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topElem->fThisElement
, topElem->fChildren
, topElem->fChildCount
);
if (res >= 0)
{
// One of the elements is not valid for the content. NOTE that
// if no children were provided but the content model requires
// them, it comes back with a zero value. But we cannot use that
// to index the child array in this case, and have to put out a
// special message.
if (!topElem->fChildCount)
{
fValidator->emitError
(
XMLValid::EmptyNotValidForContent
, topElem->fThisElement->getFormattedContentModel()
);
}
else if ((unsigned int)res >= topElem->fChildCount)
{
fValidator->emitError
(
XMLValid::NotEnoughElemsForCM
, topElem->fThisElement->getFormattedContentModel()
);
}
else
{
fValidator->emitError
(
XMLValid::ElementNotValidForContent
, topElem->fChildren[res]->getRawName()
, topElem->fThisElement->getFormattedContentModel()
);
}
if (((SchemaValidator*) fValidator)->getErrorOccurred())
fPSVIElemContext.fErrorOccurred = true;
else if (fPSVIElemContext.fCurrentDV && fPSVIElemContext.fCurrentDV->getType() == DatatypeValidator::Union)
psviMemberType = fValidationContext->getValidatingMemberType();
{
fPSVIElemContext.fIsSpecified = ((SchemaValidator*) fValidator)->getIsElemSpecified();
if(fPSVIElemContext.fIsSpecified)
fPSVIElemContext.fNormalizedValue = ((SchemaElementDecl *)topElem->fThisElement)->getDefaultValue();
}
// call matchers and de-activate context
int oldCount = fMatcherStack->getMatcherCount();
if (oldCount ||
((SchemaElementDecl*)topElem->fThisElement)->getIdentityConstraintCount()) {
for (int i = oldCount - 1; i >= 0; i--) {
XPathMatcher* matcher = fMatcherStack->getMatcherAt(i);
matcher->endElement(*(topElem->fThisElement), fContent.getRawBuffer());
}
if (fMatcherStack->size() > 0) {
fMatcherStack->popContext();
}
// handle everything *but* keyref's.
int newCount = fMatcherStack->getMatcherCount();
for (int j = oldCount - 1; j >= newCount; j--) {
XPathMatcher* matcher = fMatcherStack->getMatcherAt(j);
IdentityConstraint* ic = matcher->getIdentityConstraint();
if (ic && (ic->getType() != IdentityConstraint::KEYREF))
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fValueStoreCache->transplant(ic, matcher->getInitialDepth());
}
// now handle keyref's...
for (int k = oldCount - 1; k >= newCount; k--) {
XPathMatcher* matcher = fMatcherStack->getMatcherAt(k);
IdentityConstraint* ic = matcher->getIdentityConstraint();
if (ic && (ic->getType() == IdentityConstraint::KEYREF)) {
ValueStore* values = fValueStoreCache->getValueStoreFor(ic, matcher->getInitialDepth());
if (values) { // nothing to do if nothing matched!
values->endDcocumentFragment(fValueStoreCache);
}
}
}
fValueStoreCache->endElement();
}
}
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committed
if(!isRoot)
((SchemaElementDecl *)fElemStack.topElement()->fThisElement)->updateValidityFromElement(topElem->fThisElement, fGrammarType);
if (fPSVIHandler)
{
endElementPSVI
(
(SchemaElementDecl*)topElem->fThisElement, psviMemberType
);
}
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committed
// now we can reset the datatype buffer, since the
// application has had a chance to copy the characters somewhere else
((SchemaValidator *)fValidator)->clearDatatypeBuffer();
// If we have a doc handler, tell it about the end tag
if (fDocHandler)
{
fDocHandler->endElement
(
*topElem->fThisElement
, uriId
, isRoot
, fPrefixBuf.getRawBuffer()
);
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// pass information about type info:
const XMLCh *typeName = SchemaSymbols::fgATTVAL_ANYTYPE;
const XMLCh *typeURI = SchemaSymbols::fgURI_SCHEMAFORSCHEMA;
if(!fPSVIElemContext.fErrorOccurred)
{
if(fPSVIElemContext.fCurrentTypeInfo != 0)
{
if(fPSVIElemContext.fCurrentTypeInfo->getAnonymous())
typeName = XMLUni::fgZeroLenString;
else
typeName = fPSVIElemContext.fCurrentTypeInfo->getTypeLocalName();
typeURI = fPSVIElemContext.fCurrentTypeInfo->getTypeUri();
}
else
{
DatatypeValidator *actualDV = (psviMemberType)?psviMemberType:fPSVIElemContext.fCurrentDV;
if(actualDV)
{
if(actualDV->getAnonymous())
typeName = XMLUni::fgZeroLenString;
else
typeName = actualDV->getTypeLocalName();
typeURI = actualDV->getTypeUri();
}
}
}
else
{
// idiosyncratically, if there's an
// error but this element was simpleType-validated,
// the tests demand anySimpleType be returned
if(fPSVIElemContext.fCurrentDV)
typeName = SchemaSymbols::fgDT_ANYSIMPLETYPE;
}
fDocHandler->elementTypeInfo(typeName, typeURI);
// reset xsi:type ComplexTypeInfo
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((SchemaElementDecl*)topElem->fThisElement)->reset();
if (!isRoot)
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((SchemaElementDecl*)(fElemStack.topElement()->fThisElement))->
setXsiComplexTypeInfo(((SchemaValidator*)fValidator)->getCurrentTypeInfo());
// update error information
fErrorStack->push(fErrorStack->pop() || fPSVIElemContext.fErrorOccurred);
}
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// If this was the root, then done with content
gotData = !isRoot;
if (gotData) {
// Restore the grammar
fGrammar = fElemStack.getCurrentGrammar();
fGrammarType = fGrammar->getGrammarType();
fValidator->setGrammar(fGrammar);
// Restore the validation flag
fValidate = fElemStack.getValidationFlag();
}
}
// This method handles the high level logic of scanning the DOCType
// declaration. This calls the DTDScanner and kicks off both the scanning of
// the internal subset and the scanning of the external subset, if any.
//
// When we get here the '<!DOCTYPE' part has already been scanned, which is
// what told us that we had a doc type decl to parse.
void SGXMLScanner::scanDocTypeDecl()
{
// Just skips over it
// REVISIT: Should we issue a warning
static const XMLCh doctypeIE[] =
{
chOpenSquare, chCloseAngle, chNull
};
XMLCh nextCh = fReaderMgr.skipUntilIn(doctypeIE);
if (nextCh == chOpenSquare)
fReaderMgr.skipPastChar(chCloseSquare);
fReaderMgr.skipPastChar(chCloseAngle);
}
// This method is called to scan a start tag when we are processing
// namespaces. This method is called after we've scanned the < of a
// start tag. So we have to get the element name, then scan the attributes,
// after which we are either going to see >, />, or attributes followed
// by one of those sequences.
bool SGXMLScanner::scanStartTag(bool& gotData)
{
// Assume we will still have data until proven otherwise. It will only
// ever be false if this is the root and its empty.
gotData = true;
// Reset element content
fContent.reset();
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// The current position is after the open bracket, so we need to read in
// in the element name.
if (!fReaderMgr.getName(fQNameBuf))
{
emitError(XMLErrs::ExpectedElementName);
fReaderMgr.skipToChar(chOpenAngle);
return false;
}
// See if its the root element
const bool isRoot = fElemStack.isEmpty();
// Skip any whitespace after the name
fReaderMgr.skipPastSpaces();
// First we have to do the rawest attribute scan. We don't do any
// normalization of them at all, since we don't know yet what type they
// might be (since we need the element decl in order to do that.)
bool isEmpty;
unsigned int attCount = rawAttrScan
(
fQNameBuf.getRawBuffer()
, *fRawAttrList
, isEmpty
);
const bool gotAttrs = (attCount != 0);
// save the contentleafname and currentscope before addlevel, for later use
ContentLeafNameTypeVector* cv = 0;
XMLContentModel* cm = 0;
int currentScope = Grammar::TOP_LEVEL_SCOPE;
bool laxThisOne = false;
if (!isRoot)
{
// schema validator will have correct type if validating
SchemaElementDecl* tempElement = (SchemaElementDecl*)
fElemStack.topElement()->fThisElement;
SchemaElementDecl::ModelTypes modelType = tempElement->getModelType();
ComplexTypeInfo *currType = 0;
if (fValidate)
{
currType = ((SchemaValidator*)fValidator)->getCurrentTypeInfo();
if (currType)
modelType = (SchemaElementDecl::ModelTypes)currType->getContentType();
else // something must have gone wrong
modelType = SchemaElementDecl::Any;
}
else
{
currType = tempElement->getComplexTypeInfo();
}
if ((modelType == SchemaElementDecl::Mixed_Simple)
|| (modelType == SchemaElementDecl::Mixed_Complex)
|| (modelType == SchemaElementDecl::Children))
{
cm = currType->getContentModel();
cv = cm->getContentLeafNameTypeVector();
currentScope = fElemStack.getCurrentScope();
}
else if (modelType == SchemaElementDecl::Any) {
laxThisOne = true;
}
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}
// Now, since we might have to update the namespace map for this element,
// but we don't have the element decl yet, we just tell the element stack
// to expand up to get ready.
unsigned int elemDepth = fElemStack.addLevel();
fElemStack.setValidationFlag(fValidate);
// Check if there is any external schema location specified, and if we are at root,
// go through them first before scanning those specified in the instance document
if (isRoot
&& (fExternalSchemaLocation || fExternalNoNamespaceSchemaLocation)) {
if (fExternalSchemaLocation)
parseSchemaLocation(fExternalSchemaLocation);
if (fExternalNoNamespaceSchemaLocation)
resolveSchemaGrammar(fExternalNoNamespaceSchemaLocation, XMLUni::fgZeroLenString);
}
// Make an initial pass through the list and find any xmlns attributes or
// schema attributes.
if (attCount)
scanRawAttrListforNameSpaces(fRawAttrList, attCount);
// Resolve the qualified name to a URI and name so that we can look up
// the element decl for this element. We have now update the prefix to
// namespace map so we should get the correct element now.
int prefixColonPos = -1;
const XMLCh* qnameRawBuf = fQNameBuf.getRawBuffer();
unsigned int uriId = resolveQName
(
qnameRawBuf
, fPrefixBuf
, ElemStack::Mode_Element
, prefixColonPos
);
//if schema, check if we should lax or skip the validation of this element
bool parentValidation = fValidate;
if (cv) {
QName element(fPrefixBuf.getRawBuffer(), &qnameRawBuf[prefixColonPos + 1], uriId, fMemoryManager);
// elementDepth will be > 0, as cv is only constructed if element is not
// root.
laxThisOne = laxElementValidation(&element, cv, cm, elemDepth - 1);
}
// Look up the element now in the grammar. This will get us back a
// generic element decl object. We tell him to fault one in if he does
// not find it.
XMLElementDecl* elemDecl = 0;
bool wasAdded = false;
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bool errorBeforeElementFound = false;
bool laxBeforeElementFound = false;
const XMLCh* nameRawBuf = &qnameRawBuf[prefixColonPos + 1];
const XMLCh* original_uriStr = fGrammar->getTargetNamespace();
unsigned orgGrammarUri = fURIStringPool->getId(original_uriStr);
if (uriId != fEmptyNamespaceId) {
// Check in current grammar before switching if necessary
elemDecl = fGrammar->getElemDecl
(
uriId
, nameRawBuf
, qnameRawBuf
, currentScope
);
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committed
if(!elemDecl)
{
// look in the list of undeclared elements, as would have been done
// before we made grammars stateless:
elemDecl = fElemNonDeclPool->getByKey(nameRawBuf, uriId, currentScope);
}
if (!elemDecl && (orgGrammarUri != uriId)) {
// not found, switch to the specified grammar
const XMLCh* uriStr = getURIText(uriId);
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bool errorCondition = !switchGrammar(uriStr) && fValidate;
if (errorCondition && !laxThisOne)
{
fValidator->emitError
(
XMLValid::GrammarNotFound
,uriStr
);
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errorBeforeElementFound = true;
}
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else if(errorCondition)
laxBeforeElementFound = true;
elemDecl = fGrammar->getElemDecl
(
uriId
, nameRawBuf
, qnameRawBuf
, currentScope
);
}
if (!elemDecl && currentScope != Grammar::TOP_LEVEL_SCOPE) {
// if not found, then it may be a reference, try TOP_LEVEL_SCOPE
elemDecl = fGrammar->getElemDecl
(
uriId
, nameRawBuf
, qnameRawBuf
, Grammar::TOP_LEVEL_SCOPE
);
Neil Graham
committed
if(!elemDecl)
{
// look in the list of undeclared elements, as would have been done
// before we made grammars stateless:
elemDecl = fElemNonDeclPool->getByKey(nameRawBuf, uriId, Grammar::TOP_LEVEL_SCOPE);
}
if(!elemDecl) {
// still not found in specified uri
// try emptyNamesapce see if element should be un-qualified.
elemDecl = fGrammar->getElemDecl
(
fEmptyNamespaceId
, nameRawBuf
, qnameRawBuf
, currentScope
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);
Gareth Reakes
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bool errorCondition = elemDecl && elemDecl->getCreateReason() != XMLElementDecl::JustFaultIn;
if (errorCondition && fValidate) {
fValidator->emitError
(
XMLValid::ElementNotUnQualified
, elemDecl->getFullName()
);
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errorBeforeElementFound = true;
else if(errorCondition)
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laxBeforeElementFound = true;
}
}
if (!elemDecl) {
// still not found, fault this in and issue error later
// switch back to original grammar first
switchGrammar(original_uriStr);
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elemDecl = new (fMemoryManager) SchemaElementDecl
(
fPrefixBuf.getRawBuffer()
, nameRawBuf
, uriId
, SchemaElementDecl::Any
, Grammar::TOP_LEVEL_SCOPE
, fMemoryManager
);
elemDecl->setId(fElemNonDeclPool->put((void*)elemDecl->getBaseName(), uriId, currentScope, (SchemaElementDecl*)elemDecl));
wasAdded = true;
}
}
else if (!elemDecl)
{
//the element has no prefix,
//thus it is either a non-qualified element defined in current targetNS
//or an element that is defined in the globalNS
//try unqualifed first
elemDecl = fGrammar->getElemDecl
(
uriId
, nameRawBuf
, qnameRawBuf
, currentScope
);
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committed
if(!elemDecl)
{
// look in the list of undeclared elements, as would have been done
// before we made grammars stateless:
elemDecl = fElemNonDeclPool->getByKey(nameRawBuf, uriId, currentScope);
}
if (!elemDecl && orgGrammarUri != fEmptyNamespaceId) {
//not found, switch grammar and try globalNS
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bool errorCondition = !switchGrammar(XMLUni::fgZeroLenString) && fValidate;
if (errorCondition && !laxThisOne)
{
fValidator->emitError
(
XMLValid::GrammarNotFound
, XMLUni::fgZeroLenString
);
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committed
errorBeforeElementFound = true;
Gareth Reakes
committed
else if(errorCondition)
laxBeforeElementFound = true;
elemDecl = fGrammar->getElemDecl
(
uriId
, nameRawBuf
, qnameRawBuf
, currentScope
);
}
if (!elemDecl && currentScope != Grammar::TOP_LEVEL_SCOPE) {
// if not found, then it may be a reference, try TOP_LEVEL_SCOPE
elemDecl = fGrammar->getElemDecl
(
uriId
, nameRawBuf
, qnameRawBuf
, Grammar::TOP_LEVEL_SCOPE
);
Neil Graham
committed
if(!elemDecl)
{
// look in the list of undeclared elements, as would have been done
// before we made grammars stateless:
elemDecl = fElemNonDeclPool->getByKey(nameRawBuf, uriId, Grammar::TOP_LEVEL_SCOPE);
}
if (!elemDecl && orgGrammarUri != fEmptyNamespaceId) {
// still Not found in specified uri
// go to original Grammar again to see if element needs to be fully qualified.
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committed
const XMLCh* uriStr = getURIText(orgGrammarUri);
bool errorCondition = !switchGrammar(original_uriStr) && fValidate;
if (errorCondition && !laxThisOne)
{
fValidator->emitError
(
XMLValid::GrammarNotFound
,original_uriStr
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committed
errorBeforeElementFound = true;
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committed
else if(errorCondition)
laxBeforeElementFound = true;
elemDecl = fGrammar->getElemDecl
(
orgGrammarUri
, nameRawBuf
, qnameRawBuf
, currentScope
);
if (elemDecl && elemDecl->getCreateReason() != XMLElementDecl::JustFaultIn && fValidate) {
fValidator->emitError
(
XMLValid::ElementNotQualified
, elemDecl->getFullName()
);
Gareth Reakes
committed
errorBeforeElementFound = true;
}
}
}
if (!elemDecl) {
// still not found, fault this in and issue error later
// switch back to original grammar first
switchGrammar(original_uriStr);
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committed
elemDecl = new (fMemoryManager) SchemaElementDecl
(
fPrefixBuf.getRawBuffer()
, nameRawBuf
, uriId
, SchemaElementDecl::Any
, Grammar::TOP_LEVEL_SCOPE
, fMemoryManager
);
elemDecl->setId(fElemNonDeclPool->put((void*)elemDecl->getBaseName(), uriId, currentScope, (SchemaElementDecl*)elemDecl));
// this info needed for DOMTypeInfo
fPSVIElemContext.fErrorOccurred = false;
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committed
// We do something different here according to whether we found the
// element or not.
if (wasAdded)
{
if (laxThisOne) {
fValidate = false;
fElemStack.setValidationFlag(fValidate);
}
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else if(fValidate) {
((SchemaElementDecl *)(elemDecl))->setValidationAttempted(PSVIDefs::FULL);
}
// If validating then emit an error
if (fValidate)
{
// This is to tell the reuse Validator that this element was
// faulted-in, was not an element in the grammar pool originally
elemDecl->setCreateReason(XMLElementDecl::JustFaultIn);
fValidator->emitError
(
XMLValid::ElementNotDefined
, elemDecl->getFullName()
);
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((SchemaElementDecl *)(elemDecl))->setValidity(PSVIDefs::INVALID);
fPSVIElemContext.fErrorOccurred = true;
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committed
if(!laxBeforeElementFound) {
if (fValidate) {
((SchemaElementDecl *)(elemDecl))->setValidationAttempted(PSVIDefs::FULL);
((SchemaElementDecl *)(elemDecl))->setValidity(PSVIDefs::VALID);
}
}
// If its not marked declared and validating, then emit an error
if (!elemDecl->isDeclared()) {
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committed
if(elemDecl->getCreateReason() == XMLElementDecl::NoReason) {
((SchemaElementDecl *)(elemDecl))->setValidity(PSVIDefs::INVALID);
((SchemaElementDecl *)(elemDecl))->setValidationAttempted(PSVIDefs::FULL);
fPSVIElemContext.fErrorOccurred = true;
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}
fElemStack.setValidationFlag(fValidate);
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{
fValidator->emitError
(
XMLValid::ElementNotDefined
, elemDecl->getFullName()
);
}
}
((SchemaElementDecl*)elemDecl)->setXsiComplexTypeInfo(0);
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((SchemaElementDecl*)elemDecl)->setXsiSimpleTypeInfo(0);
}
if(errorBeforeElementFound) {
((SchemaElementDecl *)(elemDecl))->setValidity(PSVIDefs::INVALID);
}
// Now we can update the element stack to set the current element
// decl. We expanded the stack above, but couldn't store the element
// decl because we didn't know it yet.
fElemStack.setElement(elemDecl, fReaderMgr.getCurrentReaderNum());
fElemStack.setCurrentURI(uriId);
if (isRoot)
fRootElemName = XMLString::replicate(qnameRawBuf, fMemoryManager);
}
if (fPSVIHandler)
{
fPSVIElemContext.fElemDepth++;
if (elemDecl->isDeclared())
{
fPSVIElemContext.fNoneValidationDepth = fPSVIElemContext.fElemDepth;
}
else
{
fPSVIElemContext.fFullValidationDepth = fPSVIElemContext.fElemDepth;
/******
* While we report an error for historical reasons, this should
* actually result in lax assessment - NG.
if (isRoot && fValidate)
fPSVIElemContext.fErrorOccurred = true;
if (((SchemaValidator*) fValidator)->getErrorOccurred())
fPSVIElemContext.fErrorOccurred = true;
ComplexTypeInfo* typeinfo = (fValidate)
? ((SchemaValidator*)fValidator)->getCurrentTypeInfo()
: ((SchemaElementDecl*) elemDecl)->getComplexTypeInfo();
if (typeinfo) {
currentScope = typeinfo->getScopeDefined();
// switch grammar if the typeinfo has a different grammar (happens when there is xsi:type)
XMLCh* typeName = typeinfo->getTypeName();
const XMLCh poundStr[] = {chPound, chNull};
if (!XMLString::startsWith(typeName, poundStr)) {
const int comma = XMLString::indexOf(typeName, chComma);
if (comma > 0) {
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XMLBuffer prefixBuf(comma+1, fMemoryManager);
prefixBuf.append(typeName, comma);
const XMLCh* uriStr = prefixBuf.getRawBuffer();
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committed
bool errorCondition = !switchGrammar(uriStr) && fValidate;
if (errorCondition && !laxThisOne)
{
fValidator->emitError
(
XMLValid::GrammarNotFound
, prefixBuf.getRawBuffer()
);
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committed
((SchemaElementDecl *)(elemDecl))->setValidity(PSVIDefs::INVALID);
}
else if(errorCondition) {
((SchemaElementDecl *)(elemDecl))->setValidationAttempted(PSVIDefs::NONE);
((SchemaElementDecl *)(elemDecl))->setValidity(PSVIDefs::UNKNOWN);
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}
}
}
fElemStack.setCurrentScope(currentScope);
// Set element next state
if (elemDepth >= fElemStateSize) {
resizeElemState();
}
fElemState[elemDepth] = 0;
fElemStack.setCurrentGrammar(fGrammar);
// If this is the first element and we are validating, check the root
// element.
if (isRoot)
{
if (fValidate)
{
// Some validators may also want to check the root, call the
// XMLValidator::checkRootElement
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committed
if (fValidatorFromUser && !fValidator->checkRootElement(elemDecl->getId())) {
fValidator->emitError(XMLValid::RootElemNotLikeDocType);
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committed
((SchemaElementDecl *)(elemDecl))->setValidity(PSVIDefs::INVALID);
}
}
}
else if (parentValidation)
{
// If the element stack is not empty, then add this element as a
// child of the previous top element. If its empty, this is the root
// elem and is not the child of anything.
fElemStack.addChild(elemDecl->getElementName(), true);
}
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committed
// clear the map used to detect duplicate attributes
fUndeclaredAttrRegistryNS->removeAll();
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// Now lets get the fAttrList filled in. This involves faulting in any
// defaulted and fixed attributes and normalizing the values of any that
// we got explicitly.
//
// We update the attCount value with the total number of attributes, but
// it goes in with the number of values we got during the raw scan of
// explictly provided attrs above.
attCount = buildAttList(*fRawAttrList, attCount, elemDecl, *fAttrList);
// activate identity constraints
if (fValidate) {
unsigned int count = ((SchemaElementDecl*) elemDecl)->getIdentityConstraintCount();
if (count || fMatcherStack->getMatcherCount()) {
fValueStoreCache->startElement();
fMatcherStack->pushContext();
fValueStoreCache->initValueStoresFor((SchemaElementDecl*) elemDecl, (int) elemDepth);
for (unsigned int i = 0; i < count; i++) {
activateSelectorFor(((SchemaElementDecl*) elemDecl)->getIdentityConstraintAt(i), (int) elemDepth);
}
// call all active identity constraints
count = fMatcherStack->getMatcherCount();
for (unsigned int j = 0; j < count; j++) {
XPathMatcher* matcher = fMatcherStack->getMatcherAt(j);
matcher->startElement(*elemDecl, uriId, fPrefixBuf.getRawBuffer(), *fAttrList, attCount);
}
}
}
// Since the element may have default values, call start tag now regardless if it is empty or not
// If we have a document handler, then tell it about this start tag
if (fDocHandler)
{
fDocHandler->startElement
(
*elemDecl
, uriId
, fPrefixBuf.getRawBuffer()
, *fAttrList
, attCount
, false
, isRoot
);
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} // may be where we output something...
// if we have a PSVIHandler, now's the time to call
// its handleAttributesPSVI method:
if(fPSVIHandler)
{
QName *eName = elemDecl->getElementName();
fPSVIHandler->handleAttributesPSVI
(
eName->getLocalPart()
, fURIStringPool->getValueForId(eName->getURI())
, fPSVIAttrList
);
}
// If empty, validate content right now if we are validating and then
// pop the element stack top. Else, we have to update the current stack
// top's namespace mapping elements.
if (isEmpty)
{
// Pop the element stack back off since it'll never be used now
fElemStack.popTop();
DatatypeValidator* psviMemberType = 0;
if (fGrammarType == Grammar::SchemaGrammarType)
{
if (fValidate && elemDecl->isDeclared())
{
fPSVIElemContext.fCurrentDV = ((SchemaValidator*) fValidator)->getCurrentDatatypeValidator();
fPSVIElemContext.fCurrentTypeInfo = ((SchemaValidator*) fValidator)->getCurrentTypeInfo();
if(fPSVIHandler)
{
fPSVIElemContext.fNormalizedValue = ((SchemaValidator*) fValidator)->getNormalizedValue();
if (XMLString::equals(fPSVIElemContext.fNormalizedValue, XMLUni::fgZeroLenString))
fPSVIElemContext.fNormalizedValue = 0;
}
}
else
{
fPSVIElemContext.fCurrentDV = 0;
fPSVIElemContext.fCurrentTypeInfo = 0;
fPSVIElemContext.fNormalizedValue = 0;
// If validating, then insure that its legal to have no content
if (fValidate)
{
const int res = fValidator->checkContent(elemDecl, 0, 0);
if (res >= 0)
{
// REVISIT: in the case of xsi:type, this may
// return the wrong string...
fValidator->emitError
(
XMLValid::ElementNotValidForContent
, elemDecl->getFullName()
, elemDecl->getFormattedContentModel()
);
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((SchemaElementDecl *)(elemDecl))->setValidity(PSVIDefs::INVALID);
if (((SchemaValidator*) fValidator)->getErrorOccurred())
fPSVIElemContext.fErrorOccurred = true;
// note that if we're empty, won't be a current DV
else
{
fPSVIElemContext.fIsSpecified = ((SchemaValidator*) fValidator)->getIsElemSpecified();
if(fPSVIElemContext.fIsSpecified)
fPSVIElemContext.fNormalizedValue = ((SchemaElementDecl *)elemDecl)->getDefaultValue();
}
if (fPSVIElemContext.fCurrentDV && fPSVIElemContext.fCurrentDV->getType() == DatatypeValidator::Union)
psviMemberType = fValidationContext->getValidatingMemberType();
}
// call matchers and de-activate context
int oldCount = fMatcherStack->getMatcherCount();
if (oldCount || ((SchemaElementDecl*) elemDecl)->getIdentityConstraintCount()) {
for (int i = oldCount - 1; i >= 0; i--) {
XPathMatcher* matcher = fMatcherStack->getMatcherAt(i);
matcher->endElement(*elemDecl, fContent.getRawBuffer());
}
if (fMatcherStack->size() > 0) {
fMatcherStack->popContext();
}
// handle everything *but* keyref's.
int newCount = fMatcherStack->getMatcherCount();
for (int j = oldCount - 1; j >= newCount; j--) {
XPathMatcher* matcher = fMatcherStack->getMatcherAt(j);
IdentityConstraint* ic = matcher->getIdentityConstraint();
if (ic && (ic->getType() != IdentityConstraint::KEYREF))
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fValueStoreCache->transplant(ic, matcher->getInitialDepth());
}
// now handle keyref's...
for (int k = oldCount - 1; k >= newCount; k--) {
XPathMatcher* matcher = fMatcherStack->getMatcherAt(k);
IdentityConstraint* ic = matcher->getIdentityConstraint();
if (ic && (ic->getType() == IdentityConstraint::KEYREF)) {
ValueStore* values = fValueStoreCache->getValueStoreFor(ic, matcher->getInitialDepth());
if (values) { // nothing to do if nothing matched!
values->endDcocumentFragment(fValueStoreCache);
}
}
}
fValueStoreCache->endElement();
}
}
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if(!isRoot)
((SchemaElementDecl *)fElemStack.topElement()->fThisElement)->updateValidityFromElement(elemDecl, fGrammarType);
if (fPSVIHandler)
{
endElementPSVI
(
(SchemaElementDecl*)elemDecl, psviMemberType
);
}
// If we have a doc handler, tell it about the end tag
if (fDocHandler)
{
fDocHandler->endElement
(
*elemDecl
, uriId
, isRoot
, fPrefixBuf.getRawBuffer()
);
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// pass information about type info:
const XMLCh *typeName = SchemaSymbols::fgATTVAL_ANYTYPE;
const XMLCh *typeURI = SchemaSymbols::fgURI_SCHEMAFORSCHEMA;
if(!fPSVIElemContext.fErrorOccurred)
{
if(fPSVIElemContext.fCurrentTypeInfo != 0)
{
if(fPSVIElemContext.fCurrentTypeInfo->getAnonymous())
typeName = XMLUni::fgZeroLenString;
else
typeName = fPSVIElemContext.fCurrentTypeInfo->getTypeLocalName();
typeURI = fPSVIElemContext.fCurrentTypeInfo->getTypeUri();
}
else
{
DatatypeValidator *actualDV = (psviMemberType)?psviMemberType:fPSVIElemContext.fCurrentDV;
if(actualDV)
{
if(actualDV->getAnonymous())
typeName = XMLUni::fgZeroLenString;
else
typeName = actualDV->getTypeLocalName();
typeURI = actualDV->getTypeUri();
}
}
}
else
{
// idiosyncratically, if there's an
// error but this element was simpleType-validated,
// the tests demand anySimpleType be returned
if(fPSVIElemContext.fCurrentDV)
typeName = SchemaSymbols::fgDT_ANYSIMPLETYPE;
}
fDocHandler->elementTypeInfo(typeName, typeURI);
// reset xsi:type ComplexTypeInfo
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((SchemaElementDecl*)elemDecl)->reset();
if (!isRoot)
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((SchemaElementDecl*)(fElemStack.topElement()->fThisElement))->
setXsiComplexTypeInfo(((SchemaValidator*)fValidator)->getCurrentTypeInfo());
// If the elem stack is empty, then it was an empty root
if (isRoot)
gotData = false;
else
{
// Restore the grammar
fGrammar = fElemStack.getCurrentGrammar();
fGrammarType = fGrammar->getGrammarType();
fValidator->setGrammar(fGrammar);
// Restore the validation flag
fValidate = fElemStack.getValidationFlag();
}
}
else // not empty
fErrorStack->push(fPSVIElemContext.fErrorOccurred);