2018-06-18 22:18:53 +02:00
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// Copyright 2018 The Abseil Authors.
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//
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// Licensed under the Apache License, Version 2.0 (the "License");
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// you may not use this file except in compliance with the License.
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// You may obtain a copy of the License at
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//
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2019-03-08 16:27:53 +01:00
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// https://www.apache.org/licenses/LICENSE-2.0
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2018-06-18 22:18:53 +02:00
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//
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the License is distributed on an "AS IS" BASIS,
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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// See the License for the specific language governing permissions and
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// limitations under the License.
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#include "absl/strings/internal/charconv_parse.h"
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#include <string>
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#include <utility>
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#include "gmock/gmock.h"
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#include "gtest/gtest.h"
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#include "absl/base/internal/raw_logging.h"
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#include "absl/strings/str_cat.h"
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using absl::chars_format;
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using absl::strings_internal::FloatType;
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using absl::strings_internal::ParsedFloat;
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using absl::strings_internal::ParseFloat;
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namespace {
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2018-08-21 20:31:02 +02:00
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// Check that a given string input is parsed to the expected mantissa and
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2018-06-18 22:18:53 +02:00
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// exponent.
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//
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2018-08-21 20:31:02 +02:00
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// Input string `s` must contain a '$' character. It marks the end of the
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2018-06-18 22:18:53 +02:00
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// characters that should be consumed by the match. It is stripped from the
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// input to ParseFloat.
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//
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2018-08-21 20:31:02 +02:00
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// If input string `s` contains '[' and ']' characters, these mark the region
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2018-06-18 22:18:53 +02:00
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// of characters that should be marked as the "subrange". For NaNs, this is
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2018-08-21 20:31:02 +02:00
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// the location of the extended NaN string. For numbers, this is the location
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2018-06-18 22:18:53 +02:00
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// of the full, over-large mantissa.
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template <int base>
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void ExpectParsedFloat(std::string s, absl::chars_format format_flags,
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FloatType expected_type, uint64_t expected_mantissa,
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int expected_exponent,
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int expected_literal_exponent = -999) {
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SCOPED_TRACE(s);
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int begin_subrange = -1;
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int end_subrange = -1;
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// If s contains '[' and ']', then strip these characters and set the subrange
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// indices appropriately.
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std::string::size_type open_bracket_pos = s.find('[');
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if (open_bracket_pos != std::string::npos) {
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begin_subrange = static_cast<int>(open_bracket_pos);
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s.replace(open_bracket_pos, 1, "");
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std::string::size_type close_bracket_pos = s.find(']');
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ABSL_RAW_CHECK(close_bracket_pos != absl::string_view::npos,
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"Test input contains [ without matching ]");
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end_subrange = static_cast<int>(close_bracket_pos);
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s.replace(close_bracket_pos, 1, "");
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}
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const std::string::size_type expected_characters_matched = s.find('$');
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ABSL_RAW_CHECK(expected_characters_matched != std::string::npos,
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2020-03-10 17:28:06 +01:00
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"Input string must contain $");
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2018-06-18 22:18:53 +02:00
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s.replace(expected_characters_matched, 1, "");
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ParsedFloat parsed =
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ParseFloat<base>(s.data(), s.data() + s.size(), format_flags);
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EXPECT_NE(parsed.end, nullptr);
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if (parsed.end == nullptr) {
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return; // The following tests are not useful if we fully failed to parse
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}
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EXPECT_EQ(parsed.type, expected_type);
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if (begin_subrange == -1) {
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EXPECT_EQ(parsed.subrange_begin, nullptr);
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EXPECT_EQ(parsed.subrange_end, nullptr);
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} else {
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EXPECT_EQ(parsed.subrange_begin, s.data() + begin_subrange);
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EXPECT_EQ(parsed.subrange_end, s.data() + end_subrange);
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}
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if (parsed.type == FloatType::kNumber) {
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EXPECT_EQ(parsed.mantissa, expected_mantissa);
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EXPECT_EQ(parsed.exponent, expected_exponent);
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if (expected_literal_exponent != -999) {
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EXPECT_EQ(parsed.literal_exponent, expected_literal_exponent);
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}
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}
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auto characters_matched = static_cast<int>(parsed.end - s.data());
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EXPECT_EQ(characters_matched, expected_characters_matched);
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}
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2018-08-21 20:31:02 +02:00
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// Check that a given string input is parsed to the expected mantissa and
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2018-06-18 22:18:53 +02:00
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// exponent.
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//
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2018-08-21 20:31:02 +02:00
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// Input string `s` must contain a '$' character. It marks the end of the
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2018-06-18 22:18:53 +02:00
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// characters that were consumed by the match.
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template <int base>
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void ExpectNumber(std::string s, absl::chars_format format_flags,
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uint64_t expected_mantissa, int expected_exponent,
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int expected_literal_exponent = -999) {
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ExpectParsedFloat<base>(std::move(s), format_flags, FloatType::kNumber,
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expected_mantissa, expected_exponent,
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expected_literal_exponent);
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}
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2018-08-21 20:31:02 +02:00
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// Check that a given string input is parsed to the given special value.
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2018-06-18 22:18:53 +02:00
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//
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// This tests against both number bases, since infinities and NaNs have
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// identical representations in both modes.
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void ExpectSpecial(const std::string& s, absl::chars_format format_flags,
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FloatType type) {
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ExpectParsedFloat<10>(s, format_flags, type, 0, 0);
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ExpectParsedFloat<16>(s, format_flags, type, 0, 0);
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}
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2018-08-21 20:31:02 +02:00
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// Check that a given input string is not matched by Float.
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2018-06-18 22:18:53 +02:00
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template <int base>
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void ExpectFailedParse(absl::string_view s, absl::chars_format format_flags) {
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ParsedFloat parsed =
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ParseFloat<base>(s.data(), s.data() + s.size(), format_flags);
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EXPECT_EQ(parsed.end, nullptr);
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}
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TEST(ParseFloat, SimpleValue) {
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// Test that various forms of floating point numbers all parse correctly.
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ExpectNumber<10>("1.23456789e5$", chars_format::general, 123456789, -3);
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ExpectNumber<10>("1.23456789e+5$", chars_format::general, 123456789, -3);
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ExpectNumber<10>("1.23456789E5$", chars_format::general, 123456789, -3);
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ExpectNumber<10>("1.23456789e05$", chars_format::general, 123456789, -3);
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ExpectNumber<10>("123.456789e3$", chars_format::general, 123456789, -3);
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ExpectNumber<10>("0.000123456789e9$", chars_format::general, 123456789, -3);
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ExpectNumber<10>("123456.789$", chars_format::general, 123456789, -3);
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ExpectNumber<10>("123456789e-3$", chars_format::general, 123456789, -3);
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ExpectNumber<16>("1.234abcdefp28$", chars_format::general, 0x1234abcdef, -8);
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ExpectNumber<16>("1.234abcdefp+28$", chars_format::general, 0x1234abcdef, -8);
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ExpectNumber<16>("1.234ABCDEFp28$", chars_format::general, 0x1234abcdef, -8);
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ExpectNumber<16>("1.234AbCdEfP0028$", chars_format::general, 0x1234abcdef,
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-8);
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ExpectNumber<16>("123.4abcdefp20$", chars_format::general, 0x1234abcdef, -8);
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ExpectNumber<16>("0.0001234abcdefp44$", chars_format::general, 0x1234abcdef,
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-8);
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ExpectNumber<16>("1234abcd.ef$", chars_format::general, 0x1234abcdef, -8);
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ExpectNumber<16>("1234abcdefp-8$", chars_format::general, 0x1234abcdef, -8);
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// ExpectNumber does not attempt to drop trailing zeroes.
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ExpectNumber<10>("0001.2345678900e005$", chars_format::general, 12345678900,
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-5);
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ExpectNumber<16>("0001.234abcdef000p28$", chars_format::general,
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0x1234abcdef000, -20);
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// Ensure non-matching characters after a number are ignored, even when they
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// look like potentially matching characters.
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ExpectNumber<10>("1.23456789e5$ ", chars_format::general, 123456789, -3);
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ExpectNumber<10>("1.23456789e5$e5e5", chars_format::general, 123456789, -3);
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ExpectNumber<10>("1.23456789e5$.25", chars_format::general, 123456789, -3);
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ExpectNumber<10>("1.23456789e5$-", chars_format::general, 123456789, -3);
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ExpectNumber<10>("1.23456789e5$PUPPERS!!!", chars_format::general, 123456789,
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-3);
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ExpectNumber<10>("123456.789$efghij", chars_format::general, 123456789, -3);
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ExpectNumber<10>("123456.789$e", chars_format::general, 123456789, -3);
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ExpectNumber<10>("123456.789$p5", chars_format::general, 123456789, -3);
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ExpectNumber<10>("123456.789$.10", chars_format::general, 123456789, -3);
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ExpectNumber<16>("1.234abcdefp28$ ", chars_format::general, 0x1234abcdef,
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-8);
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ExpectNumber<16>("1.234abcdefp28$p28", chars_format::general, 0x1234abcdef,
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-8);
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ExpectNumber<16>("1.234abcdefp28$.125", chars_format::general, 0x1234abcdef,
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-8);
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ExpectNumber<16>("1.234abcdefp28$-", chars_format::general, 0x1234abcdef, -8);
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ExpectNumber<16>("1.234abcdefp28$KITTEHS!!!", chars_format::general,
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0x1234abcdef, -8);
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ExpectNumber<16>("1234abcd.ef$ghijk", chars_format::general, 0x1234abcdef,
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-8);
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ExpectNumber<16>("1234abcd.ef$p", chars_format::general, 0x1234abcdef, -8);
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ExpectNumber<16>("1234abcd.ef$.10", chars_format::general, 0x1234abcdef, -8);
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// Ensure we can read a full resolution mantissa without overflow.
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ExpectNumber<10>("9999999999999999999$", chars_format::general,
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9999999999999999999u, 0);
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ExpectNumber<16>("fffffffffffffff$", chars_format::general,
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0xfffffffffffffffu, 0);
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// Check that zero is consistently read.
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ExpectNumber<10>("0$", chars_format::general, 0, 0);
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ExpectNumber<16>("0$", chars_format::general, 0, 0);
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ExpectNumber<10>("000000000000000000000000000000000000000$",
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chars_format::general, 0, 0);
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ExpectNumber<16>("000000000000000000000000000000000000000$",
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chars_format::general, 0, 0);
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ExpectNumber<10>("0000000000000000000000.000000000000000000$",
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chars_format::general, 0, 0);
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ExpectNumber<16>("0000000000000000000000.000000000000000000$",
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chars_format::general, 0, 0);
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ExpectNumber<10>("0.00000000000000000000000000000000e123456$",
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chars_format::general, 0, 0);
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ExpectNumber<16>("0.00000000000000000000000000000000p123456$",
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chars_format::general, 0, 0);
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}
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TEST(ParseFloat, LargeDecimalMantissa) {
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// After 19 significant decimal digits in the mantissa, ParsedFloat will
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// truncate additional digits. We need to test that:
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// 1) the truncation to 19 digits happens
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// 2) the returned exponent reflects the dropped significant digits
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// 3) a correct literal_exponent is set
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//
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// If and only if a significant digit is found after 19 digits, then the
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// entirety of the mantissa in case the exact value is needed to make a
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// rounding decision. The [ and ] characters below denote where such a
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// subregion was marked by by ParseFloat. They are not part of the input.
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// Mark a capture group only if a dropped digit is significant (nonzero).
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ExpectNumber<10>("100000000000000000000000000$", chars_format::general,
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1000000000000000000,
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/* adjusted exponent */ 8);
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ExpectNumber<10>("123456789123456789100000000$", chars_format::general,
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1234567891234567891,
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/* adjusted exponent */ 8);
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ExpectNumber<10>("[123456789123456789123456789]$", chars_format::general,
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1234567891234567891,
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/* adjusted exponent */ 8,
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/* literal exponent */ 0);
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ExpectNumber<10>("[123456789123456789100000009]$", chars_format::general,
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1234567891234567891,
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/* adjusted exponent */ 8,
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/* literal exponent */ 0);
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ExpectNumber<10>("[123456789123456789120000000]$", chars_format::general,
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1234567891234567891,
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/* adjusted exponent */ 8,
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/* literal exponent */ 0);
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// Leading zeroes should not count towards the 19 significant digit limit
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ExpectNumber<10>("[00000000123456789123456789123456789]$",
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chars_format::general, 1234567891234567891,
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/* adjusted exponent */ 8,
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/* literal exponent */ 0);
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ExpectNumber<10>("00000000123456789123456789100000000$",
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chars_format::general, 1234567891234567891,
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/* adjusted exponent */ 8);
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// Truncated digits after the decimal point should not cause a further
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// exponent adjustment.
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ExpectNumber<10>("1.234567891234567891e123$", chars_format::general,
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1234567891234567891, 105);
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ExpectNumber<10>("[1.23456789123456789123456789]e123$", chars_format::general,
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1234567891234567891,
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/* adjusted exponent */ 105,
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/* literal exponent */ 123);
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// Ensure we truncate, and not round. (The from_chars algorithm we use
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// depends on our guess missing low, if it misses, so we need the rounding
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// error to be downward.)
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ExpectNumber<10>("[1999999999999999999999]$", chars_format::general,
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1999999999999999999,
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/* adjusted exponent */ 3,
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/* literal exponent */ 0);
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}
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TEST(ParseFloat, LargeHexadecimalMantissa) {
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// After 15 significant hex digits in the mantissa, ParsedFloat will treat
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// additional digits as sticky, We need to test that:
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// 1) The truncation to 15 digits happens
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// 2) The returned exponent reflects the dropped significant digits
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// 3) If a nonzero digit is dropped, the low bit of mantissa is set.
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ExpectNumber<16>("123456789abcdef123456789abcdef$", chars_format::general,
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0x123456789abcdef, 60);
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// Leading zeroes should not count towards the 15 significant digit limit
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ExpectNumber<16>("000000123456789abcdef123456789abcdef$",
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chars_format::general, 0x123456789abcdef, 60);
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// Truncated digits after the radix point should not cause a further
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// exponent adjustment.
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ExpectNumber<16>("1.23456789abcdefp100$", chars_format::general,
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0x123456789abcdef, 44);
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ExpectNumber<16>("1.23456789abcdef123456789abcdefp100$",
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chars_format::general, 0x123456789abcdef, 44);
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// test sticky digit behavior. The low bit should be set iff any dropped
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// digit is nonzero.
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ExpectNumber<16>("123456789abcdee123456789abcdee$", chars_format::general,
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0x123456789abcdef, 60);
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ExpectNumber<16>("123456789abcdee000000000000001$", chars_format::general,
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0x123456789abcdef, 60);
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ExpectNumber<16>("123456789abcdee000000000000000$", chars_format::general,
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0x123456789abcdee, 60);
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}
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TEST(ParseFloat, ScientificVsFixed) {
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// In fixed mode, an exponent is never matched (but the remainder of the
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// number will be matched.)
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ExpectNumber<10>("1.23456789$e5", chars_format::fixed, 123456789, -8);
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ExpectNumber<10>("123456.789$", chars_format::fixed, 123456789, -3);
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ExpectNumber<16>("1.234abcdef$p28", chars_format::fixed, 0x1234abcdef, -36);
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ExpectNumber<16>("1234abcd.ef$", chars_format::fixed, 0x1234abcdef, -8);
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// In scientific mode, numbers don't match *unless* they have an exponent.
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ExpectNumber<10>("1.23456789e5$", chars_format::scientific, 123456789, -3);
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ExpectFailedParse<10>("-123456.789$", chars_format::scientific);
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|
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ExpectNumber<16>("1.234abcdefp28$", chars_format::scientific, 0x1234abcdef,
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|
-8);
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|
|
ExpectFailedParse<16>("1234abcd.ef$", chars_format::scientific);
|
|
|
|
}
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|
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|
|
|
|
TEST(ParseFloat, Infinity) {
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|
|
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ExpectFailedParse<10>("in", chars_format::general);
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|
|
|
ExpectFailedParse<16>("in", chars_format::general);
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|
|
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ExpectFailedParse<10>("inx", chars_format::general);
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ExpectFailedParse<16>("inx", chars_format::general);
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|
|
|
ExpectSpecial("inf$", chars_format::general, FloatType::kInfinity);
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ExpectSpecial("Inf$", chars_format::general, FloatType::kInfinity);
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|
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ExpectSpecial("INF$", chars_format::general, FloatType::kInfinity);
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|
ExpectSpecial("inf$inite", chars_format::general, FloatType::kInfinity);
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|
|
ExpectSpecial("iNfInItY$", chars_format::general, FloatType::kInfinity);
|
|
|
|
ExpectSpecial("infinity$!!!", chars_format::general, FloatType::kInfinity);
|
|
|
|
}
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|
|
|
|
|
|
|
TEST(ParseFloat, NaN) {
|
|
|
|
ExpectFailedParse<10>("na", chars_format::general);
|
|
|
|
ExpectFailedParse<16>("na", chars_format::general);
|
|
|
|
ExpectFailedParse<10>("nah", chars_format::general);
|
|
|
|
ExpectFailedParse<16>("nah", chars_format::general);
|
|
|
|
ExpectSpecial("nan$", chars_format::general, FloatType::kNan);
|
|
|
|
ExpectSpecial("NaN$", chars_format::general, FloatType::kNan);
|
|
|
|
ExpectSpecial("nAn$", chars_format::general, FloatType::kNan);
|
|
|
|
ExpectSpecial("NAN$", chars_format::general, FloatType::kNan);
|
|
|
|
ExpectSpecial("NaN$aNaNaNaNaBatman!", chars_format::general, FloatType::kNan);
|
|
|
|
|
|
|
|
// A parenthesized sequence of the characters [a-zA-Z0-9_] is allowed to
|
|
|
|
// appear after an NaN. Check that this is allowed, and that the correct
|
|
|
|
// characters are grouped.
|
|
|
|
//
|
|
|
|
// (The characters [ and ] in the pattern below delimit the expected matched
|
|
|
|
// subgroup; they are not part of the input passed to ParseFloat.)
|
|
|
|
ExpectSpecial("nan([0xabcdef])$", chars_format::general, FloatType::kNan);
|
|
|
|
ExpectSpecial("nan([0xabcdef])$...", chars_format::general, FloatType::kNan);
|
|
|
|
ExpectSpecial("nan([0xabcdef])$)...", chars_format::general, FloatType::kNan);
|
|
|
|
ExpectSpecial("nan([])$", chars_format::general, FloatType::kNan);
|
|
|
|
ExpectSpecial("nan([aAzZ09_])$", chars_format::general, FloatType::kNan);
|
|
|
|
// If the subgroup contains illegal characters, don't match it at all.
|
|
|
|
ExpectSpecial("nan$(bad-char)", chars_format::general, FloatType::kNan);
|
|
|
|
// Also cope with a missing close paren.
|
|
|
|
ExpectSpecial("nan$(0xabcdef", chars_format::general, FloatType::kNan);
|
|
|
|
}
|
|
|
|
|
|
|
|
} // namespace
|