%o", 0 - static_cast(INT_MIN)); EXPECT_EQ(buffer, format("{0:o}", INT_MIN)); safe_sprintf(buffer, "%o", INT_MAX); EXPECT_EQ(buffer, format("{0:o}", INT_MAX)); safe_sprintf(buffer, "%o", UINT_MAX); EXPECT_EQ(buffer, format("{0:o}", UINT_MAX)); safe_sprintf(buffer, "-%lo", 0 - static_cast(LONG_MIN)); EXPECT_EQ(buffer, format("{0:o}", LONG_MIN)); safe_sprintf(buffer, "%lo", LONG_MAX); EXPECT_EQ(buffer, format("{0:o}", LONG_MAX)); safe_sprintf(buffer, "%lo", ULONG_MAX); EXPECT_EQ(buffer, format("{0:o}", ULONG_MAX)); } TEST(FormatterTest, FormatIntLocale) { EXPECT_EQ("123", format("{:n}", 123)); EXPECT_EQ("1,234", format("{:n}", 1234)); EXPECT_EQ("1,234,567", format("{:n}", 1234567)); EXPECT_EQ("4,294,967,295", format("{:n}", std::numeric_limits::max())); } struct ConvertibleToLongLong { operator long long() const { return 1LL << 32; } }; TEST(FormatterTest, FormatConvertibleToLongLong) { EXPECT_EQ("100000000", format("{:x}", ConvertibleToLongLong())); } TEST(FormatterTest, FormatFloat) { EXPECT_EQ("392.500000", format("{0:f}", 392.5f)); EXPECT_EQ("12.500000%", format("{0:%}", 0.125f)); } TEST(FormatterTest, FormatDouble) { check_unknown_types(1.2, "eEfFgGaA%", "double"); EXPECT_EQ("0.0", format("{:}", 0.0)); EXPECT_EQ("0.000000", format("{:f}", 0.0)); EXPECT_EQ("0", format("{:g}", 0.0)); EXPECT_EQ("392.65", format("{:}", 392.65)); EXPECT_EQ("392.65", format("{:g}", 392.65)); EXPECT_EQ("392.65", format("{:G}", 392.65)); EXPECT_EQ("392.650000", format("{:f}", 392.65)); EXPECT_EQ("392.650000", format("{:F}", 392.65)); EXPECT_EQ("12.500000%", format("{:%}", 0.125)); EXPECT_EQ("12.34%", format("{:.2%}", 0.1234432)); char buffer[BUFFER_SIZE]; safe_sprintf(buffer, "%e", 392.65); EXPECT_EQ(buffer, format("{0:e}", 392.65)); safe_sprintf(buffer, "%E", 392.65); EXPECT_EQ(buffer, format("{0:E}", 392.65)); EXPECT_EQ("+0000392.6", format("{0:+010.4g}", 392.65)); safe_sprintf(buffer, "%a", -42.0); EXPECT_EQ(buffer, format("{:a}", -42.0)); safe_sprintf(buffer, "%A", -42.0); EXPECT_EQ(buffer, format("{:A}", -42.0)); } TEST(FormatterTest, PrecisionRounding) { EXPECT_EQ("0", format("{:.0f}", 0.1)); EXPECT_EQ("0.000", format("{:.3f}", 0.00049)); EXPECT_EQ("0.001", format("{:.3f}", 0.0005)); EXPECT_EQ("0.001", format("{:.3f}", 0.00149)); EXPECT_EQ("0.002", format("{:.3f}", 0.0015)); EXPECT_EQ("1.000", format("{:.3f}", 0.9999)); EXPECT_EQ("0.00123", format("{:.3}", 0.00123)); EXPECT_EQ("0.1", format("{:.16g}", 0.1)); // Trigger rounding error in Grisu by a carefully chosen number. auto n = 3788512123356.985352; char buffer[64]; sprintf(buffer, "%f", n); EXPECT_EQ(buffer, format("{:f}", n)); } TEST(FormatterTest, FormatNaN) { double nan = std::numeric_limits::quiet_NaN(); EXPECT_EQ("nan", format("{}", nan)); EXPECT_EQ("+nan", format("{:+}", nan)); EXPECT_EQ(" nan", format("{: }", nan)); EXPECT_EQ("NAN", format("{:F}", nan)); EXPECT_EQ("nan ", format("{:<7}", nan)); EXPECT_EQ(" nan ", format("{:^7}", nan)); EXPECT_EQ(" nan", format("{:>7}", nan)); EXPECT_EQ("nan%", format("{:%}", nan)); } TEST(FormatterTest, FormatInfinity) { double inf = std::numeric_limits::infinity(); EXPECT_EQ("inf", format("{}", inf)); EXPECT_EQ("+inf", format("{:+}", inf)); EXPECT_EQ("-inf", format("{}", -inf)); EXPECT_EQ(" inf", format("{: }", inf)); EXPECT_EQ("INF", format("{:F}", inf)); EXPECT_EQ("inf ", format("{:<7}", inf)); EXPECT_EQ(" inf ", format("{:^7}", inf)); EXPECT_EQ(" inf", format("{:>7}", inf)); EXPECT_EQ("inf%", format("{:%}", inf)); } TEST(FormatterTest, FormatLongDouble) { EXPECT_EQ("0.0", format("{0:}", 0.0l)); EXPECT_EQ("0.000000", format("{0:f}", 0.0l)); EXPECT_EQ("392.65", format("{0:}", 392.65l)); EXPECT_EQ("392.65", format("{0:g}", 392.65l)); EXPECT_EQ("392.65", format("{0:G}", 392.65l)); EXPECT_EQ("392.650000", format("{0:f}", 392.65l)); EXPECT_EQ("392.650000", format("{0:F}", 392.65l)); EXPECT_EQ("12.500000%", format("{:%}", 0.125l)); EXPECT_EQ("12.34%", format("{:.2%}", 0.1234432l)); char buffer[BUFFER_SIZE]; safe_sprintf(buffer, "%Le", 392.65l); EXPECT_EQ(buffer, format("{0:e}", 392.65l)); EXPECT_EQ("+0000392.6", format("{0:+010.4g}", 392.64l)); } TEST(FormatterTest, FormatChar) { const char types[] = "cbBdoxXn"; check_unknown_types('a', types, "char"); EXPECT_EQ("a", format("{0}", 'a')); EXPECT_EQ("z", format("{0:c}", 'z')); EXPECT_EQ(L"a", format(L"{0}", 'a')); int n = 'x'; for (const char* type = types + 1; *type; ++type) { std::string format_str = fmt::format("{{:{}}}", *type); EXPECT_EQ(fmt::format(format_str, n), fmt::format(format_str, 'x')); } EXPECT_EQ(fmt::format("{:02X}", n), fmt::format("{:02X}", 'x')); } TEST(FormatterTest, FormatVolatileChar) { volatile char c = 'x'; EXPECT_EQ("x", format("{}", c)); } TEST(FormatterTest, FormatUnsignedChar) { EXPECT_EQ("42", format("{}", static_cast(42))); EXPECT_EQ("42", format("{}", static_cast(42))); } TEST(FormatterTest, FormatWChar) { EXPECT_EQ(L"a", format(L"{0}", L'a')); // This shouldn't compile: // format("{}", L'a'); } TEST(FormatterTest, FormatCString) { check_unknown_types("test", "sp", "string"); EXPECT_EQ("test", format("{0}", "test")); EXPECT_EQ("test", format("{0:s}", "test")); char nonconst[] = "nonconst"; EXPECT_EQ("nonconst", format("{0}", nonconst)); EXPECT_THROW_MSG(format("{0}", static_cast(nullptr)), format_error, "string pointer is null"); } TEST(FormatterTest, FormatSCharString) { signed char str[] = "test"; EXPECT_EQ("test", format("{0:s}", str)); const signed char* const_str = str; EXPECT_EQ("test", format("{0:s}", const_str)); } TEST(FormatterTest, FormatUCharString) { unsigned char str[] = "test"; EXPECT_EQ("test", format("{0:s}", str)); const unsigned char* const_str = str; EXPECT_EQ("test", format("{0:s}", const_str)); unsigned char* ptr = str; EXPECT_EQ("test", format("{0:s}", ptr)); } TEST(FormatterTest, FormatPointer) { check_unknown_types(reinterpret_cast(0x1234), "p", "pointer"); EXPECT_EQ("0x0", format("{0}", static_cast(nullptr))); EXPECT_EQ("0x1234", format("{0}", reinterpret_cast(0x1234))); EXPECT_EQ("0x1234", format("{0:p}", reinterpret_cast(0x1234))); EXPECT_EQ("0x" + std::string(sizeof(void*) * CHAR_BIT / 4, 'f'), format("{0}", reinterpret_cast(~uintptr_t()))); EXPECT_EQ("0x1234", format("{}", fmt::ptr(reinterpret_cast(0x1234)))); std::unique_ptr up(new int(1)); EXPECT_EQ(format("{}", fmt::ptr(up.get())), format("{}", fmt::ptr(up))); std::shared_ptr sp(new int(1)); EXPECT_EQ(format("{}", fmt::ptr(sp.get())), format("{}", fmt::ptr(sp))); #if FMT_USE_NULLPTR EXPECT_EQ("0x0", format("{}", nullptr)); #endif } TEST(FormatterTest, FormatString) { EXPECT_EQ("test", format("{0}", std::string("test"))); } TEST(FormatterTest, FormatStringView) { EXPECT_EQ("test", format("{}", string_view("test"))); EXPECT_EQ("", format("{}", string_view())); } #ifdef FMT_USE_STD_STRING_VIEW TEST(FormatterTest, FormatStdStringView) { EXPECT_EQ("test", format("{0}", std::string_view("test"))); } #endif FMT_BEGIN_NAMESPACE template <> struct formatter { template FMT_CONSTEXPR auto parse(ParseContext& ctx) -> decltype(ctx.begin()) { auto it = ctx.begin(); if (*it == 'd') ++it; return it; } auto format(const Date& d, format_context& ctx) -> decltype(ctx.out()) { format_to(ctx.out(), "{}-{}-{}", d.year(), d.month(), d.day()); return ctx.out(); } }; FMT_END_NAMESPACE TEST(FormatterTest, FormatCustom) { Date date(2012, 12, 9); EXPECT_THROW_MSG(fmt::format("{:s}", date), format_error, "unknown format specifier"); } class Answer {}; FMT_BEGIN_NAMESPACE template <> struct formatter : formatter { template auto format(Answer, FormatContext& ctx) -> decltype(ctx.out()) { return formatter::format(42, ctx); } }; FMT_END_NAMESPACE TEST(FormatterTest, CustomFormat) { EXPECT_EQ("42", format("{0}", Answer())); EXPECT_EQ("0042", format("{:04}", Answer())); } TEST(FormatterTest, CustomFormatTo) { char buf[10] = {}; auto end = &*fmt::format_to(fmt::internal::make_checked(buf, 10), "{}", Answer()); EXPECT_EQ(end, buf + 2); EXPECT_STREQ(buf, "42"); } TEST(FormatterTest, WideFormatString) { EXPECT_EQ(L"42", format(L"{}", 42)); EXPECT_EQ(L"4.2", format(L"{}", 4.2)); EXPECT_EQ(L"abc", format(L"{}", L"abc")); EXPECT_EQ(L"z", format(L"{}", L'z')); } TEST(FormatterTest, FormatStringFromSpeedTest) { EXPECT_EQ("1.2340000000:0042:+3.13:str:0x3e8:X:%", format("{0:0.10f}:{1:04}:{2:+g}:{3}:{4}:{5}:%", 1.234, 42, 3.13, "str", reinterpret_cast(1000), 'X')); } TEST(FormatterTest, FormatExamples) { std::string message = format("The answer is {}", 42); EXPECT_EQ("The answer is 42", message); EXPECT_EQ("42", format("{}", 42)); EXPECT_EQ("42", format(std::string("{}"), 42)); memory_buffer out; format_to(out, "The answer is {}.", 42); EXPECT_EQ("The answer is 42.", to_string(out)); const char* filename = "nonexistent"; FILE* ftest = safe_fopen(filename, "r"); if (ftest) fclose(ftest); int error_code = errno; EXPECT_TRUE(ftest == nullptr); EXPECT_SYSTEM_ERROR( { FILE* f = safe_fopen(filename, "r"); if (!f) throw fmt::system_error(errno, "Cannot open file '{}'", filename); fclose(f); }, error_code, "Cannot open file 'nonexistent'"); } TEST(FormatterTest, Examples) { EXPECT_EQ("First, thou shalt count to three", format("First, thou shalt count to {0}", "three")); EXPECT_EQ("Bring me a shrubbery", format("Bring me a {}", "shrubbery")); EXPECT_EQ("From 1 to 3", format("From {} to {}", 1, 3)); char buffer[BUFFER_SIZE]; safe_sprintf(buffer, "%03.2f", -1.2); EXPECT_EQ(buffer, format("{:03.2f}", -1.2)); EXPECT_EQ("a, b, c", format("{0}, {1}, {2}", 'a', 'b', 'c')); EXPECT_EQ("a, b, c", format("{}, {}, {}", 'a', 'b', 'c')); EXPECT_EQ("c, b, a", format("{2}, {1}, {0}", 'a', 'b', 'c')); EXPECT_EQ("abracadabra", format("{0}{1}{0}", "abra", "cad")); EXPECT_EQ("left aligned ", format("{:<30}", "left aligned")); EXPECT_EQ(" right aligned", format("{:>30}", "right aligned")); EXPECT_EQ(" centered ", format("{:^30}", "centered")); EXPECT_EQ("***********centered***********", format("{:*^30}", "centered")); EXPECT_EQ("+3.140000; -3.140000", format("{:+f}; {:+f}", 3.14, -3.14)); EXPECT_EQ(" 3.140000; -3.140000", format("{: f}; {: f}", 3.14, -3.14)); EXPECT_EQ("3.140000; -3.140000", format("{:-f}; {:-f}", 3.14, -3.14)); EXPECT_EQ("int: 42; hex: 2a; oct: 52", format("int: {0:d}; hex: {0:x}; oct: {0:o}", 42)); EXPECT_EQ("int: 42; hex: 0x2a; oct: 052", format("int: {0:d}; hex: {0:#x}; oct: {0:#o}", 42)); EXPECT_EQ("The answer is 42", format("The answer is {}", 42)); EXPECT_THROW_MSG(format("The answer is {:d}", "forty-two"), format_error, "invalid type specifier"); EXPECT_EQ(L"Cyrillic letter \x42e", format(L"Cyrillic letter {}", L'\x42e')); EXPECT_WRITE( stdout, fmt::print("{}", std::numeric_limits::infinity()), "inf"); } TEST(FormatIntTest, Data) { fmt::format_int format_int(42); EXPECT_EQ("42", std::string(format_int.data(), format_int.size())); } TEST(FormatIntTest, FormatInt) { EXPECT_EQ("42", fmt::format_int(42).str()); EXPECT_EQ(2u, fmt::format_int(42).size()); EXPECT_EQ("-42", fmt::format_int(-42).str()); EXPECT_EQ(3u, fmt::format_int(-42).size()); EXPECT_EQ("42", fmt::format_int(42ul).str()); EXPECT_EQ("-42", fmt::format_int(-42l).str()); EXPECT_EQ("42", fmt::format_int(42ull).str()); EXPECT_EQ("-42", fmt::format_int(-42ll).str()); std::ostringstream os; os << std::numeric_limits::max(); EXPECT_EQ(os.str(), fmt::format_int(std::numeric_limits::max()).str()); } TEST(FormatTest, Print) { #if FMT_USE_FILE_DESCRIPTORS EXPECT_WRITE(stdout, fmt::print("Don't {}!", "panic"), "Don't panic!"); EXPECT_WRITE(stderr, fmt::print(stderr, "Don't {}!", "panic"), "Don't panic!"); #endif } TEST(FormatTest, Variadic) { EXPECT_EQ("abc1", format("{}c{}", "ab", 1)); EXPECT_EQ(L"abc1", format(L"{}c{}", L"ab", 1)); } TEST(FormatTest, Dynamic) { typedef fmt::format_context ctx; std::vector> args; args.emplace_back(fmt::internal::make_arg(42)); args.emplace_back(fmt::internal::make_arg("abc1")); args.emplace_back(fmt::internal::make_arg(1.5f)); std::string result = fmt::vformat( "{} and {} and {}", fmt::basic_format_args( args.data(), static_cast(args.size()))); EXPECT_EQ("42 and abc1 and 1.5", result); } TEST(FormatTest, JoinArg) { using fmt::join; int v1[3] = {1, 2, 3}; std::vector v2; v2.push_back(1.2f); v2.push_back(3.4f); void* v3[2] = {&v1[0], &v1[1]}; EXPECT_EQ("(1, 2, 3)", format("({})", join(v1, v1 + 3, ", "))); EXPECT_EQ("(1)", format("({})", join(v1, v1 + 1, ", "))); EXPECT_EQ("()", format("({})", join(v1, v1, ", "))); EXPECT_EQ("(001, 002, 003)", format("({:03})", join(v1, v1 + 3, ", "))); EXPECT_EQ("(+01.20, +03.40)", format("({:+06.2f})", join(v2.begin(), v2.end(), ", "))); EXPECT_EQ(L"(1, 2, 3)", format(L"({})", join(v1, v1 + 3, L", "))); EXPECT_EQ("1, 2, 3", format("{0:{1}}", join(v1, v1 + 3, ", "), 1)); EXPECT_EQ(format("{}, {}", v3[0], v3[1]), format("{}", join(v3, v3 + 2, ", "))); #if !FMT_GCC_VERSION || FMT_GCC_VERSION >= 405 EXPECT_EQ("(1, 2, 3)", format("({})", join(v1, ", "))); EXPECT_EQ("(+01.20, +03.40)", format("({:+06.2f})", join(v2, ", "))); #endif } template std::string str(const T& value) { return fmt::format("{}", value); } TEST(StrTest, Convert) { EXPECT_EQ("42", str(42)); std::string s = str(Date(2012, 12, 9)); EXPECT_EQ("2012-12-9", s); } std::string vformat_message(int id, const char* format, fmt::format_args args) { fmt::memory_buffer buffer; format_to(buffer, "[{}] ", id); vformat_to(buffer, format, args); return to_string(buffer); } template std::string format_message(int id, const char* format, const Args&... args) { auto va = fmt::make_format_args(args...); return vformat_message(id, format, va); } TEST(FormatTest, FormatMessageExample) { EXPECT_EQ("[42] something happened", format_message(42, "{} happened", "something")); } template void print_error(const char* file, int line, const char* format, const Args&... args) { fmt::print("{}: {}: ", file, line); fmt::print(format, args...); } TEST(FormatTest, UnpackedArgs) { EXPECT_EQ("0123456789abcdefg", fmt::format("{}{}{}{}{}{}{}{}{}{}{}{}{}{}{}{}{}", 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 'a', 'b', 'c', 'd', 'e', 'f', 'g')); } #if FMT_USE_USER_DEFINED_LITERALS // Passing user-defined literals directly to EXPECT_EQ causes problems // with macro argument stringification (#) on some versions of GCC. // Workaround: Assing the UDL result to a variable before the macro. using namespace fmt::literals; TEST(LiteralsTest, Format) { auto udl_format = "{}c{}"_format("ab", 1); EXPECT_EQ(format("{}c{}", "ab", 1), udl_format); auto udl_format_w = L"{}c{}"_format(L"ab", 1); EXPECT_EQ(format(L"{}c{}", L"ab", 1), udl_format_w); } TEST(LiteralsTest, NamedArg) { auto udl_a = format("{first}{second}{first}{third}", "first"_a = "abra", "second"_a = "cad", "third"_a = 99); EXPECT_EQ(format("{first}{second}{first}{third}", fmt::arg("first", "abra"), fmt::arg("second", "cad"), fmt::arg("third", 99)), udl_a); auto udl_a_w = format(L"{first}{second}{first}{third}", L"first"_a = L"abra", L"second"_a = L"cad", L"third"_a = 99); EXPECT_EQ( format(L"{first}{second}{first}{third}", fmt::arg(L"first", L"abra"), fmt::arg(L"second", L"cad"), fmt::arg(L"third", 99)), udl_a_w); } TEST(FormatTest, UdlTemplate) { EXPECT_EQ("foo", "foo"_format()); EXPECT_EQ(" 42", "{0:10}"_format(42)); EXPECT_EQ("42", fmt::format(FMT_STRING("{}"), 42)); EXPECT_EQ(L"42", fmt::format(FMT_STRING(L"{}"), 42)); } #endif // FMT_USE_USER_DEFINED_LITERALS enum TestEnum { A }; TEST(FormatTest, Enum) { EXPECT_EQ("0", fmt::format("{}", A)); } TEST(FormatTest, EnumFormatterUnambiguous) { fmt::formatter f; ASSERT_GE(sizeof(f), 0); // use f to avoid compiler warning } #if FMT_HAS_FEATURE(cxx_strong_enums) enum TestFixedEnum : short { B }; TEST(FormatTest, FixedEnum) { EXPECT_EQ("0", fmt::format("{}", B)); } #endif typedef fmt::back_insert_range> buffer_range; class mock_arg_formatter : public fmt::internal::function< fmt::internal::arg_formatter_base::iterator>, public fmt::internal::arg_formatter_base { private: MOCK_METHOD1(call, void(long long value)); public: typedef fmt::internal::arg_formatter_base base; typedef buffer_range range; mock_arg_formatter(fmt::format_context& ctx, fmt::format_parse_context*, fmt::format_specs* s = nullptr) : base(fmt::internal::get_container(ctx.out()), s, ctx.locale()) { EXPECT_CALL(*this, call(42)); } template typename std::enable_if::value, iterator>::type operator()(T value) { call(value); return base::operator()(value); } template typename std::enable_if::value, iterator>::type operator()(T value) { return base::operator()(value); } iterator operator()(fmt::basic_format_arg::handle) { return base::operator()(fmt::monostate()); } }; static void custom_vformat(fmt::string_view format_str, fmt::format_args args) { fmt::memory_buffer buffer; fmt::vformat_to(buffer, format_str, args); } template void custom_format(const char* format_str, const Args&... args) { auto va = fmt::make_format_args(args...); return custom_vformat(format_str, va); } TEST(FormatTest, CustomArgFormatter) { custom_format("{}", 42); } TEST(FormatTest, NonNullTerminatedFormatString) { EXPECT_EQ("42", format(string_view("{}foo", 2), 42)); } struct variant { enum { INT, STRING } type; explicit variant(int) : type(INT) {} explicit variant(const char*) : type(STRING) {} }; FMT_BEGIN_NAMESPACE template <> struct formatter : dynamic_formatter<> { auto format(variant value, format_context& ctx) -> decltype(ctx.out()) { if (value.type == variant::INT) return dynamic_formatter<>::format(42, ctx); return dynamic_formatter<>::format("foo", ctx); } }; FMT_END_NAMESPACE TEST(FormatTest, DynamicFormatter) { auto num = variant(42); auto str = variant("foo"); EXPECT_EQ("42", format("{:d}", num)); EXPECT_EQ("foo", format("{:s}", str)); EXPECT_EQ(" 42 foo ", format("{:{}} {:{}}", num, 3, str, 4)); EXPECT_THROW_MSG(format("{0:{}}", num), format_error, "cannot switch from manual to automatic argument indexing"); EXPECT_THROW_MSG(format("{:{0}}", num), format_error, "cannot switch from automatic to manual argument indexing"); EXPECT_THROW_MSG(format("{:=}", str), format_error, "format specifier requires numeric argument"); EXPECT_THROW_MSG(format("{:+}", str), format_error, "format specifier requires numeric argument"); EXPECT_THROW_MSG(format("{:-}", str), format_error, "format specifier requires numeric argument"); EXPECT_THROW_MSG(format("{: }", str), format_error, "format specifier requires numeric argument"); EXPECT_THROW_MSG(format("{:#}", str), format_error, "format specifier requires numeric argument"); EXPECT_THROW_MSG(format("{:0}", str), format_error, "format specifier requires numeric argument"); EXPECT_THROW_MSG(format("{:.2}", num), format_error, "precision not allowed for this argument type"); } TEST(FormatTest, ToString) { EXPECT_EQ("42", fmt::to_string(42)); EXPECT_EQ("0x1234", fmt::to_string(reinterpret_cast(0x1234))); } TEST(FormatTest, ToWString) { EXPECT_EQ(L"42", fmt::to_wstring(42)); } TEST(FormatTest, OutputIterators) { std::list out; fmt::format_to(std::back_inserter(out), "{}", 42); EXPECT_EQ("42", std::string(out.begin(), out.end())); std::stringstream s; fmt::format_to(std::ostream_iterator(s), "{}", 42); EXPECT_EQ("42", s.str()); } TEST(FormatTest, FormattedSize) { EXPECT_EQ(2u, fmt::formatted_size("{}", 42)); } TEST(FormatTest, FormatToN) { char buffer[4]; buffer[3] = 'x'; auto result = fmt::format_to_n(buffer, 3, "{}", 12345); EXPECT_EQ(5u, result.size); EXPECT_EQ(buffer + 3, result.out); EXPECT_EQ("123x", fmt::string_view(buffer, 4)); result = fmt::format_to_n(buffer, 3, "{:s}", "foobar"); EXPECT_EQ(6u, result.size); EXPECT_EQ(buffer + 3, result.out); EXPECT_EQ("foox", fmt::string_view(buffer, 4)); buffer[0] = 'x'; buffer[1] = 'x'; buffer[2] = 'x'; result = fmt::format_to_n(buffer, 3, "{}", 'A'); EXPECT_EQ(1u, result.size); EXPECT_EQ(buffer + 1, result.out); EXPECT_EQ("Axxx", fmt::string_view(buffer, 4)); result = fmt::format_to_n(buffer, 3, "{}{} ", 'B', 'C'); EXPECT_EQ(3u, result.size); EXPECT_EQ(buffer + 3, result.out); EXPECT_EQ("BC x", fmt::string_view(buffer, 4)); } TEST(FormatTest, WideFormatToN) { wchar_t buffer[4]; buffer[3] = L'x'; auto result = fmt::format_to_n(buffer, 3, L"{}", 12345); EXPECT_EQ(5u, result.size); EXPECT_EQ(buffer + 3, result.out); EXPECT_EQ(L"123x", fmt::wstring_view(buffer, 4)); buffer[0] = L'x'; buffer[1] = L'x'; buffer[2] = L'x'; result = fmt::format_to_n(buffer, 3, L"{}", L'A'); EXPECT_EQ(1u, result.size); EXPECT_EQ(buffer + 1, result.out); EXPECT_EQ(L"Axxx", fmt::wstring_view(buffer, 4)); result = fmt::format_to_n(buffer, 3, L"{}{} ", L'B', L'C'); EXPECT_EQ(3u, result.size); EXPECT_EQ(buffer + 3, result.out); EXPECT_EQ(L"BC x", fmt::wstring_view(buffer, 4)); } #if FMT_USE_CONSTEXPR struct test_arg_id_handler { enum result { NONE, EMPTY, INDEX, NAME, ERROR }; result res = NONE; unsigned index = 0; string_view name; FMT_CONSTEXPR void operator()() { res = EMPTY; } FMT_CONSTEXPR void operator()(unsigned i) { res = INDEX; index = i; } FMT_CONSTEXPR void operator()(string_view n) { res = NAME; name = n; } FMT_CONSTEXPR void on_error(const char*) { res = ERROR; } }; template FMT_CONSTEXPR test_arg_id_handler parse_arg_id(const char (&s)[N]) { test_arg_id_handler h; fmt::internal::parse_arg_id(s, s + N, h); return h; } TEST(FormatTest, ConstexprParseArgID) { static_assert(parse_arg_id(":").res == test_arg_id_handler::EMPTY, ""); static_assert(parse_arg_id("}").res == test_arg_id_handler::EMPTY, ""); static_assert(parse_arg_id("42:").res == test_arg_id_handler::INDEX, ""); static_assert(parse_arg_id("42:").index == 42, ""); static_assert(parse_arg_id("foo:").res == test_arg_id_handler::NAME, ""); static_assert(parse_arg_id("foo:").name.size() == 3, ""); static_assert(parse_arg_id("!").res == test_arg_id_handler::ERROR, ""); } struct test_format_specs_handler { enum Result { NONE, PLUS, MINUS, SPACE, HASH, ZERO, ERROR }; Result res = NONE; fmt::alignment align_ = fmt::ALIGN_DEFAULT; char fill = 0; unsigned width = 0; fmt::internal::arg_ref width_ref; unsigned precision = 0; fmt::internal::arg_ref precision_ref; char type = 0; // Workaround for MSVC2017 bug that results in "expression did not evaluate // to a constant" with compiler-generated copy ctor. FMT_CONSTEXPR test_format_specs_handler() {} FMT_CONSTEXPR test_format_specs_handler( const test_format_specs_handler& other) : res(other.res), align_(other.align_), fill(other.fill), width(other.width), width_ref(other.width_ref), precision(other.precision), precision_ref(other.precision_ref), type(other.type) {} FMT_CONSTEXPR void on_align(fmt::alignment a) { align_ = a; } FMT_CONSTEXPR void on_fill(char f) { fill = f; } FMT_CONSTEXPR void on_plus() { res = PLUS; } FMT_CONSTEXPR void on_minus() { res = MINUS; } FMT_CONSTEXPR void on_space() { res = SPACE; } FMT_CONSTEXPR void on_hash() { res = HASH; } FMT_CONSTEXPR void on_zero() { res = ZERO; } FMT_CONSTEXPR void on_width(unsigned w) { width = w; } FMT_CONSTEXPR void on_dynamic_width(fmt::internal::auto_id) {} FMT_CONSTEXPR void on_dynamic_width(unsigned index) { width_ref = index; } FMT_CONSTEXPR void on_dynamic_width(string_view) {} FMT_CONSTEXPR void on_precision(unsigned p) { precision = p; } FMT_CONSTEXPR void on_dynamic_precision(fmt::internal::auto_id) {} FMT_CONSTEXPR void on_dynamic_precision(unsigned index) { precision_ref = index; } FMT_CONSTEXPR void on_dynamic_precision(string_view) {} FMT_CONSTEXPR void end_precision() {} FMT_CONSTEXPR void on_type(char t) { type = t; } FMT_CONSTEXPR void on_error(const char*) { res = ERROR; } }; template FMT_CONSTEXPR test_format_specs_handler parse_test_specs(const char (&s)[N]) { test_format_specs_handler h; fmt::internal::parse_format_specs(s, s + N, h); return h; } TEST(FormatTest, ConstexprParseFormatSpecs) { typedef test_format_specs_handler handler; static_assert(parse_test_specs("<").align_ == fmt::ALIGN_LEFT, ""); static_assert(parse_test_specs("*^").fill == '*', ""); static_assert(parse_test_specs("+").res == handler::PLUS, ""); static_assert(parse_test_specs("-").res == handler::MINUS, ""); static_assert(parse_test_specs(" ").res == handler::SPACE, ""); static_assert(parse_test_specs("#").res == handler::HASH, ""); static_assert(parse_test_specs("0").res == handler::ZERO, ""); static_assert(parse_test_specs("42").width == 42, ""); static_assert(parse_test_specs("{42}").width_ref.val.index == 42, ""); static_assert(parse_test_specs(".42").precision == 42, ""); static_assert(parse_test_specs(".{42}").precision_ref.val.index == 42, ""); static_assert(parse_test_specs("d").type == 'd', ""); static_assert(parse_test_specs("{<").res == handler::ERROR, ""); } struct test_parse_context { typedef char char_type; FMT_CONSTEXPR unsigned next_arg_id() { return 11; } template FMT_CONSTEXPR void check_arg_id(Id) {} FMT_CONSTEXPR const char* begin() { return nullptr; } FMT_CONSTEXPR const char* end() { return nullptr; } void on_error(const char*) {} }; struct test_context { typedef char char_type; typedef fmt::basic_format_arg format_arg; template struct formatter_type { typedef fmt::formatter type; }; template FMT_CONSTEXPR fmt::basic_format_arg arg(Id id) { return fmt::internal::make_arg(id); } void on_error(const char*) {} FMT_CONSTEXPR test_context error_handler() { return *this; } }; template FMT_CONSTEXPR fmt::format_specs parse_specs(const char (&s)[N]) { fmt::format_specs specs; test_parse_context parse_ctx; test_context ctx{}; fmt::internal::specs_handler h( specs, parse_ctx, ctx); parse_format_specs(s, s + N, h); return specs; } TEST(FormatTest, ConstexprSpecsHandler) { static_assert(parse_specs("<").align() == fmt::ALIGN_LEFT, ""); static_assert(parse_specs("*^").fill() == '*', ""); static_assert(parse_specs("+").has(fmt::PLUS_FLAG), ""); static_assert(parse_specs("-").has(fmt::MINUS_FLAG), ""); static_assert(parse_specs(" ").has(fmt::SIGN_FLAG), ""); static_assert(parse_specs("#").has(fmt::HASH_FLAG), ""); static_assert(parse_specs("0").align() == fmt::ALIGN_NUMERIC, ""); static_assert(parse_specs("42").width() == 42, ""); static_assert(parse_specs("{}").width() == 11, ""); static_assert(parse_specs("{22}").width() == 22, ""); static_assert(parse_specs(".42").precision == 42, ""); static_assert(parse_specs(".{}").precision == 11, ""); static_assert(parse_specs(".{22}").precision == 22, ""); static_assert(parse_specs("d").type == 'd', ""); } template FMT_CONSTEXPR fmt::internal::dynamic_format_specs parse_dynamic_specs( const char (&s)[N]) { fmt::internal::dynamic_format_specs specs; test_parse_context ctx{}; fmt::internal::dynamic_specs_handler h(specs, ctx); parse_format_specs(s, s + N, h); return specs; } TEST(FormatTest, ConstexprDynamicSpecsHandler) { static_assert(parse_dynamic_specs("<").align() == fmt::ALIGN_LEFT, ""); static_assert(parse_dynamic_specs("*^").fill() == '*', ""); static_assert(parse_dynamic_specs("+").has(fmt::PLUS_FLAG), ""); static_assert(parse_dynamic_specs("-").has(fmt::MINUS_FLAG), ""); static_assert(parse_dynamic_specs(" ").has(fmt::SIGN_FLAG), ""); static_assert(parse_dynamic_specs("#").has(fmt::HASH_FLAG), ""); static_assert(parse_dynamic_specs("0").align() == fmt::ALIGN_NUMERIC, ""); static_assert(parse_dynamic_specs("42").width() == 42, ""); static_assert(parse_dynamic_specs("{}").width_ref.val.index == 11, ""); static_assert(parse_dynamic_specs("{42}").width_ref.val.index == 42, ""); static_assert(parse_dynamic_specs(".42").precision == 42, ""); static_assert(parse_dynamic_specs(".{}").precision_ref.val.index == 11, ""); static_assert(parse_dynamic_specs(".{42}").precision_ref.val.index == 42, ""); static_assert(parse_dynamic_specs("d").type == 'd', ""); } template FMT_CONSTEXPR test_format_specs_handler check_specs(const char (&s)[N]) { fmt::internal::specs_checker checker( test_format_specs_handler(), fmt::internal::double_type); parse_format_specs(s, s + N, checker); return checker; } TEST(FormatTest, ConstexprSpecsChecker) { typedef test_format_specs_handler handler; static_assert(check_specs("<").align_ == fmt::ALIGN_LEFT, ""); static_assert(check_specs("*^").fill == '*', ""); static_assert(check_specs("+").res == handler::PLUS, ""); static_assert(check_specs("-").res == handler::MINUS, ""); static_assert(check_specs(" ").res == handler::SPACE, ""); static_assert(check_specs("#").res == handler::HASH, ""); static_assert(check_specs("0").res == handler::ZERO, ""); static_assert(check_specs("42").width == 42, ""); static_assert(check_specs("{42}").width_ref.val.index == 42, ""); static_assert(check_specs(".42").precision == 42, ""); static_assert(check_specs(".{42}").precision_ref.val.index == 42, ""); static_assert(check_specs("d").type == 'd', ""); static_assert(check_specs("{<").res == handler::ERROR, ""); } struct test_format_string_handler { FMT_CONSTEXPR void on_text(const char*, const char*) {} FMT_CONSTEXPR void on_arg_id() {} template FMT_CONSTEXPR void on_arg_id(T) {} FMT_CONSTEXPR void on_replacement_field(const char*) {} FMT_CONSTEXPR const char* on_format_specs(const char* begin, const char*) { return begin; } FMT_CONSTEXPR void on_error(const char*) { error = true; } bool error = false; }; template FMT_CONSTEXPR bool parse_string(const char (&s)[N]) { test_format_string_handler h; fmt::internal::parse_format_string(fmt::string_view(s, N - 1), h); return !h.error; } TEST(FormatTest, ConstexprParseFormatString) { static_assert(parse_string("foo"), ""); static_assert(!parse_string("}"), ""); static_assert(parse_string("{}"), ""); static_assert(parse_string("{42}"), ""); static_assert(parse_string("{foo}"), ""); static_assert(parse_string("{:}"), ""); } struct test_error_handler { const char*& error; FMT_CONSTEXPR test_error_handler(const char*& err) : error(err) {} FMT_CONSTEXPR test_error_handler(const test_error_handler& other) : error(other.error) {} FMT_CONSTEXPR void on_error(const char* message) { if (!error) error = message; } }; FMT_CONSTEXPR size_t len(const char* s) { size_t len = 0; while (*s++) ++len; return len; } FMT_CONSTEXPR bool equal(const char* s1, const char* s2) { if (!s1 || !s2) return s1 == s2; while (*s1 && *s1 == *s2) { ++s1; ++s2; } return *s1 == *s2; } template FMT_CONSTEXPR bool test_error(const char* fmt, const char* expected_error) { const char* actual_error = nullptr; fmt::internal::do_check_format_string( string_view(fmt, len(fmt)), test_error_handler(actual_error)); return equal(actual_error, expected_error); } # define EXPECT_ERROR_NOARGS(fmt, error) \ static_assert(test_error(fmt, error), "") # define EXPECT_ERROR(fmt, error, ...) \ static_assert(test_error<__VA_ARGS__>(fmt, error), "") TEST(FormatTest, FormatStringErrors) { EXPECT_ERROR_NOARGS("foo", nullptr); EXPECT_ERROR_NOARGS("}", "unmatched '}' in format string"); EXPECT_ERROR("{0:s", "unknown format specifier", Date); # if FMT_MSC_VER >= 1916 // This causes an internal compiler error in MSVC2017. EXPECT_ERROR("{0:=5", "unknown format specifier", int); EXPECT_ERROR("{:{<}", "invalid fill character '{'", int); EXPECT_ERROR("{:10000000000}", "number is too big", int); EXPECT_ERROR("{:.10000000000}", "number is too big", int); EXPECT_ERROR_NOARGS("{:x}", "argument index out of range"); EXPECT_ERROR("{:=}", "format specifier requires numeric argument", const char*); EXPECT_ERROR("{:+}", "format specifier requires numeric argument", const char*); EXPECT_ERROR("{:-}", "format specifier requires numeric argument", const char*); EXPECT_ERROR("{:#}", "format specifier requires numeric argument", const char*); EXPECT_ERROR("{: }", "format specifier requires numeric argument", const char*); EXPECT_ERROR("{:0}", "format specifier requires numeric argument", const char*); EXPECT_ERROR("{:+}", "format specifier requires signed argument", unsigned); EXPECT_ERROR("{:-}", "format specifier requires signed argument", unsigned); EXPECT_ERROR("{: }", "format specifier requires signed argument", unsigned); EXPECT_ERROR("{:.2}", "precision not allowed for this argument type", int); EXPECT_ERROR("{:s}", "invalid type specifier", int); EXPECT_ERROR("{:s}", "invalid type specifier", bool); EXPECT_ERROR("{:s}", "invalid type specifier", char); EXPECT_ERROR("{:+}", "invalid format specifier for char", char); EXPECT_ERROR("{:s}", "invalid type specifier", double); EXPECT_ERROR("{:d}", "invalid type specifier", const char*); EXPECT_ERROR("{:d}", "invalid type specifier", std::string); EXPECT_ERROR("{:s}", "invalid type specifier", void*); # else fmt::print("warning: constexpr is broken in this version of MSVC\n"); # endif EXPECT_ERROR("{foo", "compile-time checks don't support named arguments", int); EXPECT_ERROR_NOARGS("{10000000000}", "number is too big"); EXPECT_ERROR_NOARGS("{0x}", "invalid format string"); EXPECT_ERROR_NOARGS("{-}", "invalid format string"); EXPECT_ERROR("{:{0x}}", "invalid format string", int); EXPECT_ERROR("{:{-}}", "invalid format string", int); EXPECT_ERROR("{:.{0x}}", "invalid format string", int); EXPECT_ERROR("{:.{-}}", "invalid format string", int); EXPECT_ERROR("{:.x}", "missing precision specifier", int); EXPECT_ERROR_NOARGS("{}", "argument index out of range"); EXPECT_ERROR("{1}", "argument index out of range", int); EXPECT_ERROR("{1}{}", "cannot switch from manual to automatic argument indexing", int, int); EXPECT_ERROR("{}{1}", "cannot switch from automatic to manual argument indexing", int, int); } TEST(FormatTest, VFormatTo) { typedef fmt::format_context context; fmt::basic_format_arg arg = fmt::internal::make_arg(42); fmt::basic_format_args args(&arg, 1); std::string s; fmt::vformat_to(std::back_inserter(s), "{}", args); EXPECT_EQ("42", s); s.clear(); fmt::vformat_to(std::back_inserter(s), FMT_STRING("{}"), args); EXPECT_EQ("42", s); typedef fmt::wformat_context wcontext; fmt::basic_format_arg warg = fmt::internal::make_arg(42); fmt::basic_format_args wargs(&warg, 1); std::wstring w; fmt::vformat_to(std::back_inserter(w), L"{}", wargs); EXPECT_EQ(L"42", w); w.clear(); fmt::vformat_to(std::back_inserter(w), FMT_STRING(L"{}"), wargs); EXPECT_EQ(L"42", w); } template static std::string FmtToString(const T& t) { return fmt::format(FMT_STRING("{}"), t); } TEST(FormatTest, FmtStringInTemplate) { EXPECT_EQ(FmtToString(1), "1"); EXPECT_EQ(FmtToString(0), "0"); } #endif // FMT_USE_CONSTEXPR // C++20 feature test, since r346892 Clang considers char8_t a fundamental // type in this mode. If this is the case __cpp_char8_t will be defined. #ifndef __cpp_char8_t // Locally provide type char8_t defined in format.h using fmt::char8_t; #endif TEST(FormatTest, ConstructU8StringViewFromCString) { fmt::u8string_view s("ab"); EXPECT_EQ(s.size(), 2u); const char8_t* data = s.data(); EXPECT_EQ(data[0], 'a'); EXPECT_EQ(data[1], 'b'); } TEST(FormatTest, ConstructU8StringViewFromDataAndSize) { fmt::u8string_view s("foobar", 3); EXPECT_EQ(s.size(), 3u); const char8_t* data = s.data(); EXPECT_EQ(data[0], 'f'); EXPECT_EQ(data[1], 'o'); EXPECT_EQ(data[2], 'o'); } #if FMT_USE_USER_DEFINED_LITERALS TEST(FormatTest, U8StringViewLiteral) { using namespace fmt::literals; fmt::u8string_view s = "ab"_u; EXPECT_EQ(s.size(), 2u); const char8_t* data = s.data(); EXPECT_EQ(data[0], 'a'); EXPECT_EQ(data[1], 'b'); EXPECT_EQ(format("{:*^5}"_u, "🤡"_u), "**🤡**"_u); } #endif TEST(FormatTest, FormatU8String) { EXPECT_EQ(format(fmt::u8string_view("{}"), 42), fmt::u8string_view("42")); } TEST(FormatTest, EmphasisNonHeaderOnly) { // ensure this compiles even if FMT_HEADER_ONLY is not defined. EXPECT_EQ(fmt::format(fmt::emphasis::bold, "bold error"), "\x1b[1mbold error\x1b[0m"); } TEST(FormatTest, CharTraitsIsNotAmbiguous) { // Test that we don't inject internal names into the std namespace. using namespace std; char_traits::char_type c; (void)c; #if __cplusplus >= 201103L std::string s; auto lval = begin(s); (void)lval; #endif } struct mychar { int value; mychar() = default; mychar(char val) : value(val) {} operator int() const { return value; } }; FMT_BEGIN_NAMESPACE template <> struct is_char : std::true_type {}; FMT_END_NAMESPACE TEST(FormatTest, FormatCustomChar) { const mychar format[] = {'{', '}', 0}; auto result = fmt::format(format, mychar('x')); EXPECT_EQ(result.size(), 1); EXPECT_EQ(result[0], mychar('x')); }