void FAnimNode_HandIKRetargeting::EvaluateBoneTransforms(USkeletalMeshComponent* SkelComp, FCSPose<FCompactPose>& MeshBases, TArray<FBoneTransform>& OutBoneTransforms) { checkSlow(OutBoneTransforms.Num() == 0); const FBoneContainer& BoneContainer = MeshBases.GetPose().GetBoneContainer(); // Get component space transforms for all of our IK and FK bones. const FTransform& RightHandFKTM = MeshBases.GetComponentSpaceTransform(RightHandFK.GetCompactPoseIndex(BoneContainer)); const FTransform& LeftHandFKTM = MeshBases.GetComponentSpaceTransform(LeftHandFK.GetCompactPoseIndex(BoneContainer)); const FTransform& RightHandIKTM = MeshBases.GetComponentSpaceTransform(RightHandIK.GetCompactPoseIndex(BoneContainer)); const FTransform& LeftHandIKTM = MeshBases.GetComponentSpaceTransform(LeftHandIK.GetCompactPoseIndex(BoneContainer)); // Compute weight FK and IK hand location. And translation from IK to FK. FVector const FKLocation = FMath::Lerp<FVector>(LeftHandFKTM.GetTranslation(), RightHandFKTM.GetTranslation(), HandFKWeight); FVector const IKLocation = FMath::Lerp<FVector>(LeftHandIKTM.GetTranslation(), RightHandIKTM.GetTranslation(), HandFKWeight); FVector const IK_To_FK_Translation = FKLocation - IKLocation; // If we're not translating, don't send any bones to update. if (!IK_To_FK_Translation.IsNearlyZero()) { // Move desired bones for (const FBoneReference& BoneReference : IKBonesToMove) { if (BoneReference.IsValid(BoneContainer)) { FCompactPoseBoneIndex BoneIndex = BoneReference.GetCompactPoseIndex(BoneContainer); FTransform BoneTransform = MeshBases.GetComponentSpaceTransform(BoneIndex); BoneTransform.AddToTranslation(IK_To_FK_Translation); OutBoneTransforms.Add(FBoneTransform(BoneIndex, BoneTransform)); } } } }
void FAnimNode_CopyBone::EvaluateBoneTransforms(USkeletalMeshComponent* SkelComp, FCSPose<FCompactPose>& MeshBases, TArray<FBoneTransform>& OutBoneTransforms) { check(OutBoneTransforms.Num() == 0); // Pass through if we're not doing anything. if( !bCopyTranslation && !bCopyRotation && !bCopyScale ) { return; } // Get component space transform for source and current bone. const FBoneContainer& BoneContainer = MeshBases.GetPose().GetBoneContainer(); FCompactPoseBoneIndex SourceBoneIndex = SourceBone.GetCompactPoseIndex(BoneContainer); FCompactPoseBoneIndex TargetBoneIndex = TargetBone.GetCompactPoseIndex(BoneContainer); FTransform SourceBoneTM = MeshBases.GetComponentSpaceTransform(SourceBoneIndex); FTransform CurrentBoneTM = MeshBases.GetComponentSpaceTransform(TargetBoneIndex); if(ControlSpace != BCS_ComponentSpace) { // Convert out to selected space FAnimationRuntime::ConvertCSTransformToBoneSpace(SkelComp, MeshBases, SourceBoneTM, SourceBoneIndex, ControlSpace); FAnimationRuntime::ConvertCSTransformToBoneSpace(SkelComp, MeshBases, CurrentBoneTM, TargetBoneIndex, ControlSpace); } // Copy individual components if (bCopyTranslation) { CurrentBoneTM.SetTranslation( SourceBoneTM.GetTranslation() ); } if (bCopyRotation) { CurrentBoneTM.SetRotation( SourceBoneTM.GetRotation() ); } if (bCopyScale) { CurrentBoneTM.SetScale3D( SourceBoneTM.GetScale3D() ); } if(ControlSpace != BCS_ComponentSpace) { // Convert back out if we aren't operating in component space FAnimationRuntime::ConvertBoneSpaceTransformToCS(SkelComp, MeshBases, CurrentBoneTM, TargetBoneIndex, ControlSpace); } // Output new transform for current bone. OutBoneTransforms.Add(FBoneTransform(TargetBoneIndex, CurrentBoneTM)); }
void FAnimNode_WheelHandler::EvaluateBoneTransforms(USkeletalMeshComponent* SkelComp, FCSPose<FCompactPose>& MeshBases, TArray<FBoneTransform>& OutBoneTransforms) { check(OutBoneTransforms.Num() == 0); const TArray<FWheelAnimData>& WheelAnimData = AnimInstanceProxy->GetWheelAnimData(); const FBoneContainer& BoneContainer = MeshBases.GetPose().GetBoneContainer(); for(const FWheelLookupData& Wheel : Wheels) { if (Wheel.BoneReference.IsValid(BoneContainer)) { FCompactPoseBoneIndex WheelSimBoneIndex = Wheel.BoneReference.GetCompactPoseIndex(BoneContainer); // the way we apply transform is same as FMatrix or FTransform // we apply scale first, and rotation, and translation // if you'd like to translate first, you'll need two nodes that first node does translate and second nodes to rotate. FTransform NewBoneTM = MeshBases.GetComponentSpaceTransform(WheelSimBoneIndex); FAnimationRuntime::ConvertCSTransformToBoneSpace(SkelComp, MeshBases, NewBoneTM, WheelSimBoneIndex, BCS_ComponentSpace); // Apply rotation offset const FQuat BoneQuat(WheelAnimData[Wheel.WheelIndex].RotOffset); NewBoneTM.SetRotation(BoneQuat * NewBoneTM.GetRotation()); // Apply loc offset NewBoneTM.AddToTranslation(WheelAnimData[Wheel.WheelIndex].LocOffset); // Convert back to Component Space. FAnimationRuntime::ConvertBoneSpaceTransformToCS(SkelComp, MeshBases, NewBoneTM, WheelSimBoneIndex, BCS_ComponentSpace); // add back to it OutBoneTransforms.Add(FBoneTransform(WheelSimBoneIndex, NewBoneTM)); } } }
/** Convert a BoneSpace FTransform to ComponentSpace. */ void FAnimationRuntime::ConvertBoneSpaceTransformToCS ( USkeletalMeshComponent * SkelComp, FCSPose<FCompactPose> & MeshBases, /*inout*/ FTransform& BoneSpaceTM, FCompactPoseBoneIndex BoneIndex, uint8 Space ) { switch( Space ) { case BCS_WorldSpace : BoneSpaceTM.SetToRelativeTransform(SkelComp->ComponentToWorld); break; case BCS_ComponentSpace : // Component Space, no change. break; case BCS_ParentBoneSpace : if( BoneIndex != INDEX_NONE ) { const FCompactPoseBoneIndex ParentIndex = MeshBases.GetPose().GetParentBoneIndex(BoneIndex); if( ParentIndex != INDEX_NONE ) { const FTransform& ParentTM = MeshBases.GetComponentSpaceTransform(ParentIndex); BoneSpaceTM *= ParentTM; } } break; case BCS_BoneSpace : if( BoneIndex != INDEX_NONE ) { const FTransform& BoneTM = MeshBases.GetComponentSpaceTransform(BoneIndex); BoneSpaceTM *= BoneTM; } break; default: UE_LOG(LogAnimation, Warning, TEXT("ConvertBoneSpaceTransformToCS: Unknown BoneSpace %d for Mesh: %s"), Space, *GetNameSafe(SkelComp->SkeletalMesh)); break; } }
void FAnimNode_RotationMultiplier::EvaluateBoneTransforms(USkeletalMeshComponent* SkelComp, FCSPose<FCompactPose>& MeshBases, TArray<FBoneTransform>& OutBoneTransforms) { check(OutBoneTransforms.Num() == 0); if ( Multiplier != 0.f ) { // Reference bone const FBoneContainer& BoneContainer = MeshBases.GetPose().GetBoneContainer(); const FCompactPoseBoneIndex TargetBoneIndex = TargetBone.GetCompactPoseIndex(BoneContainer); const FCompactPoseBoneIndex SourceBoneIndex = SourceBone.GetCompactPoseIndex(BoneContainer); const FQuat RefQuat = MeshBases.GetPose().GetRefPose(TargetBoneIndex).GetRotation(); const FTransform& SourceRefPose = MeshBases.GetPose().GetRefPose(SourceBoneIndex); FQuat NewQuat = MultiplyQuatBasedOnSourceIndex(SourceRefPose, MeshBases.GetLocalSpaceTransform(SourceBoneIndex), RotationAxisToRefer, Multiplier, RefQuat); FTransform NewLocalTransform = MeshBases.GetLocalSpaceTransform(TargetBoneIndex); if (bIsAdditive) { NewQuat = NewLocalTransform.GetRotation() * NewQuat; } NewLocalTransform.SetRotation(NewQuat); const FCompactPoseBoneIndex ParentIndex = MeshBases.GetPose().GetParentBoneIndex(TargetBoneIndex); if( ParentIndex != INDEX_NONE ) { const FTransform& ParentTM = MeshBases.GetComponentSpaceTransform(ParentIndex); FTransform NewTransform = NewLocalTransform * ParentTM; OutBoneTransforms.Add( FBoneTransform(TargetBoneIndex, NewTransform) ); } else { OutBoneTransforms.Add( FBoneTransform(TargetBoneIndex, NewLocalTransform) ); } } }
void FAnimNode_ModifyFinger::EvaluateOneBoneTransforms(FBoneReference* BoneToModify, FRotator* Rotation, const FBoneContainer BoneContainer, FCSPose<FCompactPose> &MeshBases, USkeletalMeshComponent* SkelComp, TArray<FBoneTransform> &OutBoneTransforms) { FCompactPoseBoneIndex CompactPoseBoneToModify = BoneToModify->GetCompactPoseIndex(BoneContainer); FTransform NewBoneTM = MeshBases.GetComponentSpaceTransform(CompactPoseBoneToModify); if (RotationMode != BMM_Ignore) { // Convert to Bone Space. FAnimationRuntime::ConvertCSTransformToBoneSpace(SkelComp, MeshBases, NewBoneTM, CompactPoseBoneToModify, RotationSpace); const FQuat BoneQuat(*Rotation); if (RotationMode == BMM_Additive) { NewBoneTM.SetRotation(BoneQuat * NewBoneTM.GetRotation()); } else { NewBoneTM.SetRotation(BoneQuat); } // Convert back to Component Space. FAnimationRuntime::ConvertBoneSpaceTransformToCS(SkelComp, MeshBases, NewBoneTM, CompactPoseBoneToModify, RotationSpace); } if (ScaleMode != BMM_Ignore) { // Convert to Bone Space. FAnimationRuntime::ConvertCSTransformToBoneSpace(SkelComp, MeshBases, NewBoneTM, CompactPoseBoneToModify, ScaleSpace); if (ScaleMode == BMM_Additive) { NewBoneTM.SetScale3D(NewBoneTM.GetScale3D() * Scale); } else { NewBoneTM.SetScale3D(Scale); } // Convert back to Component Space. FAnimationRuntime::ConvertBoneSpaceTransformToCS(SkelComp, MeshBases, NewBoneTM, CompactPoseBoneToModify, ScaleSpace); } if (TranslationMode != BMM_Ignore) { // Convert to Bone Space. FAnimationRuntime::ConvertCSTransformToBoneSpace(SkelComp, MeshBases, NewBoneTM, CompactPoseBoneToModify, TranslationSpace); if (TranslationMode == BMM_Additive) { NewBoneTM.AddToTranslation(Translation1); } else { NewBoneTM.SetTranslation(Translation1); } // Convert back to Component Space. FAnimationRuntime::ConvertBoneSpaceTransformToCS(SkelComp, MeshBases, NewBoneTM, CompactPoseBoneToModify, TranslationSpace); } OutBoneTransforms.Add(FBoneTransform(BoneToModify->GetCompactPoseIndex(BoneContainer), NewBoneTM)); const float BlendWeight = FMath::Clamp<float>(Alpha, 0.f, 1.f); MeshBases.LocalBlendCSBoneTransforms(OutBoneTransforms, BlendWeight); OutBoneTransforms.Empty(); }
void FAnimNode_CopyBoneDelta::EvaluateBoneTransforms(USkeletalMeshComponent* SkelComp, FCSPose<FCompactPose>& MeshBases, TArray<FBoneTransform>& OutBoneTransforms) { if(!bCopyTranslation && !bCopyRotation && !bCopyScale) { return; } const FBoneContainer& BoneContainer = MeshBases.GetPose().GetBoneContainer(); FCompactPoseBoneIndex SourceBoneIndex = SourceBone.GetCompactPoseIndex(BoneContainer); FCompactPoseBoneIndex TargetBoneIndex = TargetBone.GetCompactPoseIndex(BoneContainer); FTransform SourceTM = MeshBases.GetComponentSpaceTransform(SourceBoneIndex); FTransform TargetTM = MeshBases.GetComponentSpaceTransform(TargetBoneIndex); // Convert to parent space FAnimationRuntime::ConvertCSTransformToBoneSpace(SkelComp, MeshBases, SourceTM, SourceBoneIndex, BCS_ParentBoneSpace); FAnimationRuntime::ConvertCSTransformToBoneSpace(SkelComp, MeshBases, TargetTM, TargetBoneIndex, BCS_ParentBoneSpace); // Ref pose transform FTransform RefLSTransform = SkelComp->SkeletalMesh->RefSkeleton.GetRefBonePose()[SourceBone.GetMeshPoseIndex().GetInt()]; // Get transform relative to ref pose SourceTM.SetToRelativeTransform(RefLSTransform); if(CopyMode == CopyBoneDeltaMode::Accumulate) { if(bCopyTranslation) { TargetTM.AddToTranslation(SourceTM.GetTranslation() * TranslationMultiplier); } if(bCopyRotation) { FVector Axis; float Angle; SourceTM.GetRotation().ToAxisAndAngle(Axis, Angle); TargetTM.SetRotation(FQuat(Axis, Angle * RotationMultiplier) * TargetTM.GetRotation()); } if(bCopyScale) { TargetTM.SetScale3D(TargetTM.GetScale3D() * (SourceTM.GetScale3D() * ScaleMultiplier)); } } else //CopyMode = CopyBoneDeltaMode::Copy { if(bCopyTranslation) { TargetTM.SetTranslation(SourceTM.GetTranslation() * TranslationMultiplier); } if(bCopyRotation) { FVector Axis; float Angle; SourceTM.GetRotation().ToAxisAndAngle(Axis, Angle); TargetTM.SetRotation(FQuat(Axis, Angle * RotationMultiplier)); } if(bCopyScale) { TargetTM.SetScale3D(SourceTM.GetScale3D() * ScaleMultiplier); } } // Back out to component space FAnimationRuntime::ConvertBoneSpaceTransformToCS(SkelComp, MeshBases, TargetTM, TargetBoneIndex, BCS_ParentBoneSpace); OutBoneTransforms.Add(FBoneTransform(TargetBoneIndex, TargetTM)); }
void FAnimNode_LookAt::EvaluateBoneTransforms(USkeletalMeshComponent* SkelComp, FCSPose<FCompactPose>& MeshBases, TArray<FBoneTransform>& OutBoneTransforms) { check(OutBoneTransforms.Num() == 0); const FBoneContainer& BoneContainer = MeshBases.GetPose().GetBoneContainer(); const FCompactPoseBoneIndex ModifyBoneIndex = BoneToModify.GetCompactPoseIndex(BoneContainer); FTransform ComponentBoneTransform = MeshBases.GetComponentSpaceTransform(ModifyBoneIndex); // get target location FVector TargetLocationInComponentSpace; if (LookAtBone.IsValid(BoneContainer)) { const FTransform& LookAtTransform = MeshBases.GetComponentSpaceTransform(LookAtBone.GetCompactPoseIndex(BoneContainer)); TargetLocationInComponentSpace = LookAtTransform.GetLocation(); } else { TargetLocationInComponentSpace = SkelComp->ComponentToWorld.InverseTransformPosition(LookAtLocation); } FVector OldCurrentTargetLocation = CurrentTargetLocation; FVector NewCurrentTargetLocation = TargetLocationInComponentSpace; if ((NewCurrentTargetLocation - OldCurrentTargetLocation).SizeSquared() > InterpolationTriggerThreashold*InterpolationTriggerThreashold) { if (AccumulatedInterpoolationTime >= InterpolationTime) { // reset current Alpha, we're starting to move AccumulatedInterpoolationTime = 0.f; } PreviousTargetLocation = OldCurrentTargetLocation; CurrentTargetLocation = NewCurrentTargetLocation; } else if (InterpolationTriggerThreashold == 0.f) { CurrentTargetLocation = NewCurrentTargetLocation; } if (InterpolationTime > 0.f) { float CurrentAlpha = AccumulatedInterpoolationTime/InterpolationTime; if (CurrentAlpha < 1.f) { float BlendAlpha = AlphaToBlendType(CurrentAlpha, GetInterpolationType()); CurrentLookAtLocation = FMath::Lerp(PreviousTargetLocation, CurrentTargetLocation, BlendAlpha); } } else { CurrentLookAtLocation = CurrentTargetLocation; } if (bEnableDebug) { UWorld* World = SkelComp->GetWorld(); DrawDebugData(World, SkelComp->GetComponentToWorld(), ComponentBoneTransform.GetLocation(), PreviousTargetLocation, FColor(0, 255, 0)); DrawDebugData(World, SkelComp->GetComponentToWorld(), ComponentBoneTransform.GetLocation(), CurrentTargetLocation, FColor(255, 0, 0)); DrawDebugData(World, SkelComp->GetComponentToWorld(), ComponentBoneTransform.GetLocation(), CurrentLookAtLocation, FColor(0, 0, 255)); } // lookat vector FVector LookAtVector = GetAlignVector(ComponentBoneTransform, LookAtAxis); // flip to target vector if it wasnt negative bool bShouldFlip = LookAtAxis == EAxisOption::X_Neg || LookAtAxis == EAxisOption::Y_Neg || LookAtAxis == EAxisOption::Z_Neg; FVector ToTarget = CurrentLookAtLocation - ComponentBoneTransform.GetLocation(); ToTarget.Normalize(); if (bShouldFlip) { ToTarget *= -1.f; } if ( LookAtClamp > ZERO_ANIMWEIGHT_THRESH ) { float LookAtClampInRadians = FMath::DegreesToRadians(LookAtClamp); float DiffAngle = FMath::Acos(FVector::DotProduct(LookAtVector, ToTarget)); if (LookAtClampInRadians > 0.f && DiffAngle > LookAtClampInRadians) { FVector OldToTarget = ToTarget; FVector DeltaTarget = ToTarget-LookAtVector; float Ratio = LookAtClampInRadians/DiffAngle; DeltaTarget *= Ratio; ToTarget = LookAtVector + DeltaTarget; ToTarget.Normalize(); // UE_LOG(LogAnimation, Warning, TEXT("Recalculation required - old target %f, new target %f"), // FMath::RadiansToDegrees(FMath::Acos(FVector::DotProduct(LookAtVector, OldToTarget))), FMath::RadiansToDegrees(FMath::Acos(FVector::DotProduct(LookAtVector, ToTarget)))); } } FQuat DeltaRot; // if want to use look up, if (bUseLookUpAxis) { // find look up vector in local space FVector LookUpVector = GetAlignVector(ComponentBoneTransform, LookUpAxis); // project target to the plane FVector NewTarget = FVector::VectorPlaneProject(ToTarget, LookUpVector); NewTarget.Normalize(); DeltaRot = FQuat::FindBetween(LookAtVector, NewTarget); } else { DeltaRot = FQuat::FindBetween(LookAtVector, ToTarget); } // transform current rotation to delta rotation FQuat CurrentRot = ComponentBoneTransform.GetRotation(); FQuat NewRotation = DeltaRot * CurrentRot; ComponentBoneTransform.SetRotation(NewRotation); OutBoneTransforms.Add(FBoneTransform(ModifyBoneIndex, ComponentBoneTransform)); }
void UDebugSkelMeshComponent::RefreshBoneTransforms(FActorComponentTickFunction* TickFunction) { // Run regular update first so we get RequiredBones up to date. Super::RefreshBoneTransforms(NULL); // Pass NULL so we force non threaded work const bool bIsPreviewInstance = (PreviewInstance && PreviewInstance == AnimScriptInstance); BakedAnimationPoses.Empty(); if(bDisplayBakedAnimation && bIsPreviewInstance && PreviewInstance->RequiredBones.IsValid()) { if(UAnimSequence* Sequence = Cast<UAnimSequence>(PreviewInstance->CurrentAsset)) { BakedAnimationPoses.AddUninitialized(PreviewInstance->RequiredBones.GetNumBones()); bool bSavedUseSourceData = AnimScriptInstance->RequiredBones.ShouldUseSourceData(); AnimScriptInstance->RequiredBones.SetUseRAWData(true); AnimScriptInstance->RequiredBones.SetUseSourceData(false); PreviewInstance->EnableControllers(false); GenSpaceBases(BakedAnimationPoses); AnimScriptInstance->RequiredBones.SetUseRAWData(false); AnimScriptInstance->RequiredBones.SetUseSourceData(bSavedUseSourceData); PreviewInstance->EnableControllers(true); } } SourceAnimationPoses.Empty(); if(bDisplaySourceAnimation && bIsPreviewInstance && PreviewInstance->RequiredBones.IsValid()) { if(UAnimSequence* Sequence = Cast<UAnimSequence>(PreviewInstance->CurrentAsset)) { SourceAnimationPoses.AddUninitialized(PreviewInstance->RequiredBones.GetNumBones()); bool bSavedUseSourceData = AnimScriptInstance->RequiredBones.ShouldUseSourceData(); AnimScriptInstance->RequiredBones.SetUseSourceData(true); PreviewInstance->EnableControllers(false); GenSpaceBases(SourceAnimationPoses); AnimScriptInstance->RequiredBones.SetUseSourceData(bSavedUseSourceData); PreviewInstance->EnableControllers(true); } } UncompressedSpaceBases.Empty(); if (bDisplayRawAnimation && AnimScriptInstance && AnimScriptInstance->RequiredBones.IsValid()) { UncompressedSpaceBases.AddUninitialized(AnimScriptInstance->RequiredBones.GetNumBones()); AnimScriptInstance->RequiredBones.SetUseRAWData(true); GenSpaceBases(UncompressedSpaceBases); AnimScriptInstance->RequiredBones.SetUseRAWData(false); } // Non retargeted pose. NonRetargetedSpaceBases.Empty(); if( bDisplayNonRetargetedPose && AnimScriptInstance && AnimScriptInstance->RequiredBones.IsValid() ) { NonRetargetedSpaceBases.AddUninitialized(AnimScriptInstance->RequiredBones.GetNumBones()); AnimScriptInstance->RequiredBones.SetDisableRetargeting(true); GenSpaceBases(NonRetargetedSpaceBases); AnimScriptInstance->RequiredBones.SetDisableRetargeting(false); } // Only works in PreviewInstance, and not for anim blueprint. This is intended. AdditiveBasePoses.Empty(); if( bDisplayAdditiveBasePose && bIsPreviewInstance && PreviewInstance->RequiredBones.IsValid() ) { if (UAnimSequence* Sequence = Cast<UAnimSequence>(PreviewInstance->CurrentAsset)) { if (Sequence->IsValidAdditive()) { FCSPose<FCompactPose> CSAdditiveBasePose; { FCompactPose AdditiveBasePose; FBlendedCurve AdditiveCurve(PreviewInstance); AdditiveBasePose.SetBoneContainer(&PreviewInstance->RequiredBones); Sequence->GetAdditiveBasePose(AdditiveBasePose, AdditiveCurve, FAnimExtractContext(PreviewInstance->CurrentTime)); CSAdditiveBasePose.InitPose(AdditiveBasePose); } for (int32 i = 0; i < AdditiveBasePoses.Num(); ++i) { FCompactPoseBoneIndex CompactIndex = PreviewInstance->RequiredBones.MakeCompactPoseIndex(FMeshPoseBoneIndex(i)); AdditiveBasePoses[i] = CSAdditiveBasePose.GetComponentSpaceTransform(CompactIndex); } } } } }
void FAnimNode_KinectV2Retarget::EvaluateBoneTransforms(USkeletalMeshComponent* SkelComp, FCSPose<FCompactPose>& MeshBases, TArray<FBoneTransform>& OutBoneTransforms) { uint8 i = 0; if (!KinectBody.bIsTracked) { return; } const FBoneContainer BoneContainer = MeshBases.GetPose().GetBoneContainer(); FA2CSPose TempPose; TempPose.AllocateLocalPoses(BoneContainer, SkelComp->LocalAtoms); for (auto Bone : KinectBody.KinectBones) { if (BonesToRetarget[i].IsValid(BoneContainer)) { auto DeltaTranform = Bone.MirroredJointTransform.GetRelativeTransform(SkelComp->GetBoneTransform(0)); //AxisMeshes[Bone.JointTypeEnd]->SetRelativeLocation(PosableMesh->GetBoneLocationByName(RetargetBoneNames[Bone.JointTypeEnd], EBoneSpaces::ComponentSpace)); auto BoneBaseTransform = DeltaTranform*SkelComp->GetBoneTransform(0); FRotator PreAdjusmentRotator = BoneBaseTransform.Rotator(); FRotator PostBoneDirAdjustmentRotator = (BoneAdjustments[Bone.JointTypeEnd].BoneDirAdjustment.Quaternion()*PreAdjusmentRotator.Quaternion()).Rotator(); FRotator CompSpaceRotator = (PostBoneDirAdjustmentRotator.Quaternion()*BoneAdjustments[Bone.JointTypeEnd].BoneNormalAdjustment.Quaternion()).Rotator(); FVector Normal, Binormal, Dir; UKismetMathLibrary::BreakRotIntoAxes(CompSpaceRotator, Normal, Binormal, Dir); Dir *= BoneAdjustments[Bone.JointTypeEnd].bInvertDir ? -1 : 1; Normal *= BoneAdjustments[Bone.JointTypeEnd].bInvertNormal ? -1 : 1; FVector X, Y, Z; switch (BoneAdjustments[Bone.JointTypeEnd].BoneDirAxis) { case EAxis::X: X = Dir; break; case EAxis::Y: Y = Dir; break; case EAxis::Z: Z = Dir; break; default: ; } switch (BoneAdjustments[Bone.JointTypeEnd].BoneBinormalAxis) { case EAxis::X: X = Binormal; break; case EAxis::Y: Y = Binormal; break; case EAxis::Z: Z = Binormal; break; default: ; } switch (BoneAdjustments[Bone.JointTypeEnd].BoneNormalAxis) { case EAxis::X: X = Normal; break; case EAxis::Y: Y = Normal; break; case EAxis::Z: Z = Normal; break; default: ; } FRotator SwiveledRot = UKismetMathLibrary::MakeRotationFromAxes(X, Y, Z); SwiveledRot = (SkelComp->GetBoneTransform(0).Rotator().Quaternion()*SwiveledRot.Quaternion()).Rotator(); //PosableMesh->SetBoneRotationByName(RetargetBoneNames[Bone.JointTypeEnd], (PosableMesh->GetBoneTransform(0).Rotator().Quaternion()*SwiveledRot.Quaternion()).Rotator(), EBoneSpaces::ComponentSpace); #if !(UE_BUILD_SHIPPING || UE_BUILD_TEST) if (BoneAdjustments[i].bDebugDraw) { DrawDebugCoordinateSystem(SkelComp->GetWorld(), SkelComp->GetBoneLocation(BonesToRetarget[i].BoneName), SwiveledRot, 100.f, false, 0.1f); } #endif FCompactPoseBoneIndex CompactPoseBoneToModify = BonesToRetarget[i].GetCompactPoseIndex(BoneContainer); FTransform NewBoneTM = MeshBases.GetComponentSpaceTransform(CompactPoseBoneToModify); FAnimationRuntime::ConvertCSTransformToBoneSpace(SkelComp, MeshBases, NewBoneTM, CompactPoseBoneToModify, BCS_ComponentSpace); const FQuat BoneQuat(SwiveledRot); NewBoneTM.SetRotation(BoneQuat); // Convert back to Component Space. FAnimationRuntime::ConvertBoneSpaceTransformToCS(SkelComp, MeshBases, NewBoneTM, CompactPoseBoneToModify, BCS_ComponentSpace); FAnimationRuntime::SetSpaceTransform(TempPose, BonesToRetarget[i].BoneIndex, NewBoneTM); OutBoneTransforms.Add(FBoneTransform(BonesToRetarget[i].GetCompactPoseIndex(BoneContainer), NewBoneTM)); } ++i; } }
void FAnimNode_Trail::EvaluateBoneTransforms(USkeletalMeshComponent* SkelComp, FCSPose<FCompactPose>& MeshBases, TArray<FBoneTransform>& OutBoneTransforms) { check(OutBoneTransforms.Num() == 0); if( ChainLength < 2 ) { return; } // The incoming BoneIndex is the 'end' of the spline chain. We need to find the 'start' by walking SplineLength bones up hierarchy. // Fail if we walk past the root bone. const FBoneContainer& BoneContainer = MeshBases.GetPose().GetBoneContainer(); FCompactPoseBoneIndex WalkBoneIndex = TrailBone.GetCompactPoseIndex(BoneContainer); TArray<FCompactPoseBoneIndex> ChainBoneIndices; ChainBoneIndices.AddZeroed(ChainLength); ChainBoneIndices[ChainLength - 1] = WalkBoneIndex; for (int32 i = 1; i < ChainLength; i++) { // returns to avoid a crash // @TODO : shows an error message why failed if (WalkBoneIndex == 0) { return; } // Get parent bone. WalkBoneIndex = BoneContainer.GetParentBoneIndex(WalkBoneIndex); //Insert indices at the start of array, so that parents are before children in the array. int32 TransformIndex = ChainLength - (i + 1); ChainBoneIndices[TransformIndex] = WalkBoneIndex; } OutBoneTransforms.AddZeroed(ChainLength); // If we have >0 this frame, but didn't last time, record positions of all the bones. // Also do this if number has changed or array is zero. bool bHasValidStrength = (Alpha > 0.f); if(TrailBoneLocations.Num() != ChainLength || (bHasValidStrength && !bHadValidStrength)) { TrailBoneLocations.Empty(); TrailBoneLocations.AddZeroed(ChainLength); for(int32 i=0; i<ChainBoneIndices.Num(); i++) { FCompactPoseBoneIndex ChildIndex = ChainBoneIndices[i]; const FTransform& ChainTransform = MeshBases.GetComponentSpaceTransform(ChildIndex); TrailBoneLocations[i] = ChainTransform.GetTranslation(); } OldLocalToWorld = SkelComp->GetTransformMatrix(); } bHadValidStrength = bHasValidStrength; // transform between last frame and now. FMatrix OldToNewTM = OldLocalToWorld * SkelComp->GetTransformMatrix().InverseFast(); // Add fake velocity if present to all but root bone if(!FakeVelocity.IsZero()) { FVector FakeMovement = -FakeVelocity * ThisTimstep; if (bActorSpaceFakeVel && SkelComp->GetOwner()) { const FTransform BoneToWorld(SkelComp->GetOwner()->GetActorQuat(), SkelComp->GetOwner()->GetActorLocation()); FakeMovement = BoneToWorld.TransformVector(FakeMovement); } FakeMovement = SkelComp->GetTransformMatrix().InverseTransformVector(FakeMovement); // Then add to each bone for(int32 i=1; i<TrailBoneLocations.Num(); i++) { TrailBoneLocations[i] += FakeMovement; } } // Root bone of trail is not modified. FCompactPoseBoneIndex RootIndex = ChainBoneIndices[0]; const FTransform& ChainTransform = MeshBases.GetComponentSpaceTransform(RootIndex); OutBoneTransforms[0] = FBoneTransform(RootIndex, ChainTransform); TrailBoneLocations[0] = ChainTransform.GetTranslation(); // Starting one below head of chain, move bones. for(int32 i=1; i<ChainBoneIndices.Num(); i++) { // Parent bone position in component space. FCompactPoseBoneIndex ParentIndex = ChainBoneIndices[i - 1]; FVector ParentPos = TrailBoneLocations[i-1]; FVector ParentAnimPos = MeshBases.GetComponentSpaceTransform(ParentIndex).GetTranslation(); // Child bone position in component space. FCompactPoseBoneIndex ChildIndex = ChainBoneIndices[i]; FVector ChildPos = OldToNewTM.TransformPosition(TrailBoneLocations[i]); // move from 'last frames component' frame to 'this frames component' frame FVector ChildAnimPos = MeshBases.GetComponentSpaceTransform(ChildIndex).GetTranslation(); // Desired parent->child offset. FVector TargetDelta = (ChildAnimPos - ParentAnimPos); // Desired child position. FVector ChildTarget = ParentPos + TargetDelta; // Find vector from child to target FVector Error = ChildTarget - ChildPos; // Calculate how much to push the child towards its target float Correction = FMath::Clamp<float>(ThisTimstep * TrailRelaxation, 0.f, 1.f); // Scale correction vector and apply to get new world-space child position. TrailBoneLocations[i] = ChildPos + (Error * Correction); // If desired, prevent bones stretching too far. if(bLimitStretch) { float RefPoseLength = TargetDelta.Size(); FVector CurrentDelta = TrailBoneLocations[i] - TrailBoneLocations[i-1]; float CurrentLength = CurrentDelta.Size(); // If we are too far - cut it back (just project towards parent particle). if( (CurrentLength - RefPoseLength > StretchLimit) && CurrentLength > SMALL_NUMBER ) { FVector CurrentDir = CurrentDelta / CurrentLength; TrailBoneLocations[i] = TrailBoneLocations[i-1] + (CurrentDir * (RefPoseLength + StretchLimit)); } } // Modify child matrix OutBoneTransforms[i] = FBoneTransform(ChildIndex, MeshBases.GetComponentSpaceTransform(ChildIndex)); OutBoneTransforms[i].Transform.SetTranslation(TrailBoneLocations[i]); // Modify rotation of parent matrix to point at this one. // Calculate the direction that parent bone is currently pointing. FVector CurrentBoneDir = OutBoneTransforms[i-1].Transform.TransformVector( GetAlignVector(ChainBoneAxis, bInvertChainBoneAxis) ); CurrentBoneDir = CurrentBoneDir.GetSafeNormal(SMALL_NUMBER); // Calculate vector from parent to child. FVector NewBoneDir = FVector(OutBoneTransforms[i].Transform.GetTranslation() - OutBoneTransforms[i - 1].Transform.GetTranslation()).GetSafeNormal(SMALL_NUMBER); // Calculate a quaternion that gets us from our current rotation to the desired one. FQuat DeltaLookQuat = FQuat::FindBetween(CurrentBoneDir, NewBoneDir); FTransform DeltaTM( DeltaLookQuat, FVector(0.f) ); // Apply to the current parent bone transform. FTransform TmpMatrix = FTransform::Identity; TmpMatrix.CopyRotationPart(OutBoneTransforms[i - 1].Transform); TmpMatrix = TmpMatrix * DeltaTM; OutBoneTransforms[i - 1].Transform.CopyRotationPart(TmpMatrix); } // For the last bone in the chain, use the rotation from the bone above it. OutBoneTransforms[ChainLength - 1].Transform.CopyRotationPart(OutBoneTransforms[ChainLength - 2].Transform); // Update OldLocalToWorld OldLocalToWorld = SkelComp->GetTransformMatrix(); }
void FAnimNode_AnimDynamics::UpdateLimits(USkeletalMeshComponent* SkelComp, FCSPose<FCompactPose>& MeshBases) { SCOPE_CYCLE_COUNTER(STAT_AnimDynamicsLimitUpdate); // We're always going to use the same number so don't realloc LinearLimits.Empty(LinearLimits.Num()); AngularLimits.Empty(AngularLimits.Num()); Springs.Empty(Springs.Num()); const FBoneContainer& BoneContainer = MeshBases.GetPose().GetBoneContainer(); for (int32 Idx = 0; Idx < Bodies.Num(); ++Idx) { const FBoneReference& CurrentBoneRef = BoundBoneReferences[Idx]; // If our bone isn't valid, move on if(!CurrentBoneRef.IsValid(BoneContainer)) { continue; } FAnimPhysLinkedBody& ChainBody = Bodies[Idx]; FAnimPhysRigidBody& RigidBody = Bodies[Idx].RigidBody.PhysBody; FAnimPhysRigidBody* PrevBody = nullptr; if (ChainBody.ParentBody) { PrevBody = &ChainBody.ParentBody->PhysBody; } // Get joint transform FCompactPoseBoneIndex BoneIndex = CurrentBoneRef.GetCompactPoseIndex(BoneContainer); FTransform BoundBoneTransform = MeshBases.GetComponentSpaceTransform(BoneIndex); FTransform ShapeTransform = BoundBoneTransform; // Local offset to joint for Body1 FVector Body1JointOffset = LocalJointOffset; if (PrevBody) { // Get the correct offset Body1JointOffset = JointOffsets[Idx]; // Modify the shape transform to be correct in Body0 frame ShapeTransform = FTransform(FQuat::Identity, -Body1JointOffset); } if (ConstraintSetup.bLinearFullyLocked) { // Rather than calculate prismatic limits, just lock the transform (1 limit instead of 6) FAnimPhys::ConstrainPositionNailed(NextTimeStep, LinearLimits, PrevBody, ShapeTransform.GetTranslation(), &RigidBody, Body1JointOffset); } else { if (ConstraintSetup.LinearXLimitType != AnimPhysLinearConstraintType::Free) { FAnimPhys::ConstrainAlongDirection(NextTimeStep, LinearLimits, PrevBody, ShapeTransform.GetTranslation(), &RigidBody, Body1JointOffset, ShapeTransform.GetRotation().GetAxisX(), FVector2D(ConstraintSetup.LinearAxesMin.X, ConstraintSetup.LinearAxesMax.X)); } if (ConstraintSetup.LinearYLimitType != AnimPhysLinearConstraintType::Free) { FAnimPhys::ConstrainAlongDirection(NextTimeStep, LinearLimits, PrevBody, ShapeTransform.GetTranslation(), &RigidBody, Body1JointOffset, ShapeTransform.GetRotation().GetAxisY(), FVector2D(ConstraintSetup.LinearAxesMin.Y, ConstraintSetup.LinearAxesMax.Y)); } if (ConstraintSetup.LinearZLimitType != AnimPhysLinearConstraintType::Free) { FAnimPhys::ConstrainAlongDirection(NextTimeStep, LinearLimits, PrevBody, ShapeTransform.GetTranslation(), &RigidBody, Body1JointOffset, ShapeTransform.GetRotation().GetAxisZ(), FVector2D(ConstraintSetup.LinearAxesMin.Z, ConstraintSetup.LinearAxesMax.Z)); } } if (ConstraintSetup.AngularConstraintType == AnimPhysAngularConstraintType::Angular) { #if WITH_EDITOR // Check the ranges are valid when running in the editor, log if something is wrong if(ConstraintSetup.AngularLimitsMin.X > ConstraintSetup.AngularLimitsMax.X || ConstraintSetup.AngularLimitsMin.Y > ConstraintSetup.AngularLimitsMax.Y || ConstraintSetup.AngularLimitsMin.Z > ConstraintSetup.AngularLimitsMax.Z) { UE_LOG(LogAnimation, Warning, TEXT("AnimDynamics: Min/Max angular limits for bone %s incorrect, at least one min axis value is greater than the corresponding max."), *BoundBone.BoneName.ToString()); } #endif // Add angular limits. any limit with 360+ degree range is ignored and left free. FAnimPhys::ConstrainAngularRange(NextTimeStep, AngularLimits, PrevBody, &RigidBody, ShapeTransform.GetRotation(), ConstraintSetup.TwistAxis, ConstraintSetup.AngularLimitsMin, ConstraintSetup.AngularLimitsMax); } else { FAnimPhys::ConstrainConeAngle(NextTimeStep, AngularLimits, PrevBody, BoundBoneTransform.GetRotation().GetAxisX(), &RigidBody, FVector(1.0f, 0.0f, 0.0f), ConstraintSetup.ConeAngle); } if(PlanarLimits.Num() > 0) { for(FAnimPhysPlanarLimit& PlanarLimit : PlanarLimits) { FTransform LimitPlaneTransform = PlanarLimit.PlaneTransform; if(PlanarLimit.DrivingBone.IsValid(BoneContainer)) { FCompactPoseBoneIndex DrivingBoneIndex = PlanarLimit.DrivingBone.GetCompactPoseIndex(BoneContainer); LimitPlaneTransform *= MeshBases.GetComponentSpaceTransform(DrivingBoneIndex);// * LimitPlaneTransform; } FAnimPhys::ConstrainPlanar(NextTimeStep, LinearLimits, &RigidBody, LimitPlaneTransform); } } // Add spring if we need spring forces if (bAngularSpring || bLinearSpring) { FAnimPhys::CreateSpring(Springs, PrevBody, ShapeTransform.GetTranslation(), &RigidBody, FVector::ZeroVector); FAnimPhysSpring& NewSpring = Springs.Last(); NewSpring.SpringConstantLinear = LinearSpringConstant; NewSpring.SpringConstantAngular = AngularSpringConstant; NewSpring.AngularTarget = ConstraintSetup.AngularTarget.GetSafeNormal(); NewSpring.AngularTargetAxis = ConstraintSetup.AngularTargetAxis; NewSpring.TargetOrientationOffset = ShapeTransform.GetRotation(); NewSpring.bApplyAngular = bAngularSpring; NewSpring.bApplyLinear = bLinearSpring; } } }
void FAnimNode_AnimDynamics::InitPhysics(USkeletalMeshComponent* Component, FCSPose<FCompactPose>& MeshBases) { // Clear up any existing physics data TermPhysics(); const FBoneContainer& BoneContainer = MeshBases.GetPose().GetBoneContainer(); // List of bone indices in the chain. TArray<int32> ChainBoneIndices; TArray<FName> ChainBoneNames; if(ChainEnd.IsValid(BoneContainer)) { // Add the end of the chain. We have to walk from the bottom upwards to find a chain // as walking downwards doesn't guarantee a single end point. ChainBoneIndices.Add(ChainEnd.BoneIndex); ChainBoneNames.Add(ChainEnd.BoneName); int32 ParentBoneIndex = BoneContainer.GetParentBoneIndex(ChainEnd.BoneIndex); // Walk up the chain until we either find the top or hit the root bone while(ParentBoneIndex != 0) { ChainBoneIndices.Add(ParentBoneIndex); ChainBoneNames.Add(Component->GetBoneName(ParentBoneIndex)); if(ParentBoneIndex == BoundBone.BoneIndex) { // Found the top of the chain break; } ParentBoneIndex = BoneContainer.GetParentBoneIndex(ParentBoneIndex); } // Bail if we can't find a chain, and let the user know if(ParentBoneIndex != BoundBone.BoneIndex) { UE_LOG(LogAnimation, Error, TEXT("AnimDynamics: Attempted to find bone chain starting at %s and ending at %s but failed."), *BoundBone.BoneName.ToString(), *ChainEnd.BoneName.ToString()); return; } } else { // No chain specified, just use the bound bone ChainBoneIndices.Add(BoundBone.BoneIndex); ChainBoneNames.Add(BoundBone.BoneName); } Bodies.Reserve(ChainBoneIndices.Num()); // Walk backwards here as the chain was discovered in reverse order for (int32 Idx = ChainBoneIndices.Num() - 1; Idx >= 0; --Idx) { TArray<FAnimPhysShape> BodyShapes; BodyShapes.Add(FAnimPhysShape::MakeBox(BoxExtents)); FBoneReference LinkBoneRef; LinkBoneRef.BoneName = ChainBoneNames[Idx]; LinkBoneRef.Initialize(BoneContainer); // Calculate joint offsets by looking at the length of the bones and extending the provided offset if (BoundBoneReferences.Num() > 0) { FTransform CurrentBoneTransform = MeshBases.GetComponentSpaceTransform(LinkBoneRef.GetCompactPoseIndex(BoneContainer)); FTransform PreviousBoneTransform = MeshBases.GetComponentSpaceTransform(BoundBoneReferences.Last().GetCompactPoseIndex(BoneContainer)); FVector PreviousAnchor = PreviousBoneTransform.TransformPosition(-LocalJointOffset); float DistanceToAnchor = (PreviousBoneTransform.GetTranslation() - CurrentBoneTransform.GetTranslation()).Size() * 0.5f; if(LocalJointOffset.SizeSquared() < SMALL_NUMBER) { // No offset, just use the position between chain links as the offset // This is likely to just look horrible, but at least the bodies will // be placed correctly and not stack up at the top of the chain. JointOffsets.Add(PreviousAnchor - CurrentBoneTransform.GetTranslation()); } else { // Extend offset along chain. JointOffsets.Add(LocalJointOffset.GetSafeNormal() * DistanceToAnchor); } } else { // No chain to worry about, just use the specified offset. JointOffsets.Add(LocalJointOffset); } BoundBoneReferences.Add(LinkBoneRef); FTransform BodyTransform = MeshBases.GetComponentSpaceTransform(LinkBoneRef.GetCompactPoseIndex(BoneContainer)); BodyTransform.SetTranslation(BodyTransform.GetTranslation() + BodyTransform.GetRotation().RotateVector(-LocalJointOffset)); FAnimPhysLinkedBody NewChainBody(BodyShapes, BodyTransform.GetTranslation(), LinkBoneRef); FAnimPhysRigidBody& PhysicsBody = NewChainBody.RigidBody.PhysBody; PhysicsBody.Pose.Orientation = BodyTransform.GetRotation(); PhysicsBody.PreviousOrientation = PhysicsBody.Pose.Orientation; PhysicsBody.NextOrientation = PhysicsBody.Pose.Orientation; PhysicsBody.CollisionType = CollisionType; switch(PhysicsBody.CollisionType) { case AnimPhysCollisionType::CustomSphere: PhysicsBody.SphereCollisionRadius = SphereCollisionRadius; break; case AnimPhysCollisionType::InnerSphere: PhysicsBody.SphereCollisionRadius = BoxExtents.GetAbsMin() / 2.0f; break; case AnimPhysCollisionType::OuterSphere: PhysicsBody.SphereCollisionRadius = BoxExtents.GetAbsMax() / 2.0f; break; default: break; } if (bOverrideLinearDamping) { PhysicsBody.bLinearDampingOverriden = true; PhysicsBody.LinearDamping = LinearDampingOverride; } if (bOverrideAngularDamping) { PhysicsBody.bAngularDampingOverriden = true; PhysicsBody.AngularDamping = AngularDampingOverride; } PhysicsBody.GravityScale = GravityScale; // Link to parent if (Bodies.Num() > 0) { NewChainBody.ParentBody = &Bodies.Last().RigidBody; } Bodies.Add(NewChainBody); } BaseBodyPtrs.Empty(); for(FAnimPhysLinkedBody& Body : Bodies) { BaseBodyPtrs.Add(&Body.RigidBody.PhysBody); } // Set up transient constraint data const bool bXAxisLocked = ConstraintSetup.LinearXLimitType != AnimPhysLinearConstraintType::Free && ConstraintSetup.LinearAxesMin.X - ConstraintSetup.LinearAxesMax.X == 0.0f; const bool bYAxisLocked = ConstraintSetup.LinearYLimitType != AnimPhysLinearConstraintType::Free && ConstraintSetup.LinearAxesMin.Y - ConstraintSetup.LinearAxesMax.Y == 0.0f; const bool bZAxisLocked = ConstraintSetup.LinearZLimitType != AnimPhysLinearConstraintType::Free && ConstraintSetup.LinearAxesMin.Z - ConstraintSetup.LinearAxesMax.Z == 0.0f; ConstraintSetup.bLinearFullyLocked = bXAxisLocked && bYAxisLocked && bZAxisLocked; // Cache physics settings to avoid accessing UPhysicsSettings continuously if(UPhysicsSettings* Settings = UPhysicsSettings::Get()) { MaxPhysicsDeltaTime = Settings->MaxPhysicsDeltaTime; MaxSubstepDeltaTime = Settings->MaxSubstepDeltaTime; MaxSubsteps = Settings->MaxSubsteps; } else { MaxPhysicsDeltaTime = (1.0f/30.0f); MaxSubstepDeltaTime = (1.0f/60.0f); MaxSubsteps = 4; } bRequiresInit = false; }
void FAnimNode_TwoBoneIK::EvaluateBoneTransforms(USkeletalMeshComponent* SkelComp, FCSPose<FCompactPose>& MeshBases, TArray<FBoneTransform>& OutBoneTransforms) { check(OutBoneTransforms.Num() == 0); const FBoneContainer& BoneContainer = MeshBases.GetPose().GetBoneContainer(); // Get indices of the lower and upper limb bones and check validity. bool bInvalidLimb = false; FCompactPoseBoneIndex IKBoneCompactPoseIndex = IKBone.GetCompactPoseIndex(BoneContainer); const FCompactPoseBoneIndex LowerLimbIndex = BoneContainer.GetParentBoneIndex(IKBoneCompactPoseIndex); if (LowerLimbIndex == INDEX_NONE) { bInvalidLimb = true; } const FCompactPoseBoneIndex UpperLimbIndex = BoneContainer.GetParentBoneIndex(LowerLimbIndex); if (UpperLimbIndex == INDEX_NONE) { bInvalidLimb = true; } const bool bInBoneSpace = (EffectorLocationSpace == BCS_ParentBoneSpace) || (EffectorLocationSpace == BCS_BoneSpace); const int32 EffectorBoneIndex = bInBoneSpace ? BoneContainer.GetPoseBoneIndexForBoneName(EffectorSpaceBoneName) : INDEX_NONE; const FCompactPoseBoneIndex EffectorSpaceBoneIndex = BoneContainer.MakeCompactPoseIndex(FMeshPoseBoneIndex(EffectorBoneIndex)); if (bInBoneSpace && (EffectorSpaceBoneIndex == INDEX_NONE)) { bInvalidLimb = true; } // If we walked past the root, this controlled is invalid, so return no affected bones. if( bInvalidLimb ) { return; } // Get Local Space transforms for our bones. We do this first in case they already are local. // As right after we get them in component space. (And that does the auto conversion). // We might save one transform by doing local first... const FTransform EndBoneLocalTransform = MeshBases.GetLocalSpaceTransform(IKBoneCompactPoseIndex); // Now get those in component space... FTransform LowerLimbCSTransform = MeshBases.GetComponentSpaceTransform(LowerLimbIndex); FTransform UpperLimbCSTransform = MeshBases.GetComponentSpaceTransform(UpperLimbIndex); FTransform EndBoneCSTransform = MeshBases.GetComponentSpaceTransform(IKBoneCompactPoseIndex); // Get current position of root of limb. // All position are in Component space. const FVector RootPos = UpperLimbCSTransform.GetTranslation(); const FVector InitialJointPos = LowerLimbCSTransform.GetTranslation(); const FVector InitialEndPos = EndBoneCSTransform.GetTranslation(); // Transform EffectorLocation from EffectorLocationSpace to ComponentSpace. FTransform EffectorTransform(EffectorLocation); FAnimationRuntime::ConvertBoneSpaceTransformToCS(SkelComp, MeshBases, EffectorTransform, EffectorSpaceBoneIndex, EffectorLocationSpace); // This is our reach goal. FVector DesiredPos = EffectorTransform.GetTranslation(); FVector DesiredDelta = DesiredPos - RootPos; float DesiredLength = DesiredDelta.Size(); // Check to handle case where DesiredPos is the same as RootPos. FVector DesiredDir; if (DesiredLength < (float)KINDA_SMALL_NUMBER) { DesiredLength = (float)KINDA_SMALL_NUMBER; DesiredDir = FVector(1,0,0); } else { DesiredDir = DesiredDelta / DesiredLength; } // Get joint target (used for defining plane that joint should be in). FTransform JointTargetTransform(JointTargetLocation); FCompactPoseBoneIndex JointTargetSpaceBoneIndex(INDEX_NONE); if (JointTargetLocationSpace == BCS_ParentBoneSpace || JointTargetLocationSpace == BCS_BoneSpace) { int32 Index = BoneContainer.GetPoseBoneIndexForBoneName(JointTargetSpaceBoneName); JointTargetSpaceBoneIndex = BoneContainer.MakeCompactPoseIndex(FMeshPoseBoneIndex(Index)); } FAnimationRuntime::ConvertBoneSpaceTransformToCS(SkelComp, MeshBases, JointTargetTransform, JointTargetSpaceBoneIndex, JointTargetLocationSpace); FVector JointTargetPos = JointTargetTransform.GetTranslation(); FVector JointTargetDelta = JointTargetPos - RootPos; float JointTargetLength = JointTargetDelta.Size(); // Same check as above, to cover case when JointTarget position is the same as RootPos. FVector JointPlaneNormal, JointBendDir; if (JointTargetLength < (float)KINDA_SMALL_NUMBER) { JointBendDir = FVector(0,1,0); JointPlaneNormal = FVector(0,0,1); } else { JointPlaneNormal = DesiredDir ^ JointTargetDelta; // If we are trying to point the limb in the same direction that we are supposed to displace the joint in, // we have to just pick 2 random vector perp to DesiredDir and each other. if (JointPlaneNormal.Size() < (float)KINDA_SMALL_NUMBER) { DesiredDir.FindBestAxisVectors(JointPlaneNormal, JointBendDir); } else { JointPlaneNormal.Normalize(); // Find the final member of the reference frame by removing any component of JointTargetDelta along DesiredDir. // This should never leave a zero vector, because we've checked DesiredDir and JointTargetDelta are not parallel. JointBendDir = JointTargetDelta - ((JointTargetDelta | DesiredDir) * DesiredDir); JointBendDir.Normalize(); } } // Find lengths of upper and lower limb in the ref skeleton. // Use actual sizes instead of ref skeleton, so we take into account translation and scaling from other bone controllers. float LowerLimbLength = (InitialEndPos - InitialJointPos).Size(); float UpperLimbLength = (InitialJointPos - RootPos).Size(); float MaxLimbLength = LowerLimbLength + UpperLimbLength; if (bAllowStretching) { const float ScaleRange = StretchLimits.Y - StretchLimits.X; if( ScaleRange > KINDA_SMALL_NUMBER && MaxLimbLength > KINDA_SMALL_NUMBER ) { const float ReachRatio = DesiredLength / MaxLimbLength; const float ScalingFactor = (StretchLimits.Y - 1.f) * FMath::Clamp<float>((ReachRatio - StretchLimits.X) / ScaleRange, 0.f, 1.f); if (ScalingFactor > KINDA_SMALL_NUMBER) { LowerLimbLength *= (1.f + ScalingFactor); UpperLimbLength *= (1.f + ScalingFactor); MaxLimbLength *= (1.f + ScalingFactor); } } } FVector OutEndPos = DesiredPos; FVector OutJointPos = InitialJointPos; // If we are trying to reach a goal beyond the length of the limb, clamp it to something solvable and extend limb fully. if (DesiredLength > MaxLimbLength) { OutEndPos = RootPos + (MaxLimbLength * DesiredDir); OutJointPos = RootPos + (UpperLimbLength * DesiredDir); } else { // So we have a triangle we know the side lengths of. We can work out the angle between DesiredDir and the direction of the upper limb // using the sin rule: const float TwoAB = 2.f * UpperLimbLength * DesiredLength; const float CosAngle = (TwoAB != 0.f) ? ((UpperLimbLength*UpperLimbLength) + (DesiredLength*DesiredLength) - (LowerLimbLength*LowerLimbLength)) / TwoAB : 0.f; // If CosAngle is less than 0, the upper arm actually points the opposite way to DesiredDir, so we handle that. const bool bReverseUpperBone = (CosAngle < 0.f); // If CosAngle is greater than 1.f, the triangle could not be made - we cannot reach the target. // We just have the two limbs double back on themselves, and EndPos will not equal the desired EffectorLocation. if ((CosAngle > 1.f) || (CosAngle < -1.f)) { // Because we want the effector to be a positive distance down DesiredDir, we go back by the smaller section. if (UpperLimbLength > LowerLimbLength) { OutJointPos = RootPos + (UpperLimbLength * DesiredDir); OutEndPos = OutJointPos - (LowerLimbLength * DesiredDir); } else { OutJointPos = RootPos - (UpperLimbLength * DesiredDir); OutEndPos = OutJointPos + (LowerLimbLength * DesiredDir); } } else { // Angle between upper limb and DesiredDir const float Angle = FMath::Acos(CosAngle); // Now we calculate the distance of the joint from the root -> effector line. // This forms a right-angle triangle, with the upper limb as the hypotenuse. const float JointLineDist = UpperLimbLength * FMath::Sin(Angle); // And the final side of that triangle - distance along DesiredDir of perpendicular. // ProjJointDistSqr can't be neg, because JointLineDist must be <= UpperLimbLength because appSin(Angle) is <= 1. const float ProjJointDistSqr = (UpperLimbLength*UpperLimbLength) - (JointLineDist*JointLineDist); // although this shouldn't be ever negative, sometimes Xbox release produces -0.f, causing ProjJointDist to be NaN // so now I branch it. float ProjJointDist = (ProjJointDistSqr>0.f)? FMath::Sqrt(ProjJointDistSqr) : 0.f; if( bReverseUpperBone ) { ProjJointDist *= -1.f; } // So now we can work out where to put the joint! OutJointPos = RootPos + (ProjJointDist * DesiredDir) + (JointLineDist * JointBendDir); } } // Update transform for upper bone. { // Get difference in direction for old and new joint orientations FVector const OldDir = (InitialJointPos - RootPos).GetSafeNormal(); FVector const NewDir = (OutJointPos - RootPos).GetSafeNormal(); // Find Delta Rotation take takes us from Old to New dir FQuat const DeltaRotation = FQuat::FindBetweenNormals(OldDir, NewDir); // Rotate our Joint quaternion by this delta rotation UpperLimbCSTransform.SetRotation( DeltaRotation * UpperLimbCSTransform.GetRotation() ); // And put joint where it should be. UpperLimbCSTransform.SetTranslation( RootPos ); // Order important. First bone is upper limb. OutBoneTransforms.Add( FBoneTransform(UpperLimbIndex, UpperLimbCSTransform) ); } // Update transform for lower bone. { // Get difference in direction for old and new joint orientations FVector const OldDir = (InitialEndPos - InitialJointPos).GetSafeNormal(); FVector const NewDir = (OutEndPos - OutJointPos).GetSafeNormal(); // Find Delta Rotation take takes us from Old to New dir FQuat const DeltaRotation = FQuat::FindBetweenNormals(OldDir, NewDir); // Rotate our Joint quaternion by this delta rotation LowerLimbCSTransform.SetRotation( DeltaRotation * LowerLimbCSTransform.GetRotation() ); // And put joint where it should be. LowerLimbCSTransform.SetTranslation( OutJointPos ); // Order important. Second bone is lower limb. OutBoneTransforms.Add( FBoneTransform(LowerLimbIndex, LowerLimbCSTransform) ); } // Update transform for end bone. { if( bTakeRotationFromEffectorSpace ) { EndBoneCSTransform.SetRotation( EffectorTransform.GetRotation() ); } else if( bMaintainEffectorRelRot ) { EndBoneCSTransform = EndBoneLocalTransform * LowerLimbCSTransform; } // Set correct location for end bone. EndBoneCSTransform.SetTranslation(OutEndPos); // Order important. Third bone is End Bone. OutBoneTransforms.Add(FBoneTransform(IKBoneCompactPoseIndex, EndBoneCSTransform)); } // Make sure we have correct number of bones check(OutBoneTransforms.Num() == 3); }
void FAnimNode_AimOffsetLookAt::UpdateFromLookAtTarget(FPoseContext& LocalPoseContext) { const FBoneContainer& RequiredBones = LocalPoseContext.Pose.GetBoneContainer(); if (RequiredBones.GetSkeletalMeshAsset()) { const USkeletalMeshSocket* Socket = RequiredBones.GetSkeletalMeshAsset()->FindSocket(SourceSocketName); if (Socket) { const FTransform SocketLocalTransform = Socket->GetSocketLocalTransform(); FBoneReference SocketBoneReference; SocketBoneReference.BoneName = Socket->BoneName; SocketBoneReference.Initialize(RequiredBones); if (SocketBoneReference.IsValid(RequiredBones)) { const FCompactPoseBoneIndex SocketBoneIndex = SocketBoneReference.GetCompactPoseIndex(RequiredBones); FCSPose<FCompactPose> GlobalPose; GlobalPose.InitPose(LocalPoseContext.Pose); USkeletalMeshComponent* Component = LocalPoseContext.AnimInstanceProxy->GetSkelMeshComponent(); AActor* Actor = Component ? Component->GetOwner() : nullptr; if (Component && Actor && BlendSpace) { const FTransform ActorTransform = Actor->GetTransform(); const FTransform BoneTransform = GlobalPose.GetComponentSpaceTransform(SocketBoneIndex); const FTransform SocketWorldTransform = SocketLocalTransform * BoneTransform * Component->ComponentToWorld; // Convert Target to Actor Space const FTransform TargetWorldTransform(LookAtLocation); const FVector DirectionToTarget = ActorTransform.InverseTransformVectorNoScale(TargetWorldTransform.GetLocation() - SocketWorldTransform.GetLocation()).GetSafeNormal(); const FVector CurrentDirection = ActorTransform.InverseTransformVectorNoScale(SocketWorldTransform.GetUnitAxis(EAxis::X)); const FVector AxisX = FVector::ForwardVector; const FVector AxisY = FVector::RightVector; const FVector AxisZ = FVector::UpVector; const FVector2D CurrentCoords = FMath::GetAzimuthAndElevation(CurrentDirection, AxisX, AxisY, AxisZ); const FVector2D TargetCoords = FMath::GetAzimuthAndElevation(DirectionToTarget, AxisX, AxisY, AxisZ); const FVector BlendInput( FRotator::NormalizeAxis(FMath::RadiansToDegrees(TargetCoords.X - CurrentCoords.X)), FRotator::NormalizeAxis(FMath::RadiansToDegrees(TargetCoords.Y - CurrentCoords.Y)), 0.f); // Set X and Y, so ticking next frame is based on correct weights. X = BlendInput.X; Y = BlendInput.Y; // Generate BlendSampleDataCache from inputs. BlendSpace->GetSamplesFromBlendInput(BlendInput, BlendSampleDataCache); if (CVarAimOffsetLookAtDebug.GetValueOnAnyThread() == 1) { DrawDebugLine(Component->GetWorld(), SocketWorldTransform.GetLocation(), TargetWorldTransform.GetLocation(), FColor::Green); DrawDebugLine(Component->GetWorld(), SocketWorldTransform.GetLocation(), SocketWorldTransform.GetLocation() + SocketWorldTransform.GetUnitAxis(EAxis::X) * (TargetWorldTransform.GetLocation() - SocketWorldTransform.GetLocation()).Size(), FColor::Red); DrawDebugCoordinateSystem(Component->GetWorld(), ActorTransform.GetLocation(), ActorTransform.GetRotation().Rotator(), 100.f); FString DebugString = FString::Printf(TEXT("Socket (X:%f, Y:%f), Target (X:%f, Y:%f), Result (X:%f, Y:%f)") , FMath::RadiansToDegrees(CurrentCoords.X) , FMath::RadiansToDegrees(CurrentCoords.Y) , FMath::RadiansToDegrees(TargetCoords.X) , FMath::RadiansToDegrees(TargetCoords.Y) , BlendInput.X , BlendInput.Y); GEngine->AddOnScreenDebugMessage(INDEX_NONE, 0.f, FColor::Red, DebugString, false); } } } } } }
void FAnimNode_ModifyBone::EvaluateBoneTransforms(USkeletalMeshComponent* SkelComp, FCSPose<FCompactPose>& MeshBases, TArray<FBoneTransform>& OutBoneTransforms) { check(OutBoneTransforms.Num() == 0); // the way we apply transform is same as FMatrix or FTransform // we apply scale first, and rotation, and translation // if you'd like to translate first, you'll need two nodes that first node does translate and second nodes to rotate. const FBoneContainer BoneContainer = MeshBases.GetPose().GetBoneContainer(); FCompactPoseBoneIndex CompactPoseBoneToModify = BoneToModify.GetCompactPoseIndex(BoneContainer); FTransform NewBoneTM = MeshBases.GetComponentSpaceTransform(CompactPoseBoneToModify); if (ScaleMode != BMM_Ignore) { // Convert to Bone Space. FAnimationRuntime::ConvertCSTransformToBoneSpace(SkelComp, MeshBases, NewBoneTM, CompactPoseBoneToModify, ScaleSpace); if (ScaleMode == BMM_Additive) { NewBoneTM.SetScale3D(NewBoneTM.GetScale3D() * Scale); } else { NewBoneTM.SetScale3D(Scale); } // Convert back to Component Space. FAnimationRuntime::ConvertBoneSpaceTransformToCS(SkelComp, MeshBases, NewBoneTM, CompactPoseBoneToModify, ScaleSpace); } if (RotationMode != BMM_Ignore) { // Convert to Bone Space. FAnimationRuntime::ConvertCSTransformToBoneSpace(SkelComp, MeshBases, NewBoneTM, CompactPoseBoneToModify, RotationSpace); const FQuat BoneQuat(Rotation); if (RotationMode == BMM_Additive) { NewBoneTM.SetRotation(BoneQuat * NewBoneTM.GetRotation()); } else { NewBoneTM.SetRotation(BoneQuat); } // Convert back to Component Space. FAnimationRuntime::ConvertBoneSpaceTransformToCS(SkelComp, MeshBases, NewBoneTM, CompactPoseBoneToModify, RotationSpace); } if (TranslationMode != BMM_Ignore) { // Convert to Bone Space. FAnimationRuntime::ConvertCSTransformToBoneSpace(SkelComp, MeshBases, NewBoneTM, CompactPoseBoneToModify, TranslationSpace); if (TranslationMode == BMM_Additive) { NewBoneTM.AddToTranslation(Translation); } else { NewBoneTM.SetTranslation(Translation); } // Convert back to Component Space. FAnimationRuntime::ConvertBoneSpaceTransformToCS(SkelComp, MeshBases, NewBoneTM, CompactPoseBoneToModify, TranslationSpace); } OutBoneTransforms.Add( FBoneTransform(BoneToModify.GetCompactPoseIndex(BoneContainer), NewBoneTM) ); }