absl/strings/internal/str_format/parser.h - third_party/abseil-cpp - Git at Google

 #ifndef ABSL_STRINGS_INTERNAL_STR_FORMAT_PARSER_H_
 #define ABSL_STRINGS_INTERNAL_STR_FORMAT_PARSER_H_

 #include <limits.h>
 #include <stddef.h>
 #include <stdlib.h>

 #include <cassert>
 #include <initializer_list>
 #include <iosfwd>
 #include <iterator>
 #include <memory>
 #include <vector>

 #include "absl/strings/internal/str_format/checker.h"
 #include "absl/strings/internal/str_format/extension.h"

 namespace absl {
 namespace str_format_internal {

 // The analyzed properties of a single specified conversion.
 struct UnboundConversion {
   UnboundConversion()
       : flags() /* This is required to zero all the fields of flags. */ {
     flags.basic = true;
   }

   class InputValue {
    public:
     void set_value(int value) {
       assert(value >= 0);
       value_ = value;
     }
     int value() const { return value_; }

     // Marks the value as "from arg". aka the '*' format.
     // Requires `value >= 1`.
     // When set, is_from_arg() return true and get_from_arg() returns the
     // original value.
     // `value()`'s return value is unspecfied in this state.
     void set_from_arg(int value) {
       assert(value > 0);
       value_ = -value - 1;
     }
     bool is_from_arg() const { return value_ < -1; }
     int get_from_arg() const {
       assert(is_from_arg());
       return -value_ - 1;
     }

    private:
     int value_ = -1;
   };

   // No need to initialize. It will always be set in the parser.
   int arg_position;

   InputValue width;
   InputValue precision;

   Flags flags;
   LengthMod length_mod;
   ConversionChar conv;
 };

 // Consume conversion spec prefix (not including '%') of [p, end) if valid.
 // Examples of valid specs would be e.g.: "s", "d", "-12.6f".
 // If valid, it returns the first character following the conversion spec,
 // and the spec part is broken down and returned in 'conv'.
 // If invalid, returns nullptr.
 const char* ConsumeUnboundConversion(const char* p, const char* end,
                                      UnboundConversion* conv, int* next_arg);

 // Helper tag class for the table below.
 // It allows fast `char -> ConversionChar/LengthMod` checking and conversions.
 class ConvTag {
  public:
   constexpr ConvTag(ConversionChar::Id id) : tag_(id) {}  // NOLINT
   // We invert the length modifiers to make them negative so that we can easily
   // test for them.
   constexpr ConvTag(LengthMod::Id id) : tag_(~id) {}  // NOLINT
   // Everything else is -128, which is negative to make is_conv() simpler.
   constexpr ConvTag() : tag_(-128) {}

   bool is_conv() const { return tag_ >= 0; }
   bool is_length() const { return tag_ < 0 && tag_ != -128; }
   ConversionChar as_conv() const {
     assert(is_conv());
     return ConversionChar::FromId(static_cast<ConversionChar::Id>(tag_));
   }
   LengthMod as_length() const {
     assert(is_length());
     return LengthMod::FromId(static_cast<LengthMod::Id>(~tag_));
   }

  private:
   std::int8_t tag_;
 };

 extern const ConvTag kTags[256];
 // Keep a single table for all the conversion chars and length modifiers.
 inline ConvTag GetTagForChar(char c) {
   return kTags[static_cast<unsigned char>(c)];
 }

 // Parse the format string provided in 'src' and pass the identified items into
 // 'consumer'.
 // Text runs will be passed by calling
 //   Consumer::Append(string_view);
 // ConversionItems will be passed by calling
 //   Consumer::ConvertOne(UnboundConversion, string_view);
 // In the case of ConvertOne, the string_view that is passed is the
 // portion of the format string corresponding to the conversion, not including
 // the leading %. On success, it returns true. On failure, it stops and returns
 // false.
 template <typename Consumer>
 bool ParseFormatString(string_view src, Consumer consumer) {
   int next_arg = 0;
   const char* p = src.data();
   const char* const end = p + src.size();
   while (p != end) {
     const char* percent = static_cast<const char*>(memchr(p, '%', end - p));
     if (!percent) {
       // We found the last substring.
       return consumer.Append(string_view(p, end - p));
     }
     // We found a percent, so push the text run then process the percent.
     if (ABSL_PREDICT_FALSE(!consumer.Append(string_view(p, percent - p)))) {
       return false;
     }
     if (ABSL_PREDICT_FALSE(percent + 1 >= end)) return false;

     auto tag = GetTagForChar(percent[1]);
     if (tag.is_conv()) {
       if (ABSL_PREDICT_FALSE(next_arg < 0)) {
         // This indicates an error in the format std::string.
         // The only way to get `next_arg < 0` here is to have a positional
         // argument first which sets next_arg to -1 and then a non-positional
         // argument.
         return false;
       }
       p = percent + 2;

       // Keep this case separate from the one below.
       // ConvertOne is more efficient when the compiler can see that the `basic`
       // flag is set.
       UnboundConversion conv;
       conv.conv = tag.as_conv();
       conv.arg_position = ++next_arg;
       if (ABSL_PREDICT_FALSE(
               !consumer.ConvertOne(conv, string_view(percent + 1, 1)))) {
         return false;
       }
     } else if (percent[1] != '%') {
       UnboundConversion conv;
       p = ConsumeUnboundConversion(percent + 1, end, &conv, &next_arg);
       if (ABSL_PREDICT_FALSE(p == nullptr)) return false;
       if (ABSL_PREDICT_FALSE(!consumer.ConvertOne(
           conv, string_view(percent + 1, p - (percent + 1))))) {
         return false;
       }
     } else {
       if (ABSL_PREDICT_FALSE(!consumer.Append("%"))) return false;
       p = percent + 2;
       continue;
     }
   }
   return true;
 }

 // Always returns true, or fails to compile in a constexpr context if s does not
 // point to a constexpr char array.
 constexpr bool EnsureConstexpr(string_view s) {
   return s.empty() || s[0] == s[0];
 }

 class ParsedFormatBase {
  public:
   explicit ParsedFormatBase(string_view format, bool allow_ignored,
                             std::initializer_list<Conv> convs);

   ParsedFormatBase(const ParsedFormatBase& other) { *this = other; }

   ParsedFormatBase(ParsedFormatBase&& other) { *this = std::move(other); }

   ParsedFormatBase& operator=(const ParsedFormatBase& other) {
     if (this == &other) return *this;
     has_error_ = other.has_error_;
     items_ = other.items_;
     size_t text_size = items_.empty() ? 0 : items_.back().text_end;
     data_.reset(new char[text_size]);
     memcpy(data_.get(), other.data_.get(), text_size);
     return *this;
   }

   ParsedFormatBase& operator=(ParsedFormatBase&& other) {
     if (this == &other) return *this;
     has_error_ = other.has_error_;
     data_ = std::move(other.data_);
     items_ = std::move(other.items_);
     // Reset the vector to make sure the invariants hold.
     other.items_.clear();
     return *this;
   }

   template <typename Consumer>
   bool ProcessFormat(Consumer consumer) const {
     const char* const base = data_.get();
     string_view text(base, 0);
     for (const auto& item : items_) {
       const char* const end = text.data() + text.size();
       text = string_view(end, (base + item.text_end) - end);
       if (item.is_conversion) {
         if (!consumer.ConvertOne(item.conv, text)) return false;
       } else {
         if (!consumer.Append(text)) return false;
       }
     }
     return !has_error_;
   }

   bool has_error() const { return has_error_; }

  private:
   // Returns whether the conversions match and if !allow_ignored it verifies
   // that all conversions are used by the format.
   bool MatchesConversions(bool allow_ignored,
                           std::initializer_list<Conv> convs) const;

   struct ParsedFormatConsumer;

   struct ConversionItem {
     bool is_conversion;
     // Points to the past-the-end location of this element in the data_ array.
     size_t text_end;
     UnboundConversion conv;
   };

   bool has_error_;
   std::unique_ptr<char[]> data_;
   std::vector<ConversionItem> items_;
 };


 // A value type representing a preparsed format.  These can be created, copied
 // around, and reused to speed up formatting loops.
 // The user must specify through the template arguments the conversion
 // characters used in the format. This will be checked at compile time.
 //
 // This class uses Conv enum values to specify each argument.
 // This allows for more flexibility as you can specify multiple possible
 // conversion characters for each argument.
 // ParsedFormat<char...> is a simplified alias for when the user only
 // needs to specify a single conversion character for each argument.
 //
 // Example:
 //   // Extended format supports multiple characters per argument:
 //   using MyFormat = ExtendedParsedFormat<Conv::d | Conv::x>;
 //   MyFormat GetFormat(bool use_hex) {
 //     if (use_hex) return MyFormat("foo %x bar");
 //     return MyFormat("foo %d bar");
 //   }
 //   // 'format' can be used with any value that supports 'd' and 'x',
 //   // like `int`.
 //   auto format = GetFormat(use_hex);
 //   value = StringF(format, i);
 //
 // This class also supports runtime format checking with the ::New() and
 // ::NewAllowIgnored() factory functions.
 // This is the only API that allows the user to pass a runtime specified format
 // string. These factory functions will return NULL if the format does not match
 // the conversions requested by the user.
 template <str_format_internal::Conv... C>
 class ExtendedParsedFormat : public str_format_internal::ParsedFormatBase {
  public:
   explicit ExtendedParsedFormat(string_view format)
 #if ABSL_INTERNAL_ENABLE_FORMAT_CHECKER
       __attribute__((
           enable_if(str_format_internal::EnsureConstexpr(format),
                     "Format std::string is not constexpr."),
           enable_if(str_format_internal::ValidFormatImpl<C...>(format),
                     "Format specified does not match the template arguments.")))
 #endif  // ABSL_INTERNAL_ENABLE_FORMAT_CHECKER
       : ExtendedParsedFormat(format, false) {
   }

   // ExtendedParsedFormat factory function.
   // The user still has to specify the conversion characters, but they will not
   // be checked at compile time. Instead, it will be checked at runtime.
   // This delays the checking to runtime, but allows the user to pass
   // dynamically sourced formats.
   // It returns NULL if the format does not match the conversion characters.
   // The user is responsible for checking the return value before using it.
   //
   // The 'New' variant will check that all the specified arguments are being
   // consumed by the format and return NULL if any argument is being ignored.
   // The 'NewAllowIgnored' variant will not verify this and will allow formats
   // that ignore arguments.
   static std::unique_ptr<ExtendedParsedFormat> New(string_view format) {
     return New(format, false);
   }
   static std::unique_ptr<ExtendedParsedFormat> NewAllowIgnored(
       string_view format) {
     return New(format, true);
   }

  private:
   static std::unique_ptr<ExtendedParsedFormat> New(string_view format,
                                                    bool allow_ignored) {
     std::unique_ptr<ExtendedParsedFormat> conv(
         new ExtendedParsedFormat(format, allow_ignored));
     if (conv->has_error()) return nullptr;
     return conv;
   }

   ExtendedParsedFormat(string_view s, bool allow_ignored)
       : ParsedFormatBase(s, allow_ignored, {C...}) {}
 };
 }  // namespace str_format_internal
 }  // namespace absl

 #endif  // ABSL_STRINGS_INTERNAL_STR_FORMAT_PARSER_H_
	#ifndef ABSL_STRINGS_INTERNAL_STR_FORMAT_PARSER_H_
	#define ABSL_STRINGS_INTERNAL_STR_FORMAT_PARSER_H_

	#include <limits.h>
	#include <stddef.h>
	#include <stdlib.h>

	#include <cassert>
	#include <initializer_list>
	#include <iosfwd>
	#include <iterator>
	#include <memory>
	#include <vector>

	#include "absl/strings/internal/str_format/checker.h"
	#include "absl/strings/internal/str_format/extension.h"

	namespace absl {
	namespace str_format_internal {

	// The analyzed properties of a single specified conversion.
	struct UnboundConversion {
	UnboundConversion()
	: flags() /* This is required to zero all the fields of flags. */ {
	flags.basic = true;
	}

	class InputValue {
	public:
	void set_value(int value) {
	assert(value >= 0);
	value_ = value;
	}
	int value() const { return value_; }

	// Marks the value as "from arg". aka the '*' format.
	// Requires `value >= 1`.
	// When set, is_from_arg() return true and get_from_arg() returns the
	// original value.
	// `value()`'s return value is unspecfied in this state.
	void set_from_arg(int value) {
	assert(value > 0);
	value_ = -value - 1;
	}
	bool is_from_arg() const { return value_ < -1; }
	int get_from_arg() const {
	assert(is_from_arg());
	return -value_ - 1;
	}

	private:
	int value_ = -1;
	};

	// No need to initialize. It will always be set in the parser.
	int arg_position;

	InputValue width;
	InputValue precision;

	Flags flags;
	LengthMod length_mod;
	ConversionChar conv;
	};

	// Consume conversion spec prefix (not including '%') of [p, end) if valid.
	// Examples of valid specs would be e.g.: "s", "d", "-12.6f".
	// If valid, it returns the first character following the conversion spec,
	// and the spec part is broken down and returned in 'conv'.
	// If invalid, returns nullptr.
	const char* ConsumeUnboundConversion(const char* p, const char* end,
	UnboundConversion* conv, int* next_arg);

	// Helper tag class for the table below.
	// It allows fast `char -> ConversionChar/LengthMod` checking and conversions.
	class ConvTag {
	public:
	constexpr ConvTag(ConversionChar::Id id) : tag_(id) {} // NOLINT
	// We invert the length modifiers to make them negative so that we can easily
	// test for them.
	constexpr ConvTag(LengthMod::Id id) : tag_(~id) {} // NOLINT
	// Everything else is -128, which is negative to make is_conv() simpler.
	constexpr ConvTag() : tag_(-128) {}

	bool is_conv() const { return tag_ >= 0; }
	bool is_length() const { return tag_ < 0 && tag_ != -128; }
	ConversionChar as_conv() const {
	assert(is_conv());
	return ConversionChar::FromId(static_cast<ConversionChar::Id>(tag_));
	}
	LengthMod as_length() const {
	assert(is_length());
	return LengthMod::FromId(static_cast<LengthMod::Id>(~tag_));
	}

	private:
	std::int8_t tag_;
	};

	extern const ConvTag kTags[256];
	// Keep a single table for all the conversion chars and length modifiers.
	inline ConvTag GetTagForChar(char c) {
	return kTags[static_cast<unsigned char>(c)];
	}

	// Parse the format string provided in 'src' and pass the identified items into
	// 'consumer'.
	// Text runs will be passed by calling
	// Consumer::Append(string_view);
	// ConversionItems will be passed by calling
	// Consumer::ConvertOne(UnboundConversion, string_view);
	// In the case of ConvertOne, the string_view that is passed is the
	// portion of the format string corresponding to the conversion, not including
	// the leading %. On success, it returns true. On failure, it stops and returns
	// false.
	template <typename Consumer>
	bool ParseFormatString(string_view src, Consumer consumer) {
	int next_arg = 0;
	const char* p = src.data();
	const char* const end = p + src.size();
	while (p != end) {
	const char* percent = static_cast<const char*>(memchr(p, '%', end - p));
	if (!percent) {
	// We found the last substring.
	return consumer.Append(string_view(p, end - p));
	}
	// We found a percent, so push the text run then process the percent.
	if (ABSL_PREDICT_FALSE(!consumer.Append(string_view(p, percent - p)))) {
	return false;
	}
	if (ABSL_PREDICT_FALSE(percent + 1 >= end)) return false;

	auto tag = GetTagForChar(percent[1]);
	if (tag.is_conv()) {
	if (ABSL_PREDICT_FALSE(next_arg < 0)) {
	// This indicates an error in the format std::string.
	// The only way to get `next_arg < 0` here is to have a positional
	// argument first which sets next_arg to -1 and then a non-positional
	// argument.
	return false;
	}
	p = percent + 2;

	// Keep this case separate from the one below.
	// ConvertOne is more efficient when the compiler can see that the `basic`
	// flag is set.
	UnboundConversion conv;
	conv.conv = tag.as_conv();
	conv.arg_position = ++next_arg;
	if (ABSL_PREDICT_FALSE(
	!consumer.ConvertOne(conv, string_view(percent + 1, 1)))) {
	return false;
	}
	} else if (percent[1] != '%') {
	UnboundConversion conv;
	p = ConsumeUnboundConversion(percent + 1, end, &conv, &next_arg);
	if (ABSL_PREDICT_FALSE(p == nullptr)) return false;
	if (ABSL_PREDICT_FALSE(!consumer.ConvertOne(
	conv, string_view(percent + 1, p - (percent + 1))))) {
	return false;
	}
	} else {
	if (ABSL_PREDICT_FALSE(!consumer.Append("%"))) return false;
	p = percent + 2;
	continue;
	}
	}
	return true;
	}

	// Always returns true, or fails to compile in a constexpr context if s does not
	// point to a constexpr char array.
	constexpr bool EnsureConstexpr(string_view s) {
	return s.empty() \|\| s[0] == s[0];
	}

	class ParsedFormatBase {
	public:
	explicit ParsedFormatBase(string_view format, bool allow_ignored,
	std::initializer_list<Conv> convs);

	ParsedFormatBase(const ParsedFormatBase& other) { *this = other; }

	ParsedFormatBase(ParsedFormatBase&& other) { *this = std::move(other); }

	ParsedFormatBase& operator=(const ParsedFormatBase& other) {
	if (this == &other) return *this;
	has_error_ = other.has_error_;
	items_ = other.items_;
	size_t text_size = items_.empty() ? 0 : items_.back().text_end;
	data_.reset(new char[text_size]);
	memcpy(data_.get(), other.data_.get(), text_size);
	return *this;
	}

	ParsedFormatBase& operator=(ParsedFormatBase&& other) {
	if (this == &other) return *this;
	has_error_ = other.has_error_;
	data_ = std::move(other.data_);
	items_ = std::move(other.items_);
	// Reset the vector to make sure the invariants hold.
	other.items_.clear();
	return *this;
	}

	template <typename Consumer>
	bool ProcessFormat(Consumer consumer) const {
	const char* const base = data_.get();
	string_view text(base, 0);
	for (const auto& item : items_) {
	const char* const end = text.data() + text.size();
	text = string_view(end, (base + item.text_end) - end);
	if (item.is_conversion) {
	if (!consumer.ConvertOne(item.conv, text)) return false;
	} else {
	if (!consumer.Append(text)) return false;
	}
	}
	return !has_error_;
	}

	bool has_error() const { return has_error_; }

	private:
	// Returns whether the conversions match and if !allow_ignored it verifies
	// that all conversions are used by the format.
	bool MatchesConversions(bool allow_ignored,
	std::initializer_list<Conv> convs) const;

	struct ParsedFormatConsumer;

	struct ConversionItem {
	bool is_conversion;
	// Points to the past-the-end location of this element in the data_ array.
	size_t text_end;
	UnboundConversion conv;
	};

	bool has_error_;
	std::unique_ptr<char[]> data_;
	std::vector<ConversionItem> items_;
	};


	// A value type representing a preparsed format. These can be created, copied
	// around, and reused to speed up formatting loops.
	// The user must specify through the template arguments the conversion
	// characters used in the format. This will be checked at compile time.
	//
	// This class uses Conv enum values to specify each argument.
	// This allows for more flexibility as you can specify multiple possible
	// conversion characters for each argument.
	// ParsedFormat<char...> is a simplified alias for when the user only
	// needs to specify a single conversion character for each argument.
	//
	// Example:
	// // Extended format supports multiple characters per argument:
	// using MyFormat = ExtendedParsedFormat<Conv::d \| Conv::x>;
	// MyFormat GetFormat(bool use_hex) {
	// if (use_hex) return MyFormat("foo %x bar");
	// return MyFormat("foo %d bar");
	// }
	// // 'format' can be used with any value that supports 'd' and 'x',
	// // like `int`.
	// auto format = GetFormat(use_hex);
	// value = StringF(format, i);
	//
	// This class also supports runtime format checking with the ::New() and
	// ::NewAllowIgnored() factory functions.
	// This is the only API that allows the user to pass a runtime specified format
	// string. These factory functions will return NULL if the format does not match
	// the conversions requested by the user.
	template <str_format_internal::Conv... C>
	class ExtendedParsedFormat : public str_format_internal::ParsedFormatBase {
	public:
	explicit ExtendedParsedFormat(string_view format)
	#if ABSL_INTERNAL_ENABLE_FORMAT_CHECKER
	__attribute__((
	enable_if(str_format_internal::EnsureConstexpr(format),
	"Format std::string is not constexpr."),
	enable_if(str_format_internal::ValidFormatImpl<C...>(format),
	"Format specified does not match the template arguments.")))
	#endif // ABSL_INTERNAL_ENABLE_FORMAT_CHECKER
	: ExtendedParsedFormat(format, false) {
	}

	// ExtendedParsedFormat factory function.
	// The user still has to specify the conversion characters, but they will not
	// be checked at compile time. Instead, it will be checked at runtime.
	// This delays the checking to runtime, but allows the user to pass
	// dynamically sourced formats.
	// It returns NULL if the format does not match the conversion characters.
	// The user is responsible for checking the return value before using it.
	//
	// The 'New' variant will check that all the specified arguments are being
	// consumed by the format and return NULL if any argument is being ignored.
	// The 'NewAllowIgnored' variant will not verify this and will allow formats
	// that ignore arguments.
	static std::unique_ptr<ExtendedParsedFormat> New(string_view format) {
	return New(format, false);
	}
	static std::unique_ptr<ExtendedParsedFormat> NewAllowIgnored(
	string_view format) {
	return New(format, true);
	}

	private:
	static std::unique_ptr<ExtendedParsedFormat> New(string_view format,
	bool allow_ignored) {
	std::unique_ptr<ExtendedParsedFormat> conv(
	new ExtendedParsedFormat(format, allow_ignored));
	if (conv->has_error()) return nullptr;
	return conv;
	}

	ExtendedParsedFormat(string_view s, bool allow_ignored)
	: ParsedFormatBase(s, allow_ignored, {C...}) {}
	};
	} // namespace str_format_internal
	} // namespace absl

	#endif // ABSL_STRINGS_INTERNAL_STR_FORMAT_PARSER_H_