/* * synergy -- mouse and keyboard sharing utility * Copyright (C) 2012 Bolton Software Ltd. * Copyright (C) 2002 Chris Schoeneman * * This package is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * found in the file COPYING that should have accompanied this file. * * This package is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . */ #include "CUnicode.h" #include "CArch.h" #include // // local utility functions // inline static UInt16 decode16(const UInt8* n, bool byteSwapped) { union x16 { UInt8 n8[2]; UInt16 n16; } c; if (byteSwapped) { c.n8[0] = n[1]; c.n8[1] = n[0]; } else { c.n8[0] = n[0]; c.n8[1] = n[1]; } return c.n16; } inline static UInt32 decode32(const UInt8* n, bool byteSwapped) { union x32 { UInt8 n8[4]; UInt32 n32; } c; if (byteSwapped) { c.n8[0] = n[3]; c.n8[1] = n[2]; c.n8[2] = n[1]; c.n8[3] = n[0]; } else { c.n8[0] = n[0]; c.n8[1] = n[1]; c.n8[2] = n[2]; c.n8[3] = n[3]; } return c.n32; } inline static void resetError(bool* errors) { if (errors != NULL) { *errors = false; } } inline static void setError(bool* errors) { if (errors != NULL) { *errors = true; } } // // CUnicode // UInt32 CUnicode::s_invalid = 0x0000ffff; UInt32 CUnicode::s_replacement = 0x0000fffd; bool CUnicode::isUTF8(const CString& src) { // convert and test each character const UInt8* data = reinterpret_cast(src.c_str()); for (UInt32 n = (UInt32)src.size(); n > 0; ) { if (fromUTF8(data, n) == s_invalid) { return false; } } return true; } CString CUnicode::UTF8ToUCS2(const CString& src, bool* errors) { // default to success resetError(errors); // get size of input string and reserve some space in output UInt32 n = (UInt32)src.size(); CString dst; dst.reserve(2 * n); // convert each character const UInt8* data = reinterpret_cast(src.c_str()); while (n > 0) { UInt32 c = fromUTF8(data, n); if (c == s_invalid) { c = s_replacement; } else if (c >= 0x00010000) { setError(errors); c = s_replacement; } UInt16 ucs2 = static_cast(c); dst.append(reinterpret_cast(&ucs2), 2); } return dst; } CString CUnicode::UTF8ToUCS4(const CString& src, bool* errors) { // default to success resetError(errors); // get size of input string and reserve some space in output UInt32 n = (UInt32)src.size(); CString dst; dst.reserve(4 * n); // convert each character const UInt8* data = reinterpret_cast(src.c_str()); while (n > 0) { UInt32 c = fromUTF8(data, n); if (c == s_invalid) { c = s_replacement; } dst.append(reinterpret_cast(&c), 4); } return dst; } CString CUnicode::UTF8ToUTF16(const CString& src, bool* errors) { // default to success resetError(errors); // get size of input string and reserve some space in output UInt32 n = (UInt32)src.size(); CString dst; dst.reserve(2 * n); // convert each character const UInt8* data = reinterpret_cast(src.c_str()); while (n > 0) { UInt32 c = fromUTF8(data, n); if (c == s_invalid) { c = s_replacement; } else if (c >= 0x00110000) { setError(errors); c = s_replacement; } if (c < 0x00010000) { UInt16 ucs2 = static_cast(c); dst.append(reinterpret_cast(&ucs2), 2); } else { c -= 0x00010000; UInt16 utf16h = static_cast((c >> 10) + 0xd800); UInt16 utf16l = static_cast((c & 0x03ff) + 0xdc00); dst.append(reinterpret_cast(&utf16h), 2); dst.append(reinterpret_cast(&utf16l), 2); } } return dst; } CString CUnicode::UTF8ToUTF32(const CString& src, bool* errors) { // default to success resetError(errors); // get size of input string and reserve some space in output UInt32 n = (UInt32)src.size(); CString dst; dst.reserve(4 * n); // convert each character const UInt8* data = reinterpret_cast(src.c_str()); while (n > 0) { UInt32 c = fromUTF8(data, n); if (c == s_invalid) { c = s_replacement; } else if (c >= 0x00110000) { setError(errors); c = s_replacement; } dst.append(reinterpret_cast(&c), 4); } return dst; } CString CUnicode::UTF8ToText(const CString& src, bool* errors) { // default to success resetError(errors); // convert to wide char UInt32 size; wchar_t* tmp = UTF8ToWideChar(src, size, errors); // convert string to multibyte int len = ARCH->convStringWCToMB(NULL, tmp, size, errors); char* mbs = new char[len + 1]; ARCH->convStringWCToMB(mbs, tmp, size, errors); CString text(mbs, len); // clean up delete[] mbs; delete[] tmp; return text; } CString CUnicode::UCS2ToUTF8(const CString& src, bool* errors) { // default to success resetError(errors); // convert UInt32 n = (UInt32)src.size() >> 1; return doUCS2ToUTF8(reinterpret_cast(src.data()), n, errors); } CString CUnicode::UCS4ToUTF8(const CString& src, bool* errors) { // default to success resetError(errors); // convert UInt32 n = (UInt32)src.size() >> 2; return doUCS4ToUTF8(reinterpret_cast(src.data()), n, errors); } CString CUnicode::UTF16ToUTF8(const CString& src, bool* errors) { // default to success resetError(errors); // convert UInt32 n = (UInt32)src.size() >> 1; return doUTF16ToUTF8(reinterpret_cast(src.data()), n, errors); } CString CUnicode::UTF32ToUTF8(const CString& src, bool* errors) { // default to success resetError(errors); // convert UInt32 n = (UInt32)src.size() >> 2; return doUTF32ToUTF8(reinterpret_cast(src.data()), n, errors); } CString CUnicode::textToUTF8(const CString& src, bool* errors) { // default to success resetError(errors); // convert string to wide characters UInt32 n = (UInt32)src.size(); int len = ARCH->convStringMBToWC(NULL, src.c_str(), n, errors); wchar_t* wcs = new wchar_t[len + 1]; ARCH->convStringMBToWC(wcs, src.c_str(), n, errors); // convert to UTF8 CString utf8 = wideCharToUTF8(wcs, len, errors); // clean up delete[] wcs; return utf8; } wchar_t* CUnicode::UTF8ToWideChar(const CString& src, UInt32& size, bool* errors) { // convert to platform's wide character encoding CString tmp; switch (ARCH->getWideCharEncoding()) { case IArchString::kUCS2: tmp = UTF8ToUCS2(src, errors); size = (UInt32)tmp.size() >> 1; break; case IArchString::kUCS4: tmp = UTF8ToUCS4(src, errors); size = (UInt32)tmp.size() >> 2; break; case IArchString::kUTF16: tmp = UTF8ToUTF16(src, errors); size = (UInt32)tmp.size() >> 1; break; case IArchString::kUTF32: tmp = UTF8ToUTF32(src, errors); size = (UInt32)tmp.size() >> 2; break; default: assert(0 && "unknown wide character encoding"); } // copy to a wchar_t array wchar_t* dst = new wchar_t[size]; ::memcpy(dst, tmp.data(), sizeof(wchar_t) * size); return dst; } CString CUnicode::wideCharToUTF8(const wchar_t* src, UInt32 size, bool* errors) { // convert from platform's wide character encoding. // note -- this must include a wide nul character (independent of // the CString's nul character). switch (ARCH->getWideCharEncoding()) { case IArchString::kUCS2: return doUCS2ToUTF8(reinterpret_cast(src), size, errors); case IArchString::kUCS4: return doUCS4ToUTF8(reinterpret_cast(src), size, errors); case IArchString::kUTF16: return doUTF16ToUTF8(reinterpret_cast(src), size, errors); case IArchString::kUTF32: return doUTF32ToUTF8(reinterpret_cast(src), size, errors); default: assert(0 && "unknown wide character encoding"); return CString(); } } CString CUnicode::doUCS2ToUTF8(const UInt8* data, UInt32 n, bool* errors) { // make some space CString dst; dst.reserve(n); // check if first character is 0xfffe or 0xfeff bool byteSwapped = false; if (n >= 1) { switch (decode16(data, false)) { case 0x0000feff: data += 2; --n; break; case 0x0000fffe: byteSwapped = true; data += 2; --n; break; default: break; } } // convert each character for (; n > 0; data += 2, --n) { UInt32 c = decode16(data, byteSwapped); toUTF8(dst, c, errors); } return dst; } CString CUnicode::doUCS4ToUTF8(const UInt8* data, UInt32 n, bool* errors) { // make some space CString dst; dst.reserve(n); // check if first character is 0xfffe or 0xfeff bool byteSwapped = false; if (n >= 1) { switch (decode32(data, false)) { case 0x0000feff: data += 4; --n; break; case 0x0000fffe: byteSwapped = true; data += 4; --n; break; default: break; } } // convert each character for (; n > 0; data += 4, --n) { UInt32 c = decode32(data, byteSwapped); toUTF8(dst, c, errors); } return dst; } CString CUnicode::doUTF16ToUTF8(const UInt8* data, UInt32 n, bool* errors) { // make some space CString dst; dst.reserve(n); // check if first character is 0xfffe or 0xfeff bool byteSwapped = false; if (n >= 1) { switch (decode16(data, false)) { case 0x0000feff: data += 2; --n; break; case 0x0000fffe: byteSwapped = true; data += 2; --n; break; default: break; } } // convert each character for (; n > 0; data += 2, --n) { UInt32 c = decode16(data, byteSwapped); if (c < 0x0000d800 || c > 0x0000dfff) { toUTF8(dst, c, errors); } else if (n == 1) { // error -- missing second word setError(errors); toUTF8(dst, s_replacement, NULL); } else if (c >= 0x0000d800 && c <= 0x0000dbff) { UInt32 c2 = decode16(data, byteSwapped); data += 2; --n; if (c2 < 0x0000dc00 || c2 > 0x0000dfff) { // error -- [d800,dbff] not followed by [dc00,dfff] setError(errors); toUTF8(dst, s_replacement, NULL); } else { c = (((c - 0x0000d800) << 10) | (c2 - 0x0000dc00)) + 0x00010000; toUTF8(dst, c, errors); } } else { // error -- [dc00,dfff] without leading [d800,dbff] setError(errors); toUTF8(dst, s_replacement, NULL); } } return dst; } CString CUnicode::doUTF32ToUTF8(const UInt8* data, UInt32 n, bool* errors) { // make some space CString dst; dst.reserve(n); // check if first character is 0xfffe or 0xfeff bool byteSwapped = false; if (n >= 1) { switch (decode32(data, false)) { case 0x0000feff: data += 4; --n; break; case 0x0000fffe: byteSwapped = true; data += 4; --n; break; default: break; } } // convert each character for (; n > 0; data += 4, --n) { UInt32 c = decode32(data, byteSwapped); if (c >= 0x00110000) { setError(errors); c = s_replacement; } toUTF8(dst, c, errors); } return dst; } UInt32 CUnicode::fromUTF8(const UInt8*& data, UInt32& n) { assert(data != NULL); assert(n != 0); // compute character encoding length, checking for overlong // sequences (i.e. characters that don't use the shortest // possible encoding). UInt32 size; if (data[0] < 0x80) { // 0xxxxxxx size = 1; } else if (data[0] < 0xc0) { // 10xxxxxx -- in the middle of a multibyte character. counts // as one invalid character. --n; ++data; return s_invalid; } else if (data[0] < 0xe0) { // 110xxxxx size = 2; } else if (data[0] < 0xf0) { // 1110xxxx size = 3; } else if (data[0] < 0xf8) { // 11110xxx size = 4; } else if (data[0] < 0xfc) { // 111110xx size = 5; } else if (data[0] < 0xfe) { // 1111110x size = 6; } else { // invalid sequence. dunno how many bytes to skip so skip one. --n; ++data; return s_invalid; } // make sure we have enough data if (size > n) { data += n; n = 0; return s_invalid; } // extract character UInt32 c; switch (size) { case 1: c = static_cast(data[0]); break; case 2: c = ((static_cast(data[0]) & 0x1f) << 6) | ((static_cast(data[1]) & 0x3f) ); break; case 3: c = ((static_cast(data[0]) & 0x0f) << 12) | ((static_cast(data[1]) & 0x3f) << 6) | ((static_cast(data[2]) & 0x3f) ); break; case 4: c = ((static_cast(data[0]) & 0x07) << 18) | ((static_cast(data[1]) & 0x3f) << 12) | ((static_cast(data[1]) & 0x3f) << 6) | ((static_cast(data[1]) & 0x3f) ); break; case 5: c = ((static_cast(data[0]) & 0x03) << 24) | ((static_cast(data[1]) & 0x3f) << 18) | ((static_cast(data[1]) & 0x3f) << 12) | ((static_cast(data[1]) & 0x3f) << 6) | ((static_cast(data[1]) & 0x3f) ); break; case 6: c = ((static_cast(data[0]) & 0x01) << 30) | ((static_cast(data[1]) & 0x3f) << 24) | ((static_cast(data[1]) & 0x3f) << 18) | ((static_cast(data[1]) & 0x3f) << 12) | ((static_cast(data[1]) & 0x3f) << 6) | ((static_cast(data[1]) & 0x3f) ); break; default: assert(0 && "invalid size"); return s_invalid; } // check that all bytes after the first have the pattern 10xxxxxx. // truncated sequences are treated as a single malformed character. bool truncated = false; switch (size) { case 6: if ((data[5] & 0xc0) != 0x80) { truncated = true; size = 5; } // fall through case 5: if ((data[4] & 0xc0) != 0x80) { truncated = true; size = 4; } // fall through case 4: if ((data[3] & 0xc0) != 0x80) { truncated = true; size = 3; } // fall through case 3: if ((data[2] & 0xc0) != 0x80) { truncated = true; size = 2; } // fall through case 2: if ((data[1] & 0xc0) != 0x80) { truncated = true; size = 1; } } // update parameters data += size; n -= size; // invalid if sequence was truncated if (truncated) { return s_invalid; } // check for characters that didn't use the smallest possible encoding static UInt32 s_minChar[] = { 0, 0x00000000, 0x00000080, 0x00000800, 0x00010000, 0x00200000, 0x04000000 }; if (c < s_minChar[size]) { return s_invalid; } // check for characters not in ISO-10646 if (c >= 0x0000d800 && c <= 0x0000dfff) { return s_invalid; } if (c >= 0x0000fffe && c <= 0x0000ffff) { return s_invalid; } return c; } void CUnicode::toUTF8(CString& dst, UInt32 c, bool* errors) { UInt8 data[6]; // handle characters outside the valid range if ((c >= 0x0000d800 && c <= 0x0000dfff) || c >= 0x80000000) { setError(errors); c = s_replacement; } // convert to UTF-8 if (c < 0x00000080) { data[0] = static_cast(c); dst.append(reinterpret_cast(data), 1); } else if (c < 0x00000800) { data[0] = static_cast(((c >> 6) & 0x0000001f) + 0xc0); data[1] = static_cast((c & 0x0000003f) + 0x80); dst.append(reinterpret_cast(data), 2); } else if (c < 0x00010000) { data[0] = static_cast(((c >> 12) & 0x0000000f) + 0xe0); data[1] = static_cast(((c >> 6) & 0x0000003f) + 0x80); data[2] = static_cast((c & 0x0000003f) + 0x80); dst.append(reinterpret_cast(data), 3); } else if (c < 0x00200000) { data[0] = static_cast(((c >> 18) & 0x00000007) + 0xf0); data[1] = static_cast(((c >> 12) & 0x0000003f) + 0x80); data[2] = static_cast(((c >> 6) & 0x0000003f) + 0x80); data[3] = static_cast((c & 0x0000003f) + 0x80); dst.append(reinterpret_cast(data), 4); } else if (c < 0x04000000) { data[0] = static_cast(((c >> 24) & 0x00000003) + 0xf8); data[1] = static_cast(((c >> 18) & 0x0000003f) + 0x80); data[2] = static_cast(((c >> 12) & 0x0000003f) + 0x80); data[3] = static_cast(((c >> 6) & 0x0000003f) + 0x80); data[4] = static_cast((c & 0x0000003f) + 0x80); dst.append(reinterpret_cast(data), 5); } else if (c < 0x80000000) { data[0] = static_cast(((c >> 30) & 0x00000001) + 0xfc); data[1] = static_cast(((c >> 24) & 0x0000003f) + 0x80); data[2] = static_cast(((c >> 18) & 0x0000003f) + 0x80); data[3] = static_cast(((c >> 12) & 0x0000003f) + 0x80); data[4] = static_cast(((c >> 6) & 0x0000003f) + 0x80); data[5] = static_cast((c & 0x0000003f) + 0x80); dst.append(reinterpret_cast(data), 6); } else { assert(0 && "character out of range"); } }