// // VMime library (http://vmime.sourceforge.net) // Copyright (C) 2002-2005 Vincent Richard // // This program is free software; you can redistribute it and/or // modify it under the terms of the GNU General Public License as // published by the Free Software Foundation; either version 2 of // the License, or (at your option) any later version. // // This program 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, write to the Free Software // Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. // #include "vmime/text.hpp" #include "vmime/utility/stringUtils.hpp" #include "vmime/parserHelpers.hpp" #include "vmime/encoder.hpp" #include "vmime/encoderB64.hpp" #include "vmime/encoderQP.hpp" namespace vmime { text::text() { } text::text(const text& t) : component() { copyFrom(t); } text::text(const string& t, const charset& ch) { text::newFromString(t, ch, this); } text::text(const string& t) { text::newFromString(t, charset::getLocaleCharset(), this); } text::text(const word& w) { appendWord(new word(w)); } text::~text() { removeAllWords(); } void text::parse(const string& buffer, const string::size_type position, const string::size_type end, string::size_type* newPosition) { decodeAndUnfold(buffer.begin() + position, buffer.begin() + end, *this); setParsedBounds(position, end); if (newPosition) *newPosition = end; } void text::generate(utility::outputStream& os, const string::size_type maxLineLength, const string::size_type curLinePos, string::size_type* newLinePos) const { encodeAndFold(os, maxLineLength, curLinePos, newLinePos, 0); } #if VMIME_WIDE_CHAR_SUPPORT const wstring text::getDecodedText() const { wstring out; for (std::vector ::const_iterator i = m_words.begin() ; i != m_words.end() ; ++i) out += (*i)->getDecodedText(); return (out); } #endif void text::copyFrom(const component& other) { const text& t = dynamic_cast (other); removeAllWords(); for (std::vector ::const_iterator i = t.m_words.begin() ; i != t.m_words.end() ; ++i) m_words.push_back(new word(**i)); } text& text::operator=(const component& other) { copyFrom(other); return (*this); } text& text::operator=(const text& other) { copyFrom(other); return (*this); } const bool text::operator==(const text& t) const { if (getWordCount() == t.getWordCount()) { bool equal = true; std::vector ::const_iterator i = m_words.begin(); std::vector ::const_iterator j = t.m_words.begin(); for ( ; equal && i != m_words.end() ; ++i, ++j) equal = (**i == **j); return (equal); } return (false); } const bool text::operator!=(const text& t) const { return !(*this == t); } const string text::getConvertedText(const charset& dest) const { string out; for (std::vector ::const_iterator i = m_words.begin() ; i != m_words.end() ; ++i) out += (*i)->getConvertedText(dest); return (out); } void text::appendWord(word* w) { m_words.push_back(w); } void text::insertWordBefore(const int pos, word* w) { m_words.insert(m_words.begin() + pos, w); } void text::insertWordAfter(const int pos, word* w) { m_words.insert(m_words.begin() + pos + 1, w); } void text::removeWord(const int pos) { const std::vector ::iterator it = m_words.begin() + pos; delete (*it); m_words.erase(it); } void text::removeAllWords() { free_container(m_words); } const int text::getWordCount() const { return (m_words.size()); } const bool text::isEmpty() const { return (m_words.empty()); } word* text::getWordAt(const int pos) { return (m_words[pos]); } const word* const text::getWordAt(const int pos) const { return (m_words[pos]); } const std::vector text::getWordList() const { std::vector list; list.reserve(m_words.size()); for (std::vector ::const_iterator it = m_words.begin() ; it != m_words.end() ; ++it) { list.push_back(*it); } return (list); } const std::vector text::getWordList() { return (m_words); } text* text::clone() const { return new text(*this); } text* text::newFromString(const string& in, const charset& ch, text* generateInExisting) { const string::const_iterator end = in.end(); string::const_iterator p = in.begin(); string::const_iterator start = in.begin(); bool is8bit = false; // is the current word 8-bit? bool prevIs8bit = false; // is previous word 8-bit? unsigned int count = 0; // total number of words text* out = (generateInExisting != NULL) ? generateInExisting : new text(); out->removeAllWords(); for ( ; ; ) { if (p == end || isspace(*p)) { if (p != end) ++p; if (is8bit) { if (count && prevIs8bit) { // No need to create a new encoded word, just append // the current word to the previous one. out->getWordAt(out->getWordCount() - 1)-> getBuffer() += string(start, p); } else { out->appendWord(new word(string(start, p), ch)); prevIs8bit = true; ++count; } } else { if (count && !prevIs8bit) { out->getWordAt(out->getWordCount() - 1)-> getBuffer() += string(start, p); } else { out->appendWord(new word (string(start, p), charset(charsets::US_ASCII))); prevIs8bit = false; ++count; } } if (p == end) break; is8bit = false; start = p; } else if (!isascii(*p)) { is8bit = true; ++p; } else { ++p; } } return (out); } void text::encodeAndFold(utility::outputStream& os, const string::size_type maxLineLength, const string::size_type firstLineOffset, string::size_type* lastLineLength, const int flags) const { string::size_type curLineLength = firstLineOffset; for (int wi = 0 ; wi < getWordCount() ; ++wi) { const word& w = *getWordAt(wi); const string& buffer = w.getBuffer(); // Calculate the number of ASCII chars to check whether encoding is needed // and _which_ encoding to use. const string::size_type asciiCount = utility::stringUtils::countASCIIchars(buffer.begin(), buffer.end()); bool noEncoding = (flags & FORCE_NO_ENCODING) || (!(flags & FORCE_ENCODING) && asciiCount == buffer.length()); if (noEncoding) { // We will fold lines without encoding them. string::const_iterator lastWSpos = buffer.end(); // last white-space position string::const_iterator curLineStart = buffer.begin(); // current line start string::const_iterator p = buffer.begin(); const string::const_iterator end = buffer.end(); bool finished = false; bool newLine = false; while (!finished) { for ( ; p != end ; ++p, ++curLineLength) { // Exceeded maximum line length, but we have found a white-space // where we can cut the line... if (curLineLength >= maxLineLength && lastWSpos != end) break; if (*p == ' ' || *p == '\t') { // Remember the position of this white-space character lastWSpos = p; } } if (p != end) ++curLineLength; //if (p == end || curLineLength >= maxLineLength) { if (p == end || lastWSpos == end) { // If we are here, it means that we have found no whitespace // before the first "maxLineLength" characters. In this case, // we write the full line no matter of the max line length... if (!newLine && p != end && lastWSpos == end && wi != 0 && curLineStart == buffer.begin()) { // Here, we are continuing on the line of previous encoded // word, but there is not even enough space to put the // first word of this line, so we start a new line. if (flags & NO_NEW_LINE_SEQUENCE) { os << CRLF; curLineLength = 0; } else { os << NEW_LINE_SEQUENCE; curLineLength = NEW_LINE_SEQUENCE_LENGTH; } p = curLineStart; lastWSpos = end; newLine = true; } else { os << string(curLineStart, p); if (p == end) { finished = true; } else { if (flags & NO_NEW_LINE_SEQUENCE) { os << CRLF; curLineLength = 0; } else { os << NEW_LINE_SEQUENCE; curLineLength = NEW_LINE_SEQUENCE_LENGTH; } curLineStart = p; lastWSpos = end; newLine = true; } } } else { // In this case, there will not be enough space on the line for all the // characters _after_ the last white-space; so we cut the line at this // last white-space. #if 1 if (curLineLength != 1 && wi != 0) os << " "; // Separate from previous word #endif os << string(curLineStart, lastWSpos); if (flags & NO_NEW_LINE_SEQUENCE) { os << CRLF; curLineLength = 0; } else { os << NEW_LINE_SEQUENCE; curLineLength = NEW_LINE_SEQUENCE_LENGTH; } curLineStart = lastWSpos + 1; p = lastWSpos + 1; lastWSpos = end; newLine = true; } } } } /* RFC #2047: 4. Encodings Initially, the legal values for "encoding" are "Q" and "B". These encodings are described below. The "Q" encoding is recommended for use when most of the characters to be encoded are in the ASCII character set; otherwise, the "B" encoding should be used. Nevertheless, a mail reader which claims to recognize 'encoded-word's MUST be able to accept either encoding for any character set which it supports. */ else { // We will encode _AND_ fold lines /* RFC #2047: 2. Syntax of encoded-words " While there is no limit to the length of a multiple-line header field, each line of a header field that contains one or more 'encoded-word's is limited to 76 characters. " */ const string::size_type maxLineLength3 = (maxLineLength == lineLengthLimits::infinite) ? maxLineLength : std::min(maxLineLength, static_cast (76)); // Base64 if more than 60% non-ascii, quoted-printable else (default) const string::size_type asciiPercent = (100 * asciiCount) / buffer.length(); const string::value_type encoding = (asciiPercent <= 40) ? 'B' : 'Q'; string wordStart("=?" + w.getCharset().getName() + "?" + encoding + "?"); string wordEnd("?="); const string::size_type minWordLength = wordStart.length() + wordEnd.length(); const string::size_type maxLineLength2 = (maxLineLength3 < minWordLength + 1) ? maxLineLength3 + minWordLength + 1 : maxLineLength3; // Checks whether remaining space on this line is usable. If too few // characters can be encoded, start a new line. bool startNewLine = true; if (curLineLength + 2 < maxLineLength2) { const string::size_type remainingSpaceOnLine = maxLineLength2 - curLineLength - 2; if (remainingSpaceOnLine < minWordLength + 10) { // Space for no more than 10 encoded chars! // It is not worth while to continue on this line... startNewLine = true; } else { // OK, there is enough usable space on the current line. startNewLine = false; } } if (startNewLine) { os << NEW_LINE_SEQUENCE; curLineLength = NEW_LINE_SEQUENCE_LENGTH; } // Encode and fold input buffer string::const_iterator pos = buffer.begin(); string::size_type remaining = buffer.length(); encoder* theEncoder; if (encoding == 'B') theEncoder == new encoderB64; else theEncoder = new encoderQP; string qpEncodedBuffer; if (encoding == 'Q') { theEncoder->getProperties()["rfc2047"] = true; // In the case of Quoted-Printable encoding, we cannot simply encode input // buffer line by line. So, we encode the whole buffer and we will fold it // in the next loop... utility::inputStreamStringAdapter in(buffer); utility::outputStreamStringAdapter out(qpEncodedBuffer); theEncoder->encode(in, out); pos = qpEncodedBuffer.begin(); remaining = qpEncodedBuffer.length(); } #if 1 if (curLineLength != 1 && wi != 0) { os << " "; // Separate from previous word ++curLineLength; } #endif for ( ; remaining ; ) { // Start a new encoded word os << wordStart; curLineLength += minWordLength; // Compute the number of encoded chars that will fit on this line const string::size_type fit = maxLineLength2 - curLineLength; // Base-64 encoding if (encoding == 'B') { // TODO: WARNING! "Any encoded word which encodes a non-integral // number of characters or octets is incorrectly formed." // Here, we have a formula to compute the maximum number of source // characters to encode knowing the maximum number of encoded chars // (with Base64, 3 bytes of input provide 4 bytes of output). string::size_type count = (fit > 1) ? ((fit - 1) * 3) / 4 : 1; if (count > remaining) count = remaining; utility::inputStreamStringAdapter in (buffer, pos - buffer.begin(), pos - buffer.begin() + count); curLineLength += theEncoder->encode(in, os); pos += count; remaining -= count; } // Quoted-Printable encoding else { // TODO: WARNING! "Any encoded word which encodes a non-integral // number of characters or octets is incorrectly formed." // All we have to do here is to take a certain number of character // (that is less than or equal to "fit") from the QP encoded buffer, // but we also make sure not to fold a "=XY" encoded char. const string::const_iterator qpEnd = qpEncodedBuffer.end(); string::const_iterator lastFoldPos = pos; string::const_iterator p = pos; string::size_type n = 0; while (n < fit && p != qpEnd) { if (*p == '=') { if (n + 3 >= fit) { lastFoldPos = p; break; } p += 3; n += 3; } else { ++p; ++n; } } if (lastFoldPos == pos) lastFoldPos = p; os << string(pos, lastFoldPos); curLineLength += (lastFoldPos - pos) + 1; pos += n; remaining -= n; } // End of the encoded word os << wordEnd; if (remaining) { os << NEW_LINE_SEQUENCE; curLineLength = NEW_LINE_SEQUENCE_LENGTH; } } delete (theEncoder); } } if (lastLineLength) *lastLineLength = curLineLength; } text* text::decodeAndUnfold(const string& in, text* generateInExisting) { text* out = (generateInExisting != NULL) ? generateInExisting : new text(); out->removeAllWords(); decodeAndUnfold(in.begin(), in.end(), *out); return (out); } void text::decodeAndUnfold(const string::const_iterator& inStart, const string::const_iterator& inEnd, text& out) { // NOTE: See RFC-2047, Pages 11-12 for knowing about handling // of white-spaces between encoded words. out.removeAllWords(); string::const_iterator p = inStart; const string::const_iterator end = inEnd; const charset defaultCharset(charsets::US_ASCII); charset prevWordCharset(defaultCharset); bool prevIsEncoded = false; string::const_iterator prevPos = p; for ( ; ; ) { if (p == end || *p == '\n') { string::const_iterator textEnd = p; if (textEnd != inStart && *(textEnd - 1) == '\r') --textEnd; if (textEnd != prevPos) { if (!out.isEmpty() && prevWordCharset == defaultCharset) { out.getWordAt(out.getWordCount() - 1)->getBuffer() += string(prevPos, textEnd); } else { prevWordCharset = defaultCharset; out.appendWord(new word(string(prevPos, textEnd), defaultCharset)); prevIsEncoded = false; } } if (p == end) { // Finished break; } // Skip the new-line character prevPos = ++p; } else if (*p == '=' && (p + 1) != end && *(p + 1) == '?') { string::const_iterator wordPos = p; p += 2; // skip '=?' if (p != end) { const string::const_iterator charsetPos = p; for ( ; p != end && *p != '?' ; ++p); if (p != end) // a charset is specified { const string::const_iterator charsetEnd = p; const string::const_iterator encPos = ++p; // skip '?' for ( ; p != end && *p != '?' ; ++p); if (p != end) // an encoding is specified { //const string::const_iterator encEnd = p; const string::const_iterator dataPos = ++p; // skip '?' for ( ; p != end && !(*p == '?' && *(p + 1) == '=') ; ++p); if (p != end) // some data is specified { const string::const_iterator dataEnd = p; p += 2; // skip '?=' encoder* theEncoder = NULL; // Base-64 encoding if (*encPos == 'B' || *encPos == 'b') { theEncoder = new encoderB64; } // Quoted-Printable encoding else if (*encPos == 'Q' || *encPos == 'q') { theEncoder = new encoderQP; theEncoder->getProperties()["rfc2047"] = true; } if (theEncoder) { // Decode text string decodedBuffer; utility::inputStreamStringAdapter ein(string(dataPos, dataEnd)); utility::outputStreamStringAdapter eout(decodedBuffer); theEncoder->decode(ein, eout); delete (theEncoder); // Append all the unencoded text before this word if (prevPos != wordPos) { string::const_iterator p = prevPos; if (prevIsEncoded) { // Check whether there are only white-spaces between // the two encoded words for ( ; (p != wordPos) && isspace(*p) ; ++p); } if (p != wordPos) // if not empty { if (!out.isEmpty() && prevWordCharset == defaultCharset) { out.getWordAt(out.getWordCount() - 1)-> getBuffer() += string(prevPos, wordPos); } else { out.appendWord(new word (string(prevPos, wordPos), defaultCharset)); prevWordCharset = defaultCharset; } } } // Append this fresh decoded word to output text charset thisCharset(string(charsetPos, charsetEnd)); if (!out.isEmpty() && prevWordCharset == thisCharset) { out.getWordAt(out.getWordCount() - 1)-> getBuffer() += decodedBuffer; } else { prevWordCharset = thisCharset; out.appendWord(new word(decodedBuffer, thisCharset)); } // This word has been decoded: we can advance in the input buffer prevPos = p; prevIsEncoded = true; } else { // Unknown encoding: can't decode this word, we will // treat this word as ordinary text (RFC-2047, Page 9). } } } } } } else { ++p; } for ( ; p != end && *p != '=' && *p != '\n' ; ++p); } } const std::vector text::getChildComponents() const { // TODO: 'word' should inherit from 'component' return std::vector (); } } // vmime