void UEdGraphNode::PostLoad()
{
Super::PostLoad();
// Create Guid if not present (and not CDO)
if(!NodeGuid.IsValid() && !IsTemplate() && GetLinker() && GetLinker()->IsPersistent() && GetLinker()->IsLoading())
{
UE_LOG(LogBlueprint, Warning, TEXT("Node '%s' missing NodeGuid."), *GetPathName());
// Generate new one
CreateNewGuid();
}
// Duplicating a Blueprint needs to have a new Node Guid generated, which was not occuring before this version
if(GetLinkerUE4Version() < VER_UE4_POST_DUPLICATE_NODE_GUID)
{
// Generate new one
CreateNewGuid();
}
// Moving to the new style comments requires conversion to preserve previous state
if(GetLinkerUE4Version() < VER_UE4_GRAPH_INTERACTIVE_COMMENTBUBBLES)
{
bCommentBubbleVisible = !NodeComment.IsEmpty();
}
}
void USkeleton::PostLoad()
{
Super::PostLoad();
if( GetLinker() && (GetLinker()->UE4Ver() < VER_UE4_REFERENCE_SKELETON_REFACTOR) )
{
// Convert RefLocalPoses & BoneTree to FReferenceSkeleton
ConvertToFReferenceSkeleton();
}
// catch any case if guid isn't valid
check(Guid.IsValid());
}
/** Tags generated objects with flags */
void UPackage::TagSubobjects(EObjectFlags NewFlags)
{
Super::TagSubobjects(NewFlags);
if (MetaData)
{
MetaData->SetFlags(NewFlags);
}
if (GetLinker())
{
GetLinker()->SetFlags(NewFlags);
}
}
const TCHAR* UClassProperty::ImportText_Internal( const TCHAR* Buffer, void* Data, int32 PortFlags, UObject* Parent, FOutputDevice* ErrorText ) const
{
const TCHAR* Result = UObjectProperty::ImportText_Internal( Buffer, Data, PortFlags, Parent, ErrorText );
if( Result )
{
CheckValidObject(Data);
if (UClass* AssignedPropertyClass = dynamic_cast<UClass*>(GetObjectPropertyValue(Data)))
{
#if USE_CIRCULAR_DEPENDENCY_LOAD_DEFERRING
FLinkerLoad* PropertyLinker = GetLinker();
bool const bIsDeferringValueLoad = ((PropertyLinker == nullptr) || (PropertyLinker->LoadFlags & LOAD_DeferDependencyLoads)) &&
Cast<ULinkerPlaceholderClass>(MetaClass);
#if USE_DEFERRED_DEPENDENCY_CHECK_VERIFICATION_TESTS
check(bIsDeferringValueLoad || !Cast<ULinkerPlaceholderClass>(MetaClass));
#endif // USE_DEFERRED_DEPENDENCY_CHECK_VERIFICATION_TESTS
#else // USE_CIRCULAR_DEPENDENCY_LOAD_DEFERRING
bool const bIsDeferringValueLoad = false;
#endif // USE_CIRCULAR_DEPENDENCY_LOAD_DEFERRING
// Validate metaclass.
if ((!AssignedPropertyClass->IsChildOf(MetaClass)) && !bIsDeferringValueLoad)
{
// the object we imported doesn't implement our interface class
ErrorText->Logf(TEXT("Invalid object '%s' specified for property '%s'"), *AssignedPropertyClass->GetFullName(), *GetName());
SetObjectPropertyValue(Data, NULL);
Result = NULL;
}
}
}
return Result;
}
void USkeleton::PostLoad()
{
Super::PostLoad();
if( GetLinker() && (GetLinker()->UE4Ver() < VER_UE4_REFERENCE_SKELETON_REFACTOR) )
{
// Convert RefLocalPoses & BoneTree to FReferenceSkeleton
ConvertToFReferenceSkeleton();
}
// Build look up table between Slot nodes and their Group.
BuildSlotToGroupMap();
// catch any case if guid isn't valid
check(Guid.IsValid());
}
/**
* Returns the licensee version of the linker for this object.
*
* @return the licensee version of the engine's package file when this object
* was last saved, or GPackageFileLicenseeVersion (current version) if
* this object does not have a linker, which indicates that
* a) this object is a native only class, or
* b) this object's linker has been detached, in which case it is already fully loaded
*/
int32 UObjectBaseUtility::GetLinkerLicenseeUE4Version() const
{
ULinkerLoad* Loader = GetLinker();
// No linker.
if( Loader == NULL )
{
// the _Linker reference is never set for the top-most UPackage of a package (the linker root), so if this object
// is the linker root, find our loader in the global list.
if( GetOutermost() == this )
{
Loader = ULinkerLoad::FindExistingLinkerForPackage(const_cast<UPackage*>(CastChecked<UPackage>((const UObject*)this)));
}
}
if ( Loader != NULL )
{
// We have a linker so we can return its version.
return Loader->LicenseeUE4Ver();
}
else
{
// We don't have a linker associated as we e.g. might have been saved or had loaders reset, ...
return GPackageFileLicenseeUE4Version;
}
}
int32 UObjectBaseUtility::GetLinkerCustomVersion(FGuid CustomVersionKey) const
{
ULinkerLoad* Loader = GetLinker();
// No linker.
if( Loader == NULL )
{
// the _Linker reference is never set for the top-most UPackage of a package (the linker root), so if this object
// is the linker root, find our loader in the global list.
if( GetOutermost() == this )
{
Loader = ULinkerLoad::FindExistingLinkerForPackage(const_cast<UPackage*>(CastChecked<UPackage>((const UObject*)this)));
}
}
if ( Loader != NULL )
{
// We have a linker so we can return its version.
auto* CustomVersion = Loader->Summary.GetCustomVersionContainer().GetVersion(CustomVersionKey);
return CustomVersion ? CustomVersion->Version : -1;
}
// We don't have a linker associated as we e.g. might have been saved or had loaders reset, ...
// We must have a current version for this tag.
auto* CustomVersion = FCustomVersionContainer::GetRegistered().GetVersion(CustomVersionKey);
check(CustomVersion);
return CustomVersion->Version;
}
void USimpleConstructionScript::PreloadChain()
{
GetLinker()->Preload(this);
for (USCS_Node* Node : RootNodes)
{
Node->PreloadChain();
}
}
void CSpacePortal::OnRequestUseObject(int64 SourceID,ePipeline& RequestInfo){
int64 EventID = RequestInfo.PopInt();
ePipeline* ObjectInfo = (ePipeline*)RequestInfo.GetData(0);
ePipeline* ExePipe = (ePipeline*)RequestInfo.GetData(1);
CObjectData Object(*ObjectInfo);
int64 ExecuterID = Object.m_ID;
CLinker ExecuterLinker;
GetLinker(ExecuterID,ExecuterLinker);
if (!ExecuterLinker.IsValid())
{
ExePipe->GetLabel() = Format1024(_T("Error: Executer not started."));
ExePipe->SetID(RETURN_ERROR);
CLinker Requester;
GetLinker(SourceID,Requester);
if (Requester.IsValid())
{
CMsg FeedbackMsg(MSG_TASK_FEEDBACK,NULL,EventID);
ePipeline& Letter = FeedbackMsg.GetLetter();
Letter.PushPipe(*ExePipe);
Requester().PushMsgToSend(FeedbackMsg);
}
return;
}
PushExecuterEvent(ExecuterID,SourceID,EventID);
WriteLogDB(_T("Use Object Event:%I64ld"),EventID);
CMsg NewMsg(MSG_OBJECT_RUN,NULL,EventID);
ePipeline& NewLetter = NewMsg.GetLetter();
NewLetter.PushPipe(*ExePipe);
ExecuterLinker().PushMsgToSend(NewMsg);
};
void UArrayProperty::LinkInternal(FArchive& Ar)
{
ULinkerLoad* MyLinker = GetLinker();
if( MyLinker )
{
MyLinker->Preload(this);
}
Ar.Preload(Inner);
Inner->Link(Ar);
Super::LinkInternal(Ar);
}
void CSpacePortal::OnRequestCloseObject(int64 SourceID,ePipeline& RequestInfo){
int64 EventID = RequestInfo.PopInt();
ePipeline* ObjectInfo = (ePipeline*)RequestInfo.GetData(0);
ePipeline* ExePipe = (ePipeline*)RequestInfo.GetData(1);
CObjectData Object(*ObjectInfo);
//If it does not start the external organs, this is considered a normal close
int64 ExecuterID = Object.m_ID;
CLinker ExecuterLinker;
GetLinker(ExecuterID,ExecuterLinker);
if (!ExecuterLinker.IsValid())
{
CLinker Requester;
GetLinker(SourceID,Requester);
if (Requester.IsValid())
{
CMsg FeedbackMsg(MSG_TASK_FEEDBACK,NULL,EventID);
ePipeline& Letter = FeedbackMsg.GetLetter();
Letter.PushPipe(*ExePipe);
Requester().PushMsgToSend(FeedbackMsg);
}
return;
}
PushExecuterEvent(ExecuterID,SourceID,EventID);
WriteLogDB(_T("Close Object Event:%I64ld"),EventID);
CMsg NewMsg(MSG_OBJECT_CLOSE,NULL,EventID);
ePipeline& NewLetter = NewMsg.GetLetter();
NewLetter.PushPipe(*ExePipe);
ExecuterLinker().PushMsgToSend(NewMsg);
}
void UInterpCurveEdSetup::Serialize(FArchive& Ar)
{
Super::Serialize(Ar);
if (Ar.IsLoading() && GetLinker() && (GetLinker()->UE3Ver() < 203))
{
for (int32 i=0; i<Tabs.Num(); i++)
{
FCurveEdTab& Tab = Tabs[i];
for(int32 j=Tab.Curves.Num()-1; j>=0; j--)
{
FCurveEdEntry& Entry = Tab.Curves[j];
if (Entry.bHideCurve)
{
Entry.bHideCurve = 0x00000001;
}
}
}
}
}
void UInheritableComponentHandler::PreloadAll()
{
if (HasAllFlags(RF_NeedLoad))
{
auto Linker = GetLinker();
if (Linker)
{
Linker->Preload(this);
}
}
PreloadAllTempates();
}
void UChildActorComponent::PostLoad()
{
Super::PostLoad();
// For a period of time the parent component property on Actor was not a UPROPERTY so this value was not set
if (ChildActor)
{
FActorParentComponentSetter::Set(ChildActor, this);
}
// Since the template could have been changed we need to respawn the child actor
// Don't do this if there is no linker which implies component was created via duplication
if (ChildActorTemplate && GetLinker())
{
DestroyChildActor();
}
}
void UObjectPropertyBase::CheckValidObject(void* Value) const
{
UObject *Object = GetObjectPropertyValue(Value);
if (Object)
{
//
// here we want to make sure the the object value still matches the
// object type expected by the property...
UClass* ObjectClass = Object->GetClass();
// we could be in the middle of replacing references to the
// PropertyClass itself (in the middle of an FArchiveReplaceObjectRef
// pass)... if this is the case, then we might have already replaced
// the object's class, but not the PropertyClass yet (or vise-versa)...
// so we use this to ensure, in that situation, that we don't clear the
// object value (if CLASS_NewerVersionExists is set, then we are likely
// in the middle of an FArchiveReplaceObjectRef pass)
bool bIsReplacingClassRefs = PropertyClass && PropertyClass->HasAnyClassFlags(CLASS_NewerVersionExists) != ObjectClass->HasAnyClassFlags(CLASS_NewerVersionExists);
#if USE_CIRCULAR_DEPENDENCY_LOAD_DEFERRING
FLinkerLoad* PropertyLinker = GetLinker();
bool const bIsDeferringValueLoad = ((PropertyLinker == nullptr) || (PropertyLinker->LoadFlags & LOAD_DeferDependencyLoads)) &&
(Object->IsA<ULinkerPlaceholderExportObject>() || Object->IsA<ULinkerPlaceholderClass>());
#if USE_DEFERRED_DEPENDENCY_CHECK_VERIFICATION_TESTS
check( bIsDeferringValueLoad || (!Object->IsA<ULinkerPlaceholderExportObject>() && !Object->IsA<ULinkerPlaceholderClass>()) );
#endif // USE_DEFERRED_DEPENDENCY_CHECK_VERIFICATION_TESTS
#else // USE_CIRCULAR_DEPENDENCY_LOAD_DEFERRING
bool const bIsDeferringValueLoad = false;
#endif // USE_CIRCULAR_DEPENDENCY_LOAD_DEFERRING
if ((PropertyClass != nullptr) && !ObjectClass->IsChildOf(PropertyClass) && !bIsReplacingClassRefs && !bIsDeferringValueLoad)
{
UE_LOG(LogProperty, Warning,
TEXT("Serialized %s for a property of %s. Reference will be NULLed.\n Property = %s\n Item = %s"),
*Object->GetClass()->GetFullName(),
*PropertyClass->GetFullName(),
*GetFullName(),
*Object->GetFullName()
);
SetObjectPropertyValue(Value, NULL);
}
}
}
void UUserDefinedStruct::RecursivelyPreload()
{
ULinkerLoad* Linker = GetLinker();
if( Linker && (NULL == PropertyLink) )
{
TArray<UObject*> AllChildMembers;
GetObjectsWithOuter(this, AllChildMembers);
for (int32 Index = 0; Index < AllChildMembers.Num(); ++Index)
{
UObject* Member = AllChildMembers[Index];
Linker->Preload(Member);
}
Linker->Preload(this);
if (NULL == PropertyLink)
{
StaticLink(true);
}
}
}
void USCS_Node::PreloadChain()
{
if( HasAnyFlags(RF_NeedLoad) )
{
GetLinker()->Preload(this);
}
if (ComponentTemplate && ComponentTemplate->HasAnyFlags(RF_NeedLoad))
{
ComponentTemplate->GetLinker()->Preload(ComponentTemplate);
}
for( TArray<USCS_Node*>::TIterator ChildIt(ChildNodes); ChildIt; ++ChildIt )
{
USCS_Node* CurrentChild = *ChildIt;
if( CurrentChild )
{
CurrentChild->PreloadChain();
}
}
}
void UStructProperty::LinkInternal(FArchive& Ar)
{
// We potentially have to preload the property itself here, if we were the inner of an array property
if(HasAnyFlags(RF_NeedLoad))
{
GetLinker()->Preload(this);
}
#if !(UE_BUILD_SHIPPING || UE_BUILD_TEST)
if (Struct == NULL)
{
UE_LOG(LogProperty, Error, TEXT("Struct type unknown for property '%s'; perhaps the USTRUCT() was renamed or deleted?"), *GetFullName());
}
#endif
// Preload is required here in order to load the value of Struct->PropertiesSize
Ar.Preload(Struct);
if ( !ensure(Struct) )
{
Struct = GetFallbackStruct();
}
PreloadInnerStructMembers(this);
ElementSize = Align(Struct->PropertiesSize, Struct->GetMinAlignment());
if (Struct->StructFlags & STRUCT_IsPlainOldData) // if there is nothing to construct or the struct is known to be memcpy-able, then allow memcpy
{
PropertyFlags |= CPF_IsPlainOldData;
}
if (Struct->StructFlags & STRUCT_NoDestructor)
{
PropertyFlags |= CPF_NoDestructor;
}
if (Struct->StructFlags & STRUCT_ZeroConstructor)
{
PropertyFlags |= CPF_ZeroConstructor;
}
}
void CSpacePortal::OnRequestStartObject(int64 SourceID,ePipeline& RequestInfo){
int64 EventID = RequestInfo.PopInt();
ePipeline* ObjectInfo = (ePipeline*)RequestInfo.GetData(0);
ePipeline* ExePipe = (ePipeline*)RequestInfo.GetData(1);
CObjectData Object(*ObjectInfo);
ePipeline AddrData = Object.m_Address;
assert(Object.m_ID != 0);
//Checks whether the specified object addresses is valid
SpaceAddress Address = FindChildSpace(AddrData,Object.m_Fingerprint);
if (!Address.IsValid())
{
CLinker Requester;
GetLinker(SourceID,Requester);
if (Requester.IsValid())
{
CMsg FeedbackMsg(MSG_TASK_FEEDBACK,NULL,EventID);
ePipeline& Letter = FeedbackMsg.GetLetter();
ExePipe->SetID(RETURN_ERROR);
ExePipe->GetLabel() = Format1024(_T("Error: object address invalid"));
Letter.PushPipe(*ExePipe);
Requester().PushMsgToSend(FeedbackMsg);
}
return;
}
//Need to open the corresponding DLL object in advance, in order to determine the type of executer
//CSpace Space(Address.ParentID,Address.ChildID);
AddrData = Object.m_Address;
tstring FilePath = SpacePath2FileAddress(AddrData);
tstring ObjectName = GetFileName(Object.m_Name); //不含扩展名
FilePath += _T("\\")+ObjectName;
FilePath += _T("\\")+Object.m_Name;
Dll_Object TempDll(Object.m_ID,FilePath);
if (!TempDll.IsValid())
{
int32 error = ::GetLastError();
ExePipe->SetID(RETURN_ERROR);
ExePipe->GetLabel() = Format1024(_T("Load object fail: <%s>"),FilePath.c_str());
CLinker Requester;
GetLinker(SourceID,Requester);
if (Requester.IsValid())
{
CMsg FeedbackMsg(MSG_TASK_FEEDBACK,NULL,EventID);
ePipeline& Letter = FeedbackMsg.GetLetter();
Letter.PushPipe(*ExePipe);
Requester().PushMsgToSend(FeedbackMsg);
}
return ;
}
DLL_TYPE DllType = TempDll.GetDllType();
tstring ExecuterFile;
switch (DllType)
{
case DLL_VC6:
{
ExecuterFile = _T("EXE_VC6.EXE");
}
break;
case DLL_VC6D:
{
ExecuterFile = _T("EXE_VC6D.EXE");
}
break;
case DLL_VC10:
{
ExecuterFile = _T("EXE_VC10.EXE");
}
break;
case DLL_VC10D:
{
ExecuterFile = _T("EXE_VC10D.EXE");
}
break;
default:
{
ExePipe->GetLabel() = Format1024(_T("Error: dll type not support:%d"),(int)DllType);
ExePipe->SetID(RETURN_ERROR);
CLinker Requester;
GetLinker(SourceID,Requester);
if (Requester.IsValid())
{
CMsg FeedbackMsg(MSG_TASK_FEEDBACK,NULL,EventID);
ePipeline& Letter = FeedbackMsg.GetLetter();
Letter.PushPipe(*ExePipe);
Requester().PushMsgToSend(FeedbackMsg);
}
return;
}
}
//start a executer
int64 ExeSourceID = Object.m_ID; //ExecuterID is equal to the external object instance ID
bool ret = StartExecuter(ExeSourceID,ExecuterFile);
if (!ret)
{
ExePipe->GetLabel() = Format1024(_T("Error: Executer start fail."));
ExePipe->SetID(RETURN_ERROR);
CLinker Requester;
GetLinker(SourceID,Requester);
if (Requester.IsValid())
{
CMsg FeedbackMsg(MSG_TASK_FEEDBACK,NULL,EventID);
ePipeline& Letter = FeedbackMsg.GetLetter();
Letter.PushPipe(*ExePipe);
Requester().PushMsgToSend(FeedbackMsg);
}
return;
}
RegisterExecuterUser(SourceID,ExeSourceID);
CLinker ExecuterLinker;
GetLinker(ExeSourceID,ExecuterLinker);
//Register a start external object event
PushExecuterEvent(ExeSourceID,SourceID,EventID);
WriteLogDB(_T("Start Object Event:%I64ld"),EventID);
//send execute msg
CMsg NewMsg(MSG_OBJECT_START,NULL,EventID);
ePipeline& NewLetter = NewMsg.GetLetter();
NewLetter.PushString(FilePath);
NewLetter.PushPipe(*ExePipe);
ExecuterLinker().PushMsgToSend(NewMsg);
};
