/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */
/*
* This file is part of the LibreOffice project.
*
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/.
*
* This file incorporates work covered by the following license notice:
*
* Licensed to the Apache Software Foundation (ASF) under one or more
* contributor license agreements. See the NOTICE file distributed
* with this work for additional information regarding copyright
* ownership. The ASF licenses this file to you under the Apache
* License, Version 2.0 (the "License"); you may not use this file
* except in compliance with the License. You may obtain a copy of
* the License at http://www.apache.org/licenses/LICENSE-2.0 .
*/
#include "mathtype.hxx"
#include <filter/msfilter/classids.hxx>
#include <osl/diagnose.h>
#include <sfx2/docfile.hxx>
#include <sot/storage.hxx>
#include <sal/log.hxx>
#include "eqnolefilehdr.hxx"
#include <node.hxx>
void MathType::Init()
{
//These are the default MathType sizes
aSizeTable.push_back(12);
aSizeTable.push_back(8);
aSizeTable.push_back(6);
aSizeTable.push_back(24);
aSizeTable.push_back(10);
aSizeTable.push_back(12);
aSizeTable.push_back(12);
/*
These are the default MathType italic/bold settings If mathtype is changed
from its defaults, there is nothing we can do, as this information is not
stored in the document
*/
MathTypeFont aFont;
for(sal_uInt8 i=1;i<=11;i++)
{
aFont.nTface = i+128;
switch (i)
{
default:
aFont.nStyle=0;
break;
case 3:
case 4:
aFont.nStyle=1;
break;
case 7:
aFont.nStyle=2;
break;
}
aUserStyles.insert(aFont);
}
}
/*ToDo replace with table rather than switch, returns
sal_True in the case that the char is just a char, and
sal_False if the character is an operator which must not be
placed inside the quote sequence designed to protect
against being parsed as a keyword
General solution required to force starmath to handle
unicode math chars the way it handles its own math
chars rather than handle them as text as it will do
for the default case below, i.e. incorrect spacing
between math symbols and ordinary text e.g. 1=2 rather
than 1 = 2
*/
bool MathType::LookupChar(sal_Unicode nChar,OUStringBuffer &rRet,sal_uInt8 nVersion,
sal_uInt8 nTypeFace)
{
bool bRet=false;
const char *pC = nullptr;
switch(nChar)
{
case 0x0000:
pC = " none ";
break;
case 0x00ac:
pC = " neg ";
break;
case 0x00b1:
pC = " +- ";
break;
case '(':
pC = " \\( ";
break;
case ')':
pC = " \\) ";
break;
case '[':
pC = " \\[ ";
break;
case ']':
pC = " \\] ";
break;
case '.':
pC = " \".\" ";
break;
case 0xae:
if ((nVersion < 3) && (nTypeFace == 0x86))
pC = " rightarrow ";
else
{
rRet.append(OUStringLiteral1(nChar));
bRet=true;
}
break;
case 0x00fb:
if ((nVersion < 3) && (nTypeFace == 0x81))
nChar = 0xDF;
rRet.append(OUStringLiteral1(nChar));
bRet=true;
break;
case 'a':
if ((nVersion < 3) && (nTypeFace == 0x84))
nChar = 0x3b1;
rRet.append(OUStringLiteral1(nChar));
bRet=true;
break;
case 'b':
if ((nVersion < 3) && (nTypeFace == 0x84))
nChar = 0x3b2;
rRet.append(OUStringLiteral1(nChar));
bRet=true;
break;
case 'l':
if ((nVersion < 3) && (nTypeFace == 0x84))
nChar = 0x3bb;
rRet.append(OUStringLiteral1(nChar));
bRet=true;
break;
case 'n':
if ((nVersion < 3) && (nTypeFace == 0x84))
nChar = 0x3bd;
rRet.append(OUStringLiteral1(nChar));
bRet=true;
break;
case 'r':
if ((nVersion < 3) && (nTypeFace == 0x84))
nChar = 0x3c1;
rRet.append(OUStringLiteral1(nChar));
bRet=true;
break;
case 'D':
if ((nVersion < 3) && (nTypeFace == 0x84))
nChar = 0x394;
rRet.append(OUStringLiteral1(nChar));
bRet=true;
break;
case 0xa9:
if ((nVersion < 3) && (nTypeFace == 0x82))
nChar = '\'';
rRet.append(OUStringLiteral1(nChar));
bRet=true;
break;
case 0x00f1:
if ((nVersion < 3) && (nTypeFace == 0x86))
pC = " \\rangle ";
else
{
rRet.append(OUStringLiteral1(nChar));
bRet=true;
}
break;
case 0x00a3:
if ((nVersion < 3) && (nTypeFace == 0x86))
pC = " <= ";
else
{
rRet.append(OUStringLiteral1(nChar));
bRet=true;
}
break;
case 0x00de:
if ((nVersion < 3) && (nTypeFace == 0x86))
pC = " drarrow ";
else
{
rRet.append(OUStringLiteral1(nChar));
bRet=true;
}
break;
case 0x0057:
if ((nVersion < 3) && (nTypeFace == 0x85))
pC = " %OMEGA ";
else
{
rRet.append(OUStringLiteral1(nChar));
bRet=true;
}
break;
case 0x007b:
pC = " lbrace ";
break;
case 0x007c:
pC = " \\lline ";
break;
case 0x007d:
pC = " rbrace ";
break;
case 0x007e:
pC = " \"~\" ";
break;
case 0x2224:
pC = " ndivides ";
break;
case 0x2225:
pC = " parallel ";
break;
case 0x00d7:
if (nVersion < 3)
pC = " cdot ";
else
pC = " times ";
break;
case 0x00f7:
pC = " div ";
break;
case 0x019b:
pC = " lambdabar ";
break;
case 0x2026:
pC = " dotslow ";
break;
case 0x2022:
pC = " cdot ";
break;
case 0x2102:
pC = " setC ";
break;
case 0x210f:
pC = " hbar ";
break;
case 0x2111:
pC = " Im ";
break;
case 0x2115:
pC = " setN ";
break;
case 0x2118:
pC = " wp ";
break;
case 0x211a:
pC = " setQ ";
break;
case 0x211c:
pC = " Re ";
break;
case 0x211d:
pC = " setR ";
break;
case 0x2124:
pC = " setZ ";
break;
case 0x2135:
pC = " aleph ";
break;
case 0x2190:
pC = " leftarrow ";
break;
case 0x2191:
pC = " uparrow ";
break;
case 0x2192:
pC = " rightarrow ";
break;
case 0x0362:
pC = " widevec ";
break;
case 0x2193:
pC = " downarrow ";
break;
case 0x21d0:
pC = " dlarrow ";
break;
case 0x21d2:
pC = " drarrow ";
break;
case 0x21d4:
pC = " dlrarrow ";
break;
case 0x2200:
pC = " forall ";
break;
case 0x2202:
pC = " partial ";
break;
case 0x2203:
pC = " exists ";
break;
case 0x2204:
pC = " notexists ";
break;
case 0x2205:
pC = " emptyset ";
break;
case 0x2207:
pC = " nabla ";
break;
case 0x2208: // in
case 0x2209: // notin
rRet.append(" func ").append(OUStringLiteral1(nChar)).append(" ");
break;
case 0x220d: // owns
rRet.append(" func ").append(OUStringLiteral1(0x220b)).append(" ");
break;
case 0x220f:
pC = " prod ";
break;
case 0x2210:
pC = " coprod ";
break;
case 0x2211:
pC = " sum ";
break;
case 0x2212:
pC = " - ";
break;
case 0x2213:
pC = " -+ ";
break;
case 0x2217:
pC = " * ";
break;
case 0x2218:
pC = " circ ";
break;
case 0x221d:
pC = " prop ";
break;
case 0x221e:
pC = " infinity ";
break;
case 0x2227:
pC = " and ";
break;
case 0x2228:
pC = " or ";
break;
case 0x2229:
pC = " intersection ";
break;
case 0x222a:
pC = " union ";
break;
case 0x222b:
pC = " int ";
break;
case 0x222c:
pC = " iint ";
break;
case 0x222d:
pC = " iiint ";
break;
case 0x222e:
pC = " lint ";
break;
case 0x222f:
pC = " llint ";
break;
case 0x2230:
pC = " lllint ";
break;
case 0x2245:
pC = " simeq ";
break;
case 0x2248:
pC = " approx ";
break;
case 0x2260:
pC = " <> ";
break;
case 0x2261:
pC = " equiv ";
break;
case 0x2264:
pC = " <= ";
break;
case 0x2265:
pC = " >= ";
break;
case 0x227A:
pC = " prec ";
break;
case 0x227B:
pC = " succ ";
break;
case 0x227C:
pC = " preccurlyeq ";
break;
case 0x227D:
pC = " succcurlyeq ";
break;
case 0x227E:
pC = " precsim ";
break;
case 0x227F:
pC = " succsim ";
break;
case 0x2280:
pC = " nprec ";
break;
case 0x2281:
pC = " nsucc ";
break;
case 0x2282: // subset
case 0x2283: // supset
case 0x2284: // nsubset
case 0x2285: // nsupset
case 0x2286: // subseteq
case 0x2287: // supseteq
case 0x2288: // nsubseteq
case 0x2289: // nsupseteq
case 0x22b2: // NORMAL SUBGROUP OF
case 0x22b3: // CONTAINS AS NORMAL SUBGROUP
rRet.append(" func ").append(OUStringLiteral1(nChar)).append(" ");
break;
case 0x22a5:
pC = " ortho ";
break;
case 0x22c5:
pC = " cdot ";
break;
case 0x22ee:
pC = " dotsvert ";
break;
case 0x22ef:
pC = " dotsaxis ";
break;
case 0x22f0:
pC = " dotsup ";
break;
case 0x22f1:
pC = " dotsdown ";
break;
case MS_LANGLE:
case MS_LMATHANGLE:
pC = " langle ";
break;
case MS_RANGLE:
case MS_RMATHANGLE:
pC = " rangle ";
break;
case 0x301a:
pC = " ldbracket ";
break;
case 0x301b:
pC = " rdbracket ";
break;
case 0xe083:
rRet.append("+");
bRet=true;
break;
case '^':
case 0xe091:
pC = " widehat ";
break;
case 0xe096:
pC = " widetilde ";
break;
case 0xe098:
pC = " widevec ";
break;
case 0xE421:
pC = " geslant ";
break;
case 0xE425:
pC = " leslant ";
break;
case 0xeb01: //no space
case 0xeb08: //normal space
bRet=true;
break;
case 0xef04: //tiny space
case 0xef05: //tiny space
case 0xeb02: //small space
case 0xeb04: //medium space
rRet.append("`");
break;
case 0xeb05: //large space
rRet.append("~");
break;
case 0x3a9:
pC = " %OMEGA ";
break;
default:
rRet.append(OUStringLiteral1(nChar));
bRet=true;
break;
}
if (pC)
rRet.appendAscii(pC);
return bRet;
}
void MathTypeFont::AppendStyleToText(OUString &rRet)
{
const char *pC = nullptr;
switch (nStyle)
{
default:
case 0:
break;
case 1:
pC = " ital ";
break;
case 2:
pC = " bold ";
break;
case 3:
pC = " bold italic";
break;
}
if (pC)
rRet += OUString::createFromAscii( pC );
}
void MathType::TypeFaceToString(OUString &rTxt,sal_uInt8 nFace)
{
MathTypeFont aFont(nFace);
MathTypeFontSet::iterator aItr = aUserStyles.find(aFont);
if (aItr != aUserStyles.end())
aFont.nStyle = aItr->nStyle;
aFont.AppendStyleToText(rTxt);
}
bool MathType::Parse(SotStorage *pStor)
{
tools::SvRef<SotStorageStream> xSrc = pStor->OpenSotStream(
"Equation Native",
StreamMode::STD_READ);
if ( (!xSrc.is()) || (ERRCODE_NONE != xSrc->GetError()))
return false;
return Parse(xSrc.get());
}
bool MathType::Parse(SvStream* pStream)
{
pS = pStream;
pS->SetEndian( SvStreamEndian::LITTLE );
EQNOLEFILEHDR aHdr;
aHdr.Read(pS);
sal_uInt8 nProdVersion;
sal_uInt8 nProdSubVersion;
sal_uInt8 nPlatform;
sal_uInt8 nProduct;
pS->ReadUChar( nVersion );
pS->ReadUChar( nPlatform );
pS->ReadUChar( nProduct );
pS->ReadUChar( nProdVersion );
pS->ReadUChar( nProdSubVersion );
if (nVersion > 3) // allow only supported versions of MathType to be parsed
return false;
bool bRet = HandleRecords(0);
//little crude hack to close occasionally open expressions
//a sophisticated system to determine what expressions are
//opened is required, but this is as much work as rewriting
//starmaths internals.
rRet.append("{}");
return bRet;
}
static void lcl_PrependDummyTerm(OUStringBuffer &rRet, sal_Int32 &rTextStart)
{
if ((rTextStart < rRet.getLength()) &&
(rRet[rTextStart] == '=') &&
((rTextStart == 0) || (rRet[ rTextStart-1 ] == '{'))
)
{
rRet.insert(rTextStart, " {}");
rTextStart+=3;
}
}
static void lcl_AppendDummyTerm(OUStringBuffer &rRet)
{
bool bOk=false;
for(int nI=rRet.getLength()-1;nI >= 0; nI--)
{
sal_Int32 nIdx = sal::static_int_cast< sal_Int32 >(nI);
sal_Unicode nChar = rRet[nIdx];
if (nChar == ' ')
continue;
if (rRet[nIdx] != '{')
bOk=true;
break;
}
if (!bOk) //No term, use dummy
rRet.append(" {}");
}
void MathType::HandleNudge()
{
sal_uInt8 nXNudge;
pS->ReadUChar( nXNudge );
sal_uInt8 nYNudge;
pS->ReadUChar( nYNudge );
if (nXNudge == 128 && nYNudge == 128)
{
sal_uInt16 nXLongNudge;
sal_uInt16 nYLongNudge;
pS->ReadUInt16( nXLongNudge );
pS->ReadUInt16( nYLongNudge );
}
}
/* Fabulously complicated as many tokens have to be reordered and generally
* moved around from mathtypes paradigm to starmaths. */
bool MathType::HandleRecords(int nLevel, sal_uInt8 nSelector,
sal_uInt8 nVariation, int nMatrixRows, int nMatrixCols)
{
//depth-protect
if (nLevel > 1024)
return false;
sal_uInt8 nTag,nRecord;
sal_uInt8 nTabType,nTabStops;
sal_uInt16 nTabOffset;
int i, newline=0;
bool bSilent=false;
int nPart=0;
OUString sPush,sMainTerm;
int nSetSize=0,nSetAlign=0;
int nCurRow=0,nCurCol=0;
bool bOpenString=false;
sal_Int32 nTextStart = 0;
sal_Int32 nSubSupStartPos = 0;
sal_Int32 nLastTemplateBracket=-1;
bool bRet = true;
do
{
nTag = 0;
pS->ReadUChar( nTag );
nRecord = nTag&0x0F;
/*MathType strings can of course include words which
*are StarMath keywords, the simplest solution is
to escape strings of greater than len 1 with double
quotes to avoid scanning the TokenTable for matches
Unfortunately it may turn out that the string gets
split during the handling of a character emblishment
so this special case must be handled in the
character handler case 2:
*/
if ((nRecord == CHAR) && (!bOpenString))
{
bOpenString=true;
nTextStart = rRet.getLength();
}
else if ((nRecord != CHAR) && bOpenString)
{
bOpenString=false;
if ((rRet.getLength() - nTextStart) > 1)
{
OUString aStr;
TypeFaceToString(aStr,nTypeFace);
aStr += "\"";
rRet.insert(nTextStart,aStr);
rRet.append("\"");
}
else if (nRecord == END && !rRet.isEmpty())
{
sal_Unicode cChar = 0;
sal_Int32 nI = rRet.getLength()-1;
while (nI && ((cChar = rRet[nI]) == ' '))
--nI;
if ((cChar == '=') || (cChar == '+') || (cChar == '-'))
rRet.append("{}");
}
}
switch(nRecord)
{
case LINE:
{
if (xfLMOVE(nTag))
HandleNudge();
if (newline>0)
rRet.append("\nnewline\n");
if (!(xfNULL(nTag)))
{
switch (nSelector)
{
case tmANGLE:
if (nVariation==0)
rRet.append(" langle ");
else if (nVariation==1)
rRet.append(" \\langle ");
break;
case tmPAREN:
if (nVariation==0)
rRet.append(" left (");
else if (nVariation==1)
rRet.append("\\(");
break;
case tmBRACE:
if ((nVariation==0) || (nVariation==1))
rRet.append(" left lbrace ");
else
rRet.append(" left none ");
break;
case tmBRACK:
if (nVariation==0)
rRet.append(" left [");
else if (nVariation==1)
rRet.append("\\[");
break;
case tmLBLB:
case tmLBRP:
rRet.append(" \\[");
break;
case tmBAR:
if (nVariation==0)
rRet.append(" lline ");
else if (nVariation==1)
rRet.append(" \\lline ");
break;
case tmDBAR:
if (nVariation==0)
rRet.append(" ldline ");
else if (nVariation==1)
rRet.append(" \\ldline ");
break;
case tmFLOOR:
if (nVariation == 0 || nVariation == 1)
rRet.append(" left lfloor ");
else if (nVariation==1)
rRet.append(" left none ");
break;
case tmCEILING:
if (nVariation==0)
rRet.append(" lceil ");
else if (nVariation==1)
rRet.append(" \\lceil ");
break;
case tmRBRB:
case tmRBLB:
rRet.append(" \\]");
break;
case tmLPRB:
rRet.append(" \\(");
break;
case tmROOT:
if (nPart == 0)
{
if (nVariation == 0)
rRet.append(" sqrt");
else
{
rRet.append(" nroot");
sPush = rRet.makeStringAndClear();
}
}
rRet.append(" {");
break;
case tmFRACT:
if (nPart == 0)
rRet.append(" { ");
if (nPart == 1)
rRet.append(" over ");
rRet.append(" {");
break;
case tmSCRIPT:
nSubSupStartPos = rRet.getLength();
if ((nVariation == 0) ||
((nVariation == 2) && (nPart==1)))
{
lcl_AppendDummyTerm(rRet);
rRet.append(" rSup");
}
else if ((nVariation == 1) ||
((nVariation == 2) && (nPart==0)))
{
lcl_AppendDummyTerm(rRet);
rRet.append(" rSub");
}
rRet.append(" {");
break;
case tmUBAR:
if (nVariation == 0)
rRet.append(" {underline ");
else if (nVariation == 1)
rRet.append(" {underline underline ");
rRet.append(" {");
break;
case tmOBAR:
if (nVariation == 0)
rRet.append(" {overline ");
else if (nVariation == 1)
rRet.append(" {overline overline ");
rRet.append(" {");
break;
case tmLARROW:
if (nPart == 0)
{
if (nVariation == 0)
rRet.append(" widevec ");//left arrow above
else if (nVariation == 1)
rRet.append(" widevec ");//left arrow below
rRet.append(" {");
}
break;
case tmRARROW:
if (nPart == 0)
{
if (nVariation == 0)
rRet.append(" widevec ");//right arrow above
else if (nVariation == 1)
rRet.append(" widevec ");//right arrow below
rRet.append(" {");
}
break;
case tmBARROW:
if (nPart == 0)
{
if (nVariation == 0)
rRet.append(" widevec ");//double arrow above
else if (nVariation == 1)
rRet.append(" widevec ");//double arrow below
rRet.append(" {");
}
break;
case tmSINT:
if (nPart == 0)
{
if ((nVariation == 3) || (nVariation == 4))
rRet.append(" lInt");
else
rRet.append(" Int");
if ( (nVariation != 0) && (nVariation != 3))
{
sPush = rRet.makeStringAndClear();
}
}
if (((nVariation == 1) ||
(nVariation == 4)) && (nPart==1))
rRet.append(" rSub");
else if ((nVariation == 2) && (nPart==2))
rRet.append(" rSup");
else if ((nVariation == 2) && (nPart==1))
rRet.append(" rSub");
rRet.append(" {");
break;
case tmDINT:
if (nPart == 0)
{
if ((nVariation == 2) || (nVariation == 3))
rRet.append(" llInt");
else
rRet.append(" iInt");
if ( (nVariation != 0) && (nVariation != 2))
{
sPush = rRet.makeStringAndClear();
}
}
if (((nVariation == 1) ||
(nVariation == 3)) && (nPart==1))
rRet.append(" rSub");
rRet.append(" {");
break;
case tmTINT:
if (nPart == 0)
{
if ((nVariation == 2) || (nVariation == 3))
rRet.append(" lllInt");
else
rRet.append(" iiInt");
if ( (nVariation != 0) && (nVariation != 2))
{
sPush = rRet.makeStringAndClear();
}
}
if (((nVariation == 1) ||
(nVariation == 3)) && (nPart==1))
rRet.append(" rSub");
rRet.append(" {");
break;
case tmSSINT:
if (nPart == 0)
{
if (nVariation == 2)
rRet.append(" lInt");
else
rRet.append(" Int");
sPush = rRet.makeStringAndClear();
}
if (((nVariation == 1) ||
(nVariation == 2)) && (nPart==1))
rRet.append(" cSub");
else if ((nVariation == 0) && (nPart==2))
rRet.append(" cSup");
else if ((nVariation == 0) && (nPart==1))
rRet.append(" cSub");
rRet.append(" {");
break;
case tmDSINT:
if (nPart == 0)
{
if (nVariation == 0)
rRet.append(" llInt");
else
rRet.append(" iInt");
sPush = rRet.makeStringAndClear();
}
if (nPart==1)
rRet.append(" cSub");
rRet.append(" {");
break;
case tmTSINT:
if (nPart == 0)
{
if (nVariation == 0)
rRet.append(" lllInt");
else
rRet.append(" iiInt");
sPush = rRet.makeStringAndClear();
}
if (nPart==1)
rRet.append(" cSub");
rRet.append(" {");
break;
case tmUHBRACE:
case tmLHBRACE:
rRet.append(" {");
break;
case tmSUM:
if (nPart == 0)
{
rRet.append(" Sum");
if (nVariation != 2)
{
sPush = rRet.makeStringAndClear();
}
}
if ((nVariation == 0) && (nPart==1))
rRet.append(" cSub");
else if ((nVariation == 1) && (nPart==2))
rRet.append(" cSup");
else if ((nVariation == 1) && (nPart==1))
rRet.append(" cSub");
rRet.append(" {");
break;
case tmISUM:
if (nPart == 0)
{
rRet.append(" Sum");
sPush = rRet.makeStringAndClear();
}
if ((nVariation == 0) && (nPart==1))
rRet.append(" rSub");
else if ((nVariation == 1) && (nPart==2))
rRet.append(" rSup");
else if ((nVariation == 1) && (nPart==1))
rRet.append(" rSub");
rRet.append(" {");
break;
case tmPROD:
if (nPart == 0)
{
rRet.append(" Prod");
if (nVariation != 2)
{
sPush = rRet.makeStringAndClear();
}
}
if ((nVariation == 0) && (nPart==1))
rRet.append(" cSub");
else if ((nVariation == 1) && (nPart==2))
rRet.append(" cSup");
else if ((nVariation == 1) && (nPart==1))
rRet.append(" cSub");
rRet.append(" {");
break;
case tmIPROD:
if (nPart == 0)
{
rRet.append(" Prod");
sPush = rRet.makeStringAndClear();
}
if ((nVariation == 0) && (nPart==1))
rRet.append(" rSub");
else if ((nVariation == 1) && (nPart==2))
rRet.append(" rSup");
else if ((nVariation == 1) && (nPart==1))
rRet.append(" rSub");
rRet.append(" {");
break;
case tmCOPROD:
if (nPart == 0)
{
rRet.append(" coProd");
if (nVariation != 2)
{
sPush = rRet.makeStringAndClear();
}
}
if ((nVariation == 0) && (nPart==1))
rRet.append(" cSub");
else if ((nVariation == 1) && (nPart==2))
rRet.append(" cSup");
else if ((nVariation == 1) && (nPart==1))
rRet.append(" cSub");
rRet.append(" {");
break;
case tmICOPROD:
if (nPart == 0)
{
rRet.append(" coProd");
sPush = rRet.makeStringAndClear();
}
if ((nVariation == 0) && (nPart==1))
rRet.append(" rSub");
else if ((nVariation == 1) && (nPart==2))
rRet.append(" rSup");
else if ((nVariation == 1) && (nPart==1))
rRet.append(" rSub");
rRet.append(" {");
break;
case tmUNION:
if (nPart == 0)
{
rRet.append(" union"); //union
if (nVariation != 2)
{
sPush = rRet.makeStringAndClear();
}
}
if ((nVariation == 0) && (nPart==1))
rRet.append(" cSub");
else if ((nVariation == 1) && (nPart==2))
rRet.append(" cSup");
else if ((nVariation == 1) && (nPart==1))
rRet.append(" cSub");
rRet.append(" {");
break;
case tmIUNION:
if (nPart == 0)
{
rRet.append(" union"); //union
sPush = rRet.makeStringAndClear();
}
if ((nVariation == 0) && (nPart==1))
rRet.append(" rSub");
else if ((nVariation == 1) && (nPart==2))
rRet.append(" rSup");
else if ((nVariation == 1) && (nPart==1))
rRet.append(" rSub");
rRet.append(" {");
break;
case tmINTER:
if (nPart == 0)
{
rRet.append(" intersect"); //intersect
if (nVariation != 2)
{
sPush = rRet.makeStringAndClear();
}
}
if ((nVariation == 0) && (nPart==1))
rRet.append(" cSub");
else if ((nVariation == 1) && (nPart==2))
rRet.append(" cSup");
else if ((nVariation == 1) && (nPart==1))
rRet.append(" cSub");
rRet.append(" {");
break;
case tmIINTER:
if (nPart == 0)
{
rRet.append(" intersect"); //intersect
sPush = rRet.makeStringAndClear();
}
if ((nVariation == 0) && (nPart==1))
rRet.append(" rSub");
else if ((nVariation == 1) && (nPart==2))
rRet.append(" rSup");
else if ((nVariation == 1) && (nPart==1))
rRet.append(" rSub");
rRet.append(" {");
break;
case tmLIM:
if ((nVariation == 0) && (nPart==1))
rRet.append(" cSup");
else if ((nVariation == 1) && (nPart==1))
rRet.append(" cSub");
else if ((nVariation == 2) && (nPart==1))
rRet.append(" cSub");
else if ((nVariation == 2) && (nPart==2))
rRet.append(" cSup");
rRet.append(" {");
break;
case tmLDIV:
if (nVariation == 0)
{
if (nPart == 0)
{
sPush = rRet.makeStringAndClear();
}
}
rRet.append(" {");
if (nVariation == 0)
{
if (nPart == 1)
rRet.append("alignr ");
}
if (nPart == 0)
rRet.append("\\lline ");
if (nVariation == 1)
rRet.append("overline ");
break;
case tmSLFRACT:
rRet.append(" {");
break;
case tmINTOP:
if (nPart == 0)
{
sPush = rRet.makeStringAndClear();
}
if ((nVariation == 0) && (nPart==0))
rRet.append(" rSup");
else if ((nVariation == 2) && (nPart==1))
rRet.append(" rSup");
else if ((nVariation == 1) && (nPart==0))
rRet.append(" rSub");
else if ((nVariation == 2) && (nPart==0))
rRet.append(" rSub");
rRet.append(" {");
break;
case tmSUMOP:
if (nPart == 0)
{
sPush = rRet.makeStringAndClear();
}
if ((nVariation == 0) && (nPart==0))
rRet.append(" cSup");
else if ((nVariation == 2) && (nPart==1))
rRet.append(" cSup");
else if ((nVariation == 1) && (nPart==0))
rRet.append(" cSub");
else if ((nVariation == 2) && (nPart==0))
rRet.append(" cSub");
rRet.append(" {");
break;
case tmLSCRIPT:
if (nPart == 0)
rRet.append("\"\"");
if ((nVariation == 0)
|| ((nVariation == 2) && (nPart==1)))
rRet.append(" lSup");
else if ((nVariation == 1)
|| ((nVariation == 2) && (nPart==0)))
rRet.append(" lSub");
rRet.append(" {");
break;
case tmDIRAC:
if (nVariation==0)
{
if (nPart == 0)
rRet.append(" langle ");
}
else if (nVariation==1)
{
rRet.append(" \\langle ");
newline--;
}
else if (nVariation==2)
{
rRet.append(" \\lline ");
newline--;
}
break;
case tmUARROW:
if (nVariation == 0)
rRet.append(" widevec ");//left below
else if (nVariation == 1)
rRet.append(" widevec ");//right below
else if (nVariation == 2)
rRet.append(" widevec ");//double headed below
rRet.append(" {");
break;
case tmOARROW:
if (nVariation == 0)
rRet.append(" widevec ");//left above
else if (nVariation == 1)
rRet.append(" widevec ");//right above
else if (nVariation == 2)
rRet.append(" widevec ");//double headed above
rRet.append(" {");
break;
default:
break;
}
sal_Int16 nOldCurSize=nCurSize;
sal_Int32 nSizeStartPos = rRet.getLength();
HandleSize( nLSize, nDSize, nSetSize );
bRet = HandleRecords( nLevel+1 );
while (nSetSize)
{
bool bOk=false;
sal_Int32 nI = rRet.lastIndexOf('{');
if (nI != -1)
{
for(nI=nI+1;nI<rRet.getLength();nI++)
if (rRet[nI] != ' ')
{
bOk=true;
break;
}
}
else
bOk=true;
if (bOk)
rRet.append("} ");
else if (rRet.getLength() > nSizeStartPos)
rRet = rRet.truncate(nSizeStartPos);
nSetSize--;
nCurSize=nOldCurSize;
}
HandleMatrixSeparator(nMatrixRows,nMatrixCols,
nCurCol,nCurRow);
switch (nSelector)
{
case tmANGLE:
if (nVariation==0)
rRet.append(" rangle ");
else if (nVariation==2)
rRet.append(" \\rangle ");
break;
case tmPAREN:
if (nVariation==0)
rRet.append(" right )");
else if (nVariation==2)
rRet.append("\\)");
break;
case tmBRACE:
if ((nVariation==0) || (nVariation==2))
rRet.append(" right rbrace ");
else
rRet.append(" right none ");
break;
case tmBRACK:
if (nVariation==0)
rRet.append(" right ]");
else if (nVariation==2)
rRet.append("\\]");
break;
case tmBAR:
if (nVariation==0)
rRet.append(" rline ");
else if (nVariation==2)
rRet.append(" \\rline ");
break;
case tmDBAR:
if (nVariation==0)
rRet.append(" rdline ");
else if (nVariation==2)
rRet.append(" \\rdline ");
break;
case tmFLOOR:
if (nVariation == 0 || nVariation == 2)
rRet.append(" right rfloor ");
else if (nVariation==2)
rRet.append(" right none ");
break;
case tmCEILING:
if (nVariation==0)
rRet.append(" rceil ");
else if (nVariation==2)
rRet.append(" \\rceil ");
break;
case tmLBLB:
case tmRBLB:
rRet.append("\\[");
break;
case tmRBRB:
case tmLPRB:
rRet.append("\\]");
break;
case tmROOT:
rRet.append("} ");
if (nVariation == 1)
{
if (nPart == 0)
{
newline--;
sMainTerm = rRet.makeStringAndClear();
}
else if (nPart == 1)
{
rRet.insert(0, sPush);
rRet.append(sMainTerm);
sPush.clear();
sMainTerm.clear();
}
}
else
{
if (nPart == 0)
newline--;
}
nPart++;
break;
case tmLBRP:
rRet.append("\\)");
break;
case tmFRACT:
rRet.append("} ");
if (nPart == 0)
newline--;
else
rRet.append("} ");
nPart++;
break;
case tmSCRIPT:
{
if ((nPart == 0) &&
((nVariation == 2) || (nVariation == 1)))
newline--;
bool bOk=false;
sal_Int32 nI = rRet.lastIndexOf('{');
if (nI != -1)
{
for(nI=nI+1;nI<rRet.getLength();nI++)
if (rRet[nI] != ' ')
{
bOk=true;
break;
}
}
else
bOk=true;
if (bOk)
rRet.append("} ");
else if (rRet.getLength() > nSubSupStartPos)
rRet = rRet.truncate(nSubSupStartPos);
nPart++;
}
break;
case tmLSCRIPT:
if ((nPart == 0) &&
((nVariation == 2) || (nVariation == 1)))
newline--;
rRet.append("} ");
nPart++;
break;
case tmUARROW:
case tmOARROW:
rRet.append("} ");
break;
case tmUBAR:
case tmOBAR:
rRet.append("}} ");
break;
case tmLARROW:
case tmRARROW:
case tmBARROW:
if (nPart == 0)
{
newline--;
rRet.append("} ");
}
nPart++;
break;
case tmUHBRACE:
rRet.append("} ");
if (nPart == 0)
{
newline--;
rRet.append("overbrace");
}
nPart++;
break;
case tmLHBRACE:
rRet.append("} ");
if (nPart == 0)
{
newline--;
rRet.append("underbrace");
}
nPart++;
break;
case tmLIM:
if (nPart==0)
newline--;
else if ((nPart==1) &&
((nVariation == 2) || (nVariation == 1)))
newline--;
rRet.append("} ");
nPart++;
break;
case tmLDIV:
rRet.append("} ");
if (nVariation == 0)
{
if (nPart == 0)
{
sMainTerm = rRet.makeStringAndClear();
}
else if (nPart == 1)
{
rRet.insert(0, sPush);
rRet.append(" over ").append(sMainTerm);
sPush.clear();
sMainTerm.clear();
}
}
if (nPart == 0)
newline--;
nPart++;
break;
case tmSLFRACT:
rRet.append("} ");
if (nPart == 0)
{
newline--;
switch (nVariation)
{
case 1:
rRet.append("slash");
break;
default:
rRet.append("wideslash");
break;
}
}
nPart++;
break;
case tmSUM:
case tmISUM:
case tmPROD:
case tmIPROD:
case tmCOPROD:
case tmICOPROD:
case tmUNION:
case tmIUNION:
case tmINTER:
case tmIINTER:
rRet.append("} ");
if (nPart == 0)
{
if (nVariation != 2)
{
sMainTerm = rRet.makeStringAndClear();
}
newline--;
}
else if ((nPart == 1) && (nVariation == 0))
{
rRet.insert(0, sPush);
rRet.append(sMainTerm);
sPush.clear();
sMainTerm.clear();
newline--;
}
else if ((nPart == 1) && (nVariation == 1))
newline--;
else if ((nPart == 2) && (nVariation == 1))
{
rRet.insert(0, sPush);
rRet.append(sMainTerm);
sPush.clear();
sMainTerm.clear();
newline--;
}
nPart++;
break;
case tmSINT:
rRet.append("} ");
if (nPart == 0)
{
if ((nVariation != 0) && (nVariation != 3))
{
sMainTerm = rRet.makeStringAndClear();
}
newline--;
}
else if ((nPart == 1) &&
((nVariation == 1) || (nVariation==4)))
{
rRet.insert(0, sPush);
rRet.append(sMainTerm);
sPush.clear();
sMainTerm.clear();
newline--;
}
else if ((nPart == 1) && (nVariation == 2))
newline--;
else if ((nPart == 2) && (nVariation == 2))
{
rRet.insert(0, sPush);
rRet.append(sMainTerm);
sPush.clear();
sMainTerm.clear();
newline--;
}
nPart++;
break;
case tmDINT:
case tmTINT:
rRet.append("} ");
if (nPart == 0)
{
if ((nVariation != 0) && (nVariation != 2))
{
sMainTerm = rRet.makeStringAndClear();
}
newline--;
}
else if ((nPart == 1) &&
((nVariation == 1) || (nVariation==3)))
{
rRet.insert(0, sPush);
rRet.append(sMainTerm);
sPush.clear();
sMainTerm.clear();
newline--;
}
nPart++;
break;
case tmSSINT:
rRet.append("} ");
if (nPart == 0)
{
sMainTerm = rRet.makeStringAndClear();
newline--;
}
else if ((nPart == 1) &&
((nVariation == 1) || (nVariation==2)))
{
rRet.insert(0, sPush);
rRet.append(sMainTerm);
sPush.clear();
sMainTerm.clear();
newline--;
}
else if ((nPart == 1) && (nVariation == 0))
newline--;
else if ((nPart == 2) && (nVariation == 0))
{
rRet.insert(0, sPush);
rRet.append(sMainTerm);
sPush.clear();
sMainTerm.clear();
newline--;
}
nPart++;
break;
case tmDSINT:
case tmTSINT:
rRet.append("} ");
if (nPart == 0)
{
sMainTerm = rRet.makeStringAndClear();
newline--;
}
else if (nPart == 1)
{
rRet.insert(0, sPush);
rRet.append(sMainTerm);
sPush.clear();
sMainTerm.clear();
newline--;
}
nPart++;
break;
case tmINTOP:
case tmSUMOP:
rRet.append("} ");
if ((nPart == 0) &&
((nVariation == 0) || (nVariation == 1)))
{
sMainTerm = rRet.makeStringAndClear();
newline--;
}
else if ((nPart == 0) && (nVariation == 2))
newline--;
else if ((nPart == 1) && (nVariation == 2))
{
sMainTerm = rRet.makeStringAndClear();
newline--;
}
else if ((nPart == 2) || ((nPart == 1) &&
(nVariation == 0 || nVariation == 1)))
{
rRet.insert(0, sPush);
rRet.append(sMainTerm);
sPush.clear();
sMainTerm.clear();
}
nPart++;
break;
case tmDIRAC:
if (nVariation==0)
{
if (nPart == 0)
{
newline--; //there is another term to arrive
rRet.append(" mline ");
}
else
rRet.append(" rangle ");
}
else if (nVariation==1)
rRet.append(" \\lline ");
else if (nVariation==2)
rRet.append(" \\rangle ");
nPart++;
break;
default:
break;
}
bSilent = true; //Skip the optional brackets and/or
//symbols that follow some of these
//records. Foo Data.
/*In matrices and piles we cannot separate equation
*lines with the newline keyword*/
if (nMatrixCols==0)
newline++;
}
}
break;
case CHAR:
if (xfLMOVE(nTag))
HandleNudge();
bRet = HandleChar( nTextStart, nSetSize, nLevel, nTag, nSelector, nVariation, bSilent );
break;
case TMPL:
if (xfLMOVE(nTag))
HandleNudge();
bRet = HandleTemplate( nLevel, nSelector, nVariation, nLastTemplateBracket );
break;
case PILE:
if (xfLMOVE(nTag))
HandleNudge();
bRet = HandlePile( nSetAlign, nLevel, nSelector, nVariation );
HandleMatrixSeparator( nMatrixRows, nMatrixCols, nCurCol, nCurRow );
break;
case MATRIX:
if (xfLMOVE(nTag))
HandleNudge();
bRet = HandleMatrix( nLevel, nSelector, nVariation );
HandleMatrixSeparator( nMatrixRows, nMatrixCols, nCurCol, nCurRow );
break;
case EMBEL:
if (xfLMOVE(nTag))
HandleNudge();
HandleEmblishments();
break;
case RULER:
pS->ReadUChar( nTabStops );
for (i=0;i<nTabStops;i++)
{
pS->ReadUChar( nTabType );
pS->ReadUInt16( nTabOffset );
}
SAL_WARN("starmath", "Not seen in the wild Equation Ruler Field");
break;
case FONT:
{
MathTypeFont aFont;
pS->ReadUChar( aFont.nTface );
/*
The typeface number is the negative (which makes it
positive) of the typeface value (unbiased) that appears in
CHAR records that might follow a given FONT record
*/
aFont.nTface = 128-aFont.nTface;
pS->ReadUChar( aFont.nStyle );
aUserStyles.insert(aFont);
// read font name
while(true)
{
sal_Char nChar8(0);
pS->ReadChar( nChar8 );
if (nChar8 == 0)
break;
}
}
break;
case SIZE:
HandleSetSize();
break;
case 10:
case 11:
case 12:
case 13:
case 14:
nLSize=nRecord-10;
break;
case END:
default:
break;
}
}
while (nRecord != END && !pS->eof());
while (nSetSize)
{
rRet.append("}");
nSetSize--;
}
return bRet;
}
/*Simply determine if we are at the end of a record or the end of a line,
*with fiddly logic to see if we are in a matrix or a pile or neither
Note we cannot tell until after the event that this is the last entry
of a pile, so we must strip the last separator of a pile after this
is detected in the PILE handler
*/
void MathType::HandleMatrixSeparator(int nMatrixRows,int nMatrixCols,
int &rCurCol,int &rCurRow)
{
if (nMatrixRows!=0)
{
if (rCurCol == nMatrixCols-1)
{
if (rCurRow != nMatrixRows-1)
rRet.append(" {} ##\n");
if (nMatrixRows!=-1)
{
rCurCol=0;
rCurRow++;
}
}
else
{
rRet.append(" {} # ");
if (nMatrixRows!=-1)
rCurCol++;
else
rRet.append("\n");
}
}
}
/* set the alignment of the following term, but starmath currently
* cannot handle vertical alignment */
void MathType::HandleAlign(sal_uInt8 nHorAlign, int &rSetAlign)
{
switch(nHorAlign)
{
case 1:
default:
rRet.append("alignl {");
break;
case 2:
rRet.append("alignc {");
break;
case 3:
rRet.append("alignr {");
break;
}
rSetAlign++;
}
/* set size of text, complexity due to overuse of signedness as a flag
* indicator by mathtype file format*/
bool MathType::HandleSize(sal_Int16 nLstSize,sal_Int16 nDefSize, int &rSetSize)
{
const sal_Int16 nDefaultSize = 12;
bool bRet=false;
if (nLstSize < 0)
{
if ((-nLstSize/32 != nDefaultSize) && (-nLstSize/32 != nCurSize))
{
if (rSetSize)
{
rSetSize--;
rRet.append("}");
bRet=true;
}
if (-nLstSize/32 != nLastSize)
{
nLastSize = nCurSize;
rRet.append(" size ");
rRet.append(OUString::number(-nLstSize/32));
rRet.append("{");
bRet=true;
rSetSize++;
}
nCurSize = -nLstSize/32;
}
}
else
{
/*sizetable should theoreticaly be filled with the default sizes
*of the various font groupings matching starmaths equivalents
in aTypeFaces, and a test would be done to see if the new font
size would be the same as what starmath would have chosen for
itself anyway in which case the size setting could be ignored*/
nLstSize = aSizeTable.at(nLstSize);
nLstSize = nLstSize + nDefSize;
if (nLstSize != nCurSize)
{
if (rSetSize)
{
rSetSize--;
rRet.append("}");
bRet=true;
}
if (nLstSize != nLastSize)
{
nLastSize = nCurSize;
rRet.append(" size ");
rRet.append(OUString::number(nLstSize));
rRet.append("{");
bRet=true;
rSetSize++;
}
nCurSize = nLstSize;
}
}
return bRet;
}
bool MathType::ConvertFromStarMath( SfxMedium& rMedium )
{
if (!pTree)
return false;
SvStream *pStream = rMedium.GetOutStream();
if ( pStream )
{
tools::SvRef<SotStorage> pStor = new SotStorage( pStream, false );
SvGlobalName aGName(MSO_EQUATION3_CLASSID);
pStor->SetClass( aGName, SotClipboardFormatId::NONE, "Microsoft Equation 3.0");
static sal_uInt8 const aCompObj[] = {
0x01, 0x00, 0xFE, 0xFF, 0x03, 0x0A, 0x00, 0x00,
0xFF, 0xFF, 0xFF, 0xFF, 0x02, 0xCE, 0x02, 0x00,
0x00, 0x00, 0x00, 0x00, 0xC0, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x46, 0x17, 0x00, 0x00, 0x00,
0x4D, 0x69, 0x63, 0x72, 0x6F, 0x73, 0x6F, 0x66,
0x74, 0x20, 0x45, 0x71, 0x75, 0x61, 0x74, 0x69,
0x6F, 0x6E, 0x20, 0x33, 0x2E, 0x30, 0x00, 0x0C,
0x00, 0x00, 0x00, 0x44, 0x53, 0x20, 0x45, 0x71,
0x75, 0x61, 0x74, 0x69, 0x6F, 0x6E, 0x00, 0x0B,
0x00, 0x00, 0x00, 0x45, 0x71, 0x75, 0x61, 0x74,
0x69, 0x6F, 0x6E, 0x2E, 0x33, 0x00, 0xF4, 0x39,
0xB2, 0x71, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0x00
};
tools::SvRef<SotStorageStream> xStor( pStor->OpenSotStream("\1CompObj"));
xStor->WriteBytes(aCompObj, sizeof(aCompObj));
static sal_uInt8 const aOle[] = {
0x01, 0x00, 0x00, 0x02, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x00
};
tools::SvRef<SotStorageStream> xStor2( pStor->OpenSotStream("\1Ole"));
xStor2->WriteBytes(aOle, sizeof(aOle));
xStor.clear();
xStor2.clear();
tools::SvRef<SotStorageStream> xSrc = pStor->OpenSotStream("Equation Native");
if ( (!xSrc.is()) || (ERRCODE_NONE != xSrc->GetError()))
return false;
pS = xSrc.get();
pS->SetEndian( SvStreamEndian::LITTLE );
pS->SeekRel(EQNOLEFILEHDR_SIZE); //Skip 28byte Header and fill it in later
pS->WriteUChar( 0x03 );
pS->WriteUChar( 0x01 );
pS->WriteUChar( 0x01 );
pS->WriteUChar( 0x03 );
pS->WriteUChar( 0x00 );
sal_uInt32 nSize = pS->Tell();
nPendingAttributes=0;
HandleNodes(pTree, 0);
pS->WriteUChar( END );
nSize = pS->Tell()-nSize;
pS->Seek(0);
EQNOLEFILEHDR aHdr(nSize+4+1);
aHdr.Write(pS);
pStor->Commit();
}
return true;
}
void MathType::HandleNodes(SmNode *pNode,int nLevel)
{
switch(pNode->GetType())
{
case SmNodeType::Attribut:
HandleAttributes(pNode,nLevel);
break;
case SmNodeType::Text:
HandleText(pNode);
break;
case SmNodeType::VerticalBrace:
HandleVerticalBrace(pNode,nLevel);
break;
case SmNodeType::Brace:
HandleBrace(pNode,nLevel);
break;
case SmNodeType::Oper:
HandleOperator(pNode,nLevel);
break;
case SmNodeType::BinVer:
HandleFractions(pNode,nLevel);
break;
case SmNodeType::Root:
HandleRoot(pNode,nLevel);
break;
case SmNodeType::Special:
{
SmTextNode *pText = static_cast<SmTextNode *>(pNode);
//if the token str and the result text are the same then this
//is to be seen as text, else assume it's a mathchar
if (pText->GetText() == pText->GetToken().aText)
HandleText(pText);
else
HandleMath(pText);
}
break;
case SmNodeType::Math:
case SmNodeType::MathIdent:
HandleMath(pNode);
break;
case SmNodeType::SubSup:
HandleSubSupScript(pNode,nLevel);
break;
case SmNodeType::Expression:
{
size_t nSize = pNode->GetNumSubNodes();
for (size_t i = 0; i < nSize; ++i)
{
if (SmNode *pTemp = pNode->GetSubNode(i))
HandleNodes(pTemp,nLevel+1);
}
break;
}
case SmNodeType::Table:
//Root Node, PILE equivalent, i.e. vertical stack
HandleTable(pNode,nLevel);
break;
case SmNodeType::Matrix:
HandleSmMatrix(static_cast<SmMatrixNode *>(pNode),nLevel);
break;
case SmNodeType::Line:
{
pS->WriteUChar( 0x0a );
pS->WriteUChar( LINE );
size_t nSize = pNode->GetNumSubNodes();
for (size_t i = 0; i < nSize; ++i)
{
if (SmNode *pTemp = pNode->GetSubNode(i))
HandleNodes(pTemp,nLevel+1);
}
pS->WriteUChar( END );
break;
}
case SmNodeType::Align:
HandleMAlign(pNode,nLevel);
break;
case SmNodeType::Blank:
pS->WriteUChar( CHAR );
pS->WriteUChar( 0x98 );
if (pNode->GetToken().eType == TSBLANK)
pS->WriteUInt16( 0xEB04 );
else
pS->WriteUInt16( 0xEB05 );
break;
default:
{
size_t nSize = pNode->GetNumSubNodes();
for (size_t i = 0; i < nSize; ++i)
{
if (SmNode *pTemp = pNode->GetSubNode(i))
HandleNodes(pTemp,nLevel+1);
}
break;
}
}
}
int MathType::StartTemplate(sal_uInt16 nSelector,sal_uInt16 nVariation)
{
int nOldPending=nPendingAttributes;
pS->WriteUChar( TMPL ); //Template
pS->WriteUChar( nSelector ); //selector
pS->WriteUChar( nVariation ); //variation
pS->WriteUChar( 0x00 ); //options
pS->WriteUChar( LINE );
//there's just no way we can now handle any character
//attributes (from mathtypes perspective) centered
//over an expression but above template attribute
//such as widevec and similar constructs
//we have to drop them
nPendingAttributes=0;
return nOldPending;
}
void MathType::EndTemplate(int nOldPendingAttributes)
{
pS->WriteUChar( END ); //end line
pS->WriteUChar( END ); //end template
nPendingAttributes=nOldPendingAttributes;
}
void MathType::HandleSmMatrix(SmMatrixNode *pMatrix,int nLevel)
{
pS->WriteUChar( MATRIX );
pS->WriteUChar( 0x00 ); //vAlign ?
pS->WriteUChar( 0x00 ); //h_just
pS->WriteUChar( 0x00 ); //v_just
pS->WriteUChar( pMatrix->GetNumRows() ); //v_just
pS->WriteUChar( pMatrix->GetNumCols() ); //v_just
int nBytes=(pMatrix->GetNumRows()+1)*2/8;
if (((pMatrix->GetNumRows()+1)*2)%8)
nBytes++;
for (int j = 0; j < nBytes; j++)
pS->WriteUChar( 0x00 ); //row_parts
nBytes=(pMatrix->GetNumCols()+1)*2/8;
if (((pMatrix->GetNumCols()+1)*2)%8)
nBytes++;
for (int k = 0; k < nBytes; k++)
pS->WriteUChar( 0x00 ); //col_parts
size_t nSize = pMatrix->GetNumSubNodes();
for (size_t i = 0; i < nSize; ++i)
{
if (SmNode *pTemp = pMatrix->GetSubNode(i))
{
pS->WriteUChar( LINE ); //line
HandleNodes(pTemp,nLevel+1);
pS->WriteUChar( END ); //end line
}
}
pS->WriteUChar( END );
}
//Root Node, PILE equivalent, i.e. vertical stack
void MathType::HandleTable(SmNode *pNode,int nLevel)
{
size_t nSize = pNode->GetNumSubNodes();
//The root of the starmath is a table, if
//we convert this them each iteration of
//conversion from starmath to mathtype will
//add an extra unnecessary level to the
//mathtype output stack which would grow
//without bound in a multi step conversion
if (nLevel == 0)
pS->WriteUChar( 0x0A ); //initial size
if ( nLevel || (nSize >1))
{
pS->WriteUChar( PILE );
pS->WriteUChar( nHAlign ); //vAlign ?
pS->WriteUChar( 0x01 ); //hAlign
}
for (size_t i = 0; i < nSize; ++i)
{
if (SmNode *pTemp = pNode->GetSubNode(i))
{
pS->WriteUChar( LINE );
HandleNodes(pTemp,nLevel+1);
pS->WriteUChar( END );
}
}
if (nLevel || (nSize>1))
pS->WriteUChar( END );
}
void MathType::HandleRoot(SmNode *pNode,int nLevel)
{
SmNode *pTemp;
pS->WriteUChar( TMPL ); //Template
pS->WriteUChar( 0x0D ); //selector
if (pNode->GetSubNode(0))
pS->WriteUChar( 0x01 ); //variation
else
pS->WriteUChar( 0x00 ); //variation
pS->WriteUChar( 0x00 ); //options
if (nullptr != (pTemp = pNode->GetSubNode(2)))
{
pS->WriteUChar( LINE ); //line
HandleNodes(pTemp,nLevel+1);
pS->WriteUChar( END );
}
if (nullptr != (pTemp = pNode->GetSubNode(0)))
{
pS->WriteUChar( LINE ); //line
HandleNodes(pTemp,nLevel+1);
pS->WriteUChar( END );
}
else
pS->WriteUChar( LINE|0x10 ); //dummy line
pS->WriteUChar( END );
}
sal_uInt8 MathType::HandleCScript(SmNode *pNode,SmNode *pContent,int nLevel,
sal_uInt64 *pPos,bool bTest)
{
sal_uInt8 nVariation2=0xff;
if (bTest && pNode->GetSubNode(CSUP+1))
{
nVariation2=0;
if (pNode->GetSubNode(CSUB+1))
nVariation2=2;
}
else if (pNode->GetSubNode(CSUB+1))
nVariation2=1;
if (nVariation2!=0xff)
{
if (pPos)
*pPos = pS->Tell();
pS->WriteUChar( TMPL ); //Template
pS->WriteUChar( 0x2B ); //selector
pS->WriteUChar( nVariation2 );
pS->WriteUChar( 0x00 ); //options
if (pContent)
{
pS->WriteUChar( LINE ); //line
HandleNodes(pContent,nLevel+1);
pS->WriteUChar( END ); //line
}
else
pS->WriteUChar( LINE|0x10 );
pS->WriteUChar( 0x0B );
SmNode *pTemp;
if (nullptr != (pTemp = pNode->GetSubNode(CSUB+1)))
{
pS->WriteUChar( LINE ); //line
HandleNodes(pTemp,nLevel+1);
pS->WriteUChar( END ); //line
}
else
pS->WriteUChar( LINE|0x10 );
if (bTest && nullptr != (pTemp = pNode->GetSubNode(CSUP+1)))
{
pS->WriteUChar( LINE ); //line
HandleNodes(pTemp,nLevel+1);
pS->WriteUChar( END ); //line
}
else
pS->WriteUChar( LINE|0x10 );
}
return nVariation2;
}
/*
Sub and Sup scripts and another problem area, StarMath
can have all possible options used at the same time, whereas
Mathtype cannot. The ordering of the nodes for each system
is quite different as well leading to some complexity
*/
void MathType::HandleSubSupScript(SmNode *pNode,int nLevel)
{
sal_uInt8 nVariation=0xff;
if (pNode->GetSubNode(LSUP+1))
{
nVariation=0;
if (pNode->GetSubNode(LSUB+1))
nVariation=2;
}
else if ( nullptr != pNode->GetSubNode(LSUB+1) )
nVariation=1;
SmNode *pTemp;
if (nVariation!=0xff)
{
pS->WriteUChar( TMPL ); //Template
pS->WriteUChar( 0x2c ); //selector
pS->WriteUChar( nVariation );
pS->WriteUChar( 0x00 ); //options
pS->WriteUChar( 0x0B );
if (nullptr != (pTemp = pNode->GetSubNode(LSUB+1)))
{
pS->WriteUChar( LINE ); //line
HandleNodes(pTemp,nLevel+1);
pS->WriteUChar( END ); //line
}
else
pS->WriteUChar( LINE|0x10 );
if (nullptr != (pTemp = pNode->GetSubNode(LSUP+1)))
{
pS->WriteUChar( LINE ); //line
HandleNodes(pTemp,nLevel+1);
pS->WriteUChar( END ); //line
}
else
pS->WriteUChar( LINE|0x10 );
pS->WriteUChar( END );
nVariation=0xff;
}
sal_uInt8 nVariation2=HandleCScript(pNode,nullptr,nLevel);
if (nullptr != (pTemp = pNode->GetSubNode(0)))
{
HandleNodes(pTemp,nLevel+1);
}
if (nVariation2 != 0xff)
pS->WriteUChar( END );
if (nullptr != (pNode->GetSubNode(RSUP+1)))
{
nVariation=0;
if (pNode->GetSubNode(RSUB+1))
nVariation=2;
}
else if (nullptr != pNode->GetSubNode(RSUB+1))
nVariation=1;
if (nVariation!=0xff)
{
pS->WriteUChar( TMPL ); //Template
pS->WriteUChar( 0x0F ); //selector
pS->WriteUChar( nVariation );
pS->WriteUChar( 0x00 ); //options
pS->WriteUChar( 0x0B );
if (nullptr != (pTemp = pNode->GetSubNode(RSUB+1)))
{
pS->WriteUChar( LINE ); //line
HandleNodes(pTemp,nLevel+1);
pS->WriteUChar( END ); //line
}
else
pS->WriteUChar( LINE|0x10 );
if (nullptr != (pTemp = pNode->GetSubNode(RSUP+1)))
{
pS->WriteUChar( LINE ); //line
HandleNodes(pTemp,nLevel+1);
pS->WriteUChar( END ); //line
}
else
pS->WriteUChar( LINE|0x10 );
pS->WriteUChar( END ); //line
}
//After subscript mathtype will keep the size of
//normal text at the subscript size, sigh.
pS->WriteUChar( 0x0A );
}
void MathType::HandleFractions(SmNode *pNode,int nLevel)
{
SmNode *pTemp;
pS->WriteUChar( TMPL ); //Template
pS->WriteUChar( 0x0E ); //selector
pS->WriteUChar( 0x00 ); //variation
pS->WriteUChar( 0x00 ); //options
pS->WriteUChar( 0x0A );
pS->WriteUChar( LINE ); //line
if (nullptr != (pTemp = pNode->GetSubNode(0)))
HandleNodes(pTemp,nLevel+1);
pS->WriteUChar( END );
pS->WriteUChar( 0x0A );
pS->WriteUChar( LINE ); //line
if (nullptr != (pTemp = pNode->GetSubNode(2)))
HandleNodes(pTemp,nLevel+1);
pS->WriteUChar( END );
pS->WriteUChar( END );
}
void MathType::HandleBrace(SmNode *pNode,int nLevel)
{
SmNode *pTemp;
SmNode *pLeft=pNode->GetSubNode(0);
SmNode *pRight=pNode->GetSubNode(2);
pS->WriteUChar( TMPL ); //Template
bIsReInterpBrace=false;
sal_uInt8 nBSpec=0x10;
auto nLoc = pS->Tell();
if (pLeft)
{
switch (pLeft->GetToken().eType)
{
case TLANGLE:
pS->WriteUChar( tmANGLE ); //selector
pS->WriteUChar( 0 ); //variation
pS->WriteUChar( 0 ); //options
break;
case TLBRACE:
pS->WriteUChar( tmBRACE ); //selector
pS->WriteUChar( 0 ); //variation
pS->WriteUChar( 0 ); //options
nBSpec+=3;
break;
case TLBRACKET:
pS->WriteUChar( tmBRACK ); //selector
pS->WriteUChar( 0 ); //variation
pS->WriteUChar( 0 ); //options
nBSpec+=3;
break;
case TLFLOOR:
pS->WriteUChar( tmFLOOR ); //selector
pS->WriteUChar( 0 ); //variation
pS->WriteUChar( 0 ); //options
break;
case TLLINE:
pS->WriteUChar( tmBAR ); //selector
pS->WriteUChar( 0 ); //variation
pS->WriteUChar( 0 ); //options
nBSpec+=3;
break;
case TLDLINE:
pS->WriteUChar( tmDBAR ); //selector
pS->WriteUChar( 0 ); //variation
pS->WriteUChar( 0 ); //options
break;
default:
pS->WriteUChar( tmPAREN ); //selector
pS->WriteUChar( 0 ); //variation
pS->WriteUChar( 0 ); //options
nBSpec+=3;
break;
}
}
if (nullptr != (pTemp = pNode->GetSubNode(1)))
{
pS->WriteUChar( LINE ); //line
HandleNodes(pTemp,nLevel+1);
pS->WriteUChar( END ); //options
}
nSpec=nBSpec;
if (pLeft)
HandleNodes(pLeft,nLevel+1);
if (bIsReInterpBrace)
{
auto nLoc2 = pS->Tell();
pS->Seek(nLoc);
pS->WriteUChar( 0x2D );
pS->Seek(nLoc2);
pS->WriteUChar( CHAR );
pS->WriteUChar( 0x96 );
pS->WriteUInt16( 0xEC07 );
bIsReInterpBrace=false;
}
if (pRight)
HandleNodes(pRight,nLevel+1);
nSpec=0x0;
pS->WriteUChar( END );
}
void MathType::HandleVerticalBrace(SmNode *pNode,int nLevel)
{
SmNode *pTemp;
pS->WriteUChar( TMPL ); //Template
if (pNode->GetToken().eType == TUNDERBRACE)
pS->WriteUChar( tmLHBRACE ); //selector
else
pS->WriteUChar( tmUHBRACE ); //selector
pS->WriteUChar( 0 ); //variation
pS->WriteUChar( 0 ); //options
if (nullptr != (pTemp = pNode->GetSubNode(0)))
{
pS->WriteUChar( LINE ); //line
HandleNodes(pTemp,nLevel+1);
pS->WriteUChar( END ); //options
}
if (nullptr != (pTemp = pNode->GetSubNode(2)))
{
pS->WriteUChar( LINE ); //line
HandleNodes(pTemp,nLevel+1);
pS->WriteUChar( END ); //options
}
pS->WriteUChar( END );
}
void MathType::HandleOperator(SmNode *pNode,int nLevel)
{
if (HandleLim(pNode,nLevel))
return;
sal_uInt64 nPos;
sal_uInt8 nVariation;
switch (pNode->GetToken().eType)
{
case TIINT:
case TIIINT:
case TLINT:
case TLLINT:
case TLLLINT:
nVariation=HandleCScript(pNode->GetSubNode(0),
pNode->GetSubNode(1),nLevel,&nPos,false);
break;
default:
nVariation=HandleCScript(pNode->GetSubNode(0),
pNode->GetSubNode(1),nLevel,&nPos);
break;
}
sal_uInt8 nOldVariation=nVariation;
sal_uInt8 nIntVariation=nVariation;
sal_uInt64 nPos2=0;
if (nVariation != 0xff)
{
nPos2 = pS->Tell();
pS->Seek(nPos);
if (nVariation == 2)
{
nIntVariation=0;
nVariation = 1;
}
else if (nVariation == 0)
nVariation = 1;
else if (nVariation == 1)
nVariation = 0;
}
else
{
nVariation = 2;
nIntVariation=0;
}
pS->WriteUChar( TMPL );
switch(pNode->GetToken().eType)
{
case TINT:
case TINTD:
if (nOldVariation != 0xff)
pS->WriteUChar( 0x18 ); //selector
else
pS->WriteUChar( 0x15 ); //selector
pS->WriteUChar( nIntVariation ); //variation
break;
case TIINT:
if (nOldVariation != 0xff)
{
pS->WriteUChar( 0x19 );
pS->WriteUChar( 0x01 );
}
else
{
pS->WriteUChar( 0x16 );
pS->WriteUChar( 0x00 );
}
break;
case TIIINT:
if (nOldVariation != 0xff)
{
pS->WriteUChar( 0x1a );
pS->WriteUChar( 0x01 );
}
else
{
pS->WriteUChar( 0x17 );
pS->WriteUChar( 0x00 );
}
break;
case TLINT:
if (nOldVariation != 0xff)
{
pS->WriteUChar( 0x18 );
pS->WriteUChar( 0x02 );
}
else
{
pS->WriteUChar( 0x15 );
pS->WriteUChar( 0x03 );
}
break;
case TLLINT:
if (nOldVariation != 0xff)
{
pS->WriteUChar( 0x19 );
pS->WriteUChar( 0x00 );
}
else
{
pS->WriteUChar( 0x16 );
pS->WriteUChar( 0x02 );
}
break;
case TLLLINT:
if (nOldVariation != 0xff)
{
pS->WriteUChar( 0x1a );
pS->WriteUChar( 0x00 );
}
else
{
pS->WriteUChar( 0x17 );
pS->WriteUChar( 0x02 );
}
break;
case TSUM:
default:
pS->WriteUChar( 0x1d );
pS->WriteUChar( nVariation );
break;
case TPROD:
pS->WriteUChar( 0x1f );
pS->WriteUChar( nVariation );
break;
case TCOPROD:
pS->WriteUChar( 0x21 );
pS->WriteUChar( nVariation );
break;
}
pS->WriteUChar( 0 ); //options
if (nPos2)
pS->Seek(nPos2);
else
{
pS->WriteUChar( LINE ); //line
HandleNodes(pNode->GetSubNode(1),nLevel+1);
pS->WriteUChar( END ); //line
pS->WriteUChar( LINE|0x10 );
pS->WriteUChar( LINE|0x10 );
}
pS->WriteUChar( 0x0D );
switch(pNode->GetToken().eType)
{
case TSUM:
default:
pS->WriteUChar( CHAR );
pS->WriteUChar( 0x86 );
pS->WriteUInt16( 0x2211 );
break;
case TPROD:
pS->WriteUChar( CHAR );
pS->WriteUChar( 0x86 );
pS->WriteUInt16( 0x220F );
break;
case TCOPROD:
pS->WriteUChar( CHAR );
pS->WriteUChar( 0x8B );
pS->WriteUInt16( 0x2210 );
break;
case TIIINT:
case TLLLINT:
pS->WriteUChar( CHAR );
pS->WriteUChar( 0x86 );
pS->WriteUInt16( 0x222B );
SAL_FALLTHROUGH;
case TIINT:
case TLLINT:
pS->WriteUChar( CHAR );
pS->WriteUChar( 0x86 );
pS->WriteUInt16( 0x222B );
SAL_FALLTHROUGH;
case TINT:
case TINTD:
case TLINT:
pS->WriteUChar( CHAR );
pS->WriteUChar( 0x86 );
pS->WriteUInt16( 0x222B );
break;
}
pS->WriteUChar( END );
pS->WriteUChar( 0x0A );
}
bool MathType::HandlePile(int &rSetAlign, int nLevel, sal_uInt8 nSelector, sal_uInt8 nVariation)
{
sal_uInt8 nVAlign;
pS->ReadUChar( nHAlign );
pS->ReadUChar( nVAlign );
HandleAlign(nHAlign, rSetAlign);
rRet.append(" stack {\n");
bool bRet = HandleRecords( nLevel+1, nSelector, nVariation, -1, -1 );
int nRemoveFrom = rRet.getLength() >= 3 ? rRet.getLength() - 3 : 0;
rRet.remove(nRemoveFrom, 2);
rRet.append("} ");
while (rSetAlign)
{
rRet.append("} ");
rSetAlign--;
}
return bRet;
}
bool MathType::HandleMatrix(int nLevel, sal_uInt8 nSelector, sal_uInt8 nVariation)
{
sal_uInt8 nH_just,nV_just,nRows,nCols,nVAlign;
pS->ReadUChar( nVAlign );
pS->ReadUChar( nH_just );
pS->ReadUChar( nV_just );
pS->ReadUChar( nRows );
pS->ReadUChar( nCols );
int nBytes = ((nRows+1)*2)/8;
if (((nRows+1)*2)%8)
nBytes++;
pS->SeekRel(nBytes);
nBytes = ((nCols+1)*2)/8;
if (((nCols+1)*2)%8)
nBytes++;
pS->SeekRel(nBytes);
rRet.append(" matrix {\n");
bool bRet = HandleRecords( nLevel+1, nSelector, nVariation, nRows, nCols );
sal_Int32 nI = rRet.lastIndexOf('#');
if (nI > 0)
if (rRet[nI-1] != '#') //missing column
rRet.append("{}");
rRet.append("\n} ");
return bRet;
}
bool MathType::HandleTemplate(int nLevel, sal_uInt8 &rSelector,
sal_uInt8 &rVariation, sal_Int32 &rLastTemplateBracket)
{
sal_uInt8 nOption; //This appears utterly unused
pS->ReadUChar( rSelector );
pS->ReadUChar( rVariation );
pS->ReadUChar( nOption );
OSL_ENSURE(rSelector < 48,"Selector out of range");
if ((rSelector >= 21) && (rSelector <=26))
{
OSL_ENSURE(nOption < 2,"Option out of range");
}
else if (rSelector <= 12)
{
OSL_ENSURE(nOption < 3,"Option out of range");
}
//For the (broken) case where one subscript template ends, and there is
//another one after it, mathtype handles it as if the second one was
//inside the first one and renders it as sub of sub
bool bRemove=false;
if ( (rSelector == 0xf) && (rLastTemplateBracket != -1) )
{
bRemove=true;
for (sal_Int32 nI = rLastTemplateBracket+1; nI < rRet.getLength(); nI++ )
if (rRet[nI] != ' ')
{
bRemove=false;
break;
}
}
//suborderlist
bool bRet = HandleRecords( nLevel+1, rSelector, rVariation );
if (bRemove)
{
if (rLastTemplateBracket < rRet.getLength())
rRet.remove(rLastTemplateBracket, 1);
rRet.append("} ");
rLastTemplateBracket = -1;
}
if (rSelector == 0xf)
rLastTemplateBracket = rRet.lastIndexOf('}');
else
rLastTemplateBracket = -1;
rSelector = sal::static_int_cast< sal_uInt8 >(-1);
return bRet;
}
void MathType::HandleEmblishments()
{
sal_uInt8 nEmbel;
do
{
pS->ReadUChar( nEmbel );
if (!pS->good())
break;
switch (nEmbel)
{
case 0x02:
rRet.append(" dot ");
break;
case 0x03:
rRet.append(" ddot ");
break;
case 0x04:
rRet.append(" dddot ");
break;
case 0x05:
if (!nPostSup)
{
sPost.append(" sup {}");
nPostSup = sPost.getLength();
}
sPost.insert(nPostSup-1," ' ");
nPostSup += 3;
break;
case 0x06:
if (!nPostSup)
{
sPost.append(" sup {}");
nPostSup = sPost.getLength();
}
sPost.insert(nPostSup-1," '' ");
nPostSup += 4;
break;
case 0x07:
if (!nPostlSup)
{
sPost.append(" lsup {}");
nPostlSup = sPost.getLength();
}
sPost.insert(nPostlSup-1," ' ");
nPostlSup += 3;
break;
case 0x08:
rRet.append(" tilde ");
break;
case 0x09:
rRet.append(" hat ");
break;
case 0x0b:
rRet.append(" vec ");
break;
case 0x10:
rRet.append(" overstrike ");
break;
case 0x11:
rRet.append(" bar ");
break;
case 0x12:
if (!nPostSup)
{
sPost.append(" sup {}");
nPostSup = sPost.getLength();
}
sPost.insert(nPostSup-1," ''' ");
nPostSup += 5;
break;
case 0x14:
rRet.append(" breve ");
break;
default:
OSL_ENSURE(nEmbel < 21,"Embel out of range");
break;
}
if (nVersion < 3)
break;
}while (nEmbel);
}
void MathType::HandleSetSize()
{
sal_uInt8 nTemp;
pS->ReadUChar( nTemp );
switch (nTemp)
{
case 101:
pS->ReadInt16( nLSize );
nLSize = -nLSize;
break;
case 100:
pS->ReadUChar( nTemp );
nLSize = nTemp;
pS->ReadInt16( nDSize );
break;
default:
nLSize = nTemp;
pS->ReadUChar( nTemp );
nDSize = nTemp-128;
break;
}
}
bool MathType::HandleChar(sal_Int32 &rTextStart, int &rSetSize, int nLevel,
sal_uInt8 nTag, sal_uInt8 nSelector, sal_uInt8 nVariation, bool bSilent)
{
sal_Unicode nChar(0);
bool bRet = true;
if (xfAUTO(nTag))
{
//This is a candidate for function recognition, whatever
//that is!
}
sal_uInt8 nOldTypeFace = nTypeFace;
pS->ReadUChar( nTypeFace );
if (nVersion < 3)
{
sal_uInt8 nChar8(0);
pS->ReadUChar( nChar8 );
nChar = nChar8;
}
else
pS->ReadUtf16( nChar );
/*
bad character, old mathtype < 3 has these
*/
if (nChar < 0x20)
return bRet;
if (xfEMBELL(nTag))
{
//A bit tricky, the character emblishments for
//mathtype can all be listed after each other, in
//starmath some must go before the character and some
//must go after. In addition some of the emblishments
//may repeated and in starmath some of these groups
//must be gathered together. sPost is the portion that
//follows the char and nPostSup and nPostlSup are the
//indexes at which this class of emblishment is
//collated together
sPost = "";
nPostSup = nPostlSup = 0;
int nOriglen=rRet.getLength()-rTextStart;
rRet.append(" {"); // #i24340# make what would be "vec {A}_n" become "{vec {A}}_n"
if ((!bSilent) && (nOriglen > 1))
rRet.append("\"");
bRet = HandleRecords( nLevel+1, nSelector, nVariation );
if (!bSilent)
{
if (nOriglen > 1)
{
OUString aStr;
TypeFaceToString(aStr,nOldTypeFace);
aStr += "\"";
rRet.insert(std::min(rTextStart, rRet.getLength()), aStr);
aStr.clear();
TypeFaceToString(aStr,nTypeFace);
rRet.append(aStr).append("{");
}
else
rRet.append(" {");
rTextStart = rRet.getLength();
}
}
if (!bSilent)
{
sal_Int32 nOldLen = rRet.getLength();
if (
HandleSize(nLSize,nDSize,rSetSize) ||
(nOldTypeFace != nTypeFace)
)
{
if ((nOldLen - rTextStart) > 1)
{
rRet.insert(nOldLen, "\"");
OUString aStr;
TypeFaceToString(aStr,nOldTypeFace);
aStr += "\"";
rRet.insert(rTextStart,aStr);
}
rTextStart = rRet.getLength();
}
nOldLen = rRet.getLength();
if (!LookupChar(nChar,rRet,nVersion,nTypeFace))
{
if (nOldLen - rTextStart > 1)
{
rRet.insert(nOldLen, "\"");
OUString aStr;
TypeFaceToString(aStr,nOldTypeFace);
aStr += "\"";
rRet.insert(rTextStart, aStr);
}
rTextStart = rRet.getLength();
}
lcl_PrependDummyTerm(rRet, rTextStart);
}
if ((xfEMBELL(nTag)) && (!bSilent))
{
rRet.append("}}").append(sPost); // #i24340# make what would be "vec {A}_n" become "{vec {A}}_n"
rTextStart = rRet.getLength();
}
return bRet;
}
bool MathType::HandleLim(SmNode *pNode,int nLevel)
{
bool bRet=false;
//Special case for the "lim" option in StarMath
if ((pNode->GetToken().eType == TLIM)
|| (pNode->GetToken().eType == TLIMSUP)
|| (pNode->GetToken().eType == TLIMINF)
)
{
if (pNode->GetSubNode(1))
{
sal_uInt8 nVariation2=HandleCScript(pNode->GetSubNode(0),nullptr,
nLevel);
pS->WriteUChar( 0x0A );
pS->WriteUChar( LINE ); //line
pS->WriteUChar( CHAR|0x10 );
pS->WriteUChar( 0x82 );
pS->WriteUInt16( 'l' );
pS->WriteUChar( CHAR|0x10 );
pS->WriteUChar( 0x82 );
pS->WriteUInt16( 'i' );
pS->WriteUChar( CHAR|0x10 );
pS->WriteUChar( 0x82 );
pS->WriteUInt16( 'm' );
if (pNode->GetToken().eType == TLIMSUP)
{
pS->WriteUChar( CHAR ); //some space
pS->WriteUChar( 0x98 );
pS->WriteUInt16( 0xEB04 );
pS->WriteUChar( CHAR|0x10 );
pS->WriteUChar( 0x82 );
pS->WriteUInt16( 's' );
pS->WriteUChar( CHAR|0x10 );
pS->WriteUChar( 0x82 );
pS->WriteUInt16( 'u' );
pS->WriteUChar( CHAR|0x10 );
pS->WriteUChar( 0x82 );
pS->WriteUInt16( 'p' );
}
else if (pNode->GetToken().eType == TLIMINF)
{
pS->WriteUChar( CHAR ); //some space
pS->WriteUChar( 0x98 );
pS->WriteUInt16( 0xEB04 );
pS->WriteUChar( CHAR|0x10 );
pS->WriteUChar( 0x82 );
pS->WriteUInt16( 'i' );
pS->WriteUChar( CHAR|0x10 );
pS->WriteUChar( 0x82 );
pS->WriteUInt16( 'n' );
pS->WriteUChar( CHAR|0x10 );
pS->WriteUChar( 0x82 );
pS->WriteUInt16( 'f' );
}
pS->WriteUChar( CHAR ); //some space
pS->WriteUChar( 0x98 );
pS->WriteUInt16( 0xEB04 );
if (nVariation2 != 0xff)
{
pS->WriteUChar( END );
pS->WriteUChar( END );
}
HandleNodes(pNode->GetSubNode(1),nLevel+1);
bRet = true;
}
}
return bRet;
}
void MathType::HandleMAlign(SmNode *pNode,int nLevel)
{
sal_uInt8 nPushedHAlign=nHAlign;
switch(pNode->GetToken().eType)
{
case TALIGNC:
nHAlign=2;
break;
case TALIGNR:
nHAlign=3;
break;
default:
nHAlign=1;
break;
}
size_t nSize = pNode->GetNumSubNodes();
for (size_t i = 0; i < nSize; ++i)
{
if (SmNode *pTemp = pNode->GetSubNode(i))
HandleNodes(pTemp,nLevel+1);
}
nHAlign=nPushedHAlign;
}
void MathType::HandleMath(SmNode *pNode)
{
if (pNode->GetToken().eType == TMLINE)
{
pS->WriteUChar( END );
pS->WriteUChar( LINE );
bIsReInterpBrace=true;
return;
}
SmMathSymbolNode *pTemp = static_cast<SmMathSymbolNode *>(pNode);
for(sal_Int32 i=0;i<pTemp->GetText().getLength();i++)
{
sal_Unicode nArse = SmTextNode::ConvertSymbolToUnicode(pTemp->GetText()[i]);
if ((nArse == 0x2224) || (nArse == 0x2288) || (nArse == 0x2285) ||
(nArse == 0x2289))
{
pS->WriteUChar( CHAR|0x20 );
}
else if ((nPendingAttributes) &&
(i == ((pTemp->GetText().getLength()+1)/2)-1))
{
pS->WriteUChar( 0x22 );
}
else
pS->WriteUChar( CHAR ); //char without formula recognition
//The typeface seems to be MTEXTRA for unicode characters,
//though how to determine when mathtype chooses one over
//the other is unknown. This should do the trick
//nevertheless.
sal_uInt8 nBias;
if ( (nArse == 0x2213) || (nArse == 0x2218) ||
(nArse == 0x210F) || (
(nArse >= 0x22EE) && (nArse <= 0x22FF)
))
{
nBias = 0xB; //typeface
}
else if ((nArse > 0x2000) || (nArse == 0x00D7))
nBias = 0x6; //typeface
else if (nArse == 0x3d1)
nBias = 0x4;
else if ((nArse > 0xFF) && ((nArse < 0x393) || (nArse > 0x3c9)))
nBias = 0xB; //typeface
else if ((nArse == 0x2F) || (nArse == 0x2225))
nBias = 0x2; //typeface
else
nBias = 0x3; //typeface
pS->WriteUChar( nSpec+nBias+128 ); //typeface
if (nArse == 0x2224)
{
pS->WriteUInt16( 0x7C );
pS->WriteUChar( EMBEL );
pS->WriteUChar( 0x0A );
pS->WriteUChar( END ); //end embel
pS->WriteUChar( END ); //end embel
}
else if (nArse == 0x2225)
pS->WriteUInt16( 0xEC09 );
else if (nArse == 0xE421)
pS->WriteUInt16( 0x2265 );
else if (nArse == 0x230A)
pS->WriteUInt16( 0xF8F0 );
else if (nArse == 0x230B)
pS->WriteUInt16( 0xF8FB );
else if (nArse == 0xE425)
pS->WriteUInt16( 0x2264 );
else if (nArse == 0x226A)
{
pS->WriteUInt16( 0x3C );
pS->WriteUChar( CHAR );
pS->WriteUChar( 0x98 );
pS->WriteUInt16( 0xEB01 );
pS->WriteUChar( CHAR );
pS->WriteUChar( 0x86 );
pS->WriteUInt16( 0x3c );
}
else if (nArse == 0x2288)
{
pS->WriteUInt16( 0x2286 );
pS->WriteUChar( EMBEL );
pS->WriteUChar( 0x0A );
pS->WriteUChar( END ); //end embel
pS->WriteUChar( END ); //end embel
}
else if (nArse == 0x2289)
{
pS->WriteUInt16( 0x2287 );
pS->WriteUChar( EMBEL );
pS->WriteUChar( 0x0A );
pS->WriteUChar( END ); //end embel
pS->WriteUChar( END ); //end embel
}
else if (nArse == 0x2285)
{
pS->WriteUInt16( 0x2283 );
pS->WriteUChar( EMBEL );
pS->WriteUChar( 0x0A );
pS->WriteUChar( END ); //end embel
pS->WriteUChar( END ); //end embel
}
else
pS->WriteUInt16( nArse );
}
nPendingAttributes = 0;
}
void MathType::HandleAttributes(SmNode *pNode,int nLevel)
{
int nOldPending = 0;
SmNode *pTemp = nullptr;
SmTextNode *pIsText = nullptr;
if (nullptr != (pTemp = pNode->GetSubNode(0)))
{
pIsText = static_cast<SmTextNode *>(pNode->GetSubNode(1));
switch (pTemp->GetToken().eType)
{
case TWIDEVEC:
//there's just no way we can now handle any character
//attributes (from mathtypes perspective) centered
//over an expression but above template attributes
//such as widevec and similar constructs
//we have to drop them
nOldPending = StartTemplate(0x2f,0x01);
break;
case TCHECK: //Not Exportable
case TACUTE: //Not Exportable
case TGRAVE: //Not Exportable
case TCIRCLE: //Not Exportable
case TWIDETILDE: //Not Exportable
case TWIDEHAT: //Not Exportable
break;
case TUNDERLINE:
nOldPending = StartTemplate(0x10);
break;
case TOVERLINE: //If the next node is not text
//or text with more than one char
if ((pIsText->GetToken().eType != TTEXT) ||
(pIsText->GetText().getLength() > 1))
nOldPending = StartTemplate(0x11);
break;
default:
nPendingAttributes++;
break;
}
}
if (pIsText)
HandleNodes(pIsText,nLevel+1);
switch (pTemp->GetToken().eType)
{
case TWIDEVEC:
case TUNDERLINE:
EndTemplate(nOldPending);
break;
case TOVERLINE:
if ((pIsText->GetToken().eType != TTEXT) ||
(pIsText->GetText().getLength() > 1))
EndTemplate(nOldPending);
break;
default:
break;
}
//if there was no suitable place to put the attribute,
//then we have to just give up on it
if (nPendingAttributes)
nPendingAttributes--;
else
{
if ((nInsertion != 0) && nullptr != (pTemp = pNode->GetSubNode(0)))
{
auto nPos = pS->Tell();
nInsertion--;
pS->Seek(nInsertion);
switch(pTemp->GetToken().eType)
{
case TACUTE: //Not Exportable
case TGRAVE: //Not Exportable
case TCIRCLE: //Not Exportable
break;
case TCDOT:
pS->WriteUChar( 2 );
break;
case TDDOT:
pS->WriteUChar( 3 );
break;
case TDDDOT:
pS->WriteUChar( 4 );
break;
case TTILDE:
pS->WriteUChar( 8 );
break;
case THAT:
pS->WriteUChar( 9 );
break;
case TVEC:
pS->WriteUChar( 11 );
break;
case TOVERSTRIKE:
pS->WriteUChar( 16 );
break;
case TOVERLINE:
if ((pIsText->GetToken().eType == TTEXT) &&
(pIsText->GetText().getLength() == 1))
pS->WriteUChar( 17 );
break;
case TBREVE:
pS->WriteUChar( 20 );
break;
case TWIDEVEC:
case TUNDERLINE:
case TWIDETILDE:
case TWIDEHAT:
break;
case TBAR:
pS->WriteUChar( 17 );
break;
default:
pS->WriteUChar( 2 );
break;
}
pS->Seek(nPos);
}
}
}
void MathType::HandleText(SmNode *pNode)
{
SmTextNode *pTemp = static_cast<SmTextNode *>(pNode);
for(sal_Int32 i=0;i<pTemp->GetText().getLength();i++)
{
if ((nPendingAttributes) &&
(i == ((pTemp->GetText().getLength()+1)/2)-1))
{
pS->WriteUChar( 0x22 ); //char, with attributes right
//after the character
}
else
pS->WriteUChar( CHAR );
sal_uInt8 nFace = 0x1;
if (pNode->GetFont().GetItalic() == ITALIC_NORMAL)
nFace = 0x3;
else if (pNode->GetFont().GetWeight() == WEIGHT_BOLD)
nFace = 0x7;
pS->WriteUChar( nFace+128 ); //typeface
sal_uInt16 nChar = pTemp->GetText()[i];
pS->WriteUInt16( SmTextNode::ConvertSymbolToUnicode(nChar) );
//Mathtype can only have these sort of character
//attributes on a single character, starmath can put them
//anywhere, when the entity involved is a text run this is
//a large effort to place the character attribute on the
//central mathtype character so that it does pretty much
//what the user probably has in mind. The attributes
//filled in here are dummy ones which are replaced in the
//ATTRIBUT handler if a suitable location for the
//attributes was found here. Unfortunately it is
//possible for starmath to place character attributes on
//entities which cannot occur in mathtype e.g. a Summation
//symbol so these attributes may be lost
if ((nPendingAttributes) &&
(i == ((pTemp->GetText().getLength()+1)/2)-1))
{
pS->WriteUChar( EMBEL );
while (nPendingAttributes)
{
pS->WriteUChar( 2 );
//wedge the attributes in here and clear
//the pending stack
nPendingAttributes--;
}
nInsertion=pS->Tell();
pS->WriteUChar( END ); //end embel
pS->WriteUChar( END ); //end embel
}
}
}
extern "C" SAL_DLLPUBLIC_EXPORT bool TestImportMathType(SvStream &rStream)
{
OUStringBuffer sText;
MathType aEquation(sText);
bool bRet = false;
try
{
bRet = aEquation.Parse(&rStream);
}
catch (const std::out_of_range&)
{
}
return bRet;
}
/* vim:set shiftwidth=4 softtabstop=4 expandtab: */
↑ V547 Expression 'nVariation == 2' is always false.
↑ V1004 The 'pTemp' pointer was used unsafely after it was verified against nullptr. Check lines: 3150, 3189.
↑ V560 A part of conditional expression is always false: (nArse == 0x2225).
↑ V547 Expression 'nVariation == 1' is always false.