src/url/url_canon_internal.h - cobalt - Git at Google

 // Copyright 2013 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 URL_URL_CANON_INTERNAL_H_
 #define URL_URL_CANON_INTERNAL_H_

 // This file is intended to be included in another C++ file where the character
 // types are defined. This allows us to write mostly generic code, but not have
 // template bloat because everything is inlined when anybody calls any of our
 // functions.

 #if defined(STARBOARD)
 #include "starboard/common/string.h"
 #else
 #include <stdlib.h>
 #endif

 #include "base/logging.h"
 #include "starboard/types.h"
 #include "url/url_canon.h"

 namespace url {

 // Character type handling -----------------------------------------------------

 // Bits that identify different character types. These types identify different
 // bits that are set for each 8-bit character in the kSharedCharTypeTable.
 enum SharedCharTypes {
   // Characters that do not require escaping in queries. Characters that do
   // not have this flag will be escaped; see url_canon_query.cc
   CHAR_QUERY = 1,

   // Valid in the username/password field.
   CHAR_USERINFO = 2,

   // Valid in a IPv4 address (digits plus dot and 'x' for hex).
   CHAR_IPV4 = 4,

   // Valid in an ASCII-representation of a hex digit (as in %-escaped).
   CHAR_HEX = 8,

   // Valid in an ASCII-representation of a decimal digit.
   CHAR_DEC = 16,

   // Valid in an ASCII-representation of an octal digit.
   CHAR_OCT = 32,

   // Characters that do not require escaping in encodeURIComponent. Characters
   // that do not have this flag will be escaped; see url_util.cc.
   CHAR_COMPONENT = 64,
 };

 // This table contains the flags in SharedCharTypes for each 8-bit character.
 // Some canonicalization functions have their own specialized lookup table.
 // For those with simple requirements, we have collected the flags in one
 // place so there are fewer lookup tables to load into the CPU cache.
 //
 // Using an unsigned char type has a small but measurable performance benefit
 // over using a 32-bit number.
 extern const unsigned char kSharedCharTypeTable[0x100];

 // More readable wrappers around the character type lookup table.
 inline bool IsCharOfType(unsigned char c, SharedCharTypes type) {
   return !!(kSharedCharTypeTable[c] & type);
 }
 inline bool IsQueryChar(unsigned char c) {
   return IsCharOfType(c, CHAR_QUERY);
 }
 inline bool IsIPv4Char(unsigned char c) {
   return IsCharOfType(c, CHAR_IPV4);
 }
 inline bool IsHexChar(unsigned char c) {
   return IsCharOfType(c, CHAR_HEX);
 }
 inline bool IsComponentChar(unsigned char c) {
   return IsCharOfType(c, CHAR_COMPONENT);
 }

 // Appends the given string to the output, escaping characters that do not
 // match the given |type| in SharedCharTypes.
 void AppendStringOfType(const char* source, int length,
                         SharedCharTypes type,
                         CanonOutput* output);
 void AppendStringOfType(const base::char16* source, int length,
                         SharedCharTypes type,
                         CanonOutput* output);

 // Maps the hex numerical values 0x0 to 0xf to the corresponding ASCII digit
 // that will be used to represent it.
 URL_EXPORT extern const char kHexCharLookup[0x10];

 // This lookup table allows fast conversion between ASCII hex letters and their
 // corresponding numerical value. The 8-bit range is divided up into 8
 // regions of 0x20 characters each. Each of the three character types (numbers,
 // uppercase, lowercase) falls into different regions of this range. The table
 // contains the amount to subtract from characters in that range to get at
 // the corresponding numerical value.
 //
 // See HexDigitToValue for the lookup.
 extern const char kCharToHexLookup[8];

 // Assumes the input is a valid hex digit! Call IsHexChar before using this.
 inline unsigned char HexCharToValue(unsigned char c) {
   return c - kCharToHexLookup[c / 0x20];
 }

 // Indicates if the given character is a dot or dot equivalent, returning the
 // number of characters taken by it. This will be one for a literal dot, 3 for
 // an escaped dot. If the character is not a dot, this will return 0.
 template<typename CHAR>
 inline int IsDot(const CHAR* spec, int offset, int end) {
   if (spec[offset] == '.') {
     return 1;
   } else if (spec[offset] == '%' && offset + 3 <= end &&
              spec[offset + 1] == '2' &&
              (spec[offset + 2] == 'e' || spec[offset + 2] == 'E')) {
     // Found "%2e"
     return 3;
   }
   return 0;
 }

 // Returns the canonicalized version of the input character according to scheme
 // rules. This is implemented alongside the scheme canonicalizer, and is
 // required for relative URL resolving to test for scheme equality.
 //
 // Returns 0 if the input character is not a valid scheme character.
 char CanonicalSchemeChar(base::char16 ch);

 // Write a single character, escaped, to the output. This always escapes: it
 // does no checking that thee character requires escaping.
 // Escaping makes sense only 8 bit chars, so code works in all cases of
 // input parameters (8/16bit).
 template<typename UINCHAR, typename OUTCHAR>
 inline void AppendEscapedChar(UINCHAR ch,
                               CanonOutputT<OUTCHAR>* output) {
   output->push_back('%');
   output->push_back(kHexCharLookup[(ch >> 4) & 0xf]);
   output->push_back(kHexCharLookup[ch & 0xf]);
 }

 // The character we'll substitute for undecodable or invalid characters.
 extern const base::char16 kUnicodeReplacementCharacter;

 // UTF-8 functions ------------------------------------------------------------

 // Reads one character in UTF-8 starting at |*begin| in |str| and places
 // the decoded value into |*code_point|. If the character is valid, we will
 // return true. If invalid, we'll return false and put the
 // kUnicodeReplacementCharacter into |*code_point|.
 //
 // |*begin| will be updated to point to the last character consumed so it
 // can be incremented in a loop and will be ready for the next character.
 // (for a single-byte ASCII character, it will not be changed).
 URL_EXPORT bool ReadUTFChar(const char* str, int* begin, int length,
                             unsigned* code_point_out);

 // Generic To-UTF-8 converter. This will call the given append method for each
 // character that should be appended, with the given output method. Wrappers
 // are provided below for escaped and non-escaped versions of this.
 //
 // The char_value must have already been checked that it's a valid Unicode
 // character.
 template<class Output, void Appender(unsigned char, Output*)>
 inline void DoAppendUTF8(unsigned char_value, Output* output) {
   if (char_value <= 0x7f) {
     Appender(static_cast<unsigned char>(char_value), output);
   } else if (char_value <= 0x7ff) {
     // 110xxxxx 10xxxxxx
     Appender(static_cast<unsigned char>(0xC0 | (char_value >> 6)),
              output);
     Appender(static_cast<unsigned char>(0x80 | (char_value & 0x3f)),
              output);
   } else if (char_value <= 0xffff) {
     // 1110xxxx 10xxxxxx 10xxxxxx
     Appender(static_cast<unsigned char>(0xe0 | (char_value >> 12)),
              output);
     Appender(static_cast<unsigned char>(0x80 | ((char_value >> 6) & 0x3f)),
              output);
     Appender(static_cast<unsigned char>(0x80 | (char_value & 0x3f)),
              output);
   } else if (char_value <= 0x10FFFF) {  // Max Unicode code point.
     // 11110xxx 10xxxxxx 10xxxxxx 10xxxxxx
     Appender(static_cast<unsigned char>(0xf0 | (char_value >> 18)),
              output);
     Appender(static_cast<unsigned char>(0x80 | ((char_value >> 12) & 0x3f)),
              output);
     Appender(static_cast<unsigned char>(0x80 | ((char_value >> 6) & 0x3f)),
              output);
     Appender(static_cast<unsigned char>(0x80 | (char_value & 0x3f)),
              output);
   } else {
     // Invalid UTF-8 character (>20 bits).
     NOTREACHED();
   }
 }

 // Helper used by AppendUTF8Value below. We use an unsigned parameter so there
 // are no funny sign problems with the input, but then have to convert it to
 // a regular char for appending.
 inline void AppendCharToOutput(unsigned char ch, CanonOutput* output) {
   output->push_back(static_cast<char>(ch));
 }

 // Writes the given character to the output as UTF-8. This does NO checking
 // of the validity of the Unicode characters; the caller should ensure that
 // the value it is appending is valid to append.
 inline void AppendUTF8Value(unsigned char_value, CanonOutput* output) {
   DoAppendUTF8<CanonOutput, AppendCharToOutput>(char_value, output);
 }

 // Writes the given character to the output as UTF-8, escaping ALL
 // characters (even when they are ASCII). This does NO checking of the
 // validity of the Unicode characters; the caller should ensure that the value
 // it is appending is valid to append.
 inline void AppendUTF8EscapedValue(unsigned char_value, CanonOutput* output) {
   DoAppendUTF8<CanonOutput, AppendEscapedChar>(char_value, output);
 }

 // UTF-16 functions -----------------------------------------------------------

 // Reads one character in UTF-16 starting at |*begin| in |str| and places
 // the decoded value into |*code_point|. If the character is valid, we will
 // return true. If invalid, we'll return false and put the
 // kUnicodeReplacementCharacter into |*code_point|.
 //
 // |*begin| will be updated to point to the last character consumed so it
 // can be incremented in a loop and will be ready for the next character.
 // (for a single-16-bit-word character, it will not be changed).
 URL_EXPORT bool ReadUTFChar(const base::char16* str, int* begin, int length,
                             unsigned* code_point_out);

 // Equivalent to U16_APPEND_UNSAFE in ICU but uses our output method.
 inline void AppendUTF16Value(unsigned code_point,
                              CanonOutputT<base::char16>* output) {
   if (code_point > 0xffff) {
     output->push_back(static_cast<base::char16>((code_point >> 10) + 0xd7c0));
     output->push_back(static_cast<base::char16>((code_point & 0x3ff) | 0xdc00));
   } else {
     output->push_back(static_cast<base::char16>(code_point));
   }
 }

 // Escaping functions ---------------------------------------------------------

 // Writes the given character to the output as UTF-8, escaped. Call this
 // function only when the input is wide. Returns true on success. Failure
 // means there was some problem with the encoding, we'll still try to
 // update the |*begin| pointer and add a placeholder character to the
 // output so processing can continue.
 //
 // We will append the character starting at ch[begin] with the buffer ch
 // being |length|. |*begin| will be updated to point to the last character
 // consumed (we may consume more than one for UTF-16) so that if called in
 // a loop, incrementing the pointer will move to the next character.
 //
 // Every single output character will be escaped. This means that if you
 // give it an ASCII character as input, it will be escaped. Some code uses
 // this when it knows that a character is invalid according to its rules
 // for validity. If you don't want escaping for ASCII characters, you will
 // have to filter them out prior to calling this function.
 //
 // Assumes that ch[begin] is within range in the array, but does not assume
 // that any following characters are.
 inline bool AppendUTF8EscapedChar(const base::char16* str, int* begin,
                                   int length, CanonOutput* output) {
   // UTF-16 input. ReadUTFChar will handle invalid characters for us and give
   // us the kUnicodeReplacementCharacter, so we don't have to do special
   // checking after failure, just pass through the failure to the caller.
   unsigned char_value;
   bool success = ReadUTFChar(str, begin, length, &char_value);
   AppendUTF8EscapedValue(char_value, output);
   return success;
 }

 // Handles UTF-8 input. See the wide version above for usage.
 inline bool AppendUTF8EscapedChar(const char* str, int* begin, int length,
                                   CanonOutput* output) {
   // ReadUTF8Char will handle invalid characters for us and give us the
   // kUnicodeReplacementCharacter, so we don't have to do special checking
   // after failure, just pass through the failure to the caller.
   unsigned ch;
   bool success = ReadUTFChar(str, begin, length, &ch);
   AppendUTF8EscapedValue(ch, output);
   return success;
 }

 // Given a '%' character at |*begin| in the string |spec|, this will decode
 // the escaped value and put it into |*unescaped_value| on success (returns
 // true). On failure, this will return false, and will not write into
 // |*unescaped_value|.
 //
 // |*begin| will be updated to point to the last character of the escape
 // sequence so that when called with the index of a for loop, the next time
 // through it will point to the next character to be considered. On failure,
 // |*begin| will be unchanged.
 inline bool Is8BitChar(char c) {
   return true;  // this case is specialized to avoid a warning
 }
 inline bool Is8BitChar(base::char16 c) {
   return c <= 255;
 }

 template<typename CHAR>
 inline bool DecodeEscaped(const CHAR* spec, int* begin, int end,
                           unsigned char* unescaped_value) {
   if (*begin + 3 > end ||
       !Is8BitChar(spec[*begin + 1]) || !Is8BitChar(spec[*begin + 2])) {
     // Invalid escape sequence because there's not enough room, or the
     // digits are not ASCII.
     return false;
   }

   unsigned char first = static_cast<unsigned char>(spec[*begin + 1]);
   unsigned char second = static_cast<unsigned char>(spec[*begin + 2]);
   if (!IsHexChar(first) || !IsHexChar(second)) {
     // Invalid hex digits, fail.
     return false;
   }

   // Valid escape sequence.
   *unescaped_value = (HexCharToValue(first) << 4) + HexCharToValue(second);
   *begin += 2;
   return true;
 }

 // Appends the given substring to the output, escaping "some" characters that
 // it feels may not be safe. It assumes the input values are all contained in
 // 8-bit although it allows any type.
 //
 // This is used in error cases to append invalid output so that it looks
 // approximately correct. Non-error cases should not call this function since
 // the escaping rules are not guaranteed!
 void AppendInvalidNarrowString(const char* spec, int begin, int end,
                                CanonOutput* output);
 void AppendInvalidNarrowString(const base::char16* spec, int begin, int end,
                                CanonOutput* output);

 // Misc canonicalization helpers ----------------------------------------------

 // Converts between UTF-8 and UTF-16, returning true on successful conversion.
 // The output will be appended to the given canonicalizer output (so make sure
 // it's empty if you want to replace).
 //
 // On invalid input, this will still write as much output as possible,
 // replacing the invalid characters with the "invalid character". It will
 // return false in the failure case, and the caller should not continue as
 // normal.
 URL_EXPORT bool ConvertUTF16ToUTF8(const base::char16* input, int input_len,
                                    CanonOutput* output);
 URL_EXPORT bool ConvertUTF8ToUTF16(const char* input, int input_len,
                                    CanonOutputT<base::char16>* output);

 // Converts from UTF-16 to 8-bit using the character set converter. If the
 // converter is NULL, this will use UTF-8.
 void ConvertUTF16ToQueryEncoding(const base::char16* input,
                                  const Component& query,
                                  CharsetConverter* converter,
                                  CanonOutput* output);

 // Applies the replacements to the given component source. The component source
 // should be pre-initialized to the "old" base. That is, all pointers will
 // point to the spec of the old URL, and all of the Parsed components will
 // be indices into that string.
 //
 // The pointers and components in the |source| for all non-NULL strings in the
 // |repl| (replacements) will be updated to reference those strings.
 // Canonicalizing with the new |source| and |parsed| can then combine URL
 // components from many different strings.
 void SetupOverrideComponents(const char* base,
                              const Replacements<char>& repl,
                              URLComponentSource<char>* source,
                              Parsed* parsed);

 // Like the above 8-bit version, except that it additionally converts the
 // UTF-16 input to UTF-8 before doing the overrides.
 //
 // The given utf8_buffer is used to store the converted components. They will
 // be appended one after another, with the parsed structure identifying the
 // appropriate substrings. This buffer is a parameter because the source has
 // no storage, so the buffer must have the same lifetime as the source
 // parameter owned by the caller.
 //
 // THE CALLER MUST NOT ADD TO THE |utf8_buffer| AFTER THIS CALL. Members of
 // |source| will point into this buffer, which could be invalidated if
 // additional data is added and the CanonOutput resizes its buffer.
 //
 // Returns true on success. False means that the input was not valid UTF-16,
 // although we will have still done the override with "invalid characters" in
 // place of errors.
 bool SetupUTF16OverrideComponents(const char* base,
                                   const Replacements<base::char16>& repl,
                                   CanonOutput* utf8_buffer,
                                   URLComponentSource<char>* source,
                                   Parsed* parsed);

 // Implemented in url_canon_path.cc, these are required by the relative URL
 // resolver as well, so we declare them here.
 bool CanonicalizePartialPath(const char* spec,
                              const Component& path,
                              int path_begin_in_output,
                              CanonOutput* output);
 bool CanonicalizePartialPath(const base::char16* spec,
                              const Component& path,
                              int path_begin_in_output,
                              CanonOutput* output);

 #if !defined(WIN32) || defined(STARBOARD)

 // Implementations of Windows' int-to-string conversions
 URL_EXPORT int _itoa_s(int value, char* buffer, size_t size_in_chars,
                        int radix);
 URL_EXPORT int _itow_s(int value, base::char16* buffer, size_t size_in_chars,
                        int radix);

 // Secure template overloads for these functions
 template<size_t N>
 inline int _itoa_s(int value, char (&buffer)[N], int radix) {
   return _itoa_s(value, buffer, N, radix);
 }

 template<size_t N>
 inline int _itow_s(int value, base::char16 (&buffer)[N], int radix) {
   return _itow_s(value, buffer, N, radix);
 }

 // _strtoui64 and strtoull behave the same
 inline unsigned long long _strtoui64(const char* nptr,
                                      char** endptr, int base) {
 #if defined(STARBOARD)
   return SbStringParseUInt64(nptr, endptr, base);
 #else
   return strtoull(nptr, endptr, base);
 #endif
 }

 #endif  // WIN32

 }  // namespace url

 #endif  // URL_URL_CANON_INTERNAL_H_
	// Copyright 2013 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 URL_URL_CANON_INTERNAL_H_
	#define URL_URL_CANON_INTERNAL_H_

	// This file is intended to be included in another C++ file where the character
	// types are defined. This allows us to write mostly generic code, but not have
	// template bloat because everything is inlined when anybody calls any of our
	// functions.

	#if defined(STARBOARD)
	#include "starboard/common/string.h"
	#else
	#include <stdlib.h>
	#endif

	#include "base/logging.h"
	#include "starboard/types.h"
	#include "url/url_canon.h"

	namespace url {

	// Character type handling -----------------------------------------------------

	// Bits that identify different character types. These types identify different
	// bits that are set for each 8-bit character in the kSharedCharTypeTable.
	enum SharedCharTypes {
	// Characters that do not require escaping in queries. Characters that do
	// not have this flag will be escaped; see url_canon_query.cc
	CHAR_QUERY = 1,

	// Valid in the username/password field.
	CHAR_USERINFO = 2,

	// Valid in a IPv4 address (digits plus dot and 'x' for hex).
	CHAR_IPV4 = 4,

	// Valid in an ASCII-representation of a hex digit (as in %-escaped).
	CHAR_HEX = 8,

	// Valid in an ASCII-representation of a decimal digit.
	CHAR_DEC = 16,

	// Valid in an ASCII-representation of an octal digit.
	CHAR_OCT = 32,

	// Characters that do not require escaping in encodeURIComponent. Characters
	// that do not have this flag will be escaped; see url_util.cc.
	CHAR_COMPONENT = 64,
	};

	// This table contains the flags in SharedCharTypes for each 8-bit character.
	// Some canonicalization functions have their own specialized lookup table.
	// For those with simple requirements, we have collected the flags in one
	// place so there are fewer lookup tables to load into the CPU cache.
	//
	// Using an unsigned char type has a small but measurable performance benefit
	// over using a 32-bit number.
	extern const unsigned char kSharedCharTypeTable[0x100];

	// More readable wrappers around the character type lookup table.
	inline bool IsCharOfType(unsigned char c, SharedCharTypes type) {
	return !!(kSharedCharTypeTable[c] & type);
	}
	inline bool IsQueryChar(unsigned char c) {
	return IsCharOfType(c, CHAR_QUERY);
	}
	inline bool IsIPv4Char(unsigned char c) {
	return IsCharOfType(c, CHAR_IPV4);
	}
	inline bool IsHexChar(unsigned char c) {
	return IsCharOfType(c, CHAR_HEX);
	}
	inline bool IsComponentChar(unsigned char c) {
	return IsCharOfType(c, CHAR_COMPONENT);
	}

	// Appends the given string to the output, escaping characters that do not
	// match the given \|type\| in SharedCharTypes.
	void AppendStringOfType(const char* source, int length,
	SharedCharTypes type,
	CanonOutput* output);
	void AppendStringOfType(const base::char16* source, int length,
	SharedCharTypes type,
	CanonOutput* output);

	// Maps the hex numerical values 0x0 to 0xf to the corresponding ASCII digit
	// that will be used to represent it.
	URL_EXPORT extern const char kHexCharLookup[0x10];

	// This lookup table allows fast conversion between ASCII hex letters and their
	// corresponding numerical value. The 8-bit range is divided up into 8
	// regions of 0x20 characters each. Each of the three character types (numbers,
	// uppercase, lowercase) falls into different regions of this range. The table
	// contains the amount to subtract from characters in that range to get at
	// the corresponding numerical value.
	//
	// See HexDigitToValue for the lookup.
	extern const char kCharToHexLookup[8];

	// Assumes the input is a valid hex digit! Call IsHexChar before using this.
	inline unsigned char HexCharToValue(unsigned char c) {
	return c - kCharToHexLookup[c / 0x20];
	}

	// Indicates if the given character is a dot or dot equivalent, returning the
	// number of characters taken by it. This will be one for a literal dot, 3 for
	// an escaped dot. If the character is not a dot, this will return 0.
	template<typename CHAR>
	inline int IsDot(const CHAR* spec, int offset, int end) {
	if (spec[offset] == '.') {
	return 1;
	} else if (spec[offset] == '%' && offset + 3 <= end &&
	spec[offset + 1] == '2' &&
	(spec[offset + 2] == 'e' \|\| spec[offset + 2] == 'E')) {
	// Found "%2e"
	return 3;
	}
	return 0;
	}

	// Returns the canonicalized version of the input character according to scheme
	// rules. This is implemented alongside the scheme canonicalizer, and is
	// required for relative URL resolving to test for scheme equality.
	//
	// Returns 0 if the input character is not a valid scheme character.
	char CanonicalSchemeChar(base::char16 ch);

	// Write a single character, escaped, to the output. This always escapes: it
	// does no checking that thee character requires escaping.
	// Escaping makes sense only 8 bit chars, so code works in all cases of
	// input parameters (8/16bit).
	template<typename UINCHAR, typename OUTCHAR>
	inline void AppendEscapedChar(UINCHAR ch,
	CanonOutputT<OUTCHAR>* output) {
	output->push_back('%');
	output->push_back(kHexCharLookup[(ch >> 4) & 0xf]);
	output->push_back(kHexCharLookup[ch & 0xf]);
	}

	// The character we'll substitute for undecodable or invalid characters.
	extern const base::char16 kUnicodeReplacementCharacter;

	// UTF-8 functions ------------------------------------------------------------

	// Reads one character in UTF-8 starting at \|*begin\| in \|str\| and places
	// the decoded value into \|*code_point\|. If the character is valid, we will
	// return true. If invalid, we'll return false and put the
	// kUnicodeReplacementCharacter into \|*code_point\|.
	//
	// \|*begin\| will be updated to point to the last character consumed so it
	// can be incremented in a loop and will be ready for the next character.
	// (for a single-byte ASCII character, it will not be changed).
	URL_EXPORT bool ReadUTFChar(const char* str, int* begin, int length,
	unsigned* code_point_out);

	// Generic To-UTF-8 converter. This will call the given append method for each
	// character that should be appended, with the given output method. Wrappers
	// are provided below for escaped and non-escaped versions of this.
	//
	// The char_value must have already been checked that it's a valid Unicode
	// character.
	template<class Output, void Appender(unsigned char, Output*)>
	inline void DoAppendUTF8(unsigned char_value, Output* output) {
	if (char_value <= 0x7f) {
	Appender(static_cast<unsigned char>(char_value), output);
	} else if (char_value <= 0x7ff) {
	// 110xxxxx 10xxxxxx
	Appender(static_cast<unsigned char>(0xC0 \| (char_value >> 6)),
	output);
	Appender(static_cast<unsigned char>(0x80 \| (char_value & 0x3f)),
	output);
	} else if (char_value <= 0xffff) {
	// 1110xxxx 10xxxxxx 10xxxxxx
	Appender(static_cast<unsigned char>(0xe0 \| (char_value >> 12)),
	output);
	Appender(static_cast<unsigned char>(0x80 \| ((char_value >> 6) & 0x3f)),
	output);
	Appender(static_cast<unsigned char>(0x80 \| (char_value & 0x3f)),
	output);
	} else if (char_value <= 0x10FFFF) { // Max Unicode code point.
	// 11110xxx 10xxxxxx 10xxxxxx 10xxxxxx
	Appender(static_cast<unsigned char>(0xf0 \| (char_value >> 18)),
	output);
	Appender(static_cast<unsigned char>(0x80 \| ((char_value >> 12) & 0x3f)),
	output);
	Appender(static_cast<unsigned char>(0x80 \| ((char_value >> 6) & 0x3f)),
	output);
	Appender(static_cast<unsigned char>(0x80 \| (char_value & 0x3f)),
	output);
	} else {
	// Invalid UTF-8 character (>20 bits).
	NOTREACHED();
	}
	}

	// Helper used by AppendUTF8Value below. We use an unsigned parameter so there
	// are no funny sign problems with the input, but then have to convert it to
	// a regular char for appending.
	inline void AppendCharToOutput(unsigned char ch, CanonOutput* output) {
	output->push_back(static_cast<char>(ch));
	}

	// Writes the given character to the output as UTF-8. This does NO checking
	// of the validity of the Unicode characters; the caller should ensure that
	// the value it is appending is valid to append.
	inline void AppendUTF8Value(unsigned char_value, CanonOutput* output) {
	DoAppendUTF8<CanonOutput, AppendCharToOutput>(char_value, output);
	}

	// Writes the given character to the output as UTF-8, escaping ALL
	// characters (even when they are ASCII). This does NO checking of the
	// validity of the Unicode characters; the caller should ensure that the value
	// it is appending is valid to append.
	inline void AppendUTF8EscapedValue(unsigned char_value, CanonOutput* output) {
	DoAppendUTF8<CanonOutput, AppendEscapedChar>(char_value, output);
	}

	// UTF-16 functions -----------------------------------------------------------

	// Reads one character in UTF-16 starting at \|*begin\| in \|str\| and places
	// the decoded value into \|*code_point\|. If the character is valid, we will
	// return true. If invalid, we'll return false and put the
	// kUnicodeReplacementCharacter into \|*code_point\|.
	//
	// \|*begin\| will be updated to point to the last character consumed so it
	// can be incremented in a loop and will be ready for the next character.
	// (for a single-16-bit-word character, it will not be changed).
	URL_EXPORT bool ReadUTFChar(const base::char16* str, int* begin, int length,
	unsigned* code_point_out);

	// Equivalent to U16_APPEND_UNSAFE in ICU but uses our output method.
	inline void AppendUTF16Value(unsigned code_point,
	CanonOutputT<base::char16>* output) {
	if (code_point > 0xffff) {
	output->push_back(static_cast<base::char16>((code_point >> 10) + 0xd7c0));
	output->push_back(static_cast<base::char16>((code_point & 0x3ff) \| 0xdc00));
	} else {
	output->push_back(static_cast<base::char16>(code_point));
	}
	}

	// Escaping functions ---------------------------------------------------------

	// Writes the given character to the output as UTF-8, escaped. Call this
	// function only when the input is wide. Returns true on success. Failure
	// means there was some problem with the encoding, we'll still try to
	// update the \|*begin\| pointer and add a placeholder character to the
	// output so processing can continue.
	//
	// We will append the character starting at ch[begin] with the buffer ch
	// being \|length\|. \|*begin\| will be updated to point to the last character
	// consumed (we may consume more than one for UTF-16) so that if called in
	// a loop, incrementing the pointer will move to the next character.
	//
	// Every single output character will be escaped. This means that if you
	// give it an ASCII character as input, it will be escaped. Some code uses
	// this when it knows that a character is invalid according to its rules
	// for validity. If you don't want escaping for ASCII characters, you will
	// have to filter them out prior to calling this function.
	//
	// Assumes that ch[begin] is within range in the array, but does not assume
	// that any following characters are.
	inline bool AppendUTF8EscapedChar(const base::char16* str, int* begin,
	int length, CanonOutput* output) {
	// UTF-16 input. ReadUTFChar will handle invalid characters for us and give
	// us the kUnicodeReplacementCharacter, so we don't have to do special
	// checking after failure, just pass through the failure to the caller.
	unsigned char_value;
	bool success = ReadUTFChar(str, begin, length, &char_value);
	AppendUTF8EscapedValue(char_value, output);
	return success;
	}

	// Handles UTF-8 input. See the wide version above for usage.
	inline bool AppendUTF8EscapedChar(const char* str, int* begin, int length,
	CanonOutput* output) {
	// ReadUTF8Char will handle invalid characters for us and give us the
	// kUnicodeReplacementCharacter, so we don't have to do special checking
	// after failure, just pass through the failure to the caller.
	unsigned ch;
	bool success = ReadUTFChar(str, begin, length, &ch);
	AppendUTF8EscapedValue(ch, output);
	return success;
	}

	// Given a '%' character at \|*begin\| in the string \|spec\|, this will decode
	// the escaped value and put it into \|*unescaped_value\| on success (returns
	// true). On failure, this will return false, and will not write into
	// \|*unescaped_value\|.
	//
	// \|*begin\| will be updated to point to the last character of the escape
	// sequence so that when called with the index of a for loop, the next time
	// through it will point to the next character to be considered. On failure,
	// \|*begin\| will be unchanged.
	inline bool Is8BitChar(char c) {
	return true; // this case is specialized to avoid a warning
	}
	inline bool Is8BitChar(base::char16 c) {
	return c <= 255;
	}

	template<typename CHAR>
	inline bool DecodeEscaped(const CHAR* spec, int* begin, int end,
	unsigned char* unescaped_value) {
	if (*begin + 3 > end \|\|
	!Is8BitChar(spec[begin + 1]) \|\| !Is8BitChar(spec[begin + 2])) {
	// Invalid escape sequence because there's not enough room, or the
	// digits are not ASCII.
	return false;
	}

	unsigned char first = static_cast<unsigned char>(spec[*begin + 1]);
	unsigned char second = static_cast<unsigned char>(spec[*begin + 2]);
	if (!IsHexChar(first) \|\| !IsHexChar(second)) {
	// Invalid hex digits, fail.
	return false;
	}

	// Valid escape sequence.
	*unescaped_value = (HexCharToValue(first) << 4) + HexCharToValue(second);
	*begin += 2;
	return true;
	}

	// Appends the given substring to the output, escaping "some" characters that
	// it feels may not be safe. It assumes the input values are all contained in
	// 8-bit although it allows any type.
	//
	// This is used in error cases to append invalid output so that it looks
	// approximately correct. Non-error cases should not call this function since
	// the escaping rules are not guaranteed!
	void AppendInvalidNarrowString(const char* spec, int begin, int end,
	CanonOutput* output);
	void AppendInvalidNarrowString(const base::char16* spec, int begin, int end,
	CanonOutput* output);

	// Misc canonicalization helpers ----------------------------------------------

	// Converts between UTF-8 and UTF-16, returning true on successful conversion.
	// The output will be appended to the given canonicalizer output (so make sure
	// it's empty if you want to replace).
	//
	// On invalid input, this will still write as much output as possible,
	// replacing the invalid characters with the "invalid character". It will
	// return false in the failure case, and the caller should not continue as
	// normal.
	URL_EXPORT bool ConvertUTF16ToUTF8(const base::char16* input, int input_len,
	CanonOutput* output);
	URL_EXPORT bool ConvertUTF8ToUTF16(const char* input, int input_len,
	CanonOutputT<base::char16>* output);

	// Converts from UTF-16 to 8-bit using the character set converter. If the
	// converter is NULL, this will use UTF-8.
	void ConvertUTF16ToQueryEncoding(const base::char16* input,
	const Component& query,
	CharsetConverter* converter,
	CanonOutput* output);

	// Applies the replacements to the given component source. The component source
	// should be pre-initialized to the "old" base. That is, all pointers will
	// point to the spec of the old URL, and all of the Parsed components will
	// be indices into that string.
	//
	// The pointers and components in the \|source\| for all non-NULL strings in the
	// \|repl\| (replacements) will be updated to reference those strings.
	// Canonicalizing with the new \|source\| and \|parsed\| can then combine URL
	// components from many different strings.
	void SetupOverrideComponents(const char* base,
	const Replacements<char>& repl,
	URLComponentSource<char>* source,
	Parsed* parsed);

	// Like the above 8-bit version, except that it additionally converts the
	// UTF-16 input to UTF-8 before doing the overrides.
	//
	// The given utf8_buffer is used to store the converted components. They will
	// be appended one after another, with the parsed structure identifying the
	// appropriate substrings. This buffer is a parameter because the source has
	// no storage, so the buffer must have the same lifetime as the source
	// parameter owned by the caller.
	//
	// THE CALLER MUST NOT ADD TO THE \|utf8_buffer\| AFTER THIS CALL. Members of
	// \|source\| will point into this buffer, which could be invalidated if
	// additional data is added and the CanonOutput resizes its buffer.
	//
	// Returns true on success. False means that the input was not valid UTF-16,
	// although we will have still done the override with "invalid characters" in
	// place of errors.
	bool SetupUTF16OverrideComponents(const char* base,
	const Replacements<base::char16>& repl,
	CanonOutput* utf8_buffer,
	URLComponentSource<char>* source,
	Parsed* parsed);

	// Implemented in url_canon_path.cc, these are required by the relative URL
	// resolver as well, so we declare them here.
	bool CanonicalizePartialPath(const char* spec,
	const Component& path,
	int path_begin_in_output,
	CanonOutput* output);
	bool CanonicalizePartialPath(const base::char16* spec,
	const Component& path,
	int path_begin_in_output,
	CanonOutput* output);

	#if !defined(WIN32) \|\| defined(STARBOARD)

	// Implementations of Windows' int-to-string conversions
	URL_EXPORT int _itoa_s(int value, char* buffer, size_t size_in_chars,
	int radix);
	URL_EXPORT int _itow_s(int value, base::char16* buffer, size_t size_in_chars,
	int radix);

	// Secure template overloads for these functions
	template<size_t N>
	inline int _itoa_s(int value, char (&buffer)[N], int radix) {
	return _itoa_s(value, buffer, N, radix);
	}

	template<size_t N>
	inline int _itow_s(int value, base::char16 (&buffer)[N], int radix) {
	return _itow_s(value, buffer, N, radix);
	}

	// _strtoui64 and strtoull behave the same
	inline unsigned long long _strtoui64(const char* nptr,
	char** endptr, int base) {
	#if defined(STARBOARD)
	return SbStringParseUInt64(nptr, endptr, base);
	#else
	return strtoull(nptr, endptr, base);
	#endif
	}

	#endif // WIN32

	} // namespace url

	#endif // URL_URL_CANON_INTERNAL_H_