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|
<?php
/**
*
* @package phpBB3
* @version $Id$
* @copyright (c) 2005 phpBB Group
* @license http://opensource.org/licenses/gpl-license.php GNU Public License
*
*/
/**
* Some Unicode characters encoded in UTF-8
*
* Preserved for compatibility
*/
define('UTF8_REPLACEMENT', "\xEF\xBF\xBD");
define('UTF8_MAX', "\xF4\x8F\xBF\xBF");
define('UTF8_FFFE', "\xEF\xBF\xBE");
define('UTF8_FFFF', "\xEF\xBF\xBF");
define('UTF8_SURROGATE_FIRST', "\xED\xA0\x80");
define('UTF8_SURROGATE_LAST', "\xED\xBF\xBF");
define('UTF8_HANGUL_FIRST', "\xEA\xB0\x80");
define('UTF8_HANGUL_LAST', "\xED\x9E\xA3");
define('UTF8_CJK_FIRST', "\xE4\xB8\x80");
define('UTF8_CJK_LAST', "\xE9\xBE\xBB");
define('UTF8_CJK_B_FIRST', "\xF0\xA0\x80\x80");
define('UTF8_CJK_B_LAST', "\xF0\xAA\x9B\x96");
// Unset global variables
unset($GLOBALS['utf_jamo_index'], $GLOBALS['utf_jamo_type'], $GLOBALS['utf_nfc_qc'], $GLOBALS['utf_combining_class'], $GLOBALS['utf_canonical_comp'], $GLOBALS['utf_canonical_decomp'], $GLOBALS['utf_nfkc_qc'], $GLOBALS['utf_compatibility_decomp']);
// NFC_QC and NFKC_QC values
define('UNICODE_QC_MAYBE', 0);
define('UNICODE_QC_NO', 1);
// Contains all the ASCII characters appearing in UTF-8, sorted by frequency
define('UTF8_ASCII_RANGE', "\x20\x65\x69\x61\x73\x6E\x74\x72\x6F\x6C\x75\x64\x5D\x5B\x63\x6D\x70\x27\x0A\x67\x7C\x68\x76\x2E\x66\x62\x2C\x3A\x3D\x2D\x71\x31\x30\x43\x32\x2A\x79\x78\x29\x28\x4C\x39\x41\x53\x2F\x50\x22\x45\x6A\x4D\x49\x6B\x33\x3E\x35\x54\x3C\x44\x34\x7D\x42\x7B\x38\x46\x77\x52\x36\x37\x55\x47\x4E\x3B\x4A\x7A\x56\x23\x48\x4F\x57\x5F\x26\x21\x4B\x3F\x58\x51\x25\x59\x5C\x09\x5A\x2B\x7E\x5E\x24\x40\x60\x7F\x00\x01\x02\x03\x04\x05\x06\x07\x08\x0B\x0C\x0D\x0E\x0F\x10\x11\x12\x13\x14\x15\x16\x17\x18\x19\x1A\x1B\x1C\x1D\x1E\x1F");
// Contains all the tail bytes that can appear in the composition of a UTF-8 char
define('UTF8_TRAILING_BYTES', "\xA9\xA0\xA8\x80\xAA\x99\xA7\xBB\xAB\x89\x94\x82\xB4\xA2\xAE\x83\xB0\xB9\xB8\x93\xAF\xBC\xB3\x81\xA4\xB2\x9C\xA1\xB5\xBE\xBD\xBA\x98\xAD\xB1\x84\x95\xA6\xB6\x88\x8D\x90\xB7\xBF\x92\x85\xA5\x97\x8C\x86\xA3\x8E\x9F\x8F\x87\x91\x9D\xAC\x9E\x8B\x96\x9B\x8A\x9A");
// Constants used by the Hangul [de]composition algorithms
define('UNICODE_HANGUL_SBASE', 0xAC00);
define('UNICODE_HANGUL_LBASE', 0x1100);
define('UNICODE_HANGUL_VBASE', 0x1161);
define('UNICODE_HANGUL_TBASE', 0x11A7);
define('UNICODE_HANGUL_SCOUNT', 11172);
define('UNICODE_HANGUL_LCOUNT', 19);
define('UNICODE_HANGUL_VCOUNT', 21);
define('UNICODE_HANGUL_TCOUNT', 28);
define('UNICODE_HANGUL_NCOUNT', 588);
define('UNICODE_JAMO_L', 0);
define('UNICODE_JAMO_V', 1);
define('UNICODE_JAMO_T', 2);
/**
* Unicode normalization routines
*
* @package phpBB3
*/
class utf_normalizer
{
/**
* Validate, cleanup and normalize a string
*
* The ultimate convenience function! Clean up invalid UTF-8 sequences,
* and convert to Normal Form C, canonical composition.
*
* @param string &$str The dirty string
* @return string The same string, all shiny and cleaned-up
*/
function cleanup(&$str)
{
// The string below is the list of all autorized characters, sorted by frequency in latin text
$pos = strspn($str, "\x20\x65\x69\x61\x73\x6E\x74\x72\x6F\x6C\x75\x64\x5D\x5B\x63\x6D\x70\x27\x0A\x67\x7C\x68\x76\x2E\x66\x62\x2C\x3A\x3D\x2D\x71\x31\x30\x43\x32\x2A\x79\x78\x29\x28\x4C\x39\x41\x53\x2F\x50\x22\x45\x6A\x4D\x49\x6B\x33\x3E\x35\x54\x3C\x44\x34\x7D\x42\x7B\x38\x46\x77\x52\x36\x37\x55\x47\x4E\x3B\x4A\x7A\x56\x23\x48\x4F\x57\x5F\x26\x21\x4B\x3F\x58\x51\x25\x59\x5C\x09\x5A\x2B\x7E\x5E\x24\x40\x60\x7F\x0D");
$len = strlen($str);
if ($pos == $len)
{
// ASCII strings with no special chars return immediately
return;
}
// Note: we do not check for $GLOBALS['utf_canonical_decomp']. It is assumed they are always loaded together
if (!isset($GLOBALS['utf_nfc_qc']))
{
global $phpbb_root_path, $phpEx;
include($phpbb_root_path . 'includes/utf/data/utf_nfc_qc.' . $phpEx);
}
// Replace any byte in the range 0x00..0x1F, except for \r, \n and \t
// We replace those characters with a 0xFF byte, which is illegal in UTF-8 and will in turn be replaced with a UTF replacement char
$str = strtr(
$str,
"\x00\x01\x02\x03\x04\x05\x06\x07\x08\x0B\x0C\x0E\x0F\x10\x11\x12\x13\x14\x15\x16\x17\x18\x19\x1A\x1B\x1C\x1D\x1E\x1F",
"\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF"
);
$str = utf_normalizer::recompose($str, $pos, $len, $GLOBALS['utf_nfc_qc'], $GLOBALS['utf_canonical_decomp']);
}
/**
* Validate and normalize a UTF string to NFC
*
* @param string &$str Unchecked UTF string
* @return string The string, validated and in normal form
*/
function nfc(&$str)
{
$pos = strspn($str, UTF8_ASCII_RANGE);
$len = strlen($str);
if ($pos == $len)
{
// ASCII strings return immediately
return;
}
if (!isset($GLOBALS['utf_nfc_qc']))
{
global $phpbb_root_path, $phpEx;
include($phpbb_root_path . 'includes/utf/data/utf_nfc_qc.' . $phpEx);
}
$str = utf_normalizer::recompose($str, $pos, $len, $GLOBALS['utf_nfc_qc'], $GLOBALS['utf_canonical_decomp']);
}
/**
* Validate and normalize a UTF string to NFKC
*
* @param string &$str Unchecked UTF string
* @return string The string, validated and in normal form
*/
function nfkc(&$str)
{
$pos = strspn($str, UTF8_ASCII_RANGE);
$len = strlen($str);
if ($pos == $len)
{
// ASCII strings return immediately
return;
}
if (!isset($GLOBALS['utf_nfkc_qc']))
{
global $phpbb_root_path, $phpEx;
include($phpbb_root_path . 'includes/utf/data/utf_nfkc_qc.' . $phpEx);
}
if (!isset($GLOBALS['utf_canonical_comp']))
{
global $phpbb_root_path, $phpEx;
include($phpbb_root_path . 'includes/utf/data/utf_canonical_comp.' . $phpEx);
}
$str = utf_normalizer::recompose($str, $pos, $len, $GLOBALS['utf_nfkc_qc'], $GLOBALS['utf_compatibility_decomp']);
}
/**
* Validate and normalize a UTF string to NFD
*
* @param string &$str Unchecked UTF string
* @return string The string, validated and in normal form
*/
function nfd(&$str)
{
$pos = strspn($str, UTF8_ASCII_RANGE);
$len = strlen($str);
if ($pos == $len)
{
// ASCII strings return immediately
return;
}
if (!isset($GLOBALS['utf_canonical_decomp']))
{
global $phpbb_root_path, $phpEx;
include($phpbb_root_path . 'includes/utf/data/utf_canonical_decomp.' . $phpEx);
}
$str = utf_normalizer::decompose($str, $pos, $len, $GLOBALS['utf_canonical_decomp']);
}
/**
* Validate and normalize a UTF string to NFKD
*
* @param string &$str Unchecked UTF string
* @return string The string, validated and in normal form
*/
function nfkd(&$str)
{
$pos = strspn($str, UTF8_ASCII_RANGE);
$len = strlen($str);
if ($pos == $len)
{
// ASCII strings return immediately
return;
}
if (!isset($GLOBALS['utf_compatibility_decomp']))
{
global $phpbb_root_path, $phpEx;
include($phpbb_root_path . 'includes/utf/data/utf_compatibility_decomp.' . $phpEx);
}
$str = utf_normalizer::decompose($str, $pos, $len, $GLOBALS['utf_compatibility_decomp']);
}
/**
* Recompose a UTF string
*
* @param string $str Unchecked UTF string
* @param integer $pos Position of the first UTF char (in bytes)
* @param integer $len Length of the string (in bytes)
* @param array &$qc Quick-check array, passed by reference but never modified
* @param array &$decomp_map Decomposition mapping, passed by reference but never modified
* @return string The string, validated and recomposed
*
* @access private
*/
function recompose($str, $pos, $len, &$qc, &$decomp_map)
{
global $utf_combining_class, $utf_canonical_comp, $utf_jamo_type, $utf_jamo_index;
// Load some commonly-used tables
if (!isset($utf_jamo_index, $utf_jamo_type, $utf_combining_class))
{
global $phpbb_root_path, $phpEx;
include($phpbb_root_path . 'includes/utf/data/utf_normalizer_common.' . $phpEx);
}
// Buffer the last ASCII char before the UTF-8 stuff if applicable
$tmp = '';
$i = $tmp_pos = $last_cc = 0;
$buffer = ($pos) ? array(++$i => $str[$pos - 1]) : array();
// UTF char length array
// This array is used to determine the length of a UTF character.
// Be $c the result of ($str[$pos] & "\xF0") --where $str is the string we're operating on and $pos
// the position of the cursor--, if $utf_len_mask[$c] does not exist, the byte is an ASCII char.
// Otherwise, if $utf_len_mask[$c] is greater than 0, we have a the leading byte of a multibyte character
// whose length is $utf_len_mask[$c] and if it is equal to 0, the byte is a trailing byte.
$utf_len_mask = array(
// Leading bytes masks
"\xC0" => 2, "\xD0" => 2, "\xE0" => 3, "\xF0" => 4,
// Trailing bytes masks
"\x80" => 0, "\x90" => 0, "\xA0" => 0, "\xB0" => 0
);
$extra_check = array(
"\xED" => 1, "\xEF" => 1, "\xC0" => 1, "\xC1" => 1, "\xE0" => 1, "\xF0" => 1,
"\xF4" => 1, "\xF5" => 1, "\xF6" => 1, "\xF7" => 1, "\xF8" => 1, "\xF9" => 1,
"\xFA" => 1, "\xFB" => 1, "\xFC" => 1, "\xFD" => 1, "\xFE" => 1, "\xFF" => 1
);
$utf_validation_mask = array(
2 => "\xE0\xC0",
3 => "\xF0\xC0\xC0",
4 => "\xF8\xC0\xC0\xC0"
);
$utf_validation_check = array(
2 => "\xC0\x80",
3 => "\xE0\x80\x80",
4 => "\xF0\x80\x80\x80"
);
// Main loop
do
{
// STEP 0: Capture the current char and buffer it
$c = $str[$pos];
$c_mask = $c & "\xF0";
if (isset($utf_len_mask[$c_mask]))
{
// Byte at $pos is either a leading byte or a missplaced trailing byte
if ($utf_len = $utf_len_mask[$c_mask])
{
// Capture the char
$buffer[++$i & 7] = $utf_char = substr($str, $pos, $utf_len);
// Let's find out if a thorough check is needed
if (isset($qc[$utf_char]))
{
// If the UTF char is in the qc array then it may not be in normal form. We do nothing here, the actual processing is below this "if" block
}
else if (isset($utf_combining_class[$utf_char]))
{
if ($utf_combining_class[$utf_char] < $last_cc)
{
// A combining character that is NOT canonically ordered
}
else
{
// A combining character that IS canonically ordered, skip to the next char
$last_cc = $utf_combining_class[$utf_char];
$pos += $utf_len;
continue;
}
}
else
{
// At this point, $utf_char holds a UTF char that we know is not a NF[K]C_QC and is not a combining character.
// It can be a singleton, a canonical composite, a replacement char or an even an ill-formed bunch of bytes. Let's find out
$last_cc = 0;
// Check that we have the correct number of trailing bytes
if (($utf_char & $utf_validation_mask[$utf_len]) != $utf_validation_check[$utf_len])
{
// Current char isn't well-formed or legal: either one or several trailing bytes are missing, or the Unicode char
// has been encoded in a five- or six- byte sequence
if ($utf_char[0] >= "\xF8")
{
if ($utf_char[0] < "\xFC")
{
$trailing_bytes = 4;
}
else if ($utf_char[0] > "\xFD")
{
$trailing_bytes = 0;
}
else
{
$trailing_bytes = 5;
}
}
else
{
$trailing_bytes = $utf_len - 1;
}
$tmp .= substr($str, $tmp_pos, $pos - $tmp_pos) . UTF8_REPLACEMENT;
$pos += strspn($str, UTF8_TRAILING_BYTES, ++$pos, $trailing_bytes);
$tmp_pos = $pos;
continue;
}
if (isset($extra_check[$c]))
{
switch ($c)
{
// Note: 0xED is quite common in Korean
case "\xED":
if ($utf_char >= "\xED\xA0\x80")
{
// Surrogates (U+D800..U+DFFF) are not allowed in UTF-8 (UTF sequence 0xEDA080..0xEDBFBF)
$tmp .= substr($str, $tmp_pos, $pos - $tmp_pos) . UTF8_REPLACEMENT;
$pos += $utf_len;
$tmp_pos = $pos;
continue 2;
}
break;
// Note: 0xEF is quite common in Japanese
case "\xEF":
if ($utf_char == "\xEF\xBF\xBE" || $utf_char == "\xEF\xBF\xBF")
{
// U+FFFE and U+FFFF are explicitly disallowed (UTF sequence 0xEFBFBE..0xEFBFBF)
$tmp .= substr($str, $tmp_pos, $pos - $tmp_pos) . UTF8_REPLACEMENT;
$pos += $utf_len;
$tmp_pos = $pos;
continue 2;
}
break;
case "\xC0":
case "\xC1":
if ($utf_char <= "\xC1\xBF")
{
// Overlong sequence: Unicode char U+0000..U+007F encoded as a double-byte UTF char
$tmp .= substr($str, $tmp_pos, $pos - $tmp_pos) . UTF8_REPLACEMENT;
$pos += $utf_len;
$tmp_pos = $pos;
continue 2;
}
break;
case "\xE0":
if ($utf_char <= "\xE0\x9F\xBF")
{
// Unicode char U+0000..U+07FF encoded in 3 bytes
$tmp .= substr($str, $tmp_pos, $pos - $tmp_pos) . UTF8_REPLACEMENT;
$pos += $utf_len;
$tmp_pos = $pos;
continue 2;
}
break;
case "\xF0":
if ($utf_char <= "\xF0\x8F\xBF\xBF")
{
// Unicode char U+0000..U+FFFF encoded in 4 bytes
$tmp .= substr($str, $tmp_pos, $pos - $tmp_pos) . UTF8_REPLACEMENT;
$pos += $utf_len;
$tmp_pos = $pos;
continue 2;
}
break;
default:
// Five- and six- byte sequences do not need being checked for here anymore
if ($utf_char > UTF8_MAX)
{
// Out of the Unicode range
if ($utf_char[0] < "\xF8")
{
$trailing_bytes = 3;
}
else if ($utf_char[0] < "\xFC")
{
$trailing_bytes = 4;
}
else if ($utf_char[0] > "\xFD")
{
$trailing_bytes = 0;
}
else
{
$trailing_bytes = 5;
}
$tmp .= substr($str, $tmp_pos, $pos - $tmp_pos) . UTF8_REPLACEMENT;
$pos += strspn($str, UTF8_TRAILING_BYTES, ++$pos, $trailing_bytes);
$tmp_pos = $pos;
continue 2;
}
break;
}
}
// The char is a valid starter, move the cursor and go on
$pos += $utf_len;
continue;
}
}
else
{
// A trailing byte came out of nowhere, we will advance the cursor and treat the this byte and all following trailing bytes as if
// each of them was a Unicode replacement char
$spn = strspn($str, UTF8_TRAILING_BYTES, $pos);
$tmp .= substr($str, $tmp_pos, $pos - $tmp_pos) . str_repeat(UTF8_REPLACEMENT, $spn);
$pos += $spn;
$tmp_pos = $pos;
continue;
}
// STEP 1: Decompose current char
// We have found a character that is either:
// - in the NFC_QC/NFKC_QC list
// - a non-starter char that is not canonically ordered
//
// We are going to capture the shortest UTF sequence that satisfies these two conditions:
//
// 1 - If the sequence does not start at the begginning of the string, it must begin with a starter,
// and that starter must not have the NF[K]C_QC property equal to "MAYBE"
//
// 2 - If the sequence does not end at the end of the string, it must end with a non-starter and be
// immediately followed by a starter that is not on the QC list
//
$utf_seq = array();
$last_cc = 0;
$lpos = $pos;
$pos += $utf_len;
if (isset($decomp_map[$utf_char]))
{
$_pos = 0;
$_len = strlen($decomp_map[$utf_char]);
do
{
$_utf_len =& $utf_len_mask[$decomp_map[$utf_char][$_pos] & "\xF0"];
if (isset($_utf_len))
{
$utf_seq[] = substr($decomp_map[$utf_char], $_pos, $_utf_len);
$_pos += $_utf_len;
}
else
{
$utf_seq[] = $decomp_map[$utf_char][$_pos];
++$_pos;
}
}
while ($_pos < $_len);
}
else
{
// The char is not decomposable
$utf_seq = array($utf_char);
}
// STEP 2: Capture the starter
// Check out the combining class of the first character of the UTF sequence
$k = 0;
if (isset($utf_combining_class[$utf_seq[0]]) || $qc[$utf_char] == UNICODE_QC_MAYBE)
{
// Not a starter, inspect previous characters
// The last 8 characters are kept in a buffer so that we don't have to capture them everytime.
// This is enough for all real-life strings but even if it wasn't, we can capture characters in backward mode,
// although it is slower than this method.
//
// In the following loop, $j starts at the previous buffered character ($i - 1, because current character is
// at offset $i) and process them in backward mode until we find a starter.
//
// $k is the index on each UTF character inside of our UTF sequence. At this time, $utf_seq contains one or more
// characters numbered 0 to n. $k starts at 0 and for each char we prepend we pre-decrement it and for numbering
$starter_found = 0;
$j_min = max(1, $i - 7);
for ($j = $i - 1; $j >= $j_min && $lpos > $tmp_pos; --$j)
{
$utf_char = $buffer[$j & 7];
$lpos -= strlen($utf_char);
if (isset($decomp_map[$utf_char]))
{
// The char is a composite, decompose for storage
$decomp_seq = array();
$_pos = 0;
$_len = strlen($decomp_map[$utf_char]);
do
{
$c = $decomp_map[$utf_char][$_pos];
$_utf_len =& $utf_len_mask[$c & "\xF0"];
if (isset($_utf_len))
{
$decomp_seq[] = substr($decomp_map[$utf_char], $_pos, $_utf_len);
$_pos += $_utf_len;
}
else
{
$decomp_seq[] = $c;
++$_pos;
}
}
while ($_pos < $_len);
// Prepend the UTF sequence with our decomposed sequence
if (isset($decomp_seq[1]))
{
// The char expanded into several chars
$decomp_cnt = sizeof($decomp_seq);
foreach ($decomp_seq as $decomp_i => $decomp_char)
{
$utf_seq[$k + $decomp_i - $decomp_cnt] = $decomp_char;
}
$k -= $decomp_cnt;
}
else
{
// Decomposed to a single char, easier to prepend
$utf_seq[--$k] = $decomp_seq[0];
}
}
else
{
$utf_seq[--$k] = $utf_char;
}
if (!isset($utf_combining_class[$utf_seq[$k]]))
{
// We have found our starter
$starter_found = 1;
break;
}
}
if (!$starter_found && $lpos > $tmp_pos)
{
// The starter was not found in the buffer, let's rewind some more
do
{
// $utf_len_mask contains the masks of both leading bytes and trailing bytes. If $utf_en > 0 then it's a leading byte, otherwise it's a trailing byte.
$c = $str[--$lpos];
$c_mask = $c & "\xF0";
if (isset($utf_len_mask[$c_mask]))
{
// UTF byte
if ($utf_len = $utf_len_mask[$c_mask])
{
// UTF *leading* byte
$utf_char = substr($str, $lpos, $utf_len);
if (isset($decomp_map[$utf_char]))
{
// Decompose the character
$decomp_seq = array();
$_pos = 0;
$_len = strlen($decomp_map[$utf_char]);
do
{
$c = $decomp_map[$utf_char][$_pos];
$_utf_len =& $utf_len_mask[$c & "\xF0"];
if (isset($_utf_len))
{
$decomp_seq[] = substr($decomp_map[$utf_char], $_pos, $_utf_len);
$_pos += $_utf_len;
}
else
{
$decomp_seq[] = $c;
++$_pos;
}
}
while ($_pos < $_len);
// Prepend the UTF sequence with our decomposed sequence
if (isset($decomp_seq[1]))
{
// The char expanded into several chars
$decomp_cnt = sizeof($decomp_seq);
foreach ($decomp_seq as $decomp_i => $utf_char)
{
$utf_seq[$k + $decomp_i - $decomp_cnt] = $utf_char;
}
$k -= $decomp_cnt;
}
else
{
// Decomposed to a single char, easier to prepend
$utf_seq[--$k] = $decomp_seq[0];
}
}
else
{
$utf_seq[--$k] = $utf_char;
}
}
}
else
{
// ASCII char
$utf_seq[--$k] = $c;
}
}
while ($lpos > $tmp_pos);
}
}
// STEP 3: Capture following combining modifiers
while ($pos < $len)
{
$c_mask = $str[$pos] & "\xF0";
if (isset($utf_len_mask[$c_mask]))
{
if ($utf_len = $utf_len_mask[$c_mask])
{
$utf_char = substr($str, $pos, $utf_len);
}
else
{
// A trailing byte came out of nowhere
// Trailing bytes are replaced with Unicode replacement chars, we will just ignore it for now, break out of the loop
// as if it was a starter (replacement chars ARE starters) and let the next loop replace it
break;
}
if (isset($utf_combining_class[$utf_char]) || isset($qc[$utf_char]))
{
// Combining character, add it to the sequence and move the cursor
if (isset($decomp_map[$utf_char]))
{
// Decompose the character
$_pos = 0;
$_len = strlen($decomp_map[$utf_char]);
do
{
$c = $decomp_map[$utf_char][$_pos];
$_utf_len =& $utf_len_mask[$c & "\xF0"];
if (isset($_utf_len))
{
$utf_seq[] = substr($decomp_map[$utf_char], $_pos, $_utf_len);
$_pos += $_utf_len;
}
else
{
$utf_seq[] = $c;
++$_pos;
}
}
while ($_pos < $_len);
}
else
{
$utf_seq[] = $utf_char;
}
$pos += $utf_len;
}
else
{
// Combining class 0 and no QC, break out of the loop
// Note: we do not know if that character is valid. If it's not, the next iteration will replace it
break;
}
}
else
{
// ASCII chars are starters
break;
}
}
// STEP 4: Sort and combine
// Here we sort...
$k_max = $k + sizeof($utf_seq);
if (!$k && $k_max == 1)
{
// There is only one char in the UTF sequence, add it then jump to the next iteration of main loop
// Note: the two commented lines below can be enabled under PHP5 for a very small performance gain in most cases
// if (substr_compare($str, $utf_seq[0], $lpos, $pos - $lpos))
// {
$tmp .= substr($str, $tmp_pos, $lpos - $tmp_pos) . $utf_seq[0];
$tmp_pos = $pos;
// }
continue;
}
// ...there we combine
if (isset($utf_combining_class[$utf_seq[$k]]))
{
$starter = $nf_seq = '';
}
else
{
$starter = $utf_seq[$k++];
$nf_seq = '';
}
$utf_sort = array();
// We add an empty char at the end of the UTF char sequence. It will act as a starter and trigger the sort/combine routine
// at the end of the string without altering it
$utf_seq[] = '';
do
{
$utf_char = $utf_seq[$k++];
if (isset($utf_combining_class[$utf_char]))
{
$utf_sort[$utf_combining_class[$utf_char]][] = $utf_char;
}
else
{
if (empty($utf_sort))
{
// No combining characters... check for a composite of the two starters
if (isset($utf_canonical_comp[$starter . $utf_char]))
{
// Good ol' composite character
$starter = $utf_canonical_comp[$starter . $utf_char];
}
else if (isset($utf_jamo_type[$utf_char]))
{
// Current char is a composable jamo
if (isset($utf_jamo_type[$starter]) && $utf_jamo_type[$starter] == UNICODE_JAMO_L && $utf_jamo_type[$utf_char] == UNICODE_JAMO_V)
{
// We have a L jamo followed by a V jamo, we are going to prefetch the next char to see if it's a T jamo
if (isset($utf_jamo_type[$utf_seq[$k]]) && $utf_jamo_type[$utf_seq[$k]] == UNICODE_JAMO_T)
{
// L+V+T jamos, combine to a LVT Hangul syllable ($k is incremented)
$cp = $utf_jamo_index[$starter] + $utf_jamo_index[$utf_char] + $utf_jamo_index[$utf_seq[$k]];
++$k;
}
else
{
// L+V jamos, combine to a LV Hangul syllable
$cp = $utf_jamo_index[$starter] + $utf_jamo_index[$utf_char];
}
$starter = chr(0xE0 | ($cp >> 12)) . chr(0x80 | (($cp >> 6) & 0x3F)) . chr(0x80 | ($cp & 0x3F));
}
else
{
// Non-composable jamo, just add it to the sequence
$nf_seq .= $starter;
$starter = $utf_char;
}
}
else
{
// No composite, just add the first starter to the sequence then continue with the other one
$nf_seq .= $starter;
$starter = $utf_char;
}
}
else
{
ksort($utf_sort);
// For each class of combining characters
foreach ($utf_sort as $cc => $utf_chars)
{
$j = 0;
do
{
// Look for a composite
if (isset($utf_canonical_comp[$starter . $utf_chars[$j]]))
{
// Found a composite, replace the starter
$starter = $utf_canonical_comp[$starter . $utf_chars[$j]];
unset($utf_sort[$cc][$j]);
}
else
{
// No composite, all following characters in that class are blocked
break;
}
}
while (isset($utf_sort[$cc][++$j]));
}
// Add the starter to the normalized sequence, followed by non-starters in canonical order
$nf_seq .= $starter;
foreach ($utf_sort as $utf_chars)
{
if (!empty($utf_chars))
{
$nf_seq .= implode('', $utf_chars);
}
}
// Reset the array and go on
$utf_sort = array();
$starter = $utf_char;
}
}
}
while ($k <= $k_max);
$tmp .= substr($str, $tmp_pos, $lpos - $tmp_pos) . $nf_seq;
$tmp_pos = $pos;
}
else
{
// Only a ASCII char can make the program get here
//
// First we skip the current byte with ++$pos, then we quickly skip following ASCII chars with strspn().
//
// The first two "if"'s here can be removed, with the consequences of being faster on latin text (lots of ASCII) and slower on
// multi-byte text (where the only ASCII chars are spaces and punctuation)
if (++$pos != $len)
{
if ($str[$pos] < "\x80")
{
$pos += strspn($str, UTF8_ASCII_RANGE, ++$pos);
$buffer[++$i & 7] = $str[$pos - 1];
}
else
{
$buffer[++$i & 7] = $c;
}
}
}
}
while ($pos < $len);
// Now is time to return the string
if ($tmp_pos)
{
// If the $tmp_pos cursor is not at the beggining of the string then at least one character was not in normal form. Replace $str with the fixed version
if ($tmp_pos == $len)
{
// The $tmp_pos cursor is at the end of $str, therefore $tmp holds the whole $str
return $tmp;
}
else
{
// The rightmost chunk of $str has not been appended to $tmp yet
return $tmp . substr($str, $tmp_pos);
}
}
// The string was already in normal form
return $str;
}
/**
* Decompose a UTF string
*
* @param string $str UTF string
* @param integer $pos Position of the first UTF char (in bytes)
* @param integer $len Length of the string (in bytes)
* @param array &$decomp_map Decomposition mapping, passed by reference but never modified
* @return string The string, decomposed and sorted canonically
*
* @access private
*/
function decompose($str, $pos, $len, &$decomp_map)
{
global $utf_combining_class;
// Load some commonly-used tables
if (!isset($utf_combining_class))
{
global $phpbb_root_path, $phpEx;
include($phpbb_root_path . 'includes/utf/data/utf_normalizer_common.' . $phpEx);
}
// UTF char length array
$utf_len_mask = array(
// Leading bytes masks
"\xC0" => 2, "\xD0" => 2, "\xE0" => 3, "\xF0" => 4,
// Trailing bytes masks
"\x80" => 0, "\x90" => 0, "\xA0" => 0, "\xB0" => 0
);
// Some extra checks are triggered on the first byte of a UTF sequence
$extra_check = array(
"\xED" => 1, "\xEF" => 1, "\xC0" => 1, "\xC1" => 1, "\xE0" => 1, "\xF0" => 1,
"\xF4" => 1, "\xF5" => 1, "\xF6" => 1, "\xF7" => 1, "\xF8" => 1, "\xF9" => 1,
"\xFA" => 1, "\xFB" => 1, "\xFC" => 1, "\xFD" => 1, "\xFE" => 1, "\xFF" => 1
);
// These masks are used to check if a UTF sequence is well formed. Here are the only 3 lengths we acknowledge:
// - 2-byte: 110? ???? 10?? ????
// - 3-byte: 1110 ???? 10?? ???? 10?? ????
// - 4-byte: 1111 0??? 10?? ???? 10?? ???? 10?? ????
// Note that 5- and 6- byte sequences are automatically discarded
$utf_validation_mask = array(
2 => "\xE0\xC0",
3 => "\xF0\xC0\xC0",
4 => "\xF8\xC0\xC0\xC0"
);
$utf_validation_check = array(
2 => "\xC0\x80",
3 => "\xE0\x80\x80",
4 => "\xF0\x80\x80\x80"
);
$tmp = '';
$starter_pos = $pos;
$tmp_pos = $last_cc = $sort = $dump = 0;
$utf_sort = array();
// Main loop
do
{
// STEP 0: Capture the current char
$cur_mask = $str[$pos] & "\xF0";
if (isset($utf_len_mask[$cur_mask]))
{
if ($utf_len = $utf_len_mask[$cur_mask])
{
// Multibyte char
$utf_char = substr($str, $pos, $utf_len);
$pos += $utf_len;
}
else
{
// A trailing byte came out of nowhere, we will treat it and all following trailing bytes as if each of them was a Unicode
// replacement char and we will advance the cursor
$spn = strspn($str, UTF8_TRAILING_BYTES, $pos);
if ($dump)
{
$tmp .= substr($str, $tmp_pos, $starter_pos - $tmp_pos);
// Dump combiners
if (!empty($utf_sort))
{
if ($sort)
{
ksort($utf_sort);
}
foreach ($utf_sort as $utf_chars)
{
$tmp .= implode('', $utf_chars);
}
}
$tmp .= str_repeat(UTF8_REPLACEMENT, $spn);
$dump = $sort = 0;
}
else
{
$tmp .= substr($str, $tmp_pos, $pos - $tmp_pos) . str_repeat(UTF8_REPLACEMENT, $spn);
}
$pos += $spn;
$tmp_pos = $starter_pos = $pos;
$utf_sort = array();
$last_cc = 0;
continue;
}
// STEP 1: Decide what to do with current char
// Now, in that order:
// - check if that character is decomposable
// - check if that character is a non-starter
// - check if that character requires extra checks to be performed
if (isset($decomp_map[$utf_char]))
{
// Decompose the char
$_pos = 0;
$_len = strlen($decomp_map[$utf_char]);
do
{
$c = $decomp_map[$utf_char][$_pos];
$_utf_len =& $utf_len_mask[$c & "\xF0"];
if (isset($_utf_len))
{
$_utf_char = substr($decomp_map[$utf_char], $_pos, $_utf_len);
$_pos += $_utf_len;
if (isset($utf_combining_class[$_utf_char]))
{
// The character decomposed to a non-starter, buffer it for sorting
$utf_sort[$utf_combining_class[$_utf_char]][] = $_utf_char;
if ($utf_combining_class[$_utf_char] < $last_cc)
{
// Not canonically ordered, will require sorting
$sort = $dump = 1;
}
else
{
$dump = 1;
$last_cc = $utf_combining_class[$_utf_char];
}
}
else
{
// This character decomposition contains a starter, dump the buffer and continue
if ($dump)
{
$tmp .= substr($str, $tmp_pos, $starter_pos - $tmp_pos);
// Dump combiners
if (!empty($utf_sort))
{
if ($sort)
{
ksort($utf_sort);
}
foreach ($utf_sort as $utf_chars)
{
$tmp .= implode('', $utf_chars);
}
}
$tmp .= $_utf_char;
$dump = $sort = 0;
}
else
{
$tmp .= substr($str, $tmp_pos, $starter_pos - $tmp_pos) . $_utf_char;
}
$tmp_pos = $starter_pos = $pos;
$utf_sort = array();
$last_cc = 0;
}
}
else
{
// This character decomposition contains an ASCII char, which is a starter. Dump the buffer and continue
++$_pos;
if ($dump)
{
$tmp .= substr($str, $tmp_pos, $starter_pos - $tmp_pos);
// Dump combiners
if (!empty($utf_sort))
{
if ($sort)
{
ksort($utf_sort);
}
foreach ($utf_sort as $utf_chars)
{
$tmp .= implode('', $utf_chars);
}
}
$tmp .= $c;
$dump = $sort = 0;
}
else
{
$tmp .= substr($str, $tmp_pos, $pos - $utf_len - $tmp_pos) . $c;
}
$tmp_pos = $starter_pos = $pos;
$utf_sort = array();
$last_cc = 0;
}
}
while ($_pos < $_len);
}
else if (isset($utf_combining_class[$utf_char]))
{
// Combining character
if ($utf_combining_class[$utf_char] < $last_cc)
{
// Not in canonical order
$sort = $dump = 1;
}
else
{
$last_cc = $utf_combining_class[$utf_char];
}
$utf_sort[$utf_combining_class[$utf_char]][] = $utf_char;
}
else
{
// Non-decomposable starter, check out if it's a Hangul syllable
if ($utf_char < UTF8_HANGUL_FIRST || $utf_char > UTF8_HANGUL_LAST)
{
// Nope, regular UTF char, check that we have the correct number of trailing bytes
if (($utf_char & $utf_validation_mask[$utf_len]) != $utf_validation_check[$utf_len])
{
// Current char isn't well-formed or legal: either one or several trailing bytes are missing, or the Unicode char
// has been encoded in a five- or six- byte sequence.
// Move the cursor back to its original position then advance it to the position it should really be at
$pos -= $utf_len;
$tmp .= substr($str, $tmp_pos, $starter_pos - $tmp_pos);
if (!empty($utf_sort))
{
ksort($utf_sort);
foreach ($utf_sort as $utf_chars)
{
$tmp .= implode('', $utf_chars);
}
$utf_sort = array();
}
// Add a replacement char then another replacement char for every trailing byte.
//
// @todo I'm not entirely sure that's how we're supposed to mark invalidated byte sequences, check this
$spn = strspn($str, UTF8_TRAILING_BYTES, ++$pos);
$tmp .= str_repeat(UTF8_REPLACEMENT, $spn + 1);
$dump = $sort = 0;
$pos += $spn;
$tmp_pos = $pos;
continue;
}
if (isset($extra_check[$utf_char[0]]))
{
switch ($utf_char[0])
{
// Note: 0xED is quite common in Korean
case "\xED":
if ($utf_char >= "\xED\xA0\x80")
{
// Surrogates (U+D800..U+DFFF) are not allowed in UTF-8 (UTF sequence 0xEDA080..0xEDBFBF)
$tmp .= substr($str, $tmp_pos, $starter_pos - $tmp_pos);
if (!empty($utf_sort))
{
ksort($utf_sort);
foreach ($utf_sort as $utf_chars)
{
$tmp .= implode('', $utf_chars);
}
$utf_sort = array();
}
$tmp .= UTF8_REPLACEMENT;
$dump = $sort = 0;
$tmp_pos = $starter_pos = $pos;
continue 2;
}
break;
// Note: 0xEF is quite common in Japanese
case "\xEF":
if ($utf_char == "\xEF\xBF\xBE" || $utf_char == "\xEF\xBF\xBF")
{
// U+FFFE and U+FFFF are explicitly disallowed (UTF sequence 0xEFBFBE..0xEFBFBF)
$tmp .= substr($str, $tmp_pos, $starter_pos - $tmp_pos);
if (!empty($utf_sort))
{
ksort($utf_sort);
foreach ($utf_sort as $utf_chars)
{
$tmp .= implode('', $utf_chars);
}
$utf_sort = array();
}
$tmp .= UTF8_REPLACEMENT;
$dump = $sort = 0;
$tmp_pos = $starter_pos = $pos;
continue 2;
}
break;
case "\xC0":
case "\xC1":
if ($utf_char <= "\xC1\xBF")
{
// Overlong sequence: Unicode char U+0000..U+007F encoded as a double-byte UTF char
$tmp .= substr($str, $tmp_pos, $starter_pos - $tmp_pos);
if (!empty($utf_sort))
{
ksort($utf_sort);
foreach ($utf_sort as $utf_chars)
{
$tmp .= implode('', $utf_chars);
}
$utf_sort = array();
}
$tmp .= UTF8_REPLACEMENT;
$dump = $sort = 0;
$tmp_pos = $starter_pos = $pos;
continue 2;
}
break;
case "\xE0":
if ($utf_char <= "\xE0\x9F\xBF")
{
// Unicode char U+0000..U+07FF encoded in 3 bytes
$tmp .= substr($str, $tmp_pos, $starter_pos - $tmp_pos);
if (!empty($utf_sort))
{
ksort($utf_sort);
foreach ($utf_sort as $utf_chars)
{
$tmp .= implode('', $utf_chars);
}
$utf_sort = array();
}
$tmp .= UTF8_REPLACEMENT;
$dump = $sort = 0;
$tmp_pos = $starter_pos = $pos;
continue 2;
}
break;
case "\xF0":
if ($utf_char <= "\xF0\x8F\xBF\xBF")
{
// Unicode char U+0000..U+FFFF encoded in 4 bytes
$tmp .= substr($str, $tmp_pos, $starter_pos - $tmp_pos);
if (!empty($utf_sort))
{
ksort($utf_sort);
foreach ($utf_sort as $utf_chars)
{
$tmp .= implode('', $utf_chars);
}
$utf_sort = array();
}
$tmp .= UTF8_REPLACEMENT;
$dump = $sort = 0;
$tmp_pos = $starter_pos = $pos;
continue 2;
}
break;
default:
if ($utf_char > UTF8_MAX)
{
// Out of the Unicode range
$tmp .= substr($str, $tmp_pos, $starter_pos - $tmp_pos);
if (!empty($utf_sort))
{
ksort($utf_sort);
foreach ($utf_sort as $utf_chars)
{
$tmp .= implode('', $utf_chars);
}
$utf_sort = array();
}
$tmp .= UTF8_REPLACEMENT;
$dump = $sort = 0;
$tmp_pos = $starter_pos = $pos;
continue 2;
}
break;
}
}
}
else
{
// Hangul syllable
$idx = (((ord($utf_char[0]) & 0x0F) << 12) | ((ord($utf_char[1]) & 0x3F) << 6) | (ord($utf_char[2]) & 0x3F)) - UNICODE_HANGUL_SBASE;
// LIndex can only range from 0 to 18, therefore it cannot influence the first two bytes of the L Jamo, which allows us to hardcode them (based on LBase).
//
// The same goes for VIndex, but for TIndex there's a catch: the value of the third byte could exceed 0xBF and we would have to increment the second byte
if ($t_index = $idx % UNICODE_HANGUL_TCOUNT)
{
if ($t_index < 25)
{
$utf_char = "\xE1\x84\x00\xE1\x85\x00\xE1\x86\x00";
$utf_char[8] = chr(0xA7 + $t_index);
}
else
{
$utf_char = "\xE1\x84\x00\xE1\x85\x00\xE1\x87\x00";
$utf_char[8] = chr(0x67 + $t_index);
}
}
else
{
$utf_char = "\xE1\x84\x00\xE1\x85\x00";
}
$utf_char[2] = chr(0x80 + (int) ($idx / UNICODE_HANGUL_NCOUNT));
$utf_char[5] = chr(0xA1 + (int) (($idx % UNICODE_HANGUL_NCOUNT) / UNICODE_HANGUL_TCOUNT));
// Just like other decompositions, the resulting Jamos must be dumped to the tmp string
$dump = 1;
}
// Do we need to dump stuff to the tmp string?
if ($dump)
{
$tmp .= substr($str, $tmp_pos, $starter_pos - $tmp_pos);
// Dump combiners
if (!empty($utf_sort))
{
if ($sort)
{
ksort($utf_sort);
}
foreach ($utf_sort as $utf_chars)
{
$tmp .= implode('', $utf_chars);
}
}
$tmp .= $utf_char;
$dump = $sort = 0;
$tmp_pos = $pos;
}
$last_cc = 0;
$utf_sort = array();
$starter_pos = $pos;
}
}
else
{
// ASCII char, which happens to be a starter (as any other ASCII char)
if ($dump)
{
$tmp .= substr($str, $tmp_pos, $starter_pos - $tmp_pos);
// Dump combiners
if (!empty($utf_sort))
{
if ($sort)
{
ksort($utf_sort);
}
foreach ($utf_sort as $utf_chars)
{
$tmp .= implode('', $utf_chars);
}
}
$tmp .= $str[$pos];
$dump = $sort = 0;
$tmp_pos = ++$pos;
$pos += strspn($str, UTF8_ASCII_RANGE, $pos);
}
else
{
$pos += strspn($str, UTF8_ASCII_RANGE, ++$pos);
}
$last_cc = 0;
$utf_sort = array();
$starter_pos = $pos;
}
}
while ($pos < $len);
// Now is time to return the string
if ($dump)
{
$tmp .= substr($str, $tmp_pos, $starter_pos - $tmp_pos);
// Dump combiners
if (!empty($utf_sort))
{
if ($sort)
{
ksort($utf_sort);
}
foreach ($utf_sort as $utf_chars)
{
$tmp .= implode('', $utf_chars);
}
}
return $tmp;
}
else if ($tmp_pos)
{
// If the $tmp_pos cursor was moved then at least one character was not in normal form. Replace $str with the fixed version
if ($tmp_pos == $len)
{
// The $tmp_pos cursor is at the end of $str, therefore $tmp holds the whole $str
return $tmp;
}
else
{
// The rightmost chunk of $str has not been appended to $tmp yet
return $tmp . substr($str, $tmp_pos);
}
}
// The string was already in normal form
return $str;
}
}
?>
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