Grammar* GrammarResolver::getGrammar( const XMLCh* const namespaceKey)
{
if (!namespaceKey)
return 0;
Grammar* grammar = fGrammarBucket->get(namespaceKey);
if (grammar)
return grammar;
if (fUseCachedGrammar)
{
grammar = fGrammarFromPool->get(namespaceKey);
if (grammar)
{
return grammar;
}
else
{
XMLSchemaDescription* gramDesc = fGrammarPool->createSchemaDescription(namespaceKey);
Janitor<XMLGrammarDescription> janName(gramDesc);
grammar = fGrammarPool->retrieveGrammar(gramDesc);
if (grammar)
{
fGrammarFromPool->put((void*) grammar->getGrammarDescription()->getGrammarKey(), grammar);
}
return grammar;
}
}
return 0;
}
XMLBigInteger::XMLBigInteger(const XMLCh* const strValue,
MemoryManager* const manager)
: fSign(0)
, fMagnitude(0)
, fRawData(0)
, fMemoryManager(manager)
{
if (!strValue)
ThrowXMLwithMemMgr(NumberFormatException, XMLExcepts::XMLNUM_emptyString, fMemoryManager);
XMLCh* ret_value = (XMLCh*) fMemoryManager->allocate
(
(XMLString::stringLen(strValue) + 1) * sizeof(XMLCh)
);//new XMLCh[XMLString::stringLen(strValue)+1];
ArrayJanitor<XMLCh> janName(ret_value, fMemoryManager);
parseBigInteger(strValue, ret_value, fSign, fMemoryManager);
if (fSign == 0)
fMagnitude = XMLString::replicate(XMLUni::fgZeroLenString, fMemoryManager);
else
fMagnitude = XMLString::replicate(ret_value, fMemoryManager);
fRawData = XMLString::replicate(strValue, fMemoryManager);
}
int ListDatatypeValidator::getLength(const XMLCh* const content
, MemoryManager* const manager) const
{
BaseRefVectorOf<XMLCh>* tokenVector = XMLString::tokenizeString(content, manager);
Janitor<BaseRefVectorOf<XMLCh> > janName(tokenVector);
return tokenVector->size();
}
void ListDatatypeValidator::validate( const XMLCh* const content
, ValidationContext* const context
, MemoryManager* const manager)
{
setContent(content);
BaseRefVectorOf<XMLCh>* tokenVector = XMLString::tokenizeString(content, manager);
Janitor<BaseRefVectorOf<XMLCh> > janName(tokenVector);
checkContent(tokenVector, content, context, false, manager);
}
// ---------------------------------------------------------------------------
// XMLTransService: Non-virtual API
// ---------------------------------------------------------------------------
XMLTranscoder*
XMLTransService::makeNewTranscoderFor( const char* const encodingName
, XMLTransService::Codes& resValue
, const unsigned int blockSize
, MemoryManager* const manager)
{
XMLCh* tmpName = XMLString::transcode(encodingName, manager);
ArrayJanitor<XMLCh> janName(tmpName, manager);
return makeNewTranscoderFor(tmpName, resValue, blockSize, manager);
}
BinFileOutputStream::BinFileOutputStream(const char* const fileName
, MemoryManager* const manager)
:fSource(0)
,fMemoryManager(manager)
{
// Transcode the file name and put a janitor on the temp buffer
XMLCh* realName = XMLString::transcode(fileName, manager);
ArrayJanitor<XMLCh> janName(realName, manager);
// Try to open the file
fSource = XMLPlatformUtils::openFileToWrite(realName, manager);
}
//
// Remove all occurrences of './' when it is part of '/./'
//
// Since it could be '.\' or other combination on windows ( eg, '.'+chYanSign)
// we can't make use of patterMatch().
//
//
void XMLPlatformUtils::removeDotSlash(XMLCh* const path
, MemoryManager* const manager)
{
if ((!path) || (!*path))
return;
XMLCh* srcPtr = XMLString::replicate(path, manager);
int srcLen = XMLString::stringLen(srcPtr);
ArrayJanitor<XMLCh> janName(srcPtr, manager);
XMLCh* tarPtr = path;
while (*srcPtr)
{
if ( 3 <= srcLen )
{
if ( (isAnySlash(*srcPtr)) &&
(chPeriod == *(srcPtr+1)) &&
(isAnySlash(*(srcPtr+2))) )
{
// "\.\x" seen
// skip the first two, and start from the 3rd,
// since "\x" could be another "\."
srcPtr+=2;
srcLen-=2;
}
else
{
*tarPtr++ = *srcPtr++; // eat the current char
srcLen--;
}
}
else if ( 1 == srcLen )
{
*tarPtr++ = *srcPtr++;
}
else if ( 2 == srcLen)
{
*tarPtr++ = *srcPtr++;
*tarPtr++ = *srcPtr++;
}
}
*tarPtr = 0;
return;
}
bool ListDatatypeValidator::valueSpaceCheck(BaseRefVectorOf<XMLCh>* tokenVector
, const XMLCh* const enumStr
, MemoryManager* const manager) const
{
DatatypeValidator* theItemTypeDTV = getItemTypeDTV();
BaseRefVectorOf<XMLCh>* enumVector = XMLString::tokenizeString(enumStr, manager);
Janitor<BaseRefVectorOf<XMLCh> > janName(enumVector);
if (tokenVector->size() != enumVector->size())
return false;
for ( unsigned int j = 0; j < tokenVector->size(); j++ )
{
if (theItemTypeDTV->compare(tokenVector->elementAt(j), enumVector->elementAt(j), manager) != 0)
return false;
}
return true;
}
const XMLCh* VecAttrListImpl::getValue(const char* const name) const
{
// Temporarily transcode the name for lookup
XMLCh* wideName = XMLString::transcode(name, XMLPlatformUtils::fgMemoryManager);
ArrayJanitor<XMLCh> janName(wideName, XMLPlatformUtils::fgMemoryManager);
//
// Search the vector for the attribute with the given name and return
// its type.
//
for (unsigned int index = 0; index < fCount; index++)
{
const XMLAttr* curElem = fVector->elementAt(index);
if (XMLString::equals(curElem->getQName(), wideName))
return curElem->getValue();
}
return 0;
}
bool GrammarResolver::containsNameSpace( const XMLCh* const nameSpaceKey )
{
if (!nameSpaceKey)
return false;
if (fGrammarBucket->containsKey(nameSpaceKey))
return true;
if (fUseCachedGrammar)
{
if (fGrammarFromPool->containsKey(nameSpaceKey))
return true;
// Lastly, need to check in fGrammarPool
XMLSchemaDescription* gramDesc = fGrammarPool->createSchemaDescription(nameSpaceKey);
Janitor<XMLGrammarDescription> janName(gramDesc);
Grammar* grammar = fGrammarPool->retrieveGrammar(gramDesc);
if (grammar)
return true;
}
return false;
}
/***
* 2.5.1.2 List datatypes
*
* The canonical-lexical-representation for the ·list· datatype is defined as
* the lexical form in which each item in the ·list· has the canonical
* lexical representation of its ·itemType·.
***/
const XMLCh* ListDatatypeValidator::getCanonicalRepresentation(const XMLCh* const rawData
, MemoryManager* const memMgr
, bool toValidate) const
{
MemoryManager* toUse = memMgr? memMgr : getMemoryManager();
ListDatatypeValidator* temp = (ListDatatypeValidator*) this;
temp->setContent(rawData);
BaseRefVectorOf<XMLCh>* tokenVector = XMLString::tokenizeString(rawData, toUse);
Janitor<BaseRefVectorOf<XMLCh> > janName(tokenVector);
if (toValidate)
{
try
{
temp->checkContent(tokenVector, rawData, 0, false, toUse);
}
catch (...)
{
return 0;
}
}
unsigned int retBufSize = 2 * XMLString::stringLen(rawData);
XMLCh* retBuf = (XMLCh*) toUse->allocate(retBufSize * sizeof(XMLCh));
retBuf[0] = 0;
XMLCh* retBufPtr = retBuf;
DatatypeValidator* itemDv = this->getItemTypeDTV();
try
{
for (unsigned int i = 0; i < tokenVector->size(); i++)
{
XMLCh* itemCanRep = (XMLCh*) itemDv->getCanonicalRepresentation(tokenVector->elementAt(i), toUse, false);
unsigned int itemLen = XMLString::stringLen(itemCanRep);
if(retBufPtr+itemLen+2 >= retBuf+retBufSize)
{
// need to resize
XMLCh * oldBuf = retBuf;
retBuf = (XMLCh*) toUse->allocate(retBufSize * sizeof(XMLCh) * 4);
memcpy(retBuf, oldBuf, retBufSize * sizeof(XMLCh ));
retBufPtr = (retBufPtr - oldBuf) + retBuf;
toUse->deallocate(oldBuf);
retBufSize <<= 2;
}
XMLString::catString(retBufPtr, itemCanRep);
retBufPtr = retBufPtr + itemLen + 1;
*(retBufPtr++) = chSpace;
*(retBufPtr) = chNull;
toUse->deallocate(itemCanRep);
}
return retBuf;
}
catch (...)
{
return 0;
}
}
DatatypeValidator* DatatypeValidator::loadDV(XSerializeEngine& serEng)
{
int flag;
serEng>>flag;
if (DV_BUILTIN == flag)
{
XMLCh* dvName;
serEng.readString(dvName);
ArrayJanitor<XMLCh> janName(dvName, serEng.getMemoryManager());
return DatatypeValidatorFactory::getBuiltInRegistry()->get(dvName);
}
else if (DV_ZERO == flag)
{
return 0;
}
int type;
serEng>>type;
switch((ValidatorType)type)
{
case String:
StringDatatypeValidator* stringdv;
serEng>>stringdv;
return stringdv;
case AnyURI:
AnyURIDatatypeValidator* anyuridv;
serEng>>anyuridv;
return anyuridv;
case QName:
QNameDatatypeValidator* qnamedv;
serEng>>qnamedv;
return qnamedv;
case Name:
NameDatatypeValidator* namedv;
serEng>>namedv;
return namedv;
case NCName:
NCNameDatatypeValidator* ncnamedv;
serEng>>ncnamedv;
return ncnamedv;
case Boolean:
BooleanDatatypeValidator* booleandv;
serEng>>booleandv;
return booleandv;
case Float:
FloatDatatypeValidator* floatdv;
serEng>>floatdv;
return floatdv;
case Double:
DoubleDatatypeValidator* doubledv;
serEng>>doubledv;
return doubledv;
case Decimal:
DecimalDatatypeValidator* decimaldv;
serEng>>decimaldv;
return decimaldv;
case HexBinary:
HexBinaryDatatypeValidator* hexbinarydv;
serEng>>hexbinarydv;
return hexbinarydv;
case Base64Binary:
Base64BinaryDatatypeValidator* base64binarydv;
serEng>>base64binarydv;
return base64binarydv;
case Duration:
DurationDatatypeValidator* durationdv;
serEng>>durationdv;
return durationdv;
case DateTime:
DateTimeDatatypeValidator* datetimedv;
serEng>>datetimedv;
return datetimedv;
case Date:
DateDatatypeValidator* datedv;
serEng>>datedv;
return datedv;
case Time:
TimeDatatypeValidator* timedv;
serEng>>timedv;
return timedv;
case MonthDay:
MonthDayDatatypeValidator* monthdaydv;
serEng>>monthdaydv;
return monthdaydv;
case YearMonth:
YearMonthDatatypeValidator* yearmonthdv;
serEng>>yearmonthdv;
return yearmonthdv;
case Year:
YearDatatypeValidator* yeardv;
serEng>>yeardv;
return yeardv;
case Month:
MonthDatatypeValidator* monthdv;
serEng>>monthdv;
return monthdv;
case Day:
DayDatatypeValidator* daydv;
serEng>>daydv;
return daydv;
case ID:
IDDatatypeValidator* iddv;
serEng>>iddv;
return iddv;
case IDREF:
IDREFDatatypeValidator* idrefdv;
serEng>>idrefdv;
return idrefdv;
case ENTITY:
ENTITYDatatypeValidator* entitydv;
serEng>>entitydv;
return entitydv;
case NOTATION:
NOTATIONDatatypeValidator* notationdv;
serEng>>notationdv;
return notationdv;
case List:
ListDatatypeValidator* listdv;
serEng>>listdv;
return listdv;
case Union:
UnionDatatypeValidator* uniondv;
serEng>>uniondv;
return uniondv;
case AnySimpleType:
AnySimpleTypeDatatypeValidator* anysimpletypedv;
serEng>>anysimpletypedv;
return anysimpletypedv;
case UnKnown:
return 0;
default: //we treat this same as UnKnown
return 0;
}
}
void DatatypeValidator::serialize(XSerializeEngine& serEng)
{
if (serEng.isStoring())
{
serEng<<fAnonymous;
serEng<<fFinite;
serEng<<fBounded;
serEng<<fNumeric;
serEng<<fWhiteSpace;
serEng<<fFinalSet;
serEng<<fFacetsDefined;
serEng<<fFixed;
serEng<<(int)fType;
serEng<<(int)fOrdered;
storeDV(serEng, fBaseValidator);
/***
* Serialize RefHashTableOf<KVStringPair>
***/
XTemplateSerializer::storeObject(fFacets, serEng);
serEng.writeString(fPattern);
if (fTypeUri==XMLUni::fgZeroLenString)
{
serEng<<TYPENAME_ZERO;
}
else if (fTypeUri == SchemaSymbols::fgURI_SCHEMAFORSCHEMA)
{
serEng<<TYPENAME_S4S;
serEng.writeString(fTypeLocalName);
}
else
{
serEng<<TYPENAME_NORMAL;
serEng.writeString(fTypeLocalName);
serEng.writeString(fTypeUri);
}
/***
* don't serialize
* fRegex
***/
}
else
{
serEng>>fAnonymous;
serEng>>fFinite;
serEng>>fBounded;
serEng>>fNumeric;
serEng>>fWhiteSpace;
serEng>>fFinalSet;
serEng>>fFacetsDefined;
serEng>>fFixed;
int type;
serEng>>type;
fType=(ValidatorType)type;
serEng>>type;
fOrdered = (XSSimpleTypeDefinition::ORDERING)type;
fBaseValidator = loadDV(serEng);
/***
*
* Deserialize RefHashTableOf<KVStringPair>
*
***/
XTemplateSerializer::loadObject(&fFacets, 29, true, serEng);
serEng.readString(fPattern);
/***
* Recreate through setTypeName()
* fTypeName
***/
int flag;
serEng>>flag;
if ( TYPENAME_ZERO == flag )
{
setTypeName(0);
}
else if ( TYPENAME_S4S == flag )
{
XMLCh* typeLocalName;
serEng.readString(typeLocalName);
ArrayJanitor<XMLCh> janName(typeLocalName, fMemoryManager);
setTypeName(typeLocalName);
}
else // TYPENAME_NORMAL
{
XMLCh* typeLocalName;
serEng.readString(typeLocalName);
ArrayJanitor<XMLCh> janName(typeLocalName, fMemoryManager);
XMLCh* typeUri;
serEng.readString(typeUri);
ArrayJanitor<XMLCh> janUri(typeUri, fMemoryManager);
setTypeName(typeLocalName, typeUri);
}
/***
* don't serialize fRegex
***/
fRegex = new (fMemoryManager) RegularExpression(fPattern, SchemaSymbols::fgRegEx_XOption, fMemoryManager);
}
}
/***
* 3.2.3 decimal
*
* . the preceding optional "+" sign is prohibited.
* . The decimal point is required.
* . Leading and trailing zeroes are prohibited subject to the following:
* there must be at least one digit to the right and to the left of the decimal point which may be a zero.
*
***/
XMLCh* XMLBigDecimal::getCanonicalRepresentation(const XMLCh* const rawData
, MemoryManager* const memMgr)
{
try
{
XMLCh* retBuf = (XMLCh*) memMgr->allocate( (XMLString::stringLen(rawData)+1) * sizeof(XMLCh));
ArrayJanitor<XMLCh> janName(retBuf, memMgr);
int sign, totalDigits, fractDigits;
XMLBigDecimal::parseDecimal(rawData, retBuf, sign, totalDigits, fractDigits, memMgr);
//Extra space reserved in case strLen is zero
int strLen = XMLString::stringLen(retBuf);
XMLCh* retBuffer = (XMLCh*) memMgr->allocate( (strLen + 4) * sizeof(XMLCh));
if ( (sign == 0) || (totalDigits == 0))
{
retBuffer[0] = chDigit_0;
retBuffer[1] = chPeriod;
retBuffer[2] = chDigit_0;
retBuffer[3] = chNull;
}
else
{
XMLCh* retPtr = retBuffer;
if (sign == -1)
{
*retPtr++ = chDash;
}
if (fractDigits == totalDigits) // no integer
{
*retPtr++ = chDigit_0;
*retPtr++ = chPeriod;
XMLString::copyNString(retPtr, retBuf, strLen);
retPtr += strLen;
*retPtr = chNull;
}
else if (fractDigits == 0) // no fraction
{
XMLString::copyNString(retPtr, retBuf, strLen);
retPtr += strLen;
*retPtr++ = chPeriod;
*retPtr++ = chDigit_0;
*retPtr = chNull;
}
else // normal
{
int intLen = totalDigits - fractDigits;
XMLString::copyNString(retPtr, retBuf, intLen);
retPtr += intLen;
*retPtr++ = chPeriod;
XMLString::copyNString(retPtr, &(retBuf[intLen]), fractDigits);
retPtr += fractDigits;
*retPtr = chNull;
}
}
return retBuffer;
}//try
catch (...)
{
return 0;
}
}
void DatatypeValidator::serialize(XSerializeEngine& serEng)
{
if (serEng.isStoring())
{
serEng<<fAnonymous;
serEng<<fWhiteSpace;
serEng<<fFinalSet;
serEng<<fFacetsDefined;
serEng<<fFixed;
serEng<<(int)fType;
serEng<<(int)fOrdered;
serEng<<fFinite;
serEng<<fBounded;
serEng<<fNumeric;
/***
* don't serialize the fBaseValidator if it is a built-in
***/
if (isBuiltInDV(fBaseValidator))
{
serEng<<true;
serEng.writeString(fBaseValidator->getTypeName());
}
else
{
serEng<<false;
storeDV(serEng, fBaseValidator);
}
/***
* Serialize RefHashTableOf<KVStringPair>
***/
XTemplateSerializer::storeObject(fFacets, serEng);
serEng.writeString(fPattern);
/***
* don't serialize
* fRegex
* fTypeLocalName
* fTypeUri
***/
serEng.writeString(fTypeName);
}
else
{
serEng>>fAnonymous;
serEng>>fWhiteSpace;
serEng>>fFinalSet;
serEng>>fFacetsDefined;
serEng>>fFixed;
int type;
serEng>>type;
fType=(ValidatorType)type;
serEng>>type;
fOrdered = (XSSimpleTypeDefinition::ORDERING)type;
serEng>>fFinite;
serEng>>fBounded;
serEng>>fNumeric;
/***
*
* get the basevalidator's type
*
***/
bool isBuiltInDV = false;
serEng>>isBuiltInDV;
if (isBuiltInDV)
{
XMLCh* baseTypeName;
serEng.readString(baseTypeName);
ArrayJanitor<XMLCh> janName(baseTypeName, fMemoryManager);
/***
* Link to the fBuiltInRegistry
*
* Since DatatypeValidatorFactory is always the first one
* to be deserialized in SchemaGrammar, we are sure that
* the BuiltInRegistry shall be available now.
***/
fBaseValidator = DatatypeValidatorFactory::getBuiltInRegistry()->get(baseTypeName);
}
else
{
fBaseValidator = loadDV(serEng);
}
/***
*
* Deserialize RefHashTableOf<KVStringPair>
*
***/
XTemplateSerializer::loadObject(&fFacets, 29, true, serEng);
serEng.readString(fPattern);
/***
* don't serialize fRegex
***/
fRegex = 0;
/***
* Recreate through setTypeName()
* fTypeName
* fTypeLocalName
* fTypeUri
***/
XMLCh* typeName;
serEng.readString(typeName);
ArrayJanitor<XMLCh> janName(typeName, fMemoryManager);
setTypeName(typeName);
}
}
