/* * File: math_parser.C * Purpose: Parser for mathed * Author: Alejandro Aguilar Sierra * Created: January 1996 * Description: Parse LaTeX2e math mode code. * * Dependencies: Xlib, XForms * * Copyright: 1996, Alejandro Aguilar Sierra * * Version: 0.8beta. * * You are free to use and modify this code under the terms of * the GNU General Public Licence version 2 or later. */ /* If someone desperately needs partial "structures" (such as a few cells of an array inset or similar) (s)he could uses the following hack as starting point to write some macros: \newif\ifcomment \commentfalse \ifcomment \def\makeamptab{\catcode`\&=4\relax} \def\makeampletter{\catcode`\&=11\relax} \def\b{\makeampletter\expandafter\makeamptab\bi} \long\def\bi#1\e{} \else \def\b{}\def\e{} \fi ... \[\begin{array}{ccc} 1 & 2\b & 3^2\\ 4 & 5\e & 6\\ 7 & 8 & 9 \end{array}\] */ #include #ifdef __GNUG__ #pragma implementation #endif #include "math_parser.h" #include "math_inset.h" #include "math_arrayinset.h" #include "math_braceinset.h" #include "math_casesinset.h" #include "math_charinset.h" #include "math_deliminset.h" #include "math_factory.h" #include "math_funcinset.h" #include "math_kerninset.h" #include "math_macro.h" #include "math_macrotable.h" #include "math_macrotemplate.h" #include "math_hullinset.h" #include "math_rootinset.h" #include "math_sizeinset.h" #include "math_sqrtinset.h" #include "math_scriptinset.h" #include "math_specialcharinset.h" #include "math_splitinset.h" #include "math_sqrtinset.h" #include "math_support.h" #include "math_xyarrowinset.h" #include "lyxlex.h" #include "debug.h" #include "support/lstrings.h" #include #include #include using std::istream; using std::ostream; using std::ios; using std::endl; using std::stack; using std::fill; namespace { bool stared(string const & s) { string::size_type const n = s.size(); return n && s[n - 1] == '*'; } void add(MathArray & ar, char c, MathTextCodes code) { ar.push_back(MathAtom(new MathCharInset(c, code))); } // These are TeX's catcodes enum CatCode { catEscape, // 0 backslash catBegin, // 1 { catEnd, // 2 } catMath, // 3 $ catAlign, // 4 & catNewline, // 5 ^^M catParameter, // 6 # catSuper, // 7 ^ catSub, // 8 _ catIgnore, // 9 catSpace, // 10 space catLetter, // 11 a-zA-Z catOther, // 12 none of the above catActive, // 13 ~ catComment, // 14 % catInvalid // 15 }; CatCode theCatcode[256]; inline CatCode catcode(unsigned char c) { return theCatcode[c]; } enum { FLAG_BRACE_LAST = 1 << 1, // last closing brace ends the parsing process FLAG_RIGHT = 1 << 2, // next \\right ends the parsing process FLAG_END = 1 << 3, // next \\end ends the parsing process FLAG_BRACK_END = 1 << 4, // next closing bracket ends the parsing process FLAG_BOX = 1 << 5, // we are in a box FLAG_ITEM = 1 << 6, // read a (possibly braced token) FLAG_BLOCK = 1 << 7, // next block ends the parsing process FLAG_BLOCK2 = 1 << 8, // next block2 ends the parsing process FLAG_LEAVE = 1 << 9 // leave the loop at the end }; void catInit() { fill(theCatcode, theCatcode + 256, catOther); fill(theCatcode + 'a', theCatcode + 'z' + 1, catLetter); fill(theCatcode + 'A', theCatcode + 'Z' + 1, catLetter); theCatcode['\\'] = catEscape; theCatcode['{'] = catBegin; theCatcode['}'] = catEnd; theCatcode['$'] = catMath; theCatcode['&'] = catAlign; theCatcode['\n'] = catNewline; theCatcode['#'] = catParameter; theCatcode['^'] = catSuper; theCatcode['_'] = catSub; theCatcode[''] = catIgnore; theCatcode[' '] = catSpace; theCatcode['\t'] = catSpace; theCatcode['\r'] = catSpace; theCatcode['~'] = catActive; theCatcode['%'] = catComment; } // // Helper class for parsing // class Token { public: /// Token() : cs_(), char_(0), cat_(catIgnore) {} /// Token(char c, CatCode cat) : cs_(), char_(c), cat_(cat) {} /// Token(string const & cs) : cs_(cs), char_(0), cat_(catIgnore) {} /// string const & cs() const { return cs_; } /// CatCode cat() const { return cat_; } /// char character() const { return char_; } /// string asString() const; /// bool isCR() const; private: /// string cs_; /// char char_; /// CatCode cat_; }; bool Token::isCR() const { return cs_ == "\\" || cs_ == "cr" || cs_ == "crcr"; } string Token::asString() const { return cs_.size() ? cs_ : string(1, char_); } // Angus' compiler says these are not needed //bool operator==(Token const & s, Token const & t) //{ // return s.character() == t.character() // && s.cat() == t.cat() && s.cs() == t.cs(); //} // //bool operator!=(Token const & s, Token const & t) //{ // return !(s == t); //} ostream & operator<<(ostream & os, Token const & t) { if (t.cs().size()) os << "\\" << t.cs(); else os << "[" << t.character() << "," << t.cat() << "]"; return os; } class Parser { public: /// Parser(LyXLex & lex); /// Parser(istream & is); /// bool parse_macro(string & name); /// bool parse_normal(MathAtom &); /// void parse_into(MathArray & array, unsigned flags, MathTextCodes = LM_TC_MIN); /// int lineno() const { return lineno_; } /// void putback(); private: /// void parse_into1(MathArray & array, unsigned flags, MathTextCodes); /// string getArg(char lf, char rf); /// char getChar(); /// void error(string const & msg); /// bool parse_lines(MathAtom & t, bool numbered, bool outmost); /// parses {... & ... \\ ... & ... } bool parse_lines2(MathAtom & t); /// dump contents to screen void dump() const; private: /// void tokenize(istream & is); /// void tokenize(string const & s); /// void push_back(Token const & t); /// void pop_back(); /// Token const & prevToken() const; /// Token const & nextToken() const; /// Token const & getToken(); /// skips spaces if any void skipSpaces(); /// skips opening brace void skipBegin(); /// skips closing brace void skipEnd(); /// counts a sequence of hlines int readHLines(); /// void lex(string const & s); /// bool good() const; /// int lineno_; /// std::vector tokens_; /// unsigned pos_; /// bool curr_num_; /// string curr_label_; /// string curr_skip_; }; Parser::Parser(LyXLex & lexer) : lineno_(lexer.getLineNo()), pos_(0), curr_num_(false) { tokenize(lexer.getStream()); lexer.eatLine(); } Parser::Parser(istream & is) : lineno_(0), pos_(0), curr_num_(false) { tokenize(is); } void Parser::push_back(Token const & t) { tokens_.push_back(t); } void Parser::pop_back() { tokens_.pop_back(); } Token const & Parser::prevToken() const { static const Token dummy; return pos_ > 0 ? tokens_[pos_ - 1] : dummy; } Token const & Parser::nextToken() const { static const Token dummy; return good() ? tokens_[pos_] : dummy; } Token const & Parser::getToken() { static const Token dummy; //lyxerr << "looking at token " << tokens_[pos_] << '\n'; return good() ? tokens_[pos_++] : dummy; } void Parser::skipSpaces() { while (nextToken().cat() == catSpace) getToken(); } void Parser::skipBegin() { if (nextToken().cat() == catBegin) getToken(); else lyxerr << "'{' expected\n"; } void Parser::skipEnd() { if (nextToken().cat() == catEnd) getToken(); else lyxerr << "'}' expected\n"; } int Parser::readHLines() { int num = 0; skipSpaces(); while (nextToken().cs() == "hline") { getToken(); ++num; skipSpaces(); } return num; } void Parser::putback() { --pos_; } bool Parser::good() const { return pos_ < tokens_.size(); } char Parser::getChar() { if (!good()) lyxerr << "The input stream is not well..." << endl; return tokens_[pos_++].character(); } string Parser::getArg(char lf, char rg) { skipSpaces(); string result; char c = getChar(); if (c != lf) putback(); else while ((c = getChar()) != rg && good()) result += c; return result; } void Parser::tokenize(istream & is) { // eat everything up to the next \end_inset or end of stream // and store it in s for further tokenization string s; char c; while (is.get(c)) { s += c; if (s.size() >= 10 && s.substr(s.size() - 10) == "\\end_inset") { s = s.substr(0, s.size() - 10); break; } } // tokenize buffer tokenize(s); } void Parser::tokenize(string const & buffer) { static bool init_done = false; if (!init_done) { catInit(); init_done = true; } istringstream is(buffer.c_str(), ios::in | ios::binary); char c; while (is.get(c)) { switch (catcode(c)) { case catNewline: { ++lineno_; is.get(c); if (catcode(c) == catNewline) ; //push_back(Token("par")); else { push_back(Token(' ', catSpace)); is.putback(c); } break; } case catComment: { while (is.get(c) && catcode(c) != catNewline) ; ++lineno_; break; } case catEscape: { is.get(c); string s(1, c); if (catcode(c) == catLetter) { while (is.get(c) && catcode(c) == catLetter) s += c; if (catcode(c) == catSpace) while (is.get(c) && catcode(c) == catSpace) ; is.putback(c); } push_back(Token(s)); break; } default: push_back(Token(c, catcode(c))); } } //dump(); } void Parser::dump() const { lyxerr << "\nTokens: "; for (unsigned i = 0; i < tokens_.size(); ++i) lyxerr << tokens_[i]; lyxerr << "\n"; } void Parser::error(string const & msg) { lyxerr << "Line ~" << lineno_ << ": Math parse error: " << msg << endl; dump(); //exit(1); } bool Parser::parse_lines(MathAtom & t, bool numbered, bool outmost) { MathGridInset * p = t->asGridInset(); if (!p) { dump(); lyxerr << "error in Parser::parse_lines() 1\n"; return false; } // save global variables bool const saved_num = curr_num_; string const saved_label = curr_label_; // read initial hlines p->rowinfo(0).lines_ = readHLines(); for (int row = 0; true; ++row) { // reset global variables curr_num_ = numbered; curr_label_.erase(); // reading a row for (MathInset::col_type col = 0; col < p->ncols(); ++col) { //lyxerr << "reading cell " << row << " " << col << "\n"; MathArray & ar = p->cell(col + row * p->ncols()); parse_into(ar, FLAG_BLOCK); // remove 'unnecessary' braces: if (ar.size() == 1 && ar.back()->asBraceInset()) ar = ar.back()->asBraceInset()->cell(0); // break if cell is not followed by an ampersand if (nextToken().cat() != catAlign) { //lyxerr << "less cells read than normal in row/col: " // << row << " " << col << "\n"; break; } // skip the ampersand getToken(); } if (outmost) { MathHullInset * m = t->asHullInset(); if (!m) { lyxerr << "error in Parser::parse_lines() 2\n"; return false; } m->numbered(row, curr_num_); m->label(row, curr_label_); if (curr_skip_.size()) { m->vcrskip(LyXLength(curr_skip_), row); curr_skip_.erase(); } } // is a \\ coming? if (nextToken().isCR()) { // skip the cr-token getToken(); // try to read a length //get // read hlines for next row p->rowinfo(row + 1).lines_ = readHLines(); } // we are finished if the next token is an 'end' if (nextToken().cs() == "end") { // skip the end-token getToken(); getArg('{','}'); // leave the 'read a line'-loop break; } // otherwise, we have to start a new row p->appendRow(); } // restore "global" variables curr_num_ = saved_num; curr_label_ = saved_label; return true; } bool Parser::parse_lines2(MathAtom & t) { MathGridInset * p = t->asGridInset(); if (!p) { lyxerr << "error in Parser::parse_lines() 1\n"; return false; } skipBegin(); for (int row = 0; true; ++row) { // reading a row for (MathInset::col_type col = 0; true; ++col) { //lyxerr << "reading cell " << row << " " << col << " " << p->ncols() << "\n"; if (col >= p->ncols()) { //lyxerr << "adding col " << col << "\n"; p->addCol(p->ncols()); } parse_into(p->cell(col + row * p->ncols()), FLAG_BLOCK2); //lyxerr << "read cell: " << p->cell(col + row * p->ncols()) << "\n"; // break if cell is not followed by an ampersand if (nextToken().cat() != catAlign) { //lyxerr << "less cells read than normal in row/col: " << row << " " << col << "\n"; break; } // skip the ampersand getToken(); } // is a \\ coming? if (nextToken().isCR()) { // skip the cr-token getToken(); } // we are finished if the next token is an '}' if (nextToken().cat() == catEnd) { // skip the end-token getToken(); // leave the 'read a line'-loop break; } // otherwise, we have to start a new row p->appendRow(); } return true; } bool Parser::parse_macro(string & name) { name = "{error}"; skipSpaces(); if (getToken().cs() != "newcommand") { lyxerr << "\\newcommand expected\n"; return false; } if (getToken().cat() != catBegin) { lyxerr << "'{' in \\newcommand expected (1)\n"; return false; } name = getToken().cs(); if (getToken().cat() != catEnd) { lyxerr << "'}' expected\n"; return false; } string arg = getArg('[', ']'); int narg = arg.empty() ? 0 : atoi(arg.c_str()); if (getToken().cat() != catBegin) { lyxerr << "'{' in \\newcommand expected (2)\n"; return false; } MathArray ar; parse_into(ar, FLAG_BRACE_LAST); // we cannot handle recursive stuff at all MathArray test; test.push_back(createMathInset(name)); if (ar.contains(test)) { lyxerr << "we cannot handle recursive macros at all.\n"; return false; } MathMacroTable::create(name, narg, ar); return true; } bool Parser::parse_normal(MathAtom & matrix) { skipSpaces(); Token const & t = getToken(); if (t.cs() == "(") { matrix = MathAtom(new MathHullInset(LM_OT_SIMPLE)); parse_into(matrix->cell(0), 0); return true; } if (t.cat() == catMath) { Token const & n = getToken(); if (n.cat() == catMath) { // TeX's $$...$$ syntax for displayed math matrix = MathAtom(new MathHullInset(LM_OT_EQUATION)); MathHullInset * p = matrix->asHullInset(); parse_into(p->cell(0), 0); p->numbered(0, curr_num_); p->label(0, curr_label_); } else { // simple $...$ stuff putback(); matrix = MathAtom(new MathHullInset(LM_OT_SIMPLE)); parse_into(matrix->cell(0), 0); } return true; } if (!t.cs().size()) { lyxerr << "start of math expected, got '" << t << "'\n"; return false; } string const & cs = t.cs(); if (cs == "[") { curr_num_ = 0; curr_label_.erase(); matrix = MathAtom(new MathHullInset(LM_OT_EQUATION)); MathHullInset * p = matrix->asHullInset(); parse_into(p->cell(0), 0); p->numbered(0, curr_num_); p->label(0, curr_label_); return true; } if (cs != "begin") { lyxerr << "'begin' of un-simple math expected, got '" << cs << "'\n"; return false; } string const name = getArg('{', '}'); if (name == "math") { matrix = MathAtom(new MathHullInset(LM_OT_SIMPLE)); parse_into(matrix->cell(0), 0); return true; } if (name == "equation" || name == "equation*" || name == "displaymath") { curr_num_ = (name == "equation"); curr_label_.erase(); matrix = MathAtom(new MathHullInset(LM_OT_EQUATION)); MathHullInset * p = matrix->asHullInset(); parse_into(p->cell(0), FLAG_END); p->numbered(0, curr_num_); p->label(0, curr_label_); return true; } if (name == "eqnarray" || name == "eqnarray*") { matrix = MathAtom(new MathHullInset(LM_OT_EQNARRAY)); return parse_lines(matrix, !stared(name), true); } if (name == "align" || name == "align*") { matrix = MathAtom(new MathHullInset(LM_OT_ALIGN)); return parse_lines(matrix, !stared(name), true); } if (name == "alignat" || name == "alignat*") { int nc = 2 * atoi(getArg('{', '}').c_str()); matrix = MathAtom(new MathHullInset(LM_OT_ALIGNAT, nc)); return parse_lines(matrix, !stared(name), true); } if (name == "xalignat" || name == "xalignat*") { int nc = 2 * atoi(getArg('{', '}').c_str()); matrix = MathAtom(new MathHullInset(LM_OT_XALIGNAT, nc)); return parse_lines(matrix, !stared(name), true); } if (name == "xxalignat") { int nc = 2 * atoi(getArg('{', '}').c_str()); matrix = MathAtom(new MathHullInset(LM_OT_XXALIGNAT, nc)); return parse_lines(matrix, !stared(name), true); } if (name == "multline" || name == "multline*") { matrix = MathAtom(new MathHullInset(LM_OT_MULTLINE)); return parse_lines(matrix, !stared(name), true); } if (name == "gather" || name == "gather*") { matrix = MathAtom(new MathHullInset(LM_OT_GATHER)); return parse_lines(matrix, !stared(name), true); } lyxerr[Debug::MATHED] << "1: unknown math environment: " << name << "\n"; lyxerr << "1: unknown math environment: " << name << "\n"; return false; } void Parser::parse_into(MathArray & array, unsigned flags, MathTextCodes code) { parse_into1(array, flags, code); // remove 'unnecessary' braces: if (array.size() == 1 && array.back()->asBraceInset()) array = array.back()->asBraceInset()->cell(0); } void Parser::parse_into1(MathArray & array, unsigned flags, MathTextCodes code) { bool panic = false; int limits = 0; while (good()) { Token const & t = getToken(); //lyxerr << "t: " << t << " flags: " << flags << "\n"; //array.dump(lyxerr); //lyxerr << "\n"; if (flags & FLAG_ITEM) { flags &= ~FLAG_ITEM; if (t.cat() == catBegin) { // skip the brace and collect everything to the next matching // closing brace flags |= FLAG_BRACE_LAST; continue; } else { // handle only this single token, leave the loop if done flags |= FLAG_LEAVE; } } if (flags & FLAG_BLOCK) { if (t.cat() == catAlign || t.isCR() || t.cs() == "end") { putback(); return; } } if (flags & FLAG_BLOCK2) { if (t.cat() == catAlign || t.isCR() || t.cs() == "end" || t.cat() == catEnd) { putback(); return; } } // // cat codes // if (t.cat() == catMath) { if (flags & FLAG_BOX) { // we are inside an mbox, so opening new math is allowed array.push_back(MathAtom(new MathHullInset(LM_OT_SIMPLE))); parse_into(array.back()->cell(0), 0); } else { // otherwise this is the end of the formula break; } } else if (t.cat() == catLetter) add(array, t.character(), code); else if (t.cat() == catSpace && code == LM_TC_TEXTRM) add(array, t.character(), code); else if (t.cat() == catParameter) { Token const & n = getToken(); array.push_back(MathAtom(new MathMacroArgument(n.character()-'0', code))); } else if (t.cat() == catBegin) { MathArray ar; parse_into(ar, FLAG_BRACE_LAST); #ifndef WITH_WARNINGS #warning this might be wrong in general! #endif // ignore braces around simple items if ((ar.size() == 1 && !ar.front()->needsBraces() || (ar.size() == 2 && !ar.front()->needsBraces() && ar.back()->asScriptInset())) || (ar.size() == 0 && array.size() == 0)) { array.push_back(ar); } else { array.push_back(MathAtom(new MathBraceInset)); array.back()->cell(0).swap(ar); } } else if (t.cat() == catEnd) { if (flags & FLAG_BRACE_LAST) return; lyxerr << "found '}' unexpectedly, array: '" << array << "'\n"; //lyxerr << "found '}' unexpectedly\n"; add(array, '}', LM_TC_TEX); } else if (t.cat() == catAlign) { lyxerr << "found tab unexpectedly, array: '" << array << "'\n"; //lyxerr << "found tab unexpectedly\n"; add(array, '&', LM_TC_TEX); } else if (t.cat() == catSuper || t.cat() == catSub) { bool up = (t.cat() == catSuper); MathScriptInset * p = 0; if (array.size()) p = array.back()->asScriptInset(); if (!p || p->has(up)) { array.push_back(MathAtom(new MathScriptInset(up))); p = array.back()->asScriptInset(); } p->ensure(up); parse_into(p->cell(up), FLAG_ITEM); p->limits(limits); limits = 0; } else if (t.character() == ']' && (flags & FLAG_BRACK_END)) return; else if (t.cat() == catOther) add(array, t.character(), code); // // control sequences // else if (t.cs() == "protect") // ignore \\protect, will be re-added during output ; else if (t.cs() == "end") break; else if (t.cs() == ")") break; else if (t.cs() == "]") break; else if (t.cs() == "\\") { curr_skip_ = getArg('[', ']'); //lyxerr << "found newline unexpectedly, array: '" << array << "'\n"; lyxerr << "found newline unexpectedly\n"; array.push_back(createMathInset("\\")); } else if (t.cs() == "limits") limits = 1; else if (t.cs() == "nolimits") limits = -1; else if (t.cs() == "nonumber") curr_num_ = false; else if (t.cs() == "number") curr_num_ = true; else if (t.cs() == "sqrt") { char c = getChar(); if (c == '[') { array.push_back(MathAtom(new MathRootInset)); parse_into(array.back()->cell(0), FLAG_BRACK_END); parse_into(array.back()->cell(1), FLAG_ITEM); } else { putback(); array.push_back(MathAtom(new MathSqrtInset)); parse_into(array.back()->cell(0), FLAG_ITEM); } } else if (t.cs() == "left") { string l = getToken().asString(); MathArray ar; parse_into(ar, FLAG_RIGHT); string r = getToken().asString(); MathAtom dl(new MathDelimInset(l, r)); dl->cell(0) = ar; array.push_back(dl); } else if (t.cs() == "right") { if (!(flags & FLAG_RIGHT)) { //lyxerr << "got so far: '" << array << "'\n"; error("Unmatched right delimiter"); } return; } else if (t.cs() == "begin") { string const name = getArg('{', '}'); if (name == "array") { string const valign = getArg('[', ']') + 'c'; string const halign = getArg('{', '}'); array.push_back(MathAtom(new MathArrayInset(valign[0], halign))); parse_lines(array.back(), false, false); } else if (name == "split") { array.push_back(MathAtom(new MathSplitInset(1))); parse_lines(array.back(), false, false); } else if (name == "cases") { array.push_back(MathAtom(new MathCasesInset)); parse_lines(array.back(), false, false); } else lyxerr << "unknow math inset begin '" << name << "'\n"; } else if (t.cs() == "kern") { #ifdef WITH_WARNINGS #warning A hack... #endif string s; while (1) { Token const & t = getToken(); if (!good()) { putback(); break; } s += t.character(); if (isValidLength(s)) break; } array.push_back(MathAtom(new MathKernInset(s))); } else if (t.cs() == "label") { curr_label_ = getArg('{', '}'); } else if (t.cs() == "choose" || t.cs() == "over" || t.cs() == "atop") { MathAtom p = createMathInset(t.cs()); array.swap(p->cell(0)); parse_into(p->cell(1), flags, code); array.push_back(p); return; } else if (t.cs() == "xymatrix") { array.push_back(createMathInset(t.cs())); parse_lines2(array.back()); } #if 0 // Disabled else if (1 && t.cs() == "ar") { MathXYArrowInset * p = new MathXYArrowInset; // try to read target char c = getChar(); if (c == '[') { parse_into(p->cell(0), FLAG_BRACK_END); //lyxerr << "read target: " << p->cell(0) << "\n"; } else { putback(); } // try to read label if (nextToken().cat() == catSuper || nextToken().cat() == catSub) { p->up_ = nextToken().cat() == catSuper; getToken(); parse_into(p->cell(1), FLAG_ITEM); //lyxerr << "read label: " << p->cell(1) << "\n"; } array.push_back(MathAtom(p)); //lyxerr << "read array: " << array << "\n"; } else if (t.cs() == "mbox") { array.push_back(createMathInset(t.cs())); // slurp in the argument of mbox MathBoxInset * p = array.back()->asBoxInset(); //lyx::assert(p); } #endif else if (t.cs().size()) { latexkeys const * l = in_word_set(t.cs()); if (l) { if (l->token == LM_TK_FONT) { //lyxerr << "starting font\n"; //CatCode catSpaceSave = theCatcode[' ']; //if (l->id == LM_TC_TEXTRM) { // // temporarily change catcode // theCatcode[' '] = catLetter; //} MathArray ar; parse_into(ar, FLAG_ITEM, static_cast(l->id)); array.push_back(ar); // undo catcode changes ////theCatcode[' '] = catSpaceSave; //lyxerr << "ending font\n"; } else if (l->token == LM_TK_OLDFONT) { code = static_cast(l->id); } else if (l->token == LM_TK_BOX) { MathAtom p = createMathInset(t.cs()); parse_into(p->cell(0), FLAG_ITEM | FLAG_BOX, LM_TC_BOX); array.push_back(p); } else if (l->token == LM_TK_STY) { MathAtom p = createMathInset(t.cs()); parse_into(p->cell(0), flags, code); array.push_back(p); return; } else { MathAtom p = createMathInset(t.cs()); for (MathInset::idx_type i = 0; i < p->nargs(); ++i) parse_into(p->cell(i), FLAG_ITEM); array.push_back(p); } } else { MathAtom p = createMathInset(t.cs()); for (MathInset::idx_type i = 0; i < p->nargs(); ++i) parse_into(p->cell(i), FLAG_ITEM); array.push_back(p); } } if (flags & FLAG_LEAVE) { flags &= ~FLAG_LEAVE; break; } } if (panic) { lyxerr << " Math Panic, expect problems!\n"; // Search for the end command. Token t; do { t = getToken(); } while (good() && t.cs() != "end"); } } } // anonymous namespace void mathed_parse_cell(MathArray & ar, string const & str) { istringstream is(str.c_str()); mathed_parse_cell(ar, is); } void mathed_parse_cell(MathArray & ar, istream & is) { Parser(is).parse_into(ar, 0); } bool mathed_parse_macro(string & name, string const & str) { istringstream is(str.c_str()); Parser parser(is); return parser.parse_macro(name); } bool mathed_parse_macro(string & name, istream & is) { Parser parser(is); return parser.parse_macro(name); } bool mathed_parse_macro(string & name, LyXLex & lex) { Parser parser(lex); return parser.parse_macro(name); } bool mathed_parse_normal(MathAtom & t, string const & str) { istringstream is(str.c_str()); Parser parser(is); return parser.parse_normal(t); } bool mathed_parse_normal(MathAtom & t, istream & is) { Parser parser(is); return parser.parse_normal(t); } bool mathed_parse_normal(MathAtom & t, LyXLex & lex) { Parser parser(lex); return parser.parse_normal(t); }