// FRenderResource interface.
virtual void InitRHI() override
{
uint32 TextureStride = sizeof(FVector2D);
EPixelFormat TextureFormat = PF_G32R32F;
if (Use16bitTexCoord)
{
TextureStride = sizeof(FVector2DHalf);
TextureFormat = PF_G16R16F;
}
if (!buffersAllocated)
{
PositionBuffer.VertexBufferRHI = AllocVertexBuffer(sizeof(FVector), Vertices.Num());
TangentBuffer.VertexBufferRHI = AllocVertexBuffer(sizeof(FPackedNormal), 2 * Vertices.Num());
TexCoordBuffer.VertexBufferRHI = AllocVertexBuffer(TextureStride, NumTexCoords * Vertices.Num());
ColorBuffer.VertexBufferRHI = AllocVertexBuffer(sizeof(FColor), Vertices.Num());
TangentBufferSRV = RHICreateShaderResourceView(TangentBuffer.VertexBufferRHI, 4, PF_R8G8B8A8);
TexCoordBufferSRV = RHICreateShaderResourceView(TexCoordBuffer.VertexBufferRHI, TextureStride, TextureFormat);
ColorBufferSRV = RHICreateShaderResourceView(ColorBuffer.VertexBufferRHI, 4, PF_R8G8B8A8);
PositionBufferSRV = RHICreateShaderResourceView(PositionBuffer.VertexBufferRHI, sizeof(float), PF_R32_FLOAT);
buffersAllocated = true;
}
void* TexCoordBufferData = RHILockVertexBuffer(TexCoordBuffer.VertexBufferRHI, 0, NumTexCoords * TextureStride * Vertices.Num(), RLM_WriteOnly);
FVector2D* TexCoordBufferData32 = !Use16bitTexCoord ? static_cast<FVector2D*>(TexCoordBufferData) : nullptr;
FVector2DHalf* TexCoordBufferData16 = Use16bitTexCoord ? static_cast<FVector2DHalf*>(TexCoordBufferData) : nullptr;
// Copy the vertex data into the vertex buffers.
FVector* PositionBufferData = static_cast<FVector*>(RHILockVertexBuffer(PositionBuffer.VertexBufferRHI, 0, sizeof(FVector) * Vertices.Num(), RLM_WriteOnly));
FPackedNormal* TangentBufferData = static_cast<FPackedNormal*>(RHILockVertexBuffer(TangentBuffer.VertexBufferRHI, 0, 2 * sizeof(FPackedNormal) * Vertices.Num(), RLM_WriteOnly));
FColor* ColorBufferData = static_cast<FColor*>(RHILockVertexBuffer(ColorBuffer.VertexBufferRHI, 0, sizeof(FColor) * Vertices.Num(), RLM_WriteOnly));
for (int32 i = 0; i < Vertices.Num(); i++)
{
PositionBufferData[i] = Vertices[i].Position;
TangentBufferData[2 * i + 0] = Vertices[i].TangentX;
TangentBufferData[2 * i + 1] = Vertices[i].TangentZ;
ColorBufferData[i] = Vertices[i].Color;
for (uint32 j = 0; j < NumTexCoords; j++)
{
if (Use16bitTexCoord)
{
TexCoordBufferData16[NumTexCoords * i + j] = FVector2DHalf(Vertices[i].TextureCoordinate[j]);
}
else
{
TexCoordBufferData32[NumTexCoords * i + j] = Vertices[i].TextureCoordinate[j];
}
}
}
RHIUnlockVertexBuffer(PositionBuffer.VertexBufferRHI);
RHIUnlockVertexBuffer(TangentBuffer.VertexBufferRHI);
RHIUnlockVertexBuffer(TexCoordBuffer.VertexBufferRHI);
RHIUnlockVertexBuffer(ColorBuffer.VertexBufferRHI);
}
/*-----------------------------------------------------------------------------
TGPUSkinAPEXClothVertexFactory::ClothShaderType
-----------------------------------------------------------------------------*/
void FGPUBaseSkinAPEXClothVertexFactory::ClothShaderType::UpdateClothSimulData(const TArray<FVector4>& InSimulPositions, const TArray<FVector4>& InSimulNormals)
{
uint32 NumSimulVerts = InSimulPositions.Num();
if (GRHIFeatureLevel_DEPRECATED >= ERHIFeatureLevel::SM4)
{
FMath::Min(NumSimulVerts, (uint32)MAX_APEXCLOTH_VERTICES_FOR_VB);
uint32 VectorArraySize = NumSimulVerts * sizeof(FVector4);
uint32 PooledArraySize = ClothSimulDataBufferPool.PooledSizeForCreationArguments(VectorArraySize);
if(!IsValidRef(ClothSimulPositionBuffer) || PooledArraySize != ClothSimulPositionBuffer.VertexBufferRHI->GetSize())
{
if(IsValidRef(ClothSimulPositionBuffer))
{
ClothSimulDataBufferPool.ReleasePooledResource(ClothSimulPositionBuffer);
}
ClothSimulPositionBuffer = ClothSimulDataBufferPool.CreatePooledResource(VectorArraySize);
check(IsValidRef(ClothSimulPositionBuffer));
}
if(!IsValidRef(ClothSimulNormalBuffer) || PooledArraySize != ClothSimulNormalBuffer.VertexBufferRHI->GetSize())
{
if(IsValidRef(ClothSimulNormalBuffer))
{
ClothSimulDataBufferPool.ReleasePooledResource(ClothSimulNormalBuffer);
}
ClothSimulNormalBuffer = ClothSimulDataBufferPool.CreatePooledResource(VectorArraySize);
check(IsValidRef(ClothSimulNormalBuffer));
}
if(NumSimulVerts)
{
float* Data = (float*)RHILockVertexBuffer(ClothSimulPositionBuffer.VertexBufferRHI, 0, VectorArraySize, RLM_WriteOnly);
checkSlow(Data);
FMemory::Memcpy(Data, InSimulPositions.GetData(), NumSimulVerts * sizeof(FVector4));
RHIUnlockVertexBuffer(ClothSimulPositionBuffer.VertexBufferRHI);
Data = (float*)RHILockVertexBuffer(ClothSimulNormalBuffer.VertexBufferRHI, 0, VectorArraySize, RLM_WriteOnly);
checkSlow(Data);
FMemory::Memcpy(Data, InSimulNormals.GetData(), NumSimulVerts * sizeof(FVector4));
RHIUnlockVertexBuffer(ClothSimulNormalBuffer.VertexBufferRHI);
}
}
else
{
UpdateClothUniformBuffer(InSimulPositions, InSimulNormals);
}
}
/**
* Initialize the dynamic RHI for this rendering resource
*/
void FMorphVertexBuffer::InitDynamicRHI()
{
// LOD of the skel mesh is used to find number of vertices in buffer
FStaticLODModel& LodModel = SkelMeshResource->LODModels[LODIdx];
// Create the buffer rendering resource
uint32 Size = LodModel.NumVertices * sizeof(FMorphGPUSkinVertex);
FRHIResourceCreateInfo CreateInfo;
VertexBufferRHI = RHICreateVertexBuffer(Size,BUF_Dynamic,CreateInfo);
// Lock the buffer.
FMorphGPUSkinVertex* Buffer = (FMorphGPUSkinVertex*) RHILockVertexBuffer(VertexBufferRHI,0,Size,RLM_WriteOnly);
// zero all deltas (NOTE: DeltaTangentZ is FPackedNormal, so we can't just FMemory::Memzero)
for (uint32 VertIndex=0; VertIndex < LodModel.NumVertices; ++VertIndex)
{
Buffer[VertIndex].DeltaPosition = FVector::ZeroVector;
Buffer[VertIndex].DeltaTangentZ = FPackedNormal::ZeroNormal;
}
// Unlock the buffer.
RHIUnlockVertexBuffer(VertexBufferRHI);
// hasn't been updated yet
bHasBeenUpdated = false;
}
void UpdateRenderData() const
{
// Copy the vertex data into the vertex buffer.
void* VertexBufferData = RHILockVertexBuffer(VertexBufferRHI, 0, Vertices.Num() * sizeof(FDynamicMeshVertex), RLM_WriteOnly);
FMemory::Memcpy(VertexBufferData, Vertices.GetData(), Vertices.Num() * sizeof(FDynamicMeshVertex));
RHIUnlockVertexBuffer(VertexBufferRHI);
}
void FFinalSkinVertexBuffer::InitVertexData(FStaticLODModel& LodModel)
{
// Create the buffer rendering resource
uint32 Size = LodModel.NumVertices * sizeof(FFinalSkinVertex);
FRHIResourceCreateInfo CreateInfo;
VertexBufferRHI = RHICreateVertexBuffer(Size,BUF_Dynamic, CreateInfo);
// Lock the buffer.
void* Buffer = RHILockVertexBuffer(VertexBufferRHI,0,Size,RLM_WriteOnly);
// Initialize the vertex data
// All chunks are combined into one (rigid first, soft next)
check(LodModel.VertexBufferGPUSkin.GetNumVertices() == LodModel.NumVertices);
FFinalSkinVertex* DestVertex = (FFinalSkinVertex*)Buffer;
for( uint32 VertexIdx=0; VertexIdx < LodModel.NumVertices; VertexIdx++ )
{
const TGPUSkinVertexBase<bExtraBoneInfluencesT>* SrcVertex = LodModel.VertexBufferGPUSkin.GetVertexPtr<bExtraBoneInfluencesT>(VertexIdx);
DestVertex->Position = LodModel.VertexBufferGPUSkin.GetVertexPositionFast<bExtraBoneInfluencesT>(VertexIdx);
DestVertex->TangentX = SrcVertex->TangentX;
// w component of TangentZ should already have sign of the tangent basis determinant
DestVertex->TangentZ = SrcVertex->TangentZ;
FVector2D UVs = LodModel.VertexBufferGPUSkin.GetVertexUVFast<bExtraBoneInfluencesT>(VertexIdx,0);
DestVertex->U = UVs.X;
DestVertex->V = UVs.Y;
DestVertex++;
}
// Unlock the buffer.
RHIUnlockVertexBuffer(VertexBufferRHI);
}
virtual void InitRHI()
{
VertexBufferRHI = RHICreateVertexBuffer(Vertices.Num() * sizeof(FDynamicMeshVertex), NULL, BUF_Static);
// Copy the vertex data into the vertex buffer.
void* VertexBufferData = RHILockVertexBuffer(VertexBufferRHI, 0, Vertices.Num() * sizeof(FDynamicMeshVertex), RLM_WriteOnly);
FMemory::Memcpy(VertexBufferData, Vertices.GetTypedData(), Vertices.Num() * sizeof(FDynamicMeshVertex));
RHIUnlockVertexBuffer(VertexBufferRHI);
}
virtual void InitRHI() override
{
FRHIResourceCreateInfo CreateInfo;
VertexBufferRHI = RHICreateVertexBuffer(sizeof(FVector4) * 2, BUF_Static, CreateInfo);
FVector4* DummyContents = (FVector4*)RHILockVertexBuffer(VertexBufferRHI,0,sizeof(FVector4)*2,RLM_WriteOnly);
DummyContents[0] = FVector4(0.0f, 0.0f, 0.0f, 0.0f);
DummyContents[1] = FVector4(1.0f, 1.0f, 1.0f, 1.0f);
RHIUnlockVertexBuffer(VertexBufferRHI);
}
virtual void InitRHI() override
{
FRHIResourceCreateInfo CreateInfo;
VertexBufferRHI = RHICreateVertexBuffer(Vertices.Num() * sizeof(FDynamicMeshVertex), BUF_Static, CreateInfo);
// Copy the vertex data into the vertex buffer.
void* VertexBufferData = RHILockVertexBuffer(VertexBufferRHI, 0, Vertices.Num() * sizeof(FDynamicMeshVertex), RLM_WriteOnly);
FMemory::Memcpy(VertexBufferData, Vertices.GetData(), Vertices.Num() * sizeof(FDynamicMeshVertex));
RHIUnlockVertexBuffer(VertexBufferRHI);
}
virtual void InitRHI() override
{
#if ENGINE_MAJOR_VERSION >= 4 && ENGINE_MINOR_VERSION >= 3
FRHIResourceCreateInfo CreateInfo;
VertexBufferRHI = RHICreateVertexBuffer(Vertices.Num() * sizeof(FDynamicMeshVertex), BUF_Static, CreateInfo);
#else
VertexBufferRHI = RHICreateVertexBuffer(Vertices.Num() * sizeof(FDynamicMeshVertex), NULL, BUF_Static);
#endif
// Copy the vertex data into the vertex buffer.
void* VertexBufferData = RHILockVertexBuffer(VertexBufferRHI, 0, Vertices.Num() * sizeof(FDynamicMeshVertex), RLM_WriteOnly);
FMemory::Memcpy(VertexBufferData, Vertices.GetData(), Vertices.Num() * sizeof(FDynamicMeshVertex));
RHIUnlockVertexBuffer(VertexBufferRHI);
}
/**
* Creates a vertex buffer holding texture coordinates for the four corners of a sprite.
*/
void FParticleTexCoordVertexBuffer::InitRHI()
{
const uint32 Size = sizeof(FVector2D) * 4 * MAX_PARTICLES_PER_INSTANCE;
VertexBufferRHI = RHICreateVertexBuffer( Size, NULL, BUF_Static );
FVector2D* Vertices = (FVector2D*)RHILockVertexBuffer( VertexBufferRHI, 0, Size, RLM_WriteOnly );
for (uint32 SpriteIndex = 0; SpriteIndex < MAX_PARTICLES_PER_INSTANCE; ++SpriteIndex)
{
Vertices[SpriteIndex*4 + 0] = FVector2D(0.0f, 0.0f);
Vertices[SpriteIndex*4 + 1] = FVector2D(0.0f, 1.0f);
Vertices[SpriteIndex*4 + 2] = FVector2D(1.0f, 1.0f);
Vertices[SpriteIndex*4 + 3] = FVector2D(1.0f, 0.0f);
}
RHIUnlockVertexBuffer( VertexBufferRHI );
}
void FStreetMapVertexBuffer::InitRHI()
{
if( Vertices.Num() > 0 )
{
// Allocate our vertex buffer
FRHIResourceCreateInfo CreateInfo;
VertexBufferRHI = RHICreateVertexBuffer( Vertices.Num() * sizeof( Vertices[0] ), BUF_Static, CreateInfo );
// Load the vertex buffer with data
void* VertexBufferData = RHILockVertexBuffer( VertexBufferRHI, 0, Vertices.Num() * sizeof( Vertices[0] ), RLM_WriteOnly );
FMemory::Memcpy( VertexBufferData, Vertices.GetData(), Vertices.Num() * sizeof( FStreetMapVertex ) );
RHIUnlockVertexBuffer( VertexBufferRHI );
}
}
virtual void InitRHI()
{
FRHIResourceCreateInfo CreateInfo;
VertexBufferRHI = RHICreateVertexBuffer(12 * sizeof(FPackedNormal), BUF_Dynamic, CreateInfo);
// Copy the vertex data into the vertex buffer.
FPackedNormal* TangentBufferData = (FPackedNormal*)RHILockVertexBuffer(VertexBufferRHI, 0, 12 * sizeof(FPackedNormal), RLM_WriteOnly);
for(int32 FaceIndex = 0;FaceIndex < 6;++FaceIndex)
{
const FVector UnprojectedTangentX = FVector(+1,-1,0).GetSafeNormal();
const FVector UnprojectedTangentY(-1,-1,-1);
const FVector FaceNormal = FaceNormals[FaceIndex].ToFloat();
const FVector ProjectedFaceTangentX = (UnprojectedTangentX - FaceNormal * (UnprojectedTangentX | FaceNormal)).GetSafeNormal();
*TangentBufferData++ = ProjectedFaceTangentX;
*TangentBufferData++ = FVector4(FaceNormal, FMath::Sign(UnprojectedTangentY | (FaceNormal ^ ProjectedFaceTangentX)));
}
RHIUnlockVertexBuffer(VertexBufferRHI);
}
void FGPUBaseSkinVertexFactory::ShaderDataType::UpdateBoneData()
{
uint32 NumBones = BoneMatrices.Num();
check(NumBones <= MaxGPUSkinBones);
if (GRHIFeatureLevel_DEPRECATED >= ERHIFeatureLevel::SM4)
{
static FSharedPoolPolicyData PoolPolicy;
uint32 NumVectors = NumBones*3;
check(NumVectors <= (MaxGPUSkinBones*3));
uint32 VectorArraySize = NumVectors * sizeof(FVector4);
uint32 PooledArraySize = BoneBufferPool.PooledSizeForCreationArguments(VectorArraySize);
if(!IsValidRef(BoneBuffer) || PooledArraySize != BoneBuffer.VertexBufferRHI->GetSize())
{
if(IsValidRef(BoneBuffer))
{
BoneBufferPool.ReleasePooledResource(BoneBuffer);
}
BoneBuffer = BoneBufferPool.CreatePooledResource(VectorArraySize);
check(IsValidRef(BoneBuffer));
}
if(NumBones)
{
#if PLATFORM_SUPPORTS_RHI_THREAD
check(VectorArraySize == NumBones * sizeof(BoneMatrices[0]));
if (GRHIThread)
{
GRHICommandList.GetImmediateCommandList().UpdateVertexBuffer(BoneBuffer.VertexBufferRHI, BoneMatrices.GetData(), NumBones * sizeof(BoneMatrices[0]));
}
else
#endif
{
float* Data = (float*)RHILockVertexBuffer(BoneBuffer.VertexBufferRHI, 0, VectorArraySize, RLM_WriteOnly);
checkSlow(Data);
FMemory::Memcpy(Data, BoneMatrices.GetData(), NumBones * sizeof(BoneMatrices[0]));
RHIUnlockVertexBuffer(BoneBuffer.VertexBufferRHI);
}
}
}
else
{
check(NumBones * BoneMatrices.GetTypeSize() <= sizeof(GBoneUniformStruct));
FMemory::Memcpy(&GBoneUniformStruct, BoneMatrices.GetData(), NumBones * sizeof(BoneMatrices[0]));
UniformBuffer = RHICreateUniformBuffer(&GBoneUniformStruct, FBoneMatricesUniformShaderParameters::StaticStruct.GetLayout(), UniformBuffer_MultiFrame);
}
}
/**
* Initialize the RHI for this rendering resource
*/
virtual void InitRHI() override
{
// used with a tristrip, so only 4 vertices are needed
uint32 Size = 4 * sizeof(FMaterialTileVertex);
// create vertex buffer
FRHIResourceCreateInfo CreateInfo;
VertexBufferRHI = RHICreateVertexBuffer(Size,BUF_Static,CreateInfo);
// lock it
void* Buffer = RHILockVertexBuffer(VertexBufferRHI,0,Size,RLM_WriteOnly);
// first vertex element
FMaterialTileVertex* DestVertex = (FMaterialTileVertex*)Buffer;
// fill out the verts
DestVertex[0].Initialize(1, -1, 1, 1);
DestVertex[1].Initialize(1, 1, 1, 0);
DestVertex[2].Initialize(-1, -1, 0, 1);
DestVertex[3].Initialize(-1, 1, 0, 0);
// Unlock the buffer.
RHIUnlockVertexBuffer(VertexBufferRHI);
}
/**
* Transfers a list of curves to a texture on the GPU. All main memory allocated
* for curve samples is released.
* @param CurveTextureRHI - The
* @param CurveTextureTargetRHI - The render target for the curve texture.
* @param InPendingCurves - Curves to be stored on the GPU.
*/
static void InjectCurves(
FRHICommandListImmediate& RHICmdList,
FTexture2DRHIParamRef CurveTextureRHI,
FTexture2DRHIParamRef CurveTextureTargetRHI,
TArray<FCurveSamples>& InPendingCurves )
{
static bool bFirstCall = true;
check( IsInRenderingThread() );
SCOPED_DRAW_EVENT(RHICmdList, InjectParticleCurves);
FVertexBufferRHIParamRef ScratchVertexBufferRHI = GParticleScratchVertexBuffer.VertexBufferRHI;
SetRenderTarget(RHICmdList, CurveTextureTargetRHI, FTextureRHIParamRef());
RHICmdList.SetScissorRect(false, 0, 0, 0, 0);
RHICmdList.SetViewport(0, 0, 0.0f, GParticleCurveTextureSizeX, GParticleCurveTextureSizeY, 1.0f);
RHICmdList.SetDepthStencilState(TStaticDepthStencilState<false, CF_Always>::GetRHI());
RHICmdList.SetRasterizerState(TStaticRasterizerState<FM_Solid, CM_None>::GetRHI());
RHICmdList.SetBlendState(TStaticBlendState<>::GetRHI());
if (bFirstCall)
{
RHICmdList.Clear(true, FLinearColor::Blue, false, 0.0f, false, 0, FIntRect());
bFirstCall = false;
}
int32 PendingCurveCount = InPendingCurves.Num();
for ( int32 CurveIndex = 0; CurveIndex < PendingCurveCount; ++CurveIndex )
{
FCurveSamples& Curve = InPendingCurves[CurveIndex];
check( Curve.Samples );
// Copy curve samples in to the scratch vertex buffer.
const int32 SampleCount = Curve.TexelAllocation.Size;
const int32 SampleByteCount = SampleCount * sizeof(FColor);
FColor* RESTRICT DestSamples = (FColor*)RHILockVertexBuffer( ScratchVertexBufferRHI, 0, SampleByteCount, RLM_WriteOnly );
FMemory::Memcpy( DestSamples, Curve.Samples, SampleByteCount );
RHICmdList.UnlockVertexBuffer(ScratchVertexBufferRHI);
FMemory::Free( Curve.Samples );
Curve.Samples = NULL;
// Compute the offset in to the texture.
FVector2D CurveOffset(
(float)Curve.TexelAllocation.X / GParticleCurveTextureSizeX,
(float)Curve.TexelAllocation.Y / GParticleCurveTextureSizeY );
// Grab shaders.
TShaderMapRef<FParticleCurveInjectionVS> VertexShader(GetGlobalShaderMap(GMaxRHIFeatureLevel));
TShaderMapRef<FParticleCurveInjectionPS> PixelShader(GetGlobalShaderMap(GMaxRHIFeatureLevel));
// Bound shader state.
static FGlobalBoundShaderState BoundShaderState;
SetGlobalBoundShaderState(
RHICmdList,
GMaxRHIFeatureLevel,
BoundShaderState,
GParticleCurveInjectionVertexDeclaration.VertexDeclarationRHI,
*VertexShader,
*PixelShader,
0
);
VertexShader->SetParameters(RHICmdList, CurveOffset );
// Stream 0: New particles.
RHICmdList.SetStreamSource(
0,
ScratchVertexBufferRHI,
/*Stride=*/ sizeof(FColor),
/*Offset=*/ 0
);
// Stream 1: TexCoord.
RHICmdList.SetStreamSource(
1,
GParticleTexCoordVertexBuffer.VertexBufferRHI,
/*Stride=*/ sizeof(FVector2D),
/*Offset=*/ 0
);
// Inject particles.
RHICmdList.DrawIndexedPrimitive(
GParticleIndexBuffer.IndexBufferRHI,
PT_TriangleList,
/*BaseVertexIndex=*/ 0,
/*MinIndex=*/ 0,
/*NumVertices=*/ 4,
/*StartIndex=*/ 0,
/*NumPrimitives=*/ 2,
/*NumInstances=*/ SampleCount
);
}
RHICmdList.CopyToResolveTarget(CurveTextureTargetRHI, CurveTextureRHI, /*bKeepOriginalSurface=*/ false, FResolveParams());
}
void AddElements(TArray<FDynamicMeshVertex> &Elements)
{
FDynamicMeshVertex* VertexBufferData = (FDynamicMeshVertex*)RHILockVertexBuffer(VertexBufferRHI, 0, BOSize * sizeof(FDynamicMeshVertex), RLM_WriteOnly);
FMemory::Memcpy(VertexBufferData, &Elements[0], Elements.Num() * sizeof(FDynamicMeshVertex));
RHIUnlockVertexBuffer(VertexBufferRHI);
}
