Mercurial > hg > Members > tobaru > cbc > CbC_llvm
view lib/Support/ConvertUTF.c @ 107:a03ddd01be7e
resolve warnings
author | Kaito Tokumori <e105711@ie.u-ryukyu.ac.jp> |
---|---|
date | Sun, 31 Jan 2016 17:34:49 +0900 |
parents | 54457678186b |
children |
line wrap: on
line source
/*===--- ConvertUTF.c - Universal Character Names conversions ---------------=== * * The LLVM Compiler Infrastructure * * This file is distributed under the University of Illinois Open Source * License. See LICENSE.TXT for details. * *===------------------------------------------------------------------------=*/ /* * Copyright 2001-2004 Unicode, Inc. * * Disclaimer * * This source code is provided as is by Unicode, Inc. No claims are * made as to fitness for any particular purpose. No warranties of any * kind are expressed or implied. The recipient agrees to determine * applicability of information provided. If this file has been * purchased on magnetic or optical media from Unicode, Inc., the * sole remedy for any claim will be exchange of defective media * within 90 days of receipt. * * Limitations on Rights to Redistribute This Code * * Unicode, Inc. hereby grants the right to freely use the information * supplied in this file in the creation of products supporting the * Unicode Standard, and to make copies of this file in any form * for internal or external distribution as long as this notice * remains attached. */ /* --------------------------------------------------------------------- Conversions between UTF32, UTF-16, and UTF-8. Source code file. Author: Mark E. Davis, 1994. Rev History: Rick McGowan, fixes & updates May 2001. Sept 2001: fixed const & error conditions per mods suggested by S. Parent & A. Lillich. June 2002: Tim Dodd added detection and handling of incomplete source sequences, enhanced error detection, added casts to eliminate compiler warnings. July 2003: slight mods to back out aggressive FFFE detection. Jan 2004: updated switches in from-UTF8 conversions. Oct 2004: updated to use UNI_MAX_LEGAL_UTF32 in UTF-32 conversions. See the header file "ConvertUTF.h" for complete documentation. ------------------------------------------------------------------------ */ #include "llvm/Support/ConvertUTF.h" #ifdef CVTUTF_DEBUG #include <stdio.h> #endif #include <assert.h> static const int halfShift = 10; /* used for shifting by 10 bits */ static const UTF32 halfBase = 0x0010000UL; static const UTF32 halfMask = 0x3FFUL; #define UNI_SUR_HIGH_START (UTF32)0xD800 #define UNI_SUR_HIGH_END (UTF32)0xDBFF #define UNI_SUR_LOW_START (UTF32)0xDC00 #define UNI_SUR_LOW_END (UTF32)0xDFFF #define false 0 #define true 1 /* --------------------------------------------------------------------- */ /* * Index into the table below with the first byte of a UTF-8 sequence to * get the number of trailing bytes that are supposed to follow it. * Note that *legal* UTF-8 values can't have 4 or 5-bytes. The table is * left as-is for anyone who may want to do such conversion, which was * allowed in earlier algorithms. */ static const char trailingBytesForUTF8[256] = { 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0, 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0, 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0, 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0, 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0, 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0, 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0, 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0, 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0, 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0, 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0, 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0, 1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, 1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, 2,2,2,2,2,2,2,2,2,2,2,2,2,2,2,2, 3,3,3,3,3,3,3,3,4,4,4,4,5,5,5,5 }; /* * Magic values subtracted from a buffer value during UTF8 conversion. * This table contains as many values as there might be trailing bytes * in a UTF-8 sequence. */ static const UTF32 offsetsFromUTF8[6] = { 0x00000000UL, 0x00003080UL, 0x000E2080UL, 0x03C82080UL, 0xFA082080UL, 0x82082080UL }; /* * Once the bits are split out into bytes of UTF-8, this is a mask OR-ed * into the first byte, depending on how many bytes follow. There are * as many entries in this table as there are UTF-8 sequence types. * (I.e., one byte sequence, two byte... etc.). Remember that sequencs * for *legal* UTF-8 will be 4 or fewer bytes total. */ static const UTF8 firstByteMark[7] = { 0x00, 0x00, 0xC0, 0xE0, 0xF0, 0xF8, 0xFC }; /* --------------------------------------------------------------------- */ /* The interface converts a whole buffer to avoid function-call overhead. * Constants have been gathered. Loops & conditionals have been removed as * much as possible for efficiency, in favor of drop-through switches. * (See "Note A" at the bottom of the file for equivalent code.) * If your compiler supports it, the "isLegalUTF8" call can be turned * into an inline function. */ /* --------------------------------------------------------------------- */ ConversionResult ConvertUTF32toUTF16 ( const UTF32** sourceStart, const UTF32* sourceEnd, UTF16** targetStart, UTF16* targetEnd, ConversionFlags flags) { ConversionResult result = conversionOK; const UTF32* source = *sourceStart; UTF16* target = *targetStart; while (source < sourceEnd) { UTF32 ch; if (target >= targetEnd) { result = targetExhausted; break; } ch = *source++; if (ch <= UNI_MAX_BMP) { /* Target is a character <= 0xFFFF */ /* UTF-16 surrogate values are illegal in UTF-32; 0xffff or 0xfffe are both reserved values */ if (ch >= UNI_SUR_HIGH_START && ch <= UNI_SUR_LOW_END) { if (flags == strictConversion) { --source; /* return to the illegal value itself */ result = sourceIllegal; break; } else { *target++ = UNI_REPLACEMENT_CHAR; } } else { *target++ = (UTF16)ch; /* normal case */ } } else if (ch > UNI_MAX_LEGAL_UTF32) { if (flags == strictConversion) { result = sourceIllegal; } else { *target++ = UNI_REPLACEMENT_CHAR; } } else { /* target is a character in range 0xFFFF - 0x10FFFF. */ if (target + 1 >= targetEnd) { --source; /* Back up source pointer! */ result = targetExhausted; break; } ch -= halfBase; *target++ = (UTF16)((ch >> halfShift) + UNI_SUR_HIGH_START); *target++ = (UTF16)((ch & halfMask) + UNI_SUR_LOW_START); } } *sourceStart = source; *targetStart = target; return result; } /* --------------------------------------------------------------------- */ ConversionResult ConvertUTF16toUTF32 ( const UTF16** sourceStart, const UTF16* sourceEnd, UTF32** targetStart, UTF32* targetEnd, ConversionFlags flags) { ConversionResult result = conversionOK; const UTF16* source = *sourceStart; UTF32* target = *targetStart; UTF32 ch, ch2; while (source < sourceEnd) { const UTF16* oldSource = source; /* In case we have to back up because of target overflow. */ ch = *source++; /* If we have a surrogate pair, convert to UTF32 first. */ if (ch >= UNI_SUR_HIGH_START && ch <= UNI_SUR_HIGH_END) { /* If the 16 bits following the high surrogate are in the source buffer... */ if (source < sourceEnd) { ch2 = *source; /* If it's a low surrogate, convert to UTF32. */ if (ch2 >= UNI_SUR_LOW_START && ch2 <= UNI_SUR_LOW_END) { ch = ((ch - UNI_SUR_HIGH_START) << halfShift) + (ch2 - UNI_SUR_LOW_START) + halfBase; ++source; } else if (flags == strictConversion) { /* it's an unpaired high surrogate */ --source; /* return to the illegal value itself */ result = sourceIllegal; break; } } else { /* We don't have the 16 bits following the high surrogate. */ --source; /* return to the high surrogate */ result = sourceExhausted; break; } } else if (flags == strictConversion) { /* UTF-16 surrogate values are illegal in UTF-32 */ if (ch >= UNI_SUR_LOW_START && ch <= UNI_SUR_LOW_END) { --source; /* return to the illegal value itself */ result = sourceIllegal; break; } } if (target >= targetEnd) { source = oldSource; /* Back up source pointer! */ result = targetExhausted; break; } *target++ = ch; } *sourceStart = source; *targetStart = target; #ifdef CVTUTF_DEBUG if (result == sourceIllegal) { fprintf(stderr, "ConvertUTF16toUTF32 illegal seq 0x%04x,%04x\n", ch, ch2); fflush(stderr); } #endif return result; } ConversionResult ConvertUTF16toUTF8 ( const UTF16** sourceStart, const UTF16* sourceEnd, UTF8** targetStart, UTF8* targetEnd, ConversionFlags flags) { ConversionResult result = conversionOK; const UTF16* source = *sourceStart; UTF8* target = *targetStart; while (source < sourceEnd) { UTF32 ch; unsigned short bytesToWrite = 0; const UTF32 byteMask = 0xBF; const UTF32 byteMark = 0x80; const UTF16* oldSource = source; /* In case we have to back up because of target overflow. */ ch = *source++; /* If we have a surrogate pair, convert to UTF32 first. */ if (ch >= UNI_SUR_HIGH_START && ch <= UNI_SUR_HIGH_END) { /* If the 16 bits following the high surrogate are in the source buffer... */ if (source < sourceEnd) { UTF32 ch2 = *source; /* If it's a low surrogate, convert to UTF32. */ if (ch2 >= UNI_SUR_LOW_START && ch2 <= UNI_SUR_LOW_END) { ch = ((ch - UNI_SUR_HIGH_START) << halfShift) + (ch2 - UNI_SUR_LOW_START) + halfBase; ++source; } else if (flags == strictConversion) { /* it's an unpaired high surrogate */ --source; /* return to the illegal value itself */ result = sourceIllegal; break; } } else { /* We don't have the 16 bits following the high surrogate. */ --source; /* return to the high surrogate */ result = sourceExhausted; break; } } else if (flags == strictConversion) { /* UTF-16 surrogate values are illegal in UTF-32 */ if (ch >= UNI_SUR_LOW_START && ch <= UNI_SUR_LOW_END) { --source; /* return to the illegal value itself */ result = sourceIllegal; break; } } /* Figure out how many bytes the result will require */ if (ch < (UTF32)0x80) { bytesToWrite = 1; } else if (ch < (UTF32)0x800) { bytesToWrite = 2; } else if (ch < (UTF32)0x10000) { bytesToWrite = 3; } else if (ch < (UTF32)0x110000) { bytesToWrite = 4; } else { bytesToWrite = 3; ch = UNI_REPLACEMENT_CHAR; } target += bytesToWrite; if (target > targetEnd) { source = oldSource; /* Back up source pointer! */ target -= bytesToWrite; result = targetExhausted; break; } switch (bytesToWrite) { /* note: everything falls through. */ case 4: *--target = (UTF8)((ch | byteMark) & byteMask); ch >>= 6; case 3: *--target = (UTF8)((ch | byteMark) & byteMask); ch >>= 6; case 2: *--target = (UTF8)((ch | byteMark) & byteMask); ch >>= 6; case 1: *--target = (UTF8)(ch | firstByteMark[bytesToWrite]); } target += bytesToWrite; } *sourceStart = source; *targetStart = target; return result; } /* --------------------------------------------------------------------- */ ConversionResult ConvertUTF32toUTF8 ( const UTF32** sourceStart, const UTF32* sourceEnd, UTF8** targetStart, UTF8* targetEnd, ConversionFlags flags) { ConversionResult result = conversionOK; const UTF32* source = *sourceStart; UTF8* target = *targetStart; while (source < sourceEnd) { UTF32 ch; unsigned short bytesToWrite = 0; const UTF32 byteMask = 0xBF; const UTF32 byteMark = 0x80; ch = *source++; if (flags == strictConversion ) { /* UTF-16 surrogate values are illegal in UTF-32 */ if (ch >= UNI_SUR_HIGH_START && ch <= UNI_SUR_LOW_END) { --source; /* return to the illegal value itself */ result = sourceIllegal; break; } } /* * Figure out how many bytes the result will require. Turn any * illegally large UTF32 things (> Plane 17) into replacement chars. */ if (ch < (UTF32)0x80) { bytesToWrite = 1; } else if (ch < (UTF32)0x800) { bytesToWrite = 2; } else if (ch < (UTF32)0x10000) { bytesToWrite = 3; } else if (ch <= UNI_MAX_LEGAL_UTF32) { bytesToWrite = 4; } else { bytesToWrite = 3; ch = UNI_REPLACEMENT_CHAR; result = sourceIllegal; } target += bytesToWrite; if (target > targetEnd) { --source; /* Back up source pointer! */ target -= bytesToWrite; result = targetExhausted; break; } switch (bytesToWrite) { /* note: everything falls through. */ case 4: *--target = (UTF8)((ch | byteMark) & byteMask); ch >>= 6; case 3: *--target = (UTF8)((ch | byteMark) & byteMask); ch >>= 6; case 2: *--target = (UTF8)((ch | byteMark) & byteMask); ch >>= 6; case 1: *--target = (UTF8) (ch | firstByteMark[bytesToWrite]); } target += bytesToWrite; } *sourceStart = source; *targetStart = target; return result; } /* --------------------------------------------------------------------- */ /* * Utility routine to tell whether a sequence of bytes is legal UTF-8. * This must be called with the length pre-determined by the first byte. * If not calling this from ConvertUTF8to*, then the length can be set by: * length = trailingBytesForUTF8[*source]+1; * and the sequence is illegal right away if there aren't that many bytes * available. * If presented with a length > 4, this returns false. The Unicode * definition of UTF-8 goes up to 4-byte sequences. */ static Boolean isLegalUTF8(const UTF8 *source, int length) { UTF8 a; const UTF8 *srcptr = source+length; switch (length) { default: return false; /* Everything else falls through when "true"... */ case 4: if ((a = (*--srcptr)) < 0x80 || a > 0xBF) return false; case 3: if ((a = (*--srcptr)) < 0x80 || a > 0xBF) return false; case 2: if ((a = (*--srcptr)) < 0x80 || a > 0xBF) return false; switch (*source) { /* no fall-through in this inner switch */ case 0xE0: if (a < 0xA0) return false; break; case 0xED: if (a > 0x9F) return false; break; case 0xF0: if (a < 0x90) return false; break; case 0xF4: if (a > 0x8F) return false; break; default: if (a < 0x80) return false; } case 1: if (*source >= 0x80 && *source < 0xC2) return false; } if (*source > 0xF4) return false; return true; } /* --------------------------------------------------------------------- */ /* * Exported function to return whether a UTF-8 sequence is legal or not. * This is not used here; it's just exported. */ Boolean isLegalUTF8Sequence(const UTF8 *source, const UTF8 *sourceEnd) { int length = trailingBytesForUTF8[*source]+1; if (length > sourceEnd - source) { return false; } return isLegalUTF8(source, length); } /* --------------------------------------------------------------------- */ static unsigned findMaximalSubpartOfIllFormedUTF8Sequence(const UTF8 *source, const UTF8 *sourceEnd) { UTF8 b1, b2, b3; assert(!isLegalUTF8Sequence(source, sourceEnd)); /* * Unicode 6.3.0, D93b: * * Maximal subpart of an ill-formed subsequence: The longest code unit * subsequence starting at an unconvertible offset that is either: * a. the initial subsequence of a well-formed code unit sequence, or * b. a subsequence of length one. */ if (source == sourceEnd) return 0; /* * Perform case analysis. See Unicode 6.3.0, Table 3-7. Well-Formed UTF-8 * Byte Sequences. */ b1 = *source; ++source; if (b1 >= 0xC2 && b1 <= 0xDF) { /* * First byte is valid, but we know that this code unit sequence is * invalid, so the maximal subpart has to end after the first byte. */ return 1; } if (source == sourceEnd) return 1; b2 = *source; ++source; if (b1 == 0xE0) { return (b2 >= 0xA0 && b2 <= 0xBF) ? 2 : 1; } if (b1 >= 0xE1 && b1 <= 0xEC) { return (b2 >= 0x80 && b2 <= 0xBF) ? 2 : 1; } if (b1 == 0xED) { return (b2 >= 0x80 && b2 <= 0x9F) ? 2 : 1; } if (b1 >= 0xEE && b1 <= 0xEF) { return (b2 >= 0x80 && b2 <= 0xBF) ? 2 : 1; } if (b1 == 0xF0) { if (b2 >= 0x90 && b2 <= 0xBF) { if (source == sourceEnd) return 2; b3 = *source; return (b3 >= 0x80 && b3 <= 0xBF) ? 3 : 2; } return 1; } if (b1 >= 0xF1 && b1 <= 0xF3) { if (b2 >= 0x80 && b2 <= 0xBF) { if (source == sourceEnd) return 2; b3 = *source; return (b3 >= 0x80 && b3 <= 0xBF) ? 3 : 2; } return 1; } if (b1 == 0xF4) { if (b2 >= 0x80 && b2 <= 0x8F) { if (source == sourceEnd) return 2; b3 = *source; return (b3 >= 0x80 && b3 <= 0xBF) ? 3 : 2; } return 1; } assert((b1 >= 0x80 && b1 <= 0xC1) || b1 >= 0xF5); /* * There are no valid sequences that start with these bytes. Maximal subpart * is defined to have length 1 in these cases. */ return 1; } /* --------------------------------------------------------------------- */ /* * Exported function to return the total number of bytes in a codepoint * represented in UTF-8, given the value of the first byte. */ unsigned getNumBytesForUTF8(UTF8 first) { return trailingBytesForUTF8[first] + 1; } /* --------------------------------------------------------------------- */ /* * Exported function to return whether a UTF-8 string is legal or not. * This is not used here; it's just exported. */ Boolean isLegalUTF8String(const UTF8 **source, const UTF8 *sourceEnd) { while (*source != sourceEnd) { int length = trailingBytesForUTF8[**source] + 1; if (length > sourceEnd - *source || !isLegalUTF8(*source, length)) return false; *source += length; } return true; } /* --------------------------------------------------------------------- */ ConversionResult ConvertUTF8toUTF16 ( const UTF8** sourceStart, const UTF8* sourceEnd, UTF16** targetStart, UTF16* targetEnd, ConversionFlags flags) { ConversionResult result = conversionOK; const UTF8* source = *sourceStart; UTF16* target = *targetStart; while (source < sourceEnd) { UTF32 ch = 0; unsigned short extraBytesToRead = trailingBytesForUTF8[*source]; if (extraBytesToRead >= sourceEnd - source) { result = sourceExhausted; break; } /* Do this check whether lenient or strict */ if (!isLegalUTF8(source, extraBytesToRead+1)) { result = sourceIllegal; break; } /* * The cases all fall through. See "Note A" below. */ switch (extraBytesToRead) { case 5: ch += *source++; ch <<= 6; /* remember, illegal UTF-8 */ case 4: ch += *source++; ch <<= 6; /* remember, illegal UTF-8 */ case 3: ch += *source++; ch <<= 6; case 2: ch += *source++; ch <<= 6; case 1: ch += *source++; ch <<= 6; case 0: ch += *source++; } ch -= offsetsFromUTF8[extraBytesToRead]; if (target >= targetEnd) { source -= (extraBytesToRead+1); /* Back up source pointer! */ result = targetExhausted; break; } if (ch <= UNI_MAX_BMP) { /* Target is a character <= 0xFFFF */ /* UTF-16 surrogate values are illegal in UTF-32 */ if (ch >= UNI_SUR_HIGH_START && ch <= UNI_SUR_LOW_END) { if (flags == strictConversion) { source -= (extraBytesToRead+1); /* return to the illegal value itself */ result = sourceIllegal; break; } else { *target++ = UNI_REPLACEMENT_CHAR; } } else { *target++ = (UTF16)ch; /* normal case */ } } else if (ch > UNI_MAX_UTF16) { if (flags == strictConversion) { result = sourceIllegal; source -= (extraBytesToRead+1); /* return to the start */ break; /* Bail out; shouldn't continue */ } else { *target++ = UNI_REPLACEMENT_CHAR; } } else { /* target is a character in range 0xFFFF - 0x10FFFF. */ if (target + 1 >= targetEnd) { source -= (extraBytesToRead+1); /* Back up source pointer! */ result = targetExhausted; break; } ch -= halfBase; *target++ = (UTF16)((ch >> halfShift) + UNI_SUR_HIGH_START); *target++ = (UTF16)((ch & halfMask) + UNI_SUR_LOW_START); } } *sourceStart = source; *targetStart = target; return result; } /* --------------------------------------------------------------------- */ static ConversionResult ConvertUTF8toUTF32Impl( const UTF8** sourceStart, const UTF8* sourceEnd, UTF32** targetStart, UTF32* targetEnd, ConversionFlags flags, Boolean InputIsPartial) { ConversionResult result = conversionOK; const UTF8* source = *sourceStart; UTF32* target = *targetStart; while (source < sourceEnd) { UTF32 ch = 0; unsigned short extraBytesToRead = trailingBytesForUTF8[*source]; if (extraBytesToRead >= sourceEnd - source) { if (flags == strictConversion || InputIsPartial) { result = sourceExhausted; break; } else { result = sourceIllegal; /* * Replace the maximal subpart of ill-formed sequence with * replacement character. */ source += findMaximalSubpartOfIllFormedUTF8Sequence(source, sourceEnd); *target++ = UNI_REPLACEMENT_CHAR; continue; } } if (target >= targetEnd) { result = targetExhausted; break; } /* Do this check whether lenient or strict */ if (!isLegalUTF8(source, extraBytesToRead+1)) { result = sourceIllegal; if (flags == strictConversion) { /* Abort conversion. */ break; } else { /* * Replace the maximal subpart of ill-formed sequence with * replacement character. */ source += findMaximalSubpartOfIllFormedUTF8Sequence(source, sourceEnd); *target++ = UNI_REPLACEMENT_CHAR; continue; } } /* * The cases all fall through. See "Note A" below. */ switch (extraBytesToRead) { case 5: ch += *source++; ch <<= 6; case 4: ch += *source++; ch <<= 6; case 3: ch += *source++; ch <<= 6; case 2: ch += *source++; ch <<= 6; case 1: ch += *source++; ch <<= 6; case 0: ch += *source++; } ch -= offsetsFromUTF8[extraBytesToRead]; if (ch <= UNI_MAX_LEGAL_UTF32) { /* * UTF-16 surrogate values are illegal in UTF-32, and anything * over Plane 17 (> 0x10FFFF) is illegal. */ if (ch >= UNI_SUR_HIGH_START && ch <= UNI_SUR_LOW_END) { if (flags == strictConversion) { source -= (extraBytesToRead+1); /* return to the illegal value itself */ result = sourceIllegal; break; } else { *target++ = UNI_REPLACEMENT_CHAR; } } else { *target++ = ch; } } else { /* i.e., ch > UNI_MAX_LEGAL_UTF32 */ result = sourceIllegal; *target++ = UNI_REPLACEMENT_CHAR; } } *sourceStart = source; *targetStart = target; return result; } ConversionResult ConvertUTF8toUTF32Partial(const UTF8 **sourceStart, const UTF8 *sourceEnd, UTF32 **targetStart, UTF32 *targetEnd, ConversionFlags flags) { return ConvertUTF8toUTF32Impl(sourceStart, sourceEnd, targetStart, targetEnd, flags, /*InputIsPartial=*/true); } ConversionResult ConvertUTF8toUTF32(const UTF8 **sourceStart, const UTF8 *sourceEnd, UTF32 **targetStart, UTF32 *targetEnd, ConversionFlags flags) { return ConvertUTF8toUTF32Impl(sourceStart, sourceEnd, targetStart, targetEnd, flags, /*InputIsPartial=*/false); } /* --------------------------------------------------------------------- Note A. The fall-through switches in UTF-8 reading code save a temp variable, some decrements & conditionals. The switches are equivalent to the following loop: { int tmpBytesToRead = extraBytesToRead+1; do { ch += *source++; --tmpBytesToRead; if (tmpBytesToRead) ch <<= 6; } while (tmpBytesToRead > 0); } In UTF-8 writing code, the switches on "bytesToWrite" are similarly unrolled loops. --------------------------------------------------------------------- */