base/strings/string_number_conversions_internal.h - googleurl - Git at Google

 // Copyright 2020 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef BASE_STRINGS_STRING_NUMBER_CONVERSIONS_INTERNAL_H_
 #define BASE_STRINGS_STRING_NUMBER_CONVERSIONS_INTERNAL_H_

 #include <ctype.h>
 #include <errno.h>
 #include <stdlib.h>
 #include <wctype.h>

 #include <limits>

 #include "polyfills/base/check_op.h"
 #include "polyfills/base/logging.h"
 #include "base/no_destructor.h"
 #include "base/numerics/safe_math.h"
 #include "base/strings/string_util.h"
 #include "base/third_party/double_conversion/double-conversion/double-conversion.h"

 namespace gurl_base {

 namespace internal {

 template <typename STR, typename INT>
 static STR IntToStringT(INT value) {
   // log10(2) ~= 0.3 bytes needed per bit or per byte log10(2**8) ~= 2.4.
   // So round up to allocate 3 output characters per byte, plus 1 for '-'.
   const size_t kOutputBufSize =
       3 * sizeof(INT) + std::numeric_limits<INT>::is_signed;

   // Create the string in a temporary buffer, write it back to front, and
   // then return the substr of what we ended up using.
   using CHR = typename STR::value_type;
   CHR outbuf[kOutputBufSize];

   // The ValueOrDie call below can never fail, because UnsignedAbs is valid
   // for all valid inputs.
   std::make_unsigned_t<INT> res =
       CheckedNumeric<INT>(value).UnsignedAbs().ValueOrDie();

   CHR* end = outbuf + kOutputBufSize;
   CHR* i = end;
   do {
     --i;
     GURL_DCHECK(i != outbuf);
     *i = static_cast<CHR>((res % 10) + '0');
     res /= 10;
   } while (res != 0);
   if (IsValueNegative(value)) {
     --i;
     GURL_DCHECK(i != outbuf);
     *i = static_cast<CHR>('-');
   }
   return STR(i, end);
 }

 // Utility to convert a character to a digit in a given base
 template <int BASE, typename CHAR>
 Optional<uint8_t> CharToDigit(CHAR c) {
   static_assert(1 <= BASE && BASE <= 36, "BASE needs to be in [1, 36]");
   if (c >= '0' && c < '0' + std::min(BASE, 10))
     return c - '0';

   if (c >= 'a' && c < 'a' + BASE - 10)
     return c - 'a' + 10;

   if (c >= 'A' && c < 'A' + BASE - 10)
     return c - 'A' + 10;

   return gurl_base::nullopt;
 }

 // There is an IsUnicodeWhitespace for wchars defined in string_util.h, but it
 // is locale independent, whereas the functions we are replacing were
 // locale-dependent. TBD what is desired, but for the moment let's not
 // introduce a change in behaviour.
 template <typename CHAR>
 class WhitespaceHelper {};

 template <>
 class WhitespaceHelper<char> {
  public:
   static bool Invoke(char c) {
     return 0 != isspace(static_cast<unsigned char>(c));
   }
 };

 template <>
 class WhitespaceHelper<char16> {
  public:
   static bool Invoke(char16 c) { return 0 != iswspace(c); }
 };

 template <typename CHAR>
 bool LocalIsWhitespace(CHAR c) {
   return WhitespaceHelper<CHAR>::Invoke(c);
 }

 template <typename Number, int kBase>
 class StringToNumberParser {
  public:
   struct Result {
     Number value = 0;
     bool valid = false;
   };

   static constexpr Number kMin = std::numeric_limits<Number>::min();
   static constexpr Number kMax = std::numeric_limits<Number>::max();

   // Sign provides:
   //  - a static function, CheckBounds, that determines whether the next digit
   //    causes an overflow/underflow
   //  - a static function, Increment, that appends the next digit appropriately
   //    according to the sign of the number being parsed.
   template <typename Sign>
   class Base {
    public:
     template <typename Iter>
     static Result Invoke(Iter begin, Iter end) {
       Number value = 0;

       if (begin == end) {
         return {value, false};
       }

       // Note: no performance difference was found when using template
       // specialization to remove this check in bases other than 16
       if (kBase == 16 && end - begin > 2 && *begin == '0' &&
           (*(begin + 1) == 'x' || *(begin + 1) == 'X')) {
         begin += 2;
       }

       for (Iter current = begin; current != end; ++current) {
         Optional<uint8_t> new_digit = CharToDigit<kBase>(*current);

         if (!new_digit) {
           return {value, false};
         }

         if (current != begin) {
           Result result = Sign::CheckBounds(value, *new_digit);
           if (!result.valid)
             return result;

           value *= kBase;
         }

         value = Sign::Increment(value, *new_digit);
       }
       return {value, true};
     }
   };

   class Positive : public Base<Positive> {
    public:
     static Result CheckBounds(Number value, uint8_t new_digit) {
       if (value > static_cast<Number>(kMax / kBase) ||
           (value == static_cast<Number>(kMax / kBase) &&
            new_digit > kMax % kBase)) {
         return {kMax, false};
       }
       return {value, true};
     }
     static Number Increment(Number lhs, uint8_t rhs) { return lhs + rhs; }
   };

   class Negative : public Base<Negative> {
    public:
     static Result CheckBounds(Number value, uint8_t new_digit) {
       if (value < kMin / kBase ||
           (value == kMin / kBase && new_digit > 0 - kMin % kBase)) {
         return {kMin, false};
       }
       return {value, true};
     }
     static Number Increment(Number lhs, uint8_t rhs) { return lhs - rhs; }
   };
 };

 template <typename Number, int kBase, typename Str>
 auto StringToNumber(BasicStringPiece<Str> input) {
   using Parser = StringToNumberParser<Number, kBase>;
   using Result = typename Parser::Result;

   bool has_leading_whitespace = false;
   auto begin = input.begin();
   auto end = input.end();

   while (begin != end && LocalIsWhitespace(*begin)) {
     has_leading_whitespace = true;
     ++begin;
   }

   if (begin != end && *begin == '-') {
     if (!std::numeric_limits<Number>::is_signed) {
       return Result{0, false};
     }

     Result result = Parser::Negative::Invoke(begin + 1, end);
     result.valid &= !has_leading_whitespace;
     return result;
   }

   if (begin != end && *begin == '+') {
     ++begin;
   }

   Result result = Parser::Positive::Invoke(begin, end);
   result.valid &= !has_leading_whitespace;
   return result;
 }

 template <typename STR, typename VALUE>
 bool StringToIntImpl(BasicStringPiece<STR> input, VALUE& output) {
   auto result = StringToNumber<VALUE, 10>(input);
   output = result.value;
   return result.valid;
 }

 template <typename STR, typename VALUE>
 bool HexStringToIntImpl(BasicStringPiece<STR> input, VALUE& output) {
   auto result = StringToNumber<VALUE, 16>(input);
   output = result.value;
   return result.valid;
 }

 static const double_conversion::DoubleToStringConverter*
 GetDoubleToStringConverter() {
   static NoDestructor<double_conversion::DoubleToStringConverter> converter(
       double_conversion::DoubleToStringConverter::EMIT_POSITIVE_EXPONENT_SIGN,
       nullptr, nullptr, 'e', -6, 12, 0, 0);
   return converter.get();
 }

 // Converts a given (data, size) pair to a desired string type. For
 // performance reasons, this dispatches to a different constructor if the
 // passed-in data matches the string's value_type.
 template <typename StringT>
 StringT ToString(const typename StringT::value_type* data, size_t size) {
   return StringT(data, size);
 }

 template <typename StringT, typename CharT>
 StringT ToString(const CharT* data, size_t size) {
   return StringT(data, data + size);
 }

 template <typename StringT>
 StringT DoubleToStringT(double value) {
   char buffer[32];
   double_conversion::StringBuilder builder(buffer, sizeof(buffer));
   GetDoubleToStringConverter()->ToShortest(value, &builder);
   return ToString<StringT>(buffer, builder.position());
 }

 template <typename STRING, typename CHAR>
 bool StringToDoubleImpl(STRING input, const CHAR* data, double& output) {
   static NoDestructor<double_conversion::StringToDoubleConverter> converter(
       double_conversion::StringToDoubleConverter::ALLOW_LEADING_SPACES |
           double_conversion::StringToDoubleConverter::ALLOW_TRAILING_JUNK,
       0.0, 0, nullptr, nullptr);

   int processed_characters_count;
   output = converter->StringToDouble(data, input.size(),
                                      &processed_characters_count);

   // Cases to return false:
   //  - If the input string is empty, there was nothing to parse.
   //  - If the value saturated to HUGE_VAL.
   //  - If the entire string was not processed, there are either characters
   //    remaining in the string after a parsed number, or the string does not
   //    begin with a parseable number.
   //  - If the first character is a space, there was leading whitespace
   return !input.empty() && output != HUGE_VAL && output != -HUGE_VAL &&
          static_cast<size_t>(processed_characters_count) == input.size() &&
          !IsUnicodeWhitespace(input[0]);
 }

 template <typename OutIter>
 static bool HexStringToByteContainer(StringPiece input, OutIter output) {
   size_t count = input.size();
   if (count == 0 || (count % 2) != 0)
     return false;
   for (uintptr_t i = 0; i < count / 2; ++i) {
     // most significant 4 bits
     Optional<uint8_t> msb = CharToDigit<16>(input[i * 2]);
     // least significant 4 bits
     Optional<uint8_t> lsb = CharToDigit<16>(input[i * 2 + 1]);
     if (!msb || !lsb) {
       return false;
     }
     *(output++) = (*msb << 4) | *lsb;
   }
   return true;
 }

 }  // namespace internal

 }  // namespace base

 #endif  // BASE_STRINGS_STRING_NUMBER_CONVERSIONS_INTERNAL_H_
	// Copyright 2020 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef BASE_STRINGS_STRING_NUMBER_CONVERSIONS_INTERNAL_H_
	#define BASE_STRINGS_STRING_NUMBER_CONVERSIONS_INTERNAL_H_

	#include <ctype.h>
	#include <errno.h>
	#include <stdlib.h>
	#include <wctype.h>

	#include <limits>

	#include "polyfills/base/check_op.h"
	#include "polyfills/base/logging.h"
	#include "base/no_destructor.h"
	#include "base/numerics/safe_math.h"
	#include "base/strings/string_util.h"
	#include "base/third_party/double_conversion/double-conversion/double-conversion.h"

	namespace gurl_base {

	namespace internal {

	template <typename STR, typename INT>
	static STR IntToStringT(INT value) {
	// log10(2) ~= 0.3 bytes needed per bit or per byte log10(2**8) ~= 2.4.
	// So round up to allocate 3 output characters per byte, plus 1 for '-'.
	const size_t kOutputBufSize =
	3 * sizeof(INT) + std::numeric_limits<INT>::is_signed;

	// Create the string in a temporary buffer, write it back to front, and
	// then return the substr of what we ended up using.
	using CHR = typename STR::value_type;
	CHR outbuf[kOutputBufSize];

	// The ValueOrDie call below can never fail, because UnsignedAbs is valid
	// for all valid inputs.
	std::make_unsigned_t<INT> res =
	CheckedNumeric<INT>(value).UnsignedAbs().ValueOrDie();

	CHR* end = outbuf + kOutputBufSize;
	CHR* i = end;
	do {
	--i;
	GURL_DCHECK(i != outbuf);
	*i = static_cast<CHR>((res % 10) + '0');
	res /= 10;
	} while (res != 0);
	if (IsValueNegative(value)) {
	--i;
	GURL_DCHECK(i != outbuf);
	*i = static_cast<CHR>('-');
	}
	return STR(i, end);
	}

	// Utility to convert a character to a digit in a given base
	template <int BASE, typename CHAR>
	Optional<uint8_t> CharToDigit(CHAR c) {
	static_assert(1 <= BASE && BASE <= 36, "BASE needs to be in [1, 36]");
	if (c >= '0' && c < '0' + std::min(BASE, 10))
	return c - '0';

	if (c >= 'a' && c < 'a' + BASE - 10)
	return c - 'a' + 10;

	if (c >= 'A' && c < 'A' + BASE - 10)
	return c - 'A' + 10;

	return gurl_base::nullopt;
	}

	// There is an IsUnicodeWhitespace for wchars defined in string_util.h, but it
	// is locale independent, whereas the functions we are replacing were
	// locale-dependent. TBD what is desired, but for the moment let's not
	// introduce a change in behaviour.
	template <typename CHAR>
	class WhitespaceHelper {};

	template <>
	class WhitespaceHelper<char> {
	public:
	static bool Invoke(char c) {
	return 0 != isspace(static_cast<unsigned char>(c));
	}
	};

	template <>
	class WhitespaceHelper<char16> {
	public:
	static bool Invoke(char16 c) { return 0 != iswspace(c); }
	};

	template <typename CHAR>
	bool LocalIsWhitespace(CHAR c) {
	return WhitespaceHelper<CHAR>::Invoke(c);
	}

	template <typename Number, int kBase>
	class StringToNumberParser {
	public:
	struct Result {
	Number value = 0;
	bool valid = false;
	};

	static constexpr Number kMin = std::numeric_limits<Number>::min();
	static constexpr Number kMax = std::numeric_limits<Number>::max();

	// Sign provides:
	// - a static function, CheckBounds, that determines whether the next digit
	// causes an overflow/underflow
	// - a static function, Increment, that appends the next digit appropriately
	// according to the sign of the number being parsed.
	template <typename Sign>
	class Base {
	public:
	template <typename Iter>
	static Result Invoke(Iter begin, Iter end) {
	Number value = 0;

	if (begin == end) {
	return {value, false};
	}

	// Note: no performance difference was found when using template
	// specialization to remove this check in bases other than 16
	if (kBase == 16 && end - begin > 2 && *begin == '0' &&
	((begin + 1) == 'x' \|\| (begin + 1) == 'X')) {
	begin += 2;
	}

	for (Iter current = begin; current != end; ++current) {
	Optional<uint8_t> new_digit = CharToDigit<kBase>(*current);

	if (!new_digit) {
	return {value, false};
	}

	if (current != begin) {
	Result result = Sign::CheckBounds(value, *new_digit);
	if (!result.valid)
	return result;

	value *= kBase;
	}

	value = Sign::Increment(value, *new_digit);
	}
	return {value, true};
	}
	};

	class Positive : public Base<Positive> {
	public:
	static Result CheckBounds(Number value, uint8_t new_digit) {
	if (value > static_cast<Number>(kMax / kBase) \|\|
	(value == static_cast<Number>(kMax / kBase) &&
	new_digit > kMax % kBase)) {
	return {kMax, false};
	}
	return {value, true};
	}
	static Number Increment(Number lhs, uint8_t rhs) { return lhs + rhs; }
	};

	class Negative : public Base<Negative> {
	public:
	static Result CheckBounds(Number value, uint8_t new_digit) {
	if (value < kMin / kBase \|\|
	(value == kMin / kBase && new_digit > 0 - kMin % kBase)) {
	return {kMin, false};
	}
	return {value, true};
	}
	static Number Increment(Number lhs, uint8_t rhs) { return lhs - rhs; }
	};
	};

	template <typename Number, int kBase, typename Str>
	auto StringToNumber(BasicStringPiece<Str> input) {
	using Parser = StringToNumberParser<Number, kBase>;
	using Result = typename Parser::Result;

	bool has_leading_whitespace = false;
	auto begin = input.begin();
	auto end = input.end();

	while (begin != end && LocalIsWhitespace(*begin)) {
	has_leading_whitespace = true;
	++begin;
	}

	if (begin != end && *begin == '-') {
	if (!std::numeric_limits<Number>::is_signed) {
	return Result{0, false};
	}

	Result result = Parser::Negative::Invoke(begin + 1, end);
	result.valid &= !has_leading_whitespace;
	return result;
	}

	if (begin != end && *begin == '+') {
	++begin;
	}

	Result result = Parser::Positive::Invoke(begin, end);
	result.valid &= !has_leading_whitespace;
	return result;
	}

	template <typename STR, typename VALUE>
	bool StringToIntImpl(BasicStringPiece<STR> input, VALUE& output) {
	auto result = StringToNumber<VALUE, 10>(input);
	output = result.value;
	return result.valid;
	}

	template <typename STR, typename VALUE>
	bool HexStringToIntImpl(BasicStringPiece<STR> input, VALUE& output) {
	auto result = StringToNumber<VALUE, 16>(input);
	output = result.value;
	return result.valid;
	}

	static const double_conversion::DoubleToStringConverter*
	GetDoubleToStringConverter() {
	static NoDestructor<double_conversion::DoubleToStringConverter> converter(
	double_conversion::DoubleToStringConverter::EMIT_POSITIVE_EXPONENT_SIGN,
	nullptr, nullptr, 'e', -6, 12, 0, 0);
	return converter.get();
	}

	// Converts a given (data, size) pair to a desired string type. For
	// performance reasons, this dispatches to a different constructor if the
	// passed-in data matches the string's value_type.
	template <typename StringT>
	StringT ToString(const typename StringT::value_type* data, size_t size) {
	return StringT(data, size);
	}

	template <typename StringT, typename CharT>
	StringT ToString(const CharT* data, size_t size) {
	return StringT(data, data + size);
	}

	template <typename StringT>
	StringT DoubleToStringT(double value) {
	char buffer[32];
	double_conversion::StringBuilder builder(buffer, sizeof(buffer));
	GetDoubleToStringConverter()->ToShortest(value, &builder);
	return ToString<StringT>(buffer, builder.position());
	}

	template <typename STRING, typename CHAR>
	bool StringToDoubleImpl(STRING input, const CHAR* data, double& output) {
	static NoDestructor<double_conversion::StringToDoubleConverter> converter(
	double_conversion::StringToDoubleConverter::ALLOW_LEADING_SPACES \|
	double_conversion::StringToDoubleConverter::ALLOW_TRAILING_JUNK,
	0.0, 0, nullptr, nullptr);

	int processed_characters_count;
	output = converter->StringToDouble(data, input.size(),
	&processed_characters_count);

	// Cases to return false:
	// - If the input string is empty, there was nothing to parse.
	// - If the value saturated to HUGE_VAL.
	// - If the entire string was not processed, there are either characters
	// remaining in the string after a parsed number, or the string does not
	// begin with a parseable number.
	// - If the first character is a space, there was leading whitespace
	return !input.empty() && output != HUGE_VAL && output != -HUGE_VAL &&
	static_cast<size_t>(processed_characters_count) == input.size() &&
	!IsUnicodeWhitespace(input[0]);
	}

	template <typename OutIter>
	static bool HexStringToByteContainer(StringPiece input, OutIter output) {
	size_t count = input.size();
	if (count == 0 \|\| (count % 2) != 0)
	return false;
	for (uintptr_t i = 0; i < count / 2; ++i) {
	// most significant 4 bits
	Optional<uint8_t> msb = CharToDigit<16>(input[i * 2]);
	// least significant 4 bits
	Optional<uint8_t> lsb = CharToDigit<16>(input[i * 2 + 1]);
	if (!msb \|\| !lsb) {
	return false;
	}
	(output++) = (msb << 4) \| *lsb;
	}
	return true;
	}

	} // namespace internal

	} // namespace base

	#endif // BASE_STRINGS_STRING_NUMBER_CONVERSIONS_INTERNAL_H_