net/base/parse_number_unittest.cc - platform/external/cronet - Git at Google

 // Copyright 2016 The Chromium Authors
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "net/base/parse_number.h"

 #include <limits>
 #include <sstream>

 #include "base/strings/string_number_conversions.h"
 #include "testing/gtest/include/gtest/gtest.h"

 namespace net {
 namespace {

 // Returns a decimal string that is one larger than the maximum value that type
 // T can represent.
 template <typename T>
 std::string CreateOverflowString() {
   const T value = std::numeric_limits<T>::max();
   std::string result = base::NumberToString(value);
   EXPECT_NE('9', result.back());
   result.back()++;
   return result;
 }

 // Returns a decimal string that is one less than the minimum value that
 // (signed) type T can represent.
 template <typename T>
 std::string CreateUnderflowString() {
   EXPECT_TRUE(std::numeric_limits<T>::is_signed);
   const T value = std::numeric_limits<T>::min();
   std::string result = base::NumberToString(value);
   EXPECT_EQ('-', result.front());
   EXPECT_NE('9', result.back());
   result.back()++;
   return result;
 }

 // These are potentially valid inputs, along with whether they're non-negative
 // or "strict" (minimal representations).
 const struct {
   const char* input;
   int expected_output;
   bool is_non_negative;
   bool is_strict;
 } kAnnotatedTests[] = {
     {"0", 0, /*is_non_negative=*/true, /*is_strict=*/true},
     {"10", 10, /*is_non_negative=*/true, /*is_strict=*/true},
     {"1234566", 1234566, /*is_non_negative=*/true, /*is_strict=*/true},
     {"00", 0, /*is_non_negative=*/true, /*is_strict=*/false},
     {"010", 10, /*is_non_negative=*/true, /*is_strict=*/false},
     {"0010", 10, /*is_non_negative=*/true, /*is_strict=*/false},
     {"-10", -10, /*is_non_negative=*/false, /*is_strict=*/true},
     {"-1234566", -1234566, /*is_non_negative=*/false, /*is_strict=*/true},
     {"-0", 0, /*is_non_negative=*/false, /*is_strict=*/false},
     {"-00", 0, /*is_non_negative=*/false, /*is_strict=*/false},
     {"-010", -10, /*is_non_negative=*/false, /*is_strict=*/false},
     {"-0000000000000000000000000000000000001234566", -1234566,
      /*is_non_negative=*/false, /*is_strict=*/false},
 };

 // These are invalid inputs that can not be parsed regardless of the format
 // used (they are neither valid negative or non-negative values).
 const char* kInvalidParseTests[] = {
     "",       "-",      "--",    "23-",  "134-34", "- ",   "    ",  "+42",
     " 123",   "123 ",   "123\n", "0xFF", "-0xFF",  "0x11", "-0x11", "x11",
     "-x11",   "F11",    "-F11",  "AF",   "-AF",    "0AF",  "0.0",   "13.",
     "13,000", "13.000", "13/5",  "Inf",  "NaN",    "null", "dog",
 };

 // This wrapper calls func() and expects the result to match |expected_output|.
 template <typename OutputType, typename ParseFunc, typename ExpectationType>
 void ExpectParseIntSuccess(ParseFunc func,
                            base::StringPiece input,
                            ParseIntFormat format,
                            ExpectationType expected_output) {
   // Try parsing without specifying an error output - expecting success.
   OutputType parsed_number1;
   EXPECT_TRUE(func(input, format, &parsed_number1, nullptr))
       << "Failed to parse: " << input;
   EXPECT_EQ(static_cast<OutputType>(expected_output), parsed_number1);

   // Try parsing with an error output - expecting success.
   ParseIntError kBogusError = static_cast<ParseIntError>(19);
   ParseIntError error = kBogusError;
   OutputType parsed_number2;
   EXPECT_TRUE(func(input, format, &parsed_number2, &error))
       << "Failed to parse: " << input;
   EXPECT_EQ(static_cast<OutputType>(expected_output), parsed_number2);
   // Check that the error output was not written to.
   EXPECT_EQ(kBogusError, error);
 }

 // This wrapper calls func() and expects the failure to match |expected_error|.
 template <typename OutputType, typename ParseFunc>
 void ExpectParseIntFailure(ParseFunc func,
                            base::StringPiece input,
                            ParseIntFormat format,
                            ParseIntError expected_error) {
   const OutputType kBogusOutput(23614);

   // Try parsing without specifying an error output - expecting failure.
   OutputType parsed_number1 = kBogusOutput;
   EXPECT_FALSE(func(input, format, &parsed_number1, nullptr))
       << "Succeded parsing: " << input;
   EXPECT_EQ(kBogusOutput, parsed_number1)
       << "Modified output when failed parsing";

   // Try parsing with an error output - expecting failure.
   OutputType parsed_number2 = kBogusOutput;
   ParseIntError error;
   EXPECT_FALSE(func(input, format, &parsed_number2, &error))
       << "Succeded parsing: " << input;
   EXPECT_EQ(kBogusOutput, parsed_number2)
       << "Modified output when failed parsing";
   EXPECT_EQ(expected_error, error);
 }

 // Common tests for both ParseInt*() and ParseUint*()
 //
 // When testing ParseUint*() the |format| parameter is not applicable and
 // should be passed as NON_NEGATIVE.
 template <typename T, typename ParseFunc>
 void TestParseIntUsingFormat(ParseFunc func, ParseIntFormat format) {
   bool is_format_non_negative = format == ParseIntFormat::NON_NEGATIVE ||
                                 format == ParseIntFormat::STRICT_NON_NEGATIVE;
   bool is_format_strict = format == ParseIntFormat::STRICT_NON_NEGATIVE ||
                           format == ParseIntFormat::STRICT_OPTIONALLY_NEGATIVE;
   // Test annotated inputs, some of which may not be valid inputs when parsed
   // using `format`.
   for (const auto& test : kAnnotatedTests) {
     SCOPED_TRACE(test.input);
     if ((test.is_non_negative || !is_format_non_negative) &&
         (test.is_strict || !is_format_strict)) {
       ExpectParseIntSuccess<T>(func, test.input, format, test.expected_output);
     } else {
       ExpectParseIntFailure<T>(func, test.input, format,
                                ParseIntError::FAILED_PARSE);
     }
   }

   // Test invalid inputs (invalid regardless of parsing format)
   for (auto* input : kInvalidParseTests) {
     ExpectParseIntFailure<T>(func, input, format, ParseIntError::FAILED_PARSE);
   }

   // Test parsing the largest possible value for output type.
   {
     const T value = std::numeric_limits<T>::max();
     ExpectParseIntSuccess<T>(func, base::NumberToString(value), format, value);
   }

   // Test parsing a number one larger than the output type can accomodate
   // (overflow).
   ExpectParseIntFailure<T>(func, CreateOverflowString<T>(), format,
                            ParseIntError::FAILED_OVERFLOW);

   // Test parsing a number at least as large as the output allows AND contains
   // garbage at the end. This exercises an interesting internal quirk of
   // base::StringToInt*(), in that its result cannot distinguish this case
   // from overflow.
   ExpectParseIntFailure<T>(
       func, base::NumberToString(std::numeric_limits<T>::max()) + " ", format,
       ParseIntError::FAILED_PARSE);

   ExpectParseIntFailure<T>(func, CreateOverflowString<T>() + " ", format,
                            ParseIntError::FAILED_PARSE);

   // Test parsing the smallest possible value for output type. Don't do the
   // test for unsigned types since the smallest number 0 is tested elsewhere.
   if (std::numeric_limits<T>::is_signed) {
     const T value = std::numeric_limits<T>::min();
     std::string str_value = base::NumberToString(value);

     // The minimal value is necessarily negative, since this function is
     // testing only signed output types.
     if (is_format_non_negative) {
       ExpectParseIntFailure<T>(func, str_value, format,
                                ParseIntError::FAILED_PARSE);
     } else {
       ExpectParseIntSuccess<T>(func, str_value, format, value);
     }
   }

   // Test parsing a number one less than the output type can accomodate
   // (underflow).
   if (!is_format_non_negative) {
     ExpectParseIntFailure<T>(func, CreateUnderflowString<T>(), format,
                              ParseIntError::FAILED_UNDERFLOW);
   }

   // Test parsing a string that contains a valid number followed by a NUL
   // character.
   ExpectParseIntFailure<T>(func, base::StringPiece("123\0", 4), format,
                            ParseIntError::FAILED_PARSE);
 }

 // Common tests to run for each of the versions of ParseInt*().
 //
 // The `func` parameter should be a function pointer to the particular
 // ParseInt*() function to test.
 template <typename T, typename ParseFunc>
 void TestParseInt(ParseFunc func) {
   // Test using each of the possible formats.
   ParseIntFormat kFormats[] = {ParseIntFormat::NON_NEGATIVE,
                                ParseIntFormat::OPTIONALLY_NEGATIVE,
                                ParseIntFormat::STRICT_NON_NEGATIVE,
                                ParseIntFormat::STRICT_OPTIONALLY_NEGATIVE};

   for (const auto& format : kFormats) {
     TestParseIntUsingFormat<T>(func, format);
   }
 }

 // Common tests to run for each of the versions of ParseUint*().
 //
 // The `func` parameter should be a function pointer to the particular
 // ParseUint*() function to test.
 template <typename T, typename ParseFunc>
 void TestParseUint(ParseFunc func) {
   // Test using each of the possible formats.
   ParseIntFormat kFormats[] = {
       ParseIntFormat::NON_NEGATIVE,
       ParseIntFormat::STRICT_NON_NEGATIVE,
   };

   for (const auto& format : kFormats) {
     TestParseIntUsingFormat<T>(func, format);
   }
 }

 TEST(ParseNumberTest, ParseInt32) {
   TestParseInt<int32_t>(ParseInt32);
 }

 TEST(ParseNumberTest, ParseInt64) {
   TestParseInt<int64_t>(ParseInt64);
 }

 TEST(ParseNumberTest, ParseUint32) {
   TestParseUint<uint32_t>(ParseUint32);
 }

 TEST(ParseNumberTest, ParseUint64) {
   TestParseUint<uint64_t>(ParseUint64);
 }

 }  // namespace
 }  // namespace net
	// Copyright 2016 The Chromium Authors
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "net/base/parse_number.h"

	#include <limits>
	#include <sstream>

	#include "base/strings/string_number_conversions.h"
	#include "testing/gtest/include/gtest/gtest.h"

	namespace net {
	namespace {

	// Returns a decimal string that is one larger than the maximum value that type
	// T can represent.
	template <typename T>
	std::string CreateOverflowString() {
	const T value = std::numeric_limits<T>::max();
	std::string result = base::NumberToString(value);
	EXPECT_NE('9', result.back());
	result.back()++;
	return result;
	}

	// Returns a decimal string that is one less than the minimum value that
	// (signed) type T can represent.
	template <typename T>
	std::string CreateUnderflowString() {
	EXPECT_TRUE(std::numeric_limits<T>::is_signed);
	const T value = std::numeric_limits<T>::min();
	std::string result = base::NumberToString(value);
	EXPECT_EQ('-', result.front());
	EXPECT_NE('9', result.back());
	result.back()++;
	return result;
	}

	// These are potentially valid inputs, along with whether they're non-negative
	// or "strict" (minimal representations).
	const struct {
	const char* input;
	int expected_output;
	bool is_non_negative;
	bool is_strict;
	} kAnnotatedTests[] = {
	{"0", 0, /is_non_negative=/true, /is_strict=/true},
	{"10", 10, /is_non_negative=/true, /is_strict=/true},
	{"1234566", 1234566, /is_non_negative=/true, /is_strict=/true},
	{"00", 0, /is_non_negative=/true, /is_strict=/false},
	{"010", 10, /is_non_negative=/true, /is_strict=/false},
	{"0010", 10, /is_non_negative=/true, /is_strict=/false},
	{"-10", -10, /is_non_negative=/false, /is_strict=/true},
	{"-1234566", -1234566, /is_non_negative=/false, /is_strict=/true},
	{"-0", 0, /is_non_negative=/false, /is_strict=/false},
	{"-00", 0, /is_non_negative=/false, /is_strict=/false},
	{"-010", -10, /is_non_negative=/false, /is_strict=/false},
	{"-0000000000000000000000000000000000001234566", -1234566,
	/is_non_negative=/false, /is_strict=/false},
	};

	// These are invalid inputs that can not be parsed regardless of the format
	// used (they are neither valid negative or non-negative values).
	const char* kInvalidParseTests[] = {
	"", "-", "--", "23-", "134-34", "- ", " ", "+42",
	" 123", "123 ", "123\n", "0xFF", "-0xFF", "0x11", "-0x11", "x11",
	"-x11", "F11", "-F11", "AF", "-AF", "0AF", "0.0", "13.",
	"13,000", "13.000", "13/5", "Inf", "NaN", "null", "dog",
	};

	// This wrapper calls func() and expects the result to match \|expected_output\|.
	template <typename OutputType, typename ParseFunc, typename ExpectationType>
	void ExpectParseIntSuccess(ParseFunc func,
	base::StringPiece input,
	ParseIntFormat format,
	ExpectationType expected_output) {
	// Try parsing without specifying an error output - expecting success.
	OutputType parsed_number1;
	EXPECT_TRUE(func(input, format, &parsed_number1, nullptr))
	<< "Failed to parse: " << input;
	EXPECT_EQ(static_cast<OutputType>(expected_output), parsed_number1);

	// Try parsing with an error output - expecting success.
	ParseIntError kBogusError = static_cast<ParseIntError>(19);
	ParseIntError error = kBogusError;
	OutputType parsed_number2;
	EXPECT_TRUE(func(input, format, &parsed_number2, &error))
	<< "Failed to parse: " << input;
	EXPECT_EQ(static_cast<OutputType>(expected_output), parsed_number2);
	// Check that the error output was not written to.
	EXPECT_EQ(kBogusError, error);
	}

	// This wrapper calls func() and expects the failure to match \|expected_error\|.
	template <typename OutputType, typename ParseFunc>
	void ExpectParseIntFailure(ParseFunc func,
	base::StringPiece input,
	ParseIntFormat format,
	ParseIntError expected_error) {
	const OutputType kBogusOutput(23614);

	// Try parsing without specifying an error output - expecting failure.
	OutputType parsed_number1 = kBogusOutput;
	EXPECT_FALSE(func(input, format, &parsed_number1, nullptr))
	<< "Succeded parsing: " << input;
	EXPECT_EQ(kBogusOutput, parsed_number1)
	<< "Modified output when failed parsing";

	// Try parsing with an error output - expecting failure.
	OutputType parsed_number2 = kBogusOutput;
	ParseIntError error;
	EXPECT_FALSE(func(input, format, &parsed_number2, &error))
	<< "Succeded parsing: " << input;
	EXPECT_EQ(kBogusOutput, parsed_number2)
	<< "Modified output when failed parsing";
	EXPECT_EQ(expected_error, error);
	}

	// Common tests for both ParseInt() and ParseUint()
	//
	// When testing ParseUint*() the \|format\| parameter is not applicable and
	// should be passed as NON_NEGATIVE.
	template <typename T, typename ParseFunc>
	void TestParseIntUsingFormat(ParseFunc func, ParseIntFormat format) {
	bool is_format_non_negative = format == ParseIntFormat::NON_NEGATIVE \|\|
	format == ParseIntFormat::STRICT_NON_NEGATIVE;
	bool is_format_strict = format == ParseIntFormat::STRICT_NON_NEGATIVE \|\|
	format == ParseIntFormat::STRICT_OPTIONALLY_NEGATIVE;
	// Test annotated inputs, some of which may not be valid inputs when parsed
	// using `format`.
	for (const auto& test : kAnnotatedTests) {
	SCOPED_TRACE(test.input);
	if ((test.is_non_negative \|\| !is_format_non_negative) &&
	(test.is_strict \|\| !is_format_strict)) {
	ExpectParseIntSuccess<T>(func, test.input, format, test.expected_output);
	} else {
	ExpectParseIntFailure<T>(func, test.input, format,
	ParseIntError::FAILED_PARSE);
	}
	}

	// Test invalid inputs (invalid regardless of parsing format)
	for (auto* input : kInvalidParseTests) {
	ExpectParseIntFailure<T>(func, input, format, ParseIntError::FAILED_PARSE);
	}

	// Test parsing the largest possible value for output type.
	{
	const T value = std::numeric_limits<T>::max();
	ExpectParseIntSuccess<T>(func, base::NumberToString(value), format, value);
	}

	// Test parsing a number one larger than the output type can accomodate
	// (overflow).
	ExpectParseIntFailure<T>(func, CreateOverflowString<T>(), format,
	ParseIntError::FAILED_OVERFLOW);

	// Test parsing a number at least as large as the output allows AND contains
	// garbage at the end. This exercises an interesting internal quirk of
	// base::StringToInt*(), in that its result cannot distinguish this case
	// from overflow.
	ExpectParseIntFailure<T>(
	func, base::NumberToString(std::numeric_limits<T>::max()) + " ", format,
	ParseIntError::FAILED_PARSE);

	ExpectParseIntFailure<T>(func, CreateOverflowString<T>() + " ", format,
	ParseIntError::FAILED_PARSE);

	// Test parsing the smallest possible value for output type. Don't do the
	// test for unsigned types since the smallest number 0 is tested elsewhere.
	if (std::numeric_limits<T>::is_signed) {
	const T value = std::numeric_limits<T>::min();
	std::string str_value = base::NumberToString(value);

	// The minimal value is necessarily negative, since this function is
	// testing only signed output types.
	if (is_format_non_negative) {
	ExpectParseIntFailure<T>(func, str_value, format,
	ParseIntError::FAILED_PARSE);
	} else {
	ExpectParseIntSuccess<T>(func, str_value, format, value);
	}
	}

	// Test parsing a number one less than the output type can accomodate
	// (underflow).
	if (!is_format_non_negative) {
	ExpectParseIntFailure<T>(func, CreateUnderflowString<T>(), format,
	ParseIntError::FAILED_UNDERFLOW);
	}

	// Test parsing a string that contains a valid number followed by a NUL
	// character.
	ExpectParseIntFailure<T>(func, base::StringPiece("123\0", 4), format,
	ParseIntError::FAILED_PARSE);
	}

	// Common tests to run for each of the versions of ParseInt*().
	//
	// The `func` parameter should be a function pointer to the particular
	// ParseInt*() function to test.
	template <typename T, typename ParseFunc>
	void TestParseInt(ParseFunc func) {
	// Test using each of the possible formats.
	ParseIntFormat kFormats[] = {ParseIntFormat::NON_NEGATIVE,
	ParseIntFormat::OPTIONALLY_NEGATIVE,
	ParseIntFormat::STRICT_NON_NEGATIVE,
	ParseIntFormat::STRICT_OPTIONALLY_NEGATIVE};

	for (const auto& format : kFormats) {
	TestParseIntUsingFormat<T>(func, format);
	}
	}

	// Common tests to run for each of the versions of ParseUint*().
	//
	// The `func` parameter should be a function pointer to the particular
	// ParseUint*() function to test.
	template <typename T, typename ParseFunc>
	void TestParseUint(ParseFunc func) {
	// Test using each of the possible formats.
	ParseIntFormat kFormats[] = {
	ParseIntFormat::NON_NEGATIVE,
	ParseIntFormat::STRICT_NON_NEGATIVE,
	};

	for (const auto& format : kFormats) {
	TestParseIntUsingFormat<T>(func, format);
	}
	}

	TEST(ParseNumberTest, ParseInt32) {
	TestParseInt<int32_t>(ParseInt32);
	}

	TEST(ParseNumberTest, ParseInt64) {
	TestParseInt<int64_t>(ParseInt64);
	}

	TEST(ParseNumberTest, ParseUint32) {
	TestParseUint<uint32_t>(ParseUint32);
	}

	TEST(ParseNumberTest, ParseUint64) {
	TestParseUint<uint64_t>(ParseUint64);
	}

	} // namespace
	} // namespace net