/* * This program source code file is part of KiCad, a free EDA CAD application. * * Copyright (C) 2007-2013 SoftPLC Corporation, Dick Hollenbeck * Copyright (C) 2007-2015 KiCad Developers, see change_log.txt for contributors. * * 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, you may find one here: * http://www.gnu.org/licenses/old-licenses/gpl-2.0.html * or you may search the http://www.gnu.org website for the version 2 license, * or you may write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA */ #include #include #include // bsearch() #include #include #include #include //#define STANDALONE 1 // enable this for stand alone testing. #define FMT_CLIPBOARD _( "clipboard" ) //------------------------------------------------------------------ void DSNLEXER::init() { curTok = DSN_NONE; prevTok = DSN_NONE; stringDelimiter = '"'; specctraMode = false; space_in_quoted_tokens = false; commentsAreTokens = false; curOffset = 0; #if 1 if( keywordCount > 11 ) { // resize the hashtable bucket count keyword_hash.reserve( keywordCount ); } // fill the specialized "C string" hashtable from keywords[] const KEYWORD* it = keywords; const KEYWORD* end = it + keywordCount; for( ; it < end; ++it ) { keyword_hash[it->name] = it->token; } #endif } DSNLEXER::DSNLEXER( const KEYWORD* aKeywordTable, unsigned aKeywordCount, FILE* aFile, const wxString& aFilename ) : iOwnReaders( true ), start( NULL ), next( NULL ), limit( NULL ), reader( NULL ), keywords( aKeywordTable ), keywordCount( aKeywordCount ) { FILE_LINE_READER* fileReader = new FILE_LINE_READER( aFile, aFilename ); PushReader( fileReader ); init(); } DSNLEXER::DSNLEXER( const KEYWORD* aKeywordTable, unsigned aKeywordCount, const std::string& aClipboardTxt, const wxString& aSource ) : iOwnReaders( true ), start( NULL ), next( NULL ), limit( NULL ), reader( NULL ), keywords( aKeywordTable ), keywordCount( aKeywordCount ) { STRING_LINE_READER* stringReader = new STRING_LINE_READER( aClipboardTxt, aSource.IsEmpty() ? wxString( FMT_CLIPBOARD ) : aSource ); PushReader( stringReader ); init(); } DSNLEXER::DSNLEXER( const KEYWORD* aKeywordTable, unsigned aKeywordCount, LINE_READER* aLineReader ) : iOwnReaders( false ), start( NULL ), next( NULL ), limit( NULL ), reader( NULL ), keywords( aKeywordTable ), keywordCount( aKeywordCount ) { if( aLineReader ) PushReader( aLineReader ); init(); } static const KEYWORD empty_keywords[1] = {}; DSNLEXER::DSNLEXER( const std::string& aSExpression, const wxString& aSource ) : iOwnReaders( true ), start( NULL ), next( NULL ), limit( NULL ), reader( NULL ), keywords( empty_keywords ), keywordCount( 0 ) { STRING_LINE_READER* stringReader = new STRING_LINE_READER( aSExpression, aSource.IsEmpty() ? wxString( FMT_CLIPBOARD ) : aSource ); PushReader( stringReader ); init(); } DSNLEXER::~DSNLEXER() { if( iOwnReaders ) { // delete the LINE_READERs from the stack, since I own them. for( READER_STACK::iterator it = readerStack.begin(); it!=readerStack.end(); ++it ) delete *it; } } void DSNLEXER::SetSpecctraMode( bool aMode ) { specctraMode = aMode; if( aMode ) { // specctra mode defaults, some of which can still be changed in this mode. space_in_quoted_tokens = true; } else { space_in_quoted_tokens = false; stringDelimiter = '"'; } } bool DSNLEXER::SyncLineReaderWith( DSNLEXER& aLexer ) { // Synchronize the pointers handling the data read by the LINE_READER // only if aLexer shares the same LINE_READER, because only in this case // the char buffer is be common if( reader != aLexer.reader ) return false; // We can synchronize the pointers which handle the data currently read start = aLexer.start; next = aLexer.next; limit = aLexer.limit; // Sync these parameters is not mandatory, but could help // for instance in debug curText = aLexer.curText; curOffset = aLexer.curOffset; return true; } void DSNLEXER::PushReader( LINE_READER* aLineReader ) { readerStack.push_back( aLineReader ); reader = aLineReader; start = (const char*) (*reader); // force a new readLine() as first thing. limit = start; next = start; } LINE_READER* DSNLEXER::PopReader() { LINE_READER* ret = 0; if( readerStack.size() ) { ret = reader; readerStack.pop_back(); if( readerStack.size() ) { reader = readerStack.back(); start = reader->Line(); // force a new readLine() as first thing. limit = start; next = start; } else { reader = 0; start = dummy; limit = dummy; } } return ret; } int DSNLEXER::findToken( const std::string& tok ) { KEYWORD_MAP::const_iterator it = keyword_hash.find( tok.c_str() ); if( it != keyword_hash.end() ) return it->second; return DSN_SYMBOL; // not a keyword, some arbitrary symbol. } const char* DSNLEXER::Syntax( int aTok ) { const char* ret; switch( aTok ) { case DSN_NONE: ret = "NONE"; break; case DSN_STRING_QUOTE: ret = "string_quote"; // a special DSN syntax token, see specctra spec. break; case DSN_QUOTE_DEF: ret = "quoted text delimiter"; break; case DSN_DASH: ret = "-"; break; case DSN_SYMBOL: ret = "symbol"; break; case DSN_NUMBER: ret = "number"; break; case DSN_RIGHT: ret = ")"; break; case DSN_LEFT: ret = "("; break; case DSN_STRING: ret = "quoted string"; break; case DSN_EOF: ret = "end of input"; break; default: ret = "???"; } return ret; } const char* DSNLEXER::GetTokenText( int aTok ) { const char* ret; if( aTok < 0 ) { return Syntax( aTok ); } else if( (unsigned) aTok < keywordCount ) { ret = keywords[aTok].name; } else ret = "token too big"; return ret; } wxString DSNLEXER::GetTokenString( int aTok ) { wxString ret; ret << wxT("'") << wxString::FromUTF8( GetTokenText(aTok) ) << wxT("'"); return ret; } bool DSNLEXER::IsSymbol( int aTok ) { // This is static and not inline to reduce code space. // if aTok is >= 0, then it is a coincidental match to a keyword. return aTok==DSN_SYMBOL || aTok==DSN_STRING || aTok>=0; } void DSNLEXER::Expecting( int aTok ) { wxString errText = wxString::Format( _( "Expecting %s" ), GetChars( GetTokenString( aTok ) ) ); THROW_PARSE_ERROR( errText, CurSource(), CurLine(), CurLineNumber(), CurOffset() ); } void DSNLEXER::Expecting( const char* text ) { wxString errText = wxString::Format( _( "Expecting '%s'" ), GetChars( wxString::FromUTF8( text ) ) ); THROW_PARSE_ERROR( errText, CurSource(), CurLine(), CurLineNumber(), CurOffset() ); } void DSNLEXER::Unexpected( int aTok ) { wxString errText = wxString::Format( _( "Unexpected %s" ), GetChars( GetTokenString( aTok ) ) ); THROW_PARSE_ERROR( errText, CurSource(), CurLine(), CurLineNumber(), CurOffset() ); } void DSNLEXER::Duplicate( int aTok ) { wxString errText = wxString::Format( _("%s is a duplicate"), GetTokenString( aTok ).GetData() ); THROW_PARSE_ERROR( errText, CurSource(), CurLine(), CurLineNumber(), CurOffset() ); } void DSNLEXER::Unexpected( const char* text ) { wxString errText = wxString::Format( _( "Unexpected '%s'" ), GetChars( wxString::FromUTF8( text ) ) ); THROW_PARSE_ERROR( errText, CurSource(), CurLine(), CurLineNumber(), CurOffset() ); } void DSNLEXER::NeedLEFT() { int tok = NextTok(); if( tok != DSN_LEFT ) Expecting( DSN_LEFT ); } void DSNLEXER::NeedRIGHT() { int tok = NextTok(); if( tok != DSN_RIGHT ) Expecting( DSN_RIGHT ); } int DSNLEXER::NeedSYMBOL() { int tok = NextTok(); if( !IsSymbol( tok ) ) Expecting( DSN_SYMBOL ); return tok; } int DSNLEXER::NeedSYMBOLorNUMBER() { int tok = NextTok(); if( !IsSymbol( tok ) && tok!=DSN_NUMBER ) Expecting( "a symbol or number" ); return tok; } int DSNLEXER::NeedNUMBER( const char* aExpectation ) { int tok = NextTok(); if( tok != DSN_NUMBER ) { wxString errText = wxString::Format( _( "need a number for '%s'" ), wxString::FromUTF8( aExpectation ).GetData() ); THROW_PARSE_ERROR( errText, CurSource(), CurLine(), CurLineNumber(), CurOffset() ); } return tok; } /** * Function isSpace * tests for whitespace. Our whitespace, by our definition, is a subset of ASCII, * i.e. no bytes with MSB on can be considered whitespace, since they are likely part * of a multibyte UTF8 character. */ static bool isSpace( char cc ) { // cc is signed, so it is often negative. // Treat negative as large positive to exclude rapidly. if( (unsigned char) cc <= ' ' ) { switch( (unsigned char) cc ) { case ' ': case '\n': case '\r': case '\t': case '\0': // PCAD s-expression files have this. return true; } } return false; } inline bool isDigit( char cc ) { return '0' <= cc && cc <= '9'; } /// return true if @a cc is an s-expression separator character inline bool isSep( char cc ) { return isSpace( cc ) || cc=='(' || cc==')'; } /** * Function isNumber * returns true if the next sequence of text is a number: * either an integer, fixed point, or float with exponent. Stops scanning * at the first non-number character, even if it is not whitespace. * * @param cp is the start of the current token. * @param limit is the end of the current token. * * @return bool - true if input token is a number, else false. */ static bool isNumber( const char* cp, const char* limit ) { // regex for a float: "^[-+]?[0-9]*\\.?[0-9]+([eE][-+]?[0-9]+)?" i.e. any number, // code traversal manually here: bool sawNumber = false; if( cp < limit && ( *cp=='-' || *cp=='+' ) ) ++cp; while( cp < limit && isDigit( *cp ) ) { ++cp; sawNumber = true; } if( cp < limit && *cp == '.' ) { ++cp; while( cp < limit && isDigit( *cp ) ) { ++cp; sawNumber = true; } } if( sawNumber ) { if( cp < limit && ( *cp=='E' || *cp=='e' ) ) { ++cp; sawNumber = false; // exponent mandates at least one digit thereafter. if( cp < limit && ( *cp=='-' || *cp=='+' ) ) ++cp; while( cp < limit && isDigit( *cp ) ) { ++cp; sawNumber = true; } } } return sawNumber && cp==limit; } int DSNLEXER::NextTok() { const char* cur = next; const char* head = cur; prevTok = curTok; if( curTok == DSN_EOF ) goto exit; if( cur >= limit ) { L_read: // blank lines are returned as "\n" and will have a len of 1. // EOF will have a len of 0 and so is detectable. int len = readLine(); if( len == 0 ) { cur = start; // after readLine(), since start can change, set cur offset to start curTok = DSN_EOF; goto exit; } cur = start; // after readLine() since start can change. // skip leading whitespace while( cur= limit ) goto L_read; if( *cur == '(' ) { curText = *cur; curTok = DSN_LEFT; head = cur+1; goto exit; } if( *cur == ')' ) { curText = *cur; curTok = DSN_RIGHT; head = cur+1; goto exit; } // Non-specctraMode, understands and deciphers escaped \, \r, \n, and \". // Strips off leading and trailing double quotes if( !specctraMode ) { // a quoted string, will return DSN_STRING if( *cur == stringDelimiter ) { // copy the token, character by character so we can remove doubled up quotes. curText.clear(); ++cur; // skip over the leading delimiter, which is always " in non-specctraMode head = cur; while( head= limit ) break; // throw exception at L_unterminated switch( *head++ ) { case '"': case '\\': c = head[-1]; break; case 'a': c = '\x07'; break; case 'b': c = '\x08'; break; case 'f': c = '\x0c'; break; case 'n': c = '\n'; break; case 'r': c = '\r'; break; case 't': c = '\x09'; break; case 'v': c = '\x0b'; break; case 'x': // 1 or 2 byte hex escape sequence for( i=0; i<2; ++i ) { if( !isxdigit( head[i] ) ) break; tbuf[i] = head[i]; } tbuf[i] = '\0'; if( i > 0 ) c = (char) strtoul( tbuf, NULL, 16 ); else c = 'x'; // a goofed hex escape sequence, interpret as 'x' head += i; break; default: // 1-3 byte octal escape sequence --head; for( i=0; i<3; ++i ) { if( head[i] < '0' || head[i] > '7' ) break; tbuf[i] = head[i]; } tbuf[i] = '\0'; if( i > 0 ) c = (char) strtoul( tbuf, NULL, 8 ); else c = '\\'; // a goofed octal escape sequence, interpret as '\' head += i; break; } curText += c; } else if( *head == '"' ) // end of the non-specctraMode DSN_STRING { curTok = DSN_STRING; ++head; // omit this trailing double quote goto exit; } else curText += *head++; } // while // L_unterminated: wxString errtxt( _( "Un-terminated delimited string" ) ); THROW_PARSE_ERROR( errtxt, CurSource(), CurLine(), CurLineNumber(), CurOffset() ); } } else // is specctraMode, tests in this block should not occur in KiCad mode. { /* get the dash out of a which is embedded for example like: U2-14 or "U2"-"14" This is detectable by a non-space immediately preceeding the dash. */ if( *cur == '-' && cur>start && !isSpace( cur[-1] ) ) { curText = '-'; curTok = DSN_DASH; head = cur+1; goto exit; } // switching the string_quote character if( prevTok == DSN_STRING_QUOTE ) { static const wxString errtxt( _("String delimiter must be a single character of ', \", or $")); char cc = *cur; switch( cc ) { case '\'': case '$': case '"': break; default: THROW_PARSE_ERROR( errtxt, CurSource(), CurLine(), CurLineNumber(), CurOffset() ); } curText = cc; head = cur+1; if( head= limit ) { wxString errtxt( _( "Un-terminated delimited string" ) ); THROW_PARSE_ERROR( errtxt, CurSource(), CurLine(), CurLineNumber(), CurOffset() ); } curText.clear(); curText.append( cur, head ); ++head; // skip over the trailing delimiter curTok = DSN_STRING; goto exit; } } // specctraMode // non-quoted token, read it into curText. curText.clear(); head = cur; while( headAdd( FromUTF8() ); } while( ( tok = NextTok() ) == DSN_COMMENT ); } SetCommentsAreTokens( cmt_setting ); return ret; }