valentina/src/libs/qmuparser/qmuparsertokenreader.cpp

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/***************************************************************************************************
**
** Original work Copyright (C) 2013 Ingo Berg
** Modified work Copyright 2014 Roman Telezhinsky <dismine@gmail.com>
**
** Permission is hereby granted, free of charge, to any person obtaining a copy of this
** software and associated documentation files (the "Software"), to deal in the Software
** without restriction, including without limitation the rights to use, copy, modify,
** merge, publish, distribute, sublicense, and/or sell copies of the Software, and to
** permit persons to whom the Software is furnished to do so, subject to the following conditions:
**
** The above copyright notice and this permission notice shall be included in all copies or
** substantial portions of the Software.
**
** THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT
** NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
** NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM,
** DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
** OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
**
******************************************************************************************************/
#include <cassert>
#include <cstdio>
#include <cstring>
#include <map>
#include <stack>
#include <string>
#include <QStringList>
#include "qmuparsertokenreader.h"
#include "qmuparserbase.h"
/** \file
\brief This file contains the parser token reader implementation.
*/
namespace qmu
{
// Forward declaration
class QmuParserBase;
//---------------------------------------------------------------------------
/** \brief Copy constructor.
\sa Assign
\throw nothrow
*/
QmuParserTokenReader::QmuParserTokenReader(const QmuParserTokenReader &a_Reader)
{
Assign(a_Reader);
}
//---------------------------------------------------------------------------
/** \brief Assignement operator.
Self assignement will be suppressed otherwise #Assign is called.
\param a_Reader Object to copy to this token reader.
\throw nothrow
*/
QmuParserTokenReader& QmuParserTokenReader::operator=(const QmuParserTokenReader &a_Reader)
{
if (&a_Reader!=this)
Assign(a_Reader);
return *this;
}
//---------------------------------------------------------------------------
/** \brief Assign state of a token reader to this token reader.
\param a_Reader Object from which the state should be copied.
\throw nothrow
*/
void QmuParserTokenReader::Assign(const QmuParserTokenReader &a_Reader)
{
m_pParser = a_Reader.m_pParser;
m_strFormula = a_Reader.m_strFormula;
m_iPos = a_Reader.m_iPos;
m_iSynFlags = a_Reader.m_iSynFlags;
m_UsedVar = a_Reader.m_UsedVar;
m_pFunDef = a_Reader.m_pFunDef;
m_pConstDef = a_Reader.m_pConstDef;
m_pVarDef = a_Reader.m_pVarDef;
m_pStrVarDef = a_Reader.m_pStrVarDef;
m_pPostOprtDef = a_Reader.m_pPostOprtDef;
m_pInfixOprtDef = a_Reader.m_pInfixOprtDef;
m_pOprtDef = a_Reader.m_pOprtDef;
m_bIgnoreUndefVar = a_Reader.m_bIgnoreUndefVar;
m_vIdentFun = a_Reader.m_vIdentFun;
m_pFactory = a_Reader.m_pFactory;
m_pFactoryData = a_Reader.m_pFactoryData;
m_iBrackets = a_Reader.m_iBrackets;
m_cArgSep = a_Reader.m_cArgSep;
}
//---------------------------------------------------------------------------
/** \brief Constructor.
Create a Token reader and bind it to a parser object.
\pre [assert] a_pParser may not be NULL
\post #m_pParser==a_pParser
\param a_pParent Parent parser object of the token reader.
*/
QmuParserTokenReader::QmuParserTokenReader(QmuParserBase *a_pParent)
:m_pParser(a_pParent)
,m_strFormula()
,m_iPos(0)
,m_iSynFlags(0)
,m_bIgnoreUndefVar(false)
,m_pFunDef(NULL)
,m_pPostOprtDef(NULL)
,m_pInfixOprtDef(NULL)
,m_pOprtDef(NULL)
,m_pConstDef(NULL)
,m_pStrVarDef(NULL)
,m_pVarDef(NULL)
,m_pFactory(NULL)
,m_pFactoryData(NULL)
,m_vIdentFun()
,m_UsedVar()
,m_fZero(0)
,m_iBrackets(0)
,m_lastTok()
,m_cArgSep(',')
{
assert(m_pParser);
SetParent(m_pParser);
}
//---------------------------------------------------------------------------
/** \brief Create instance of a QParserTokenReader identical with this
and return its pointer.
This is a factory method the calling function must take care of the object destruction.
\return A new QParserTokenReader object.
\throw nothrow
*/
QmuParserTokenReader* QmuParserTokenReader::Clone(QmuParserBase *a_pParent) const
{
std::auto_ptr<QmuParserTokenReader> ptr(new QmuParserTokenReader(*this));
ptr->SetParent(a_pParent);
return ptr.release();
}
//---------------------------------------------------------------------------
QmuParserTokenReader::token_type& QmuParserTokenReader::SaveBeforeReturn(const token_type &tok)
{
m_lastTok = tok;
return m_lastTok;
}
//---------------------------------------------------------------------------
void QmuParserTokenReader::AddValIdent(identfun_type a_pCallback)
{
// Use push_front is used to give user defined callbacks a higher priority than
// the built in ones. Otherwise reading hex numbers would not work
// since the "0" in "0xff" would always be read first making parsing of
// the rest impossible.
// reference:
// http://sourceforge.net/projects/muparser/forums/forum/462843/topic/4824956
m_vIdentFun.push_front(a_pCallback);
}
//---------------------------------------------------------------------------
void QmuParserTokenReader::SetVarCreator(facfun_type a_pFactory, void *pUserData)
{
m_pFactory = a_pFactory;
m_pFactoryData = pUserData;
}
//---------------------------------------------------------------------------
/** \brief Return the current position of the token reader in the formula string.
\return #m_iPos
\throw nothrow
*/
int QmuParserTokenReader::GetPos() const
{
return m_iPos;
}
//---------------------------------------------------------------------------
/** \brief Return a reference to the formula.
\return #m_strFormula
\throw nothrow
*/
const QString& QmuParserTokenReader::GetExpr() const
{
return m_strFormula;
}
//---------------------------------------------------------------------------
/** \brief Return a map containing the used variables only. */
varmap_type& QmuParserTokenReader::GetUsedVar()
{
return m_UsedVar;
}
//---------------------------------------------------------------------------
/** \brief Initialize the token Reader.
Sets the formula position index to zero and set Syntax flags to default for initial formula parsing.
\pre [assert] triggered if a_szFormula==0
*/
void QmuParserTokenReader::SetFormula(const QString &a_strFormula)
{
m_strFormula = a_strFormula;
ReInit();
}
//---------------------------------------------------------------------------
/** \brief Set Flag that contronls behaviour in case of undefined variables beeing found.
If true, the parser does not throw an exception if an undefined variable is found.
otherwise it does. This variable is used internally only!
It supresses a "undefined variable" exception in GetUsedVar().
Those function should return a complete list of variables including
those the are not defined by the time of it's call.
*/
void QmuParserTokenReader::IgnoreUndefVar(bool bIgnore)
{
m_bIgnoreUndefVar = bIgnore;
}
//---------------------------------------------------------------------------
/** \brief Reset the token reader to the start of the formula.
The syntax flags will be reset to a value appropriate for the
start of a formula.
\post #m_iPos==0, #m_iSynFlags = noOPT | noBC | noPOSTOP | noSTR
\throw nothrow
\sa ESynCodes
*/
void QmuParserTokenReader::ReInit()
{
m_iPos = 0;
m_iSynFlags = sfSTART_OF_LINE;
m_iBrackets = 0;
m_UsedVar.clear();
m_lastTok = token_type();
}
//---------------------------------------------------------------------------
/** \brief Read the next token from the string. */
QmuParserTokenReader::token_type QmuParserTokenReader::ReadNextToken()
{
assert(m_pParser);
//std::stack<int> FunArgs;
#if defined(_UNICODE)
const char_type *szFormula = m_strFormula.toStdWString().c_str();
#else
const char_type *szFormula = m_strFormula.toStdString().c_str();
#endif
token_type tok;
// Ignore all non printable characters when reading the expression
while (szFormula[m_iPos]>0 && szFormula[m_iPos]<=0x20)
{
++m_iPos;
}
if ( IsEOF(tok) ) return SaveBeforeReturn(tok); // Check for end of formula
if ( IsOprt(tok) ) return SaveBeforeReturn(tok); // Check for user defined binary operator
if ( IsFunTok(tok) ) return SaveBeforeReturn(tok); // Check for function token
if ( IsBuiltIn(tok) ) return SaveBeforeReturn(tok); // Check built in operators / tokens
if ( IsArgSep(tok) ) return SaveBeforeReturn(tok); // Check for function argument separators
if ( IsValTok(tok) ) return SaveBeforeReturn(tok); // Check for values / constant tokens
if ( IsVarTok(tok) ) return SaveBeforeReturn(tok); // Check for variable tokens
if ( IsStrVarTok(tok) ) return SaveBeforeReturn(tok); // Check for string variables
if ( IsString(tok) ) return SaveBeforeReturn(tok); // Check for String tokens
if ( IsInfixOpTok(tok) ) return SaveBeforeReturn(tok); // Check for unary operators
if ( IsPostOpTok(tok) ) return SaveBeforeReturn(tok); // Check for unary operators
// Check String for undefined variable token. Done only if a
// flag is set indicating to ignore undefined variables.
// This is a way to conditionally avoid an error if
// undefined variables occur.
// (The GetUsedVar function must suppress the error for
// undefined variables in order to collect all variable
// names including the undefined ones.)
if ( (m_bIgnoreUndefVar || m_pFactory) && IsUndefVarTok(tok) )
{
return SaveBeforeReturn(tok);
}
// Check for unknown token
//
// !!! From this point on there is no exit without an exception possible...
//
QString strTok;
int iEnd = ExtractToken(m_pParser->ValidNameChars(), strTok, m_iPos);
if (iEnd!=m_iPos)
{
Error(ecUNASSIGNABLE_TOKEN, m_iPos, strTok);
}
Error(ecUNASSIGNABLE_TOKEN, m_iPos, m_strFormula.mid(m_iPos));
return token_type(); // never reached
}
//---------------------------------------------------------------------------
void QmuParserTokenReader::SetParent(QmuParserBase *a_pParent)
{
m_pParser = a_pParent;
m_pFunDef = &a_pParent->m_FunDef;
m_pOprtDef = &a_pParent->m_OprtDef;
m_pInfixOprtDef = &a_pParent->m_InfixOprtDef;
m_pPostOprtDef = &a_pParent->m_PostOprtDef;
m_pVarDef = &a_pParent->m_VarDef;
m_pStrVarDef = &a_pParent->m_StrVarDef;
m_pConstDef = &a_pParent->m_ConstDef;
}
//---------------------------------------------------------------------------
/** \brief Extract all characters that belong to a certain charset.
\param a_szCharSet [in] Const char array of the characters allowed in the token.
\param a_strTok [out] The string that consists entirely of characters listed in a_szCharSet.
\param a_iPos [in] Position in the string from where to start reading.
\return The Position of the first character not listed in a_szCharSet.
\throw nothrow
*/
int QmuParserTokenReader::ExtractToken(const QString &a_szCharSet, QString &a_sTok, int a_iPos) const
{
#if defined(_UNICODE)
const std::wstring m_strFormulaStd = m_strFormula.toStdWString();
const std::wstring a_szCharSetstd = a_szCharSet.toStdWString();
#else
const std::string m_strFormulaStd = m_strFormula.toStdString();
const std::string a_szCharSetStd = a_szCharSet.toStdString();
#endif
int iEnd = (int)m_strFormulaStd.find_first_not_of(a_szCharSetStd, a_iPos);
if (iEnd==(int)string_type::npos)
{
iEnd = (int)m_strFormulaStd.length();
}
// Assign token string if there was something found
if (a_iPos!=iEnd)
{
#if defined(_UNICODE)
a_sTok = QString().fromStdWString(std::wstring( m_strFormulaStd.begin()+a_iPos, m_strFormulaStd.begin()+iEnd));
#else
a_sTok = QString().fromStdString(std::string( m_strFormulaStd.begin()+a_iPos, m_strFormulaStd.begin()+iEnd));
#endif
}
return iEnd;
}
//---------------------------------------------------------------------------
/** \brief Check Expression for the presence of a binary operator token.
Userdefined binary operator "++" gives inconsistent parsing result for
the equations "a++b" and "a ++ b" if alphabetic characters are allowed
in operator tokens. To avoid this this function checks specifically
for operator tokens.
*/
int QmuParserTokenReader::ExtractOperatorToken(QString &a_sTok, int a_iPos) const
{
#if defined(_UNICODE)
const std::wstring m_strFormulaStd = m_strFormula.toStdWString();
const std::wstring oprtCharsStd = m_pParser->ValidInfixOprtChars().toStdWString();
#else
const std::string m_strFormulaStd = m_strFormula.toStdString();
const std::string oprtCharsStd = m_pParser->ValidInfixOprtChars().toStdString();
#endif
int iEnd = (int)m_strFormulaStd.find_first_not_of(oprtCharsStd, a_iPos);
if (iEnd==(int)string_type::npos)
{
iEnd = (int)m_strFormulaStd.length();
}
// Assign token string if there was something found
if (a_iPos!=iEnd)
{
#if defined(_UNICODE)
a_sTok = QString().fromStdWString(string_type(m_strFormulaStd.begin() + a_iPos,
m_strFormulaStd.begin() + iEnd));
#else
a_sTok = QString().fromStdString(string_type(m_strFormulaStd.begin() + a_iPos, m_strFormulaStd.begin() + iEnd));
#endif
return iEnd;
}
else
{
// There is still the chance of having to deal with an operator consisting exclusively
// of alphabetic characters.
return ExtractToken(QMUP_CHARS, a_sTok, a_iPos);
}
}
//---------------------------------------------------------------------------
/** \brief Check if a built in operator or other token can be found
\param a_Tok [out] Operator token if one is found. This can either be a binary operator or an infix operator token.
\return true if an operator token has been found.
*/
bool QmuParserTokenReader::IsBuiltIn(token_type &a_Tok)
{
const QStringList pOprtDef = m_pParser->GetOprtDef();
// Compare token with function and operator strings
// check string for operator/function
for (int i=0; i < pOprtDef.size(); ++i)
{
int len = pOprtDef.at(i).length();
if ( pOprtDef.at(i) == m_strFormula.mid(m_iPos, m_iPos + len) )
{
switch(i)
{
//case cmAND:
//case cmOR:
//case cmXOR:
case cmLAND:
case cmLOR:
case cmLT:
case cmGT:
case cmLE:
case cmGE:
case cmNEQ:
case cmEQ:
case cmADD:
case cmSUB:
case cmMUL:
case cmDIV:
case cmPOW:
case cmASSIGN:
//if (len!=sTok.length())
// continue;
// The assignement operator need special treatment
if (i==cmASSIGN && m_iSynFlags & noASSIGN)
Error(ecUNEXPECTED_OPERATOR, m_iPos, pOprtDef.at(i));
if (!m_pParser->HasBuiltInOprt()) continue;
if (m_iSynFlags & noOPT)
{
// Maybe its an infix operator not an operator
// Both operator types can share characters in
// their identifiers
if ( IsInfixOpTok(a_Tok) )
return true;
Error(ecUNEXPECTED_OPERATOR, m_iPos, pOprtDef.at(i));
}
m_iSynFlags = noBC | noOPT | noARG_SEP | noPOSTOP | noASSIGN | noIF | noELSE;
m_iSynFlags |= ( (i != cmEND) && ( i != cmBC) ) ? noEND : 0;
break;
case cmBO:
if (m_iSynFlags & noBO)
Error(ecUNEXPECTED_PARENS, m_iPos, pOprtDef.at(i));
if (m_lastTok.GetCode()==cmFUNC)
m_iSynFlags = noOPT | noEND | noARG_SEP | noPOSTOP | noASSIGN | noIF | noELSE;
else
m_iSynFlags = noBC | noOPT | noEND | noARG_SEP | noPOSTOP | noASSIGN| noIF | noELSE;
++m_iBrackets;
break;
case cmBC:
if (m_iSynFlags & noBC)
Error(ecUNEXPECTED_PARENS, m_iPos, pOprtDef.at(i));
m_iSynFlags = noBO | noVAR | noVAL | noFUN | noINFIXOP | noSTR | noASSIGN;
if (--m_iBrackets<0)
Error(ecUNEXPECTED_PARENS, m_iPos, pOprtDef.at(i));
break;
case cmELSE:
if (m_iSynFlags & noELSE)
Error(ecUNEXPECTED_CONDITIONAL, m_iPos, pOprtDef.at(i));
m_iSynFlags = noBC | noPOSTOP | noEND | noOPT | noIF | noELSE;
break;
case cmIF:
if (m_iSynFlags & noIF)
Error(ecUNEXPECTED_CONDITIONAL, m_iPos, pOprtDef.at(i));
m_iSynFlags = noBC | noPOSTOP | noEND | noOPT | noIF | noELSE;
break;
default: // The operator is listed in c_DefaultOprt, but not here. This is a bad thing...
Error(ecINTERNAL_ERROR);
} // switch operator id
m_iPos += len;
a_Tok.Set( (ECmdCode)i, pOprtDef.at(i) );
return true;
} // if operator string found
} // end of for all operator strings
return false;
}
//---------------------------------------------------------------------------
bool QmuParserTokenReader::IsArgSep(token_type &a_Tok)
{
if (m_strFormula.at(m_iPos)==m_cArgSep)
{
// copy the separator into null terminated string
QString szSep;
szSep[0] = m_cArgSep;
szSep[1] = 0;
if (m_iSynFlags & noARG_SEP)
{
Error(ecUNEXPECTED_ARG_SEP, m_iPos, szSep);
}
m_iSynFlags = noBC | noOPT | noEND | noARG_SEP | noPOSTOP | noASSIGN;
m_iPos++;
a_Tok.Set(cmARG_SEP, szSep);
return true;
}
return false;
}
//---------------------------------------------------------------------------
/** \brief Check for End of Formula.
\return true if an end of formula is found false otherwise.
\param a_Tok [out] If an eof is found the corresponding token will be stored there.
\throw nothrow
\sa IsOprt, IsFunTok, IsStrFunTok, IsValTok, IsVarTok, IsString, IsInfixOpTok, IsPostOpTok
*/
bool QmuParserTokenReader::IsEOF(token_type &a_Tok)
{
#if defined(_UNICODE)
const char_type* szFormula = m_strFormula.toStdWString().c_str();
#else
const char_type* szFormula = m_strFormula.toStdString().c_str();
#endif
// check for EOF
if ( !szFormula[m_iPos] /*|| szFormula[m_iPos] == '\n'*/)
{
if ( m_iSynFlags & noEND )
Error(ecUNEXPECTED_EOF, m_iPos);
if (m_iBrackets>0)
Error(ecMISSING_PARENS, m_iPos, ")");
m_iSynFlags = 0;
a_Tok.Set(cmEND);
return true;
}
return false;
}
//---------------------------------------------------------------------------
/** \brief Check if a string position contains a unary infix operator.
\return true if a function token has been found false otherwise.
*/
bool QmuParserTokenReader::IsInfixOpTok(token_type &a_Tok)
{
QString sTok;
int iEnd = ExtractToken(m_pParser->ValidInfixOprtChars(), sTok, m_iPos);
if (iEnd==m_iPos)
return false;
// iteraterate over all postfix operator strings
funmap_type::const_reverse_iterator it = m_pInfixOprtDef->rbegin();
for ( ; it!=m_pInfixOprtDef->rend(); ++it)
{
if (sTok.indexOf(it->first)!=0)
continue;
a_Tok.Set(it->second, it->first);
m_iPos += (int)it->first.length();
if (m_iSynFlags & noINFIXOP)
Error(ecUNEXPECTED_OPERATOR, m_iPos, a_Tok.GetAsString());
m_iSynFlags = noPOSTOP | noINFIXOP | noOPT | noBC | noSTR | noASSIGN;
return true;
}
return false;
/*
a_Tok.Set(item->second, sTok);
m_iPos = (int)iEnd;
if (m_iSynFlags & noINFIXOP)
Error(ecUNEXPECTED_OPERATOR, m_iPos, a_Tok.GetAsString());
m_iSynFlags = noPOSTOP | noINFIXOP | noOPT | noBC | noSTR | noASSIGN;
return true;
*/
}
//---------------------------------------------------------------------------
/** \brief Check whether the token at a given position is a function token.
\param a_Tok [out] If a value token is found it will be placed here.
\throw ParserException if Syntaxflags do not allow a function at a_iPos
\return true if a function token has been found false otherwise.
\pre [assert] m_pParser!=0
*/
bool QmuParserTokenReader::IsFunTok(token_type &a_Tok)
{
QString strTok;
int iEnd = ExtractToken(m_pParser->ValidNameChars(), strTok, m_iPos);
if (iEnd==m_iPos)
return false;
funmap_type::const_iterator item = m_pFunDef->find(strTok);
if (item==m_pFunDef->end())
return false;
// Check if the next sign is an opening bracket
if (m_strFormula.at(iEnd)!='(')
return false;
a_Tok.Set(item->second, strTok);
m_iPos = iEnd;
if (m_iSynFlags & noFUN)
Error(ecUNEXPECTED_FUN, m_iPos-(int)a_Tok.GetAsString().length(), a_Tok.GetAsString());
m_iSynFlags = noANY ^ noBO;
return true;
}
//---------------------------------------------------------------------------
/** \brief Check if a string position contains a binary operator.
\param a_Tok [out] Operator token if one is found. This can either be a binary operator or an infix operator token.
\return true if an operator token has been found.
*/
bool QmuParserTokenReader::IsOprt(token_type &a_Tok)
{
QString strTok;
int iEnd = ExtractOperatorToken(strTok, m_iPos);
if (iEnd==m_iPos)
return false;
// Check if the operator is a built in operator, if so ignore it here
const QStringList pOprtDef = m_pParser->GetOprtDef();
QStringList::const_iterator constIterator;
for (constIterator = pOprtDef.constBegin(); m_pParser->HasBuiltInOprt() && constIterator != pOprtDef.constEnd();
++constIterator)
{
if ((*constIterator)==strTok)
return false;
}
// Note:
// All tokens in oprt_bin_maptype are have been sorted by their length
// Long operators must come first! Otherwise short names (like: "add") that
// are part of long token names (like: "add123") will be found instead
// of the long ones.
// Length sorting is done with ascending length so we use a reverse iterator here.
funmap_type::const_reverse_iterator it = m_pOprtDef->rbegin();
for ( ; it!=m_pOprtDef->rend(); ++it)
{
const QString &sID = it->first;
if ( sID == m_strFormula.mid(m_iPos, m_iPos + sID.length()) )
{
a_Tok.Set(it->second, strTok);
// operator was found
if (m_iSynFlags & noOPT)
{
// An operator was found but is not expected to occur at
// this position of the formula, maybe it is an infix
// operator, not a binary operator. Both operator types
// can share characters in their identifiers.
if ( IsInfixOpTok(a_Tok) )
return true;
else
{
// nope, no infix operator
return false;
//Error(ecUNEXPECTED_OPERATOR, m_iPos, a_Tok.GetAsString());
}
}
m_iPos += (int)sID.length();
m_iSynFlags = noBC | noOPT | noARG_SEP | noPOSTOP | noEND | noBC | noASSIGN;
return true;
}
}
return false;
}
//---------------------------------------------------------------------------
/** \brief Check if a string position contains a unary post value operator. */
bool QmuParserTokenReader::IsPostOpTok(token_type &a_Tok)
{
// <ibg 20110629> Do not check for postfix operators if they are not allowed at
// the current expression index.
//
// This will fix the bug reported here:
//
// http://sourceforge.net/tracker/index.php?func=detail&aid=3343891&group_id=137191&atid=737979
//
if (m_iSynFlags & noPOSTOP)
return false;
// </ibg>
// Tricky problem with equations like "3m+5":
// m is a postfix operator, + is a valid sign for postfix operators and
// for binary operators parser detects "m+" as operator string and
// finds no matching postfix operator.
//
// This is a special case so this routine slightly differs from the other
// token readers.
// Test if there could be a postfix operator
QString sTok;
int iEnd = ExtractToken(m_pParser->ValidOprtChars(), sTok, m_iPos);
if (iEnd==m_iPos)
return false;
// iteraterate over all postfix operator strings
funmap_type::const_reverse_iterator it = m_pPostOprtDef->rbegin();
for ( ; it!=m_pPostOprtDef->rend(); ++it)
{
if (sTok.indexOf(it->first)!=0)
continue;
a_Tok.Set(it->second, sTok);
m_iPos += it->first.length();
m_iSynFlags = noVAL | noVAR | noFUN | noBO | noPOSTOP | noSTR | noASSIGN;
return true;
}
return false;
}
//---------------------------------------------------------------------------
/** \brief Check whether the token at a given position is a value token.
Value tokens are either values or constants.
\param a_Tok [out] If a value token is found it will be placed here.
\return true if a value token has been found.
*/
bool QmuParserTokenReader::IsValTok(token_type &a_Tok)
{
assert(m_pConstDef);
assert(m_pParser);
QString strTok;
qreal fVal(0);
int iEnd(0);
// 2.) Check for user defined constant
// Read everything that could be a constant name
iEnd = ExtractToken(m_pParser->ValidNameChars(), strTok, m_iPos);
if (iEnd!=m_iPos)
{
valmap_type::const_iterator item = m_pConstDef->find(strTok);
if (item!=m_pConstDef->end())
{
m_iPos = iEnd;
a_Tok.SetVal(item->second, strTok);
if (m_iSynFlags & noVAL)
Error(ecUNEXPECTED_VAL, m_iPos - strTok.length(), strTok);
m_iSynFlags = noVAL | noVAR | noFUN | noBO | noINFIXOP | noSTR | noASSIGN;
return true;
}
}
// 3.call the value recognition functions provided by the user
// Call user defined value recognition functions
std::list<identfun_type>::const_iterator item = m_vIdentFun.begin();
for (item = m_vIdentFun.begin(); item!=m_vIdentFun.end(); ++item)
{
int iStart = m_iPos;
if ( (*item)(m_strFormula.mid(m_iPos), &m_iPos, &fVal)==1 )
{
strTok = m_strFormula.mid(iStart, m_iPos);
if (m_iSynFlags & noVAL)
Error(ecUNEXPECTED_VAL, m_iPos - strTok.length(), strTok);
a_Tok.SetVal(fVal, strTok);
m_iSynFlags = noVAL | noVAR | noFUN | noBO | noINFIXOP | noSTR | noASSIGN;
return true;
}
}
return false;
}
//---------------------------------------------------------------------------
/** \brief Check wheter a token at a given position is a variable token.
\param a_Tok [out] If a variable token has been found it will be placed here.
\return true if a variable token has been found.
*/
bool QmuParserTokenReader::IsVarTok(token_type &a_Tok)
{
if (!m_pVarDef->size())
return false;
QString strTok;
int iEnd = ExtractToken(m_pParser->ValidNameChars(), strTok, m_iPos);
if (iEnd==m_iPos)
return false;
varmap_type::const_iterator item = m_pVarDef->find(strTok);
if (item==m_pVarDef->end())
return false;
if (m_iSynFlags & noVAR)
Error(ecUNEXPECTED_VAR, m_iPos, strTok);
m_pParser->OnDetectVar(&m_strFormula, m_iPos, iEnd);
m_iPos = iEnd;
a_Tok.SetVar(item->second, strTok);
m_UsedVar[item->first] = item->second; // Add variable to used-var-list
m_iSynFlags = noVAL | noVAR | noFUN | noBO | noINFIXOP | noSTR;
// Zur Info hier die SynFlags von IsVal():
// m_iSynFlags = noVAL | noVAR | noFUN | noBO | noINFIXOP | noSTR | noASSIGN;
return true;
}
//---------------------------------------------------------------------------
bool QmuParserTokenReader::IsStrVarTok(token_type &a_Tok)
{
if (!m_pStrVarDef || !m_pStrVarDef->size())
return false;
QString strTok;
int iEnd = ExtractToken(m_pParser->ValidNameChars(), strTok, m_iPos);
if (iEnd==m_iPos)
return false;
strmap_type::const_iterator item = m_pStrVarDef->find(strTok);
if (item==m_pStrVarDef->end())
return false;
if (m_iSynFlags & noSTR)
Error(ecUNEXPECTED_VAR, m_iPos, strTok);
m_iPos = iEnd;
if (!m_pParser->m_vStringVarBuf.size())
Error(ecINTERNAL_ERROR);
a_Tok.SetString(m_pParser->m_vStringVarBuf[item->second], m_pParser->m_vStringVarBuf.size() );
m_iSynFlags = noANY ^ ( noBC | noOPT | noEND | noARG_SEP);
return true;
}
//---------------------------------------------------------------------------
/** \brief Check wheter a token at a given position is an undefined variable.
\param a_Tok [out] If a variable tom_pParser->m_vStringBufken has been found it will be placed here.
\return true if a variable token has been found.
\throw nothrow
*/
bool QmuParserTokenReader::IsUndefVarTok(token_type &a_Tok)
{
QString strTok;
int iEnd( ExtractToken(m_pParser->ValidNameChars(), strTok, m_iPos) );
if ( iEnd==m_iPos )
return false;
if (m_iSynFlags & noVAR)
{
// <ibg/> 20061021 added token string strTok instead of a_Tok.GetAsString() as the
// token identifier.
// related bug report:
// http://sourceforge.net/tracker/index.php?func=detail&aid=1578779&group_id=137191&atid=737979
Error(ecUNEXPECTED_VAR, m_iPos - (int)a_Tok.GetAsString().length(), strTok);
}
// If a factory is available implicitely create new variables
if (m_pFactory)
{
qreal *fVar = m_pFactory(strTok, m_pFactoryData);
a_Tok.SetVar(fVar, strTok );
// Do not use m_pParser->DefineVar( strTok, fVar );
// in order to define the new variable, it will clear the
// m_UsedVar array which will kill previousely defined variables
// from the list
// This is safe because the new variable can never override an existing one
// because they are checked first!
(*m_pVarDef)[strTok] = fVar;
m_UsedVar[strTok] = fVar; // Add variable to used-var-list
}
else
{
a_Tok.SetVar((qreal*)&m_fZero, strTok);
m_UsedVar[strTok] = 0; // Add variable to used-var-list
}
m_iPos = iEnd;
// Call the variable factory in order to let it define a new parser variable
m_iSynFlags = noVAL | noVAR | noFUN | noBO | noPOSTOP | noINFIXOP | noSTR;
return true;
}
//---------------------------------------------------------------------------
/** \brief Check wheter a token at a given position is a string.
\param a_Tok [out] If a variable token has been found it will be placed here.
\return true if a string token has been found.
\sa IsOprt, IsFunTok, IsStrFunTok, IsValTok, IsVarTok, IsEOF, IsInfixOpTok, IsPostOpTok
\throw nothrow
*/
bool QmuParserTokenReader::IsString(token_type &a_Tok)
{
if (m_strFormula[m_iPos]!='"')
return false;
QString strBuf(m_strFormula[m_iPos+1]);
int iEnd(0), iSkip(0);
// parser over escaped '\"' end replace them with '"'
for(iEnd=strBuf.indexOf( "\"" ); iEnd!=0 && iEnd!=-1; iEnd=strBuf.indexOf( "\"", iEnd))
{
if (strBuf[iEnd-1]!='\\') break;
strBuf.replace(iEnd-1, 2, "\"" );
iSkip++;
}
if (iEnd==-1)
Error(ecUNTERMINATED_STRING, m_iPos, "\"" );
QString strTok = strBuf.mid(0, iEnd);
if (m_iSynFlags & noSTR)
Error(ecUNEXPECTED_STR, m_iPos, strTok);
m_pParser->m_vStringBuf.push_back(strTok); // Store string in internal buffer
a_Tok.SetString(strTok, m_pParser->m_vStringBuf.size());
m_iPos += (int)strTok.length() + 2 + iSkip; // +2 wg Anfhrungszeichen; +iSkip fr entfernte escape zeichen
m_iSynFlags = noANY ^ ( noARG_SEP | noBC | noOPT | noEND );
return true;
}
//---------------------------------------------------------------------------
/** \brief Create an error containing the parse error position.
This function will create an Parser Exception object containing the error text and its position.
\param a_iErrc [in] The error code of type #EErrorCodes.
\param a_iPos [in] The position where the error was detected.
\param a_strTok [in] The token string representation associated with the error.
\throw ParserException always throws thats the only purpose of this function.
*/
void QmuParserTokenReader::Error( EErrorCodes a_iErrc,
int a_iPos,
const QString &a_sTok) const
{
m_pParser->Error(a_iErrc, a_iPos, a_sTok);
}
//---------------------------------------------------------------------------
void QmuParserTokenReader::SetArgSep(char_type cArgSep)
{
m_cArgSep = cArgSep;
}
//---------------------------------------------------------------------------
QChar QmuParserTokenReader::GetArgSep() const
{
return m_cArgSep;
}
} // namespace qmu