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dxvk/src/d3d11/d3d11_context.cpp

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#include <cstring>
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#include "d3d11_context.h"
#include "d3d11_device.h"
#include "d3d11_query.h"
#include "d3d11_texture.h"
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#include "../dxbc/dxbc_util.h"
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namespace dxvk {
D3D11DeviceContext::D3D11DeviceContext(
D3D11Device* pParent,
const Rc<DxvkDevice>& Device,
DxvkCsChunkFlags CsFlags)
: m_parent (pParent),
m_contextExt(this),
m_annotation(this),
m_multithread(this, false),
m_device (Device),
m_csFlags (CsFlags),
m_csChunk (AllocCsChunk()),
m_cmdData (nullptr) {
// Create default state objects. We won't ever return them
// to the application, but we'll use them to apply state.
Com<ID3D11BlendState> defaultBlendState;
Com<ID3D11DepthStencilState> defaultDepthStencilState;
Com<ID3D11RasterizerState> defaultRasterizerState;
if (FAILED(m_parent->CreateBlendState (nullptr, &defaultBlendState))
|| FAILED(m_parent->CreateDepthStencilState(nullptr, &defaultDepthStencilState))
|| FAILED(m_parent->CreateRasterizerState (nullptr, &defaultRasterizerState)))
throw DxvkError("D3D11DeviceContext: Failed to create default state objects");
// Apply default state to the context. This is required
// in order to initialize the DXVK contex properly.
m_defaultBlendState = static_cast<D3D11BlendState*> (defaultBlendState.ptr());
m_defaultDepthStencilState = static_cast<D3D11DepthStencilState*>(defaultDepthStencilState.ptr());
m_defaultRasterizerState = static_cast<D3D11RasterizerState*> (defaultRasterizerState.ptr());
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}
D3D11DeviceContext::~D3D11DeviceContext() {
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}
HRESULT STDMETHODCALLTYPE D3D11DeviceContext::QueryInterface(REFIID riid, void** ppvObject) {
if (ppvObject == nullptr)
return E_POINTER;
*ppvObject = nullptr;
if (riid == __uuidof(IUnknown)
|| riid == __uuidof(ID3D11DeviceChild)
|| riid == __uuidof(ID3D11DeviceContext)
|| riid == __uuidof(ID3D11DeviceContext1)) {
*ppvObject = ref(this);
return S_OK;
}
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if (riid == __uuidof(ID3D11VkExtContext)) {
*ppvObject = ref(&m_contextExt);
return S_OK;
}
if (riid == __uuidof(ID3DUserDefinedAnnotation)) {
*ppvObject = ref(&m_annotation);
return S_OK;
}
if (riid == __uuidof(ID3D10Multithread)) {
*ppvObject = ref(&m_multithread);
return S_OK;
}
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Logger::warn("D3D11DeviceContext::QueryInterface: Unknown interface query");
Logger::warn(str::format(riid));
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return E_NOINTERFACE;
}
void STDMETHODCALLTYPE D3D11DeviceContext::DiscardResource(ID3D11Resource* pResource) {
D3D10DeviceLock lock = LockContext();
if (!pResource)
return;
// We don't support the Discard API for images
D3D11_RESOURCE_DIMENSION resType = D3D11_RESOURCE_DIMENSION_UNKNOWN;
pResource->GetType(&resType);
if (resType == D3D11_RESOURCE_DIMENSION_BUFFER)
DiscardBuffer(static_cast<D3D11Buffer*>(pResource));
else if (resType != D3D11_RESOURCE_DIMENSION_UNKNOWN)
DiscardTexture(GetCommonTexture(pResource));
}
void STDMETHODCALLTYPE D3D11DeviceContext::DiscardView(ID3D11View* pResourceView) {
D3D10DeviceLock lock = LockContext();
// ID3D11View has no methods to query the exact type of
// the view, so we'll have to check each possible class
auto dsv = dynamic_cast<D3D11DepthStencilView*>(pResourceView);
auto rtv = dynamic_cast<D3D11RenderTargetView*>(pResourceView);
auto uav = dynamic_cast<D3D11UnorderedAccessView*>(pResourceView);
Rc<DxvkImageView> view;
if (dsv) view = dsv->GetImageView();
if (rtv) view = rtv->GetImageView();
if (uav) view = uav->GetImageView();
if (view != nullptr) {
EmitCs([cView = std::move(view)]
(DxvkContext* ctx) {
ctx->discardImage(
cView->image(),
cView->subresources());
});
}
}
void STDMETHODCALLTYPE D3D11DeviceContext::DiscardView1(
ID3D11View* pResourceView,
const D3D11_RECT* pRects,
UINT NumRects) {
static bool s_errorShown = false;
if (!std::exchange(s_errorShown, true))
Logger::err("D3D11DeviceContext::DiscardView1: Not implemented");
}
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void STDMETHODCALLTYPE D3D11DeviceContext::GetDevice(ID3D11Device **ppDevice) {
*ppDevice = ref(m_parent);
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::ClearState() {
D3D10DeviceLock lock = LockContext();
// Default shaders
m_state.vs.shader = nullptr;
m_state.hs.shader = nullptr;
m_state.ds.shader = nullptr;
m_state.gs.shader = nullptr;
m_state.ps.shader = nullptr;
m_state.cs.shader = nullptr;
// Default constant buffers
for (uint32_t i = 0; i < D3D11_COMMONSHADER_CONSTANT_BUFFER_API_SLOT_COUNT; i++) {
m_state.vs.constantBuffers[i] = { nullptr, 0, 0 };
m_state.hs.constantBuffers[i] = { nullptr, 0, 0 };
m_state.ds.constantBuffers[i] = { nullptr, 0, 0 };
m_state.gs.constantBuffers[i] = { nullptr, 0, 0 };
m_state.ps.constantBuffers[i] = { nullptr, 0, 0 };
m_state.cs.constantBuffers[i] = { nullptr, 0, 0 };
}
// Default samplers
for (uint32_t i = 0; i < D3D11_COMMONSHADER_SAMPLER_SLOT_COUNT; i++) {
m_state.vs.samplers[i] = nullptr;
m_state.hs.samplers[i] = nullptr;
m_state.ds.samplers[i] = nullptr;
m_state.gs.samplers[i] = nullptr;
m_state.ps.samplers[i] = nullptr;
m_state.cs.samplers[i] = nullptr;
}
// Default shader resources
for (uint32_t i = 0; i < D3D11_COMMONSHADER_INPUT_RESOURCE_SLOT_COUNT; i++) {
m_state.vs.shaderResources.views[i] = nullptr;
m_state.hs.shaderResources.views[i] = nullptr;
m_state.ds.shaderResources.views[i] = nullptr;
m_state.gs.shaderResources.views[i] = nullptr;
m_state.ps.shaderResources.views[i] = nullptr;
m_state.cs.shaderResources.views[i] = nullptr;
}
m_state.vs.shaderResources.hazardous.clear();
m_state.hs.shaderResources.hazardous.clear();
m_state.ds.shaderResources.hazardous.clear();
m_state.gs.shaderResources.hazardous.clear();
m_state.ps.shaderResources.hazardous.clear();
m_state.cs.shaderResources.hazardous.clear();
// Default UAVs
for (uint32_t i = 0; i < D3D11_1_UAV_SLOT_COUNT; i++) {
m_state.ps.unorderedAccessViews[i] = nullptr;
m_state.cs.unorderedAccessViews[i] = nullptr;
}
m_state.cs.uavMask.clear();
// Default ID state
m_state.id.argBuffer = nullptr;
// Default IA state
m_state.ia.inputLayout = nullptr;
m_state.ia.primitiveTopology = D3D11_PRIMITIVE_TOPOLOGY_UNDEFINED;
for (uint32_t i = 0; i < D3D11_IA_VERTEX_INPUT_RESOURCE_SLOT_COUNT; i++) {
m_state.ia.vertexBuffers[i].buffer = nullptr;
m_state.ia.vertexBuffers[i].offset = 0;
m_state.ia.vertexBuffers[i].stride = 0;
}
m_state.ia.indexBuffer.buffer = nullptr;
m_state.ia.indexBuffer.offset = 0;
m_state.ia.indexBuffer.format = DXGI_FORMAT_UNKNOWN;
// Default OM State
for (uint32_t i = 0; i < D3D11_SIMULTANEOUS_RENDER_TARGET_COUNT; i++)
m_state.om.renderTargetViews[i] = nullptr;
m_state.om.depthStencilView = nullptr;
m_state.om.cbState = nullptr;
m_state.om.dsState = nullptr;
for (uint32_t i = 0; i < 4; i++)
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m_state.om.blendFactor[i] = 1.0f;
m_state.om.sampleMask = D3D11_DEFAULT_SAMPLE_MASK;
m_state.om.stencilRef = D3D11_DEFAULT_STENCIL_REFERENCE;
m_state.om.maxRtv = 0;
m_state.om.maxUav = 0;
// Default RS state
m_state.rs.state = nullptr;
m_state.rs.numViewports = 0;
m_state.rs.numScissors = 0;
for (uint32_t i = 0; i < D3D11_VIEWPORT_AND_SCISSORRECT_OBJECT_COUNT_PER_PIPELINE; i++) {
m_state.rs.viewports[i] = D3D11_VIEWPORT { };
m_state.rs.scissors [i] = D3D11_RECT { };
}
// Default SO state
for (uint32_t i = 0; i < D3D11_SO_BUFFER_SLOT_COUNT; i++) {
m_state.so.targets[i].buffer = nullptr;
m_state.so.targets[i].offset = 0;
}
// Default predication
m_state.pr.predicateObject = nullptr;
m_state.pr.predicateValue = FALSE;
// Make sure to apply all state
RestoreState();
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::Begin(ID3D11Asynchronous *pAsync) {
D3D10DeviceLock lock = LockContext();
if (unlikely(!pAsync))
return;
Com<D3D11Query, false> query(static_cast<D3D11Query*>(pAsync));
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EmitCs([cQuery = std::move(query)]
(DxvkContext* ctx) {
cQuery->Begin(ctx);
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});
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::End(ID3D11Asynchronous *pAsync) {
D3D10DeviceLock lock = LockContext();
if (unlikely(!pAsync))
return;
Com<D3D11Query, false> query(static_cast<D3D11Query*>(pAsync));
EmitCs([cQuery = std::move(query)]
(DxvkContext* ctx) {
cQuery->End(ctx);
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});
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::SetPredication(
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ID3D11Predicate* pPredicate,
BOOL PredicateValue) {
D3D10DeviceLock lock = LockContext();
auto predicate = static_cast<D3D11Query*>(pPredicate);
m_state.pr.predicateObject = predicate;
m_state.pr.predicateValue = PredicateValue;
static bool s_errorShown = false;
if (pPredicate && !std::exchange(s_errorShown, true))
Logger::err("D3D11DeviceContext::SetPredication: Stub");
// TODO: Figure out why this breaks Watch Dogs and crashes War Thunder
// if (!m_device->features().extConditionalRendering.conditionalRendering)
// return;
// EmitCs([
// cPredicate = Com<D3D11Query, false>(predicate),
// cValue = PredicateValue
// ] (DxvkContext* ctx) {
// DxvkBufferSlice predSlice;
// if (cPredicate != nullptr)
// predSlice = cPredicate->GetPredicate(ctx);
// ctx->setPredicate(predSlice,
// cValue ? VK_CONDITIONAL_RENDERING_INVERTED_BIT_EXT : 0);
// });
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::GetPredication(
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ID3D11Predicate** ppPredicate,
BOOL* pPredicateValue) {
D3D10DeviceLock lock = LockContext();
if (ppPredicate != nullptr)
*ppPredicate = m_state.pr.predicateObject.ref();
if (pPredicateValue != nullptr)
*pPredicateValue = m_state.pr.predicateValue;
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::CopySubresourceRegion(
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ID3D11Resource* pDstResource,
UINT DstSubresource,
UINT DstX,
UINT DstY,
UINT DstZ,
ID3D11Resource* pSrcResource,
UINT SrcSubresource,
const D3D11_BOX* pSrcBox) {
CopySubresourceRegion1(
pDstResource, DstSubresource, DstX, DstY, DstZ,
pSrcResource, SrcSubresource, pSrcBox, 0);
}
void STDMETHODCALLTYPE D3D11DeviceContext::CopySubresourceRegion1(
ID3D11Resource* pDstResource,
UINT DstSubresource,
UINT DstX,
UINT DstY,
UINT DstZ,
ID3D11Resource* pSrcResource,
UINT SrcSubresource,
const D3D11_BOX* pSrcBox,
UINT CopyFlags) {
D3D10DeviceLock lock = LockContext();
D3D11_RESOURCE_DIMENSION dstResourceDim = D3D11_RESOURCE_DIMENSION_UNKNOWN;
D3D11_RESOURCE_DIMENSION srcResourceDim = D3D11_RESOURCE_DIMENSION_UNKNOWN;
pDstResource->GetType(&dstResourceDim);
pSrcResource->GetType(&srcResourceDim);
// Copying 2D image slices to 3D images and vice versa is legal
const bool copy2Dto3D = dstResourceDim == D3D11_RESOURCE_DIMENSION_TEXTURE3D
&& srcResourceDim == D3D11_RESOURCE_DIMENSION_TEXTURE2D;
const bool copy3Dto2D = dstResourceDim == D3D11_RESOURCE_DIMENSION_TEXTURE2D
&& srcResourceDim == D3D11_RESOURCE_DIMENSION_TEXTURE3D;
if (dstResourceDim != srcResourceDim && !copy2Dto3D && !copy3Dto2D) {
Logger::err(str::format(
"D3D11: CopySubresourceRegion: Incompatible resources",
"\n Dst resource type: ", dstResourceDim,
"\n Src resource type: ", srcResourceDim));
return;
}
if (dstResourceDim == D3D11_RESOURCE_DIMENSION_BUFFER) {
auto dstBuffer = static_cast<D3D11Buffer*>(pDstResource)->GetBufferSlice();
auto srcBuffer = static_cast<D3D11Buffer*>(pSrcResource)->GetBufferSlice();
if (CopyFlags & D3D11_COPY_DISCARD)
DiscardBuffer(static_cast<D3D11Buffer*>(pDstResource));
VkDeviceSize dstOffset = DstX;
VkDeviceSize srcOffset = 0;
VkDeviceSize regLength = srcBuffer.length();
if (dstOffset >= dstBuffer.length())
return;
if (pSrcBox != nullptr) {
if (pSrcBox->left >= pSrcBox->right)
return; // no-op, but legal
srcOffset = pSrcBox->left;
regLength = pSrcBox->right - pSrcBox->left;
if (srcOffset >= srcBuffer.length())
return;
}
// Clamp copy region to prevent out-of-bounds access
regLength = std::min(regLength, srcBuffer.length() - srcOffset);
regLength = std::min(regLength, dstBuffer.length() - dstOffset);
EmitCs([
cDstSlice = dstBuffer.subSlice(dstOffset, regLength),
cSrcSlice = srcBuffer.subSlice(srcOffset, regLength)
] (DxvkContext* ctx) {
bool sameResource = cDstSlice.buffer() == cSrcSlice.buffer();
if (!sameResource) {
ctx->copyBuffer(
cDstSlice.buffer(),
cDstSlice.offset(),
cSrcSlice.buffer(),
cSrcSlice.offset(),
cSrcSlice.length());
} else {
ctx->copyBufferRegion(
cDstSlice.buffer(),
cDstSlice.offset(),
cSrcSlice.offset(),
cSrcSlice.length());
}
});
} else {
const D3D11CommonTexture* dstTextureInfo = GetCommonTexture(pDstResource);
const D3D11CommonTexture* srcTextureInfo = GetCommonTexture(pSrcResource);
const Rc<DxvkImage> dstImage = dstTextureInfo->GetImage();
const Rc<DxvkImage> srcImage = srcTextureInfo->GetImage();
const DxvkFormatInfo* dstFormatInfo = imageFormatInfo(dstImage->info().format);
const DxvkFormatInfo* srcFormatInfo = imageFormatInfo(srcImage->info().format);
const VkImageSubresource dstSubresource = dstTextureInfo->GetSubresourceFromIndex(dstFormatInfo->aspectMask, DstSubresource);
const VkImageSubresource srcSubresource = srcTextureInfo->GetSubresourceFromIndex(srcFormatInfo->aspectMask, SrcSubresource);
// Copies are only supported on size-compatible formats
if (dstFormatInfo->elementSize != srcFormatInfo->elementSize) {
Logger::err(str::format(
"D3D11: CopySubresourceRegion: Incompatible texel size"
"\n Dst texel size: ", dstFormatInfo->elementSize,
"\n Src texel size: ", srcFormatInfo->elementSize));
return;
}
// Copies are only supported if the sample count matches
if (dstImage->info().sampleCount != srcImage->info().sampleCount) {
Logger::err(str::format(
"D3D11: CopySubresourceRegion: Incompatible sample count",
"\n Dst sample count: ", dstImage->info().sampleCount,
"\n Src sample count: ", srcImage->info().sampleCount));
return;
}
VkOffset3D srcOffset = { 0, 0, 0 };
VkOffset3D dstOffset = { int32_t(DstX), int32_t(DstY), int32_t(DstZ) };
VkExtent3D srcExtent = srcImage->mipLevelExtent(srcSubresource.mipLevel);
VkExtent3D dstExtent = dstImage->mipLevelExtent(dstSubresource.mipLevel);
VkExtent3D regExtent = srcExtent;
if (uint32_t(dstOffset.x) >= dstExtent.width
|| uint32_t(dstOffset.y) >= dstExtent.height
|| uint32_t(dstOffset.z) >= dstExtent.depth)
return;
if (pSrcBox != nullptr) {
if (pSrcBox->left >= pSrcBox->right
|| pSrcBox->top >= pSrcBox->bottom
|| pSrcBox->front >= pSrcBox->back)
return; // no-op, but legal
srcOffset.x = pSrcBox->left;
srcOffset.y = pSrcBox->top;
srcOffset.z = pSrcBox->front;
regExtent.width = pSrcBox->right - pSrcBox->left;
regExtent.height = pSrcBox->bottom - pSrcBox->top;
regExtent.depth = pSrcBox->back - pSrcBox->front;
if (uint32_t(srcOffset.x) >= srcExtent.width
|| uint32_t(srcOffset.y) >= srcExtent.height
|| uint32_t(srcOffset.z) >= srcExtent.depth)
return;
}
VkImageSubresourceLayers dstLayers = {
dstSubresource.aspectMask,
dstSubresource.mipLevel,
dstSubresource.arrayLayer, 1 };
VkImageSubresourceLayers srcLayers = {
srcSubresource.aspectMask,
srcSubresource.mipLevel,
srcSubresource.arrayLayer, 1 };
// Copying multiple slices does not
// seem to be supported in D3D11
if (copy2Dto3D || copy3Dto2D) {
regExtent.depth = 1;
dstLayers.layerCount = 1;
srcLayers.layerCount = 1;
}
// Don't perform the copy if the offsets aren't aligned
if (!util::isBlockAligned(srcOffset, srcFormatInfo->blockSize)
|| !util::isBlockAligned(dstOffset, dstFormatInfo->blockSize)) {
Logger::err(str::format(
"D3D11: CopySubresourceRegion: Unaligned block offset",
"\n Src offset: (", srcOffset.x, ",", srcOffset.y, ",", srcOffset.z, ")",
"\n Src block size: (", srcFormatInfo->blockSize.width, "x", srcFormatInfo->blockSize.height, "x", srcFormatInfo->blockSize.depth, ")",
"\n Dst offset: (", dstOffset.x, ",", dstOffset.y, ",", dstOffset.z, ")",
"\n Dst block size: (", dstFormatInfo->blockSize.width, "x", dstFormatInfo->blockSize.height, "x", dstFormatInfo->blockSize.depth, ")"));
return;
}
// Clamp the image region in order to avoid out-of-bounds access
VkExtent3D regBlockCount = util::computeBlockCount(regExtent, srcFormatInfo->blockSize);
VkExtent3D dstBlockCount = util::computeMaxBlockCount(dstOffset, dstExtent, dstFormatInfo->blockSize);
VkExtent3D srcBlockCount = util::computeMaxBlockCount(srcOffset, srcExtent, srcFormatInfo->blockSize);
regBlockCount = util::minExtent3D(regBlockCount, dstBlockCount);
regBlockCount = util::minExtent3D(regBlockCount, srcBlockCount);
regExtent = util::minExtent3D(regExtent, util::computeBlockExtent(regBlockCount, srcFormatInfo->blockSize));
// Don't perform the copy if the image extent is not aligned and
// if it does not touch the image border for unaligned dimensons
if (!util::isBlockAligned(srcOffset, regExtent, srcFormatInfo->blockSize, srcExtent)) {
Logger::err(str::format(
"D3D11: CopySubresourceRegion: Unaligned block size",
"\n Src offset: (", srcOffset.x, ",", srcOffset.y, ",", srcOffset.z, ")",
"\n Src extent: (", srcExtent.width, "x", srcExtent.height, "x", srcExtent.depth, ")",
"\n Src block size: (", srcFormatInfo->blockSize.width, "x", srcFormatInfo->blockSize.height, "x", srcFormatInfo->blockSize.depth, ")",
"\n Dst offset: (", dstOffset.x, ",", dstOffset.y, ",", dstOffset.z, ")",
"\n Dst extent: (", dstExtent.width, "x", dstExtent.height, "x", dstExtent.depth, ")",
"\n Dst block size: (", dstFormatInfo->blockSize.width, "x", dstFormatInfo->blockSize.height, "x", dstFormatInfo->blockSize.depth, ")",
"\n Region extent: (", regExtent.width, "x", regExtent.height, "x", regExtent.depth, ")"));
return;
}
EmitCs([
cDstImage = dstImage,
cSrcImage = srcImage,
cDstLayers = dstLayers,
cSrcLayers = srcLayers,
cDstOffset = dstOffset,
cSrcOffset = srcOffset,
cExtent = regExtent
] (DxvkContext* ctx) {
bool sameSubresource = cDstImage == cSrcImage
&& cDstLayers == cSrcLayers;
if (!sameSubresource) {
ctx->copyImage(
cDstImage, cDstLayers, cDstOffset,
cSrcImage, cSrcLayers, cSrcOffset,
cExtent);
} else {
ctx->copyImageRegion(
cDstImage, cDstLayers,
cDstOffset, cSrcOffset,
cExtent);
}
});
if (dstTextureInfo->CanUpdateMappedBufferEarly())
UpdateMappedBuffer(dstTextureInfo, dstSubresource);
}
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::CopyResource(
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ID3D11Resource* pDstResource,
ID3D11Resource* pSrcResource) {
D3D10DeviceLock lock = LockContext();
if (!pDstResource || !pSrcResource || (pDstResource == pSrcResource))
return;
D3D11_RESOURCE_DIMENSION dstResourceDim = D3D11_RESOURCE_DIMENSION_UNKNOWN;
D3D11_RESOURCE_DIMENSION srcResourceDim = D3D11_RESOURCE_DIMENSION_UNKNOWN;
pDstResource->GetType(&dstResourceDim);
pSrcResource->GetType(&srcResourceDim);
if (dstResourceDim != srcResourceDim) {
Logger::err(str::format(
"D3D11: CopyResource: Incompatible resources",
"\n Dst resource type: ", dstResourceDim,
"\n Src resource type: ", srcResourceDim));
return;
}
if (dstResourceDim == D3D11_RESOURCE_DIMENSION_BUFFER) {
auto dstBuffer = static_cast<D3D11Buffer*>(pDstResource)->GetBufferSlice();
auto srcBuffer = static_cast<D3D11Buffer*>(pSrcResource)->GetBufferSlice();
if (dstBuffer.length() != srcBuffer.length()) {
Logger::err(str::format(
"D3D11: CopyResource: Mismatched buffer size",
"\n Dst buffer size: ", dstBuffer.length(),
"\n Src buffer size: ", srcBuffer.length()));
return;
}
EmitCs([
cDstBuffer = std::move(dstBuffer),
cSrcBuffer = std::move(srcBuffer)
] (DxvkContext* ctx) {
ctx->copyBuffer(
cDstBuffer.buffer(),
cDstBuffer.offset(),
cSrcBuffer.buffer(),
cSrcBuffer.offset(),
cSrcBuffer.length());
});
} else {
auto dstTexture = GetCommonTexture(pDstResource);
auto srcTexture = GetCommonTexture(pSrcResource);
const Rc<DxvkImage> dstImage = dstTexture->GetImage();
const Rc<DxvkImage> srcImage = srcTexture->GetImage();
const DxvkFormatInfo* dstFormatInfo = imageFormatInfo(dstImage->info().format);
const DxvkFormatInfo* srcFormatInfo = imageFormatInfo(srcImage->info().format);
// Copies are only supported on size-compatible formats
if (dstFormatInfo->elementSize != srcFormatInfo->elementSize) {
Logger::err(str::format(
"D3D11: CopyResource: Incompatible texel size"
"\n Dst texel size: ", dstFormatInfo->elementSize,
"\n Src texel size: ", srcFormatInfo->elementSize));
return;
}
// Layer count, mip level count, and sample count must match
if (srcImage->info().numLayers != dstImage->info().numLayers
|| srcImage->info().mipLevels != dstImage->info().mipLevels
|| srcImage->info().sampleCount != dstImage->info().sampleCount) {
Logger::err(str::format(
"D3D11: CopyResource: Incompatible images"
"\n Dst: (", dstImage->info().numLayers,
",", dstImage->info().mipLevels,
",", dstImage->info().sampleCount, ")",
"\n Src: (", srcImage->info().numLayers,
",", srcImage->info().mipLevels,
",", srcImage->info().sampleCount, ")"));
return;
}
for (uint32_t i = 0; i < srcImage->info().mipLevels; i++) {
VkImageSubresourceLayers dstLayers = { dstFormatInfo->aspectMask, i, 0, dstImage->info().numLayers };
VkImageSubresourceLayers srcLayers = { srcFormatInfo->aspectMask, i, 0, srcImage->info().numLayers };
VkExtent3D extent = srcImage->mipLevelExtent(i);
EmitCs([
cDstImage = dstImage,
cSrcImage = srcImage,
cDstLayers = dstLayers,
cSrcLayers = srcLayers,
cExtent = extent
] (DxvkContext* ctx) {
ctx->copyImage(
cDstImage, cDstLayers, VkOffset3D { 0, 0, 0 },
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cSrcImage, cSrcLayers, VkOffset3D { 0, 0, 0 },
cExtent);
});
if (dstTexture->CanUpdateMappedBufferEarly()) {
for (uint32_t j = 0; j < dstImage->info().numLayers; j++)
UpdateMappedBuffer(dstTexture, { dstLayers.aspectMask, i, j });
}
}
}
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::CopyStructureCount(
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ID3D11Buffer* pDstBuffer,
UINT DstAlignedByteOffset,
ID3D11UnorderedAccessView* pSrcView) {
D3D10DeviceLock lock = LockContext();
auto buf = static_cast<D3D11Buffer*>(pDstBuffer);
auto uav = static_cast<D3D11UnorderedAccessView*>(pSrcView);
if (!buf || !uav)
return;
auto counterSlice = uav->GetCounterSlice();
if (!counterSlice.defined())
return;
EmitCs([
cDstSlice = buf->GetBufferSlice(DstAlignedByteOffset),
cSrcSlice = std::move(counterSlice)
] (DxvkContext* ctx) {
ctx->copyBuffer(
cDstSlice.buffer(),
cDstSlice.offset(),
cSrcSlice.buffer(),
cSrcSlice.offset(),
sizeof(uint32_t));
});
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::ClearRenderTargetView(
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ID3D11RenderTargetView* pRenderTargetView,
const FLOAT ColorRGBA[4]) {
D3D10DeviceLock lock = LockContext();
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auto rtv = static_cast<D3D11RenderTargetView*>(pRenderTargetView);
if (!rtv)
return;
auto view = rtv->GetImageView();
auto color = ConvertColorValue(ColorRGBA, view->formatInfo());
EmitCs([
cClearValue = color,
cImageView = std::move(view)
] (DxvkContext* ctx) {
ctx->clearRenderTarget(
cImageView,
VK_IMAGE_ASPECT_COLOR_BIT,
cClearValue);
});
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::ClearUnorderedAccessViewUint(
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ID3D11UnorderedAccessView* pUnorderedAccessView,
const UINT Values[4]) {
D3D10DeviceLock lock = LockContext();
auto uav = static_cast<D3D11UnorderedAccessView*>(pUnorderedAccessView);
if (!uav)
return;
// Gather UAV format info. We'll use this to determine
// whether we need to create a temporary view or not.
D3D11_UNORDERED_ACCESS_VIEW_DESC uavDesc;
uav->GetDesc(&uavDesc);
VkFormat uavFormat = m_parent->LookupFormat(uavDesc.Format, DXGI_VK_FORMAT_MODE_ANY).Format;
VkFormat rawFormat = m_parent->LookupFormat(uavDesc.Format, DXGI_VK_FORMAT_MODE_RAW).Format;
if (uavFormat != rawFormat && rawFormat == VK_FORMAT_UNDEFINED) {
Logger::err(str::format("D3D11: ClearUnorderedAccessViewUint: No raw format found for ", uavFormat));
return;
}
// Set up clear color struct
VkClearValue clearValue;
clearValue.color.uint32[0] = Values[0];
clearValue.color.uint32[1] = Values[1];
clearValue.color.uint32[2] = Values[2];
clearValue.color.uint32[3] = Values[3];
// This is the only packed format that has UAV support
if (uavFormat == VK_FORMAT_B10G11R11_UFLOAT_PACK32) {
clearValue.color.uint32[0] = ((Values[0] & 0x7FF) << 0)
| ((Values[1] & 0x7FF) << 11)
| ((Values[2] & 0x3FF) << 22);
}
if (uav->GetResourceType() == D3D11_RESOURCE_DIMENSION_BUFFER) {
// In case of raw and structured buffers as well as typed
// buffers that can be used for atomic operations, we can
// use the fast Vulkan buffer clear function.
Rc<DxvkBufferView> bufferView = uav->GetBufferView();
if (bufferView->info().format == VK_FORMAT_R32_UINT
|| bufferView->info().format == VK_FORMAT_R32_SINT
|| bufferView->info().format == VK_FORMAT_R32_SFLOAT) {
EmitCs([
cClearValue = Values[0],
cDstSlice = bufferView->slice()
] (DxvkContext* ctx) {
ctx->clearBuffer(
cDstSlice.buffer(),
cDstSlice.offset(),
cDstSlice.length(),
cClearValue);
});
} else {
// Create a view with an integer format if necessary
if (uavFormat != rawFormat) {
DxvkBufferViewCreateInfo info = bufferView->info();
info.format = rawFormat;
bufferView = m_device->createBufferView(
bufferView->buffer(), info);
}
EmitCs([
cClearValue = clearValue,
cDstView = bufferView
] (DxvkContext* ctx) {
ctx->clearBufferView(
cDstView, 0,
cDstView->elementCount(),
cClearValue.color);
});
}
} else {
// Create a view with an integer format if necessary
Rc<DxvkImageView> imageView = uav->GetImageView();
if (uavFormat != rawFormat) {
DxvkImageViewCreateInfo info = imageView->info();
info.format = rawFormat;
imageView = m_device->createImageView(
imageView->image(), info);
}
EmitCs([
cClearValue = clearValue,
cDstView = imageView
] (DxvkContext* ctx) {
ctx->clearImageView(cDstView,
VkOffset3D { 0, 0, 0 },
cDstView->mipLevelExtent(0),
VK_IMAGE_ASPECT_COLOR_BIT,
cClearValue);
});
}
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::ClearUnorderedAccessViewFloat(
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ID3D11UnorderedAccessView* pUnorderedAccessView,
const FLOAT Values[4]) {
D3D10DeviceLock lock = LockContext();
auto uav = static_cast<D3D11UnorderedAccessView*>(pUnorderedAccessView);
if (!uav)
return;
auto imgView = uav->GetImageView();
auto bufView = uav->GetBufferView();
const DxvkFormatInfo* info = nullptr;
if (imgView != nullptr) info = imgView->formatInfo();
if (bufView != nullptr) info = bufView->formatInfo();
if (!info || info->flags.any(DxvkFormatFlag::SampledSInt, DxvkFormatFlag::SampledUInt))
return;
VkClearValue clearValue;
clearValue.color.float32[0] = Values[0];
clearValue.color.float32[1] = Values[1];
clearValue.color.float32[2] = Values[2];
clearValue.color.float32[3] = Values[3];
if (uav->GetResourceType() == D3D11_RESOURCE_DIMENSION_BUFFER) {
EmitCs([
cClearValue = clearValue,
cDstView = std::move(bufView)
] (DxvkContext* ctx) {
ctx->clearBufferView(
cDstView, 0,
cDstView->elementCount(),
cClearValue.color);
});
} else {
EmitCs([
cClearValue = clearValue,
cDstView = std::move(imgView)
] (DxvkContext* ctx) {
ctx->clearImageView(cDstView,
VkOffset3D { 0, 0, 0 },
cDstView->mipLevelExtent(0),
VK_IMAGE_ASPECT_COLOR_BIT,
cClearValue);
});
}
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::ClearDepthStencilView(
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ID3D11DepthStencilView* pDepthStencilView,
UINT ClearFlags,
FLOAT Depth,
UINT8 Stencil) {
D3D10DeviceLock lock = LockContext();
auto dsv = static_cast<D3D11DepthStencilView*>(pDepthStencilView);
if (!dsv)
return;
// Figure out which aspects to clear based on
// the image view properties and clear flags.
VkImageAspectFlags aspectMask = 0;
if (ClearFlags & D3D11_CLEAR_DEPTH)
aspectMask |= VK_IMAGE_ASPECT_DEPTH_BIT;
if (ClearFlags & D3D11_CLEAR_STENCIL)
aspectMask |= VK_IMAGE_ASPECT_STENCIL_BIT;
aspectMask &= dsv->GetWritableAspectMask();
if (!aspectMask)
return;
VkClearValue clearValue;
clearValue.depthStencil.depth = Depth;
clearValue.depthStencil.stencil = Stencil;
EmitCs([
cClearValue = clearValue,
cAspectMask = aspectMask,
cImageView = dsv->GetImageView()
] (DxvkContext* ctx) {
ctx->clearRenderTarget(
cImageView,
cAspectMask,
cClearValue);
});
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}
void STDMETHODCALLTYPE D3D11DeviceContext::ClearView(
ID3D11View* pView,
const FLOAT Color[4],
const D3D11_RECT* pRect,
UINT NumRects) {
D3D10DeviceLock lock = LockContext();
// ID3D11View has no methods to query the exact type of
// the view, so we'll have to check each possible class
auto dsv = dynamic_cast<D3D11DepthStencilView*>(pView);
auto rtv = dynamic_cast<D3D11RenderTargetView*>(pView);
auto uav = dynamic_cast<D3D11UnorderedAccessView*>(pView);
// Retrieve underlying resource view
Rc<DxvkBufferView> bufView;
Rc<DxvkImageView> imgView;
if (dsv != nullptr)
imgView = dsv->GetImageView();
if (rtv != nullptr)
imgView = rtv->GetImageView();
if (uav != nullptr) {
bufView = uav->GetBufferView();
imgView = uav->GetImageView();
}
// 3D views are unsupported
if (imgView != nullptr
&& imgView->info().type == VK_IMAGE_VIEW_TYPE_3D)
return;
// Query the view format. We'll have to convert
// the clear color based on the format's data type.
VkFormat format = VK_FORMAT_UNDEFINED;
if (bufView != nullptr)
format = bufView->info().format;
if (imgView != nullptr)
format = imgView->info().format;
if (format == VK_FORMAT_UNDEFINED)
return;
// We'll need the format info to determine the buffer
// element size, and we also need it for depth images.
const DxvkFormatInfo* formatInfo = imageFormatInfo(format);
// Convert the clear color format. ClearView takes
// the clear value for integer formats as a set of
// integral floats, so we'll have to convert.
VkClearValue clearValue = ConvertColorValue(Color, formatInfo);
VkImageAspectFlags clearAspect = formatInfo->aspectMask & (VK_IMAGE_ASPECT_COLOR_BIT | VK_IMAGE_ASPECT_DEPTH_BIT);
// Clear all the rectangles that are specified
for (uint32_t i = 0; i < NumRects; i++) {
if (pRect[i].left >= pRect[i].right
|| pRect[i].top >= pRect[i].bottom)
continue;
if (bufView != nullptr) {
VkDeviceSize offset = pRect[i].left;
VkDeviceSize length = pRect[i].right - pRect[i].left;
EmitCs([
cBufferView = bufView,
cRangeOffset = offset,
cRangeLength = length,
cClearValue = clearValue
] (DxvkContext* ctx) {
ctx->clearBufferView(
cBufferView,
cRangeOffset,
cRangeLength,
cClearValue.color);
});
}
if (imgView != nullptr) {
VkOffset3D offset = { pRect[i].left, pRect[i].top, 0 };
VkExtent3D extent = {
uint32_t(pRect[i].right - pRect[i].left),
uint32_t(pRect[i].bottom - pRect[i].top), 1 };
EmitCs([
cImageView = imgView,
cAreaOffset = offset,
cAreaExtent = extent,
cClearAspect = clearAspect,
cClearValue = clearValue
] (DxvkContext* ctx) {
ctx->clearImageView(
cImageView,
cAreaOffset,
cAreaExtent,
cClearAspect,
cClearValue);
});
}
}
// The rect array is optional, so if it is not
// specified, we'll have to clear the entire view
if (pRect == nullptr) {
if (bufView != nullptr) {
EmitCs([
cBufferView = bufView,
cClearValue = clearValue,
cElementSize = formatInfo->elementSize
] (DxvkContext* ctx) {
ctx->clearBufferView(cBufferView,
cBufferView->info().rangeOffset / cElementSize,
cBufferView->info().rangeLength / cElementSize,
cClearValue.color);
});
}
if (imgView != nullptr) {
EmitCs([
cImageView = imgView,
cClearAspect = clearAspect,
cClearValue = clearValue
] (DxvkContext* ctx) {
VkOffset3D offset = { 0, 0, 0 };
VkExtent3D extent = cImageView->mipLevelExtent(0);
ctx->clearImageView(
cImageView,
offset, extent,
cClearAspect,
cClearValue);
});
}
}
}
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void STDMETHODCALLTYPE D3D11DeviceContext::GenerateMips(ID3D11ShaderResourceView* pShaderResourceView) {
D3D10DeviceLock lock = LockContext();
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auto view = static_cast<D3D11ShaderResourceView*>(pShaderResourceView);
if (!view || view->GetResourceType() == D3D11_RESOURCE_DIMENSION_BUFFER)
return;
D3D11_COMMON_RESOURCE_DESC resourceDesc = view->GetResourceDesc();
if (!(resourceDesc.MiscFlags & D3D11_RESOURCE_MISC_GENERATE_MIPS))
return;
EmitCs([cDstImageView = view->GetImageView()]
(DxvkContext* ctx) {
ctx->generateMipmaps(cDstImageView);
});
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::UpdateSubresource(
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ID3D11Resource* pDstResource,
UINT DstSubresource,
const D3D11_BOX* pDstBox,
const void* pSrcData,
UINT SrcRowPitch,
UINT SrcDepthPitch) {
UpdateSubresource1(pDstResource,
DstSubresource, pDstBox, pSrcData,
SrcRowPitch, SrcDepthPitch, 0);
}
void STDMETHODCALLTYPE D3D11DeviceContext::UpdateSubresource1(
ID3D11Resource* pDstResource,
UINT DstSubresource,
const D3D11_BOX* pDstBox,
const void* pSrcData,
UINT SrcRowPitch,
UINT SrcDepthPitch,
UINT CopyFlags) {
D3D10DeviceLock lock = LockContext();
if (!pDstResource)
return;
// Filter out invalid copy flags
CopyFlags &= D3D11_COPY_NO_OVERWRITE | D3D11_COPY_DISCARD;
// We need a different code path for buffers
D3D11_RESOURCE_DIMENSION resourceType;
pDstResource->GetType(&resourceType);
if (resourceType == D3D11_RESOURCE_DIMENSION_BUFFER) {
const auto bufferResource = static_cast<D3D11Buffer*>(pDstResource);
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const auto bufferSlice = bufferResource->GetBufferSlice();
VkDeviceSize offset = bufferSlice.offset();
VkDeviceSize size = bufferSlice.length();
if (pDstBox != nullptr) {
offset = pDstBox->left;
size = pDstBox->right - pDstBox->left;
}
if (!size || offset + size > bufferSlice.length())
return;
bool useMap = (bufferSlice.buffer()->memFlags() & VK_MEMORY_PROPERTY_HOST_VISIBLE_BIT)
&& (size == bufferSlice.length() || CopyFlags);
if (useMap) {
D3D11_MAP mapType = (CopyFlags & D3D11_COPY_NO_OVERWRITE)
? D3D11_MAP_WRITE_NO_OVERWRITE
: D3D11_MAP_WRITE_DISCARD;
D3D11_MAPPED_SUBRESOURCE mappedSr;
Map(pDstResource, 0, mapType, 0, &mappedSr);
std::memcpy(reinterpret_cast<char*>(mappedSr.pData) + offset, pSrcData, size);
Unmap(pDstResource, 0);
} else {
if (CopyFlags & D3D11_COPY_DISCARD)
DiscardBuffer(bufferResource);
DxvkDataSlice dataSlice = AllocUpdateBufferSlice(size);
std::memcpy(dataSlice.ptr(), pSrcData, size);
EmitCs([
cDataBuffer = std::move(dataSlice),
cBufferSlice = bufferSlice.subSlice(offset, size)
] (DxvkContext* ctx) {
ctx->updateBuffer(
cBufferSlice.buffer(),
cBufferSlice.offset(),
cBufferSlice.length(),
cDataBuffer.ptr());
});
}
} else {
const D3D11CommonTexture* textureInfo = GetCommonTexture(pDstResource);
VkFormat packedFormat = m_parent->LookupPackedFormat(
textureInfo->Desc()->Format,
textureInfo->GetFormatMode()).Format;
auto formatInfo = imageFormatInfo(packedFormat);
auto subresource = textureInfo->GetSubresourceFromIndex(
formatInfo->aspectMask, DstSubresource);
VkExtent3D mipExtent = textureInfo->GetImage()->mipLevelExtent(subresource.mipLevel);
VkOffset3D offset = { 0, 0, 0 };
VkExtent3D extent = mipExtent;
if (pDstBox != nullptr) {
if (pDstBox->left >= pDstBox->right
|| pDstBox->top >= pDstBox->bottom
|| pDstBox->front >= pDstBox->back)
return; // no-op, but legal
offset.x = pDstBox->left;
offset.y = pDstBox->top;
offset.z = pDstBox->front;
extent.width = pDstBox->right - pDstBox->left;
extent.height = pDstBox->bottom - pDstBox->top;
extent.depth = pDstBox->back - pDstBox->front;
}
const VkImageSubresourceLayers layers = {
subresource.aspectMask,
subresource.mipLevel,
subresource.arrayLayer, 1 };
if (!util::isBlockAligned(offset, formatInfo->blockSize)
|| !util::isBlockAligned(offset, extent, formatInfo->blockSize, mipExtent))
return;
const VkExtent3D regionExtent = util::computeBlockCount(extent, formatInfo->blockSize);
const VkDeviceSize bytesPerRow = regionExtent.width * formatInfo->elementSize;
const VkDeviceSize bytesPerLayer = regionExtent.height * bytesPerRow;
const VkDeviceSize bytesTotal = regionExtent.depth * bytesPerLayer;
DxvkDataSlice imageDataBuffer = AllocUpdateBufferSlice(bytesTotal);
util::packImageData(imageDataBuffer.ptr(), pSrcData,
regionExtent, formatInfo->elementSize,
SrcRowPitch, SrcDepthPitch);
EmitCs([
cDstImage = textureInfo->GetImage(),
cDstLayers = layers,
cDstOffset = offset,
cDstExtent = extent,
cSrcData = std::move(imageDataBuffer),
cSrcBytesPerRow = bytesPerRow,
cSrcBytesPerLayer = bytesPerLayer,
cPackedFormat = packedFormat
] (DxvkContext* ctx) {
if (cDstLayers.aspectMask != (VK_IMAGE_ASPECT_DEPTH_BIT | VK_IMAGE_ASPECT_STENCIL_BIT)) {
ctx->updateImage(cDstImage, cDstLayers,
cDstOffset, cDstExtent, cSrcData.ptr(),
cSrcBytesPerRow, cSrcBytesPerLayer);
} else {
ctx->updateDepthStencilImage(cDstImage, cDstLayers,
VkOffset2D { cDstOffset.x, cDstOffset.y },
VkExtent2D { cDstExtent.width, cDstExtent.height },
cSrcData.ptr(), cSrcBytesPerRow, cSrcBytesPerLayer,
cPackedFormat);
}
});
if (textureInfo->CanUpdateMappedBufferEarly())
UpdateMappedBuffer(textureInfo, subresource);
}
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::SetResourceMinLOD(
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ID3D11Resource* pResource,
FLOAT MinLOD) {
Logger::err("D3D11DeviceContext::SetResourceMinLOD: Not implemented");
}
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FLOAT STDMETHODCALLTYPE D3D11DeviceContext::GetResourceMinLOD(ID3D11Resource* pResource) {
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Logger::err("D3D11DeviceContext::GetResourceMinLOD: Not implemented");
return 0.0f;
}
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void STDMETHODCALLTYPE D3D11DeviceContext::ResolveSubresource(
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ID3D11Resource* pDstResource,
UINT DstSubresource,
ID3D11Resource* pSrcResource,
UINT SrcSubresource,
DXGI_FORMAT Format) {
D3D10DeviceLock lock = LockContext();
bool isSameSubresource = pDstResource == pSrcResource
&& DstSubresource == SrcSubresource;
if (!pDstResource || !pSrcResource || isSameSubresource)
return;
D3D11_RESOURCE_DIMENSION dstResourceType;
D3D11_RESOURCE_DIMENSION srcResourceType;
pDstResource->GetType(&dstResourceType);
pSrcResource->GetType(&srcResourceType);
if (dstResourceType != D3D11_RESOURCE_DIMENSION_TEXTURE2D
|| srcResourceType != D3D11_RESOURCE_DIMENSION_TEXTURE2D) {
Logger::err(str::format(
"D3D11: ResolveSubresource: Incompatible resources",
"\n Dst resource type: ", dstResourceType,
"\n Src resource type: ", srcResourceType));
return;
}
auto dstTexture = static_cast<D3D11Texture2D*>(pDstResource);
auto srcTexture = static_cast<D3D11Texture2D*>(pSrcResource);
D3D11_TEXTURE2D_DESC dstDesc;
D3D11_TEXTURE2D_DESC srcDesc;
dstTexture->GetDesc(&dstDesc);
srcTexture->GetDesc(&srcDesc);
if (dstDesc.SampleDesc.Count != 1) {
Logger::err(str::format(
"D3D11: ResolveSubresource: Invalid sample counts",
"\n Dst sample count: ", dstDesc.SampleDesc.Count,
"\n Src sample count: ", srcDesc.SampleDesc.Count));
return;
}
const D3D11CommonTexture* dstTextureInfo = GetCommonTexture(pDstResource);
const D3D11CommonTexture* srcTextureInfo = GetCommonTexture(pSrcResource);
const DXGI_VK_FORMAT_INFO dstFormatInfo = m_parent->LookupFormat(dstDesc.Format, DXGI_VK_FORMAT_MODE_ANY);
const DXGI_VK_FORMAT_INFO srcFormatInfo = m_parent->LookupFormat(srcDesc.Format, DXGI_VK_FORMAT_MODE_ANY);
auto dstVulkanFormatInfo = imageFormatInfo(dstFormatInfo.Format);
auto srcVulkanFormatInfo = imageFormatInfo(srcFormatInfo.Format);
const VkImageSubresource dstSubresource =
dstTextureInfo->GetSubresourceFromIndex(
dstVulkanFormatInfo->aspectMask, DstSubresource);
const VkImageSubresource srcSubresource =
srcTextureInfo->GetSubresourceFromIndex(
srcVulkanFormatInfo->aspectMask, SrcSubresource);
const VkImageSubresourceLayers dstSubresourceLayers = {
dstSubresource.aspectMask,
dstSubresource.mipLevel,
dstSubresource.arrayLayer, 1 };
const VkImageSubresourceLayers srcSubresourceLayers = {
srcSubresource.aspectMask,
srcSubresource.mipLevel,
srcSubresource.arrayLayer, 1 };
if (srcDesc.SampleDesc.Count == 1) {
EmitCs([
cDstImage = dstTextureInfo->GetImage(),
cSrcImage = srcTextureInfo->GetImage(),
cDstLayers = dstSubresourceLayers,
cSrcLayers = srcSubresourceLayers
] (DxvkContext* ctx) {
ctx->copyImage(
cDstImage, cDstLayers, VkOffset3D { 0, 0, 0 },
cSrcImage, cSrcLayers, VkOffset3D { 0, 0, 0 },
cDstImage->mipLevelExtent(cDstLayers.mipLevel));
});
} else {
const VkFormat format = m_parent->LookupFormat(
Format, DXGI_VK_FORMAT_MODE_ANY).Format;
EmitCs([
cDstImage = dstTextureInfo->GetImage(),
cSrcImage = srcTextureInfo->GetImage(),
cDstSubres = dstSubresourceLayers,
cSrcSubres = srcSubresourceLayers,
cFormat = format
] (DxvkContext* ctx) {
VkImageResolve region;
region.srcSubresource = cSrcSubres;
region.srcOffset = VkOffset3D { 0, 0, 0 };
region.dstSubresource = cDstSubres;
region.dstOffset = VkOffset3D { 0, 0, 0 };
region.extent = cDstImage->mipLevelExtent(cDstSubres.mipLevel);
ctx->resolveImage(cDstImage, cSrcImage, region, cFormat);
});
}
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::DrawAuto() {
D3D10DeviceLock lock = LockContext();
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D3D11Buffer* buffer = m_state.ia.vertexBuffers[0].buffer.ptr();
if (buffer == nullptr)
return;
DxvkBufferSlice vtxBuf = buffer->GetBufferSlice();
DxvkBufferSlice ctrBuf = buffer->GetSOCounter();
if (!ctrBuf.defined())
return;
EmitCs([=] (DxvkContext* ctx) {
ctx->drawIndirectXfb(ctrBuf,
vtxBuf.buffer()->getXfbVertexStride(),
vtxBuf.offset());
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});
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::Draw(
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UINT VertexCount,
UINT StartVertexLocation) {
D3D10DeviceLock lock = LockContext();
EmitCs([=] (DxvkContext* ctx) {
ctx->draw(
VertexCount, 1,
StartVertexLocation, 0);
});
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::DrawIndexed(
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UINT IndexCount,
UINT StartIndexLocation,
INT BaseVertexLocation) {
D3D10DeviceLock lock = LockContext();
EmitCs([=] (DxvkContext* ctx) {
ctx->drawIndexed(
IndexCount, 1,
StartIndexLocation,
BaseVertexLocation, 0);
});
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::DrawInstanced(
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UINT VertexCountPerInstance,
UINT InstanceCount,
UINT StartVertexLocation,
UINT StartInstanceLocation) {
D3D10DeviceLock lock = LockContext();
EmitCs([=] (DxvkContext* ctx) {
ctx->draw(
VertexCountPerInstance,
InstanceCount,
StartVertexLocation,
StartInstanceLocation);
});
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::DrawIndexedInstanced(
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UINT IndexCountPerInstance,
UINT InstanceCount,
UINT StartIndexLocation,
INT BaseVertexLocation,
UINT StartInstanceLocation) {
D3D10DeviceLock lock = LockContext();
EmitCs([=] (DxvkContext* ctx) {
ctx->drawIndexed(
IndexCountPerInstance,
InstanceCount,
StartIndexLocation,
BaseVertexLocation,
StartInstanceLocation);
});
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::DrawIndexedInstancedIndirect(
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ID3D11Buffer* pBufferForArgs,
UINT AlignedByteOffsetForArgs) {
D3D10DeviceLock lock = LockContext();
SetDrawBuffers(pBufferForArgs, nullptr);
// If possible, batch up multiple indirect draw calls of
// the same type into one single multiDrawIndirect call
constexpr VkDeviceSize stride = sizeof(VkDrawIndexedIndirectCommand);
auto cmdData = static_cast<D3D11CmdDrawIndirectData*>(m_cmdData);
bool useMultiDraw = cmdData && cmdData->type == D3D11CmdType::DrawIndirectIndexed
&& cmdData->offset + cmdData->count * stride == AlignedByteOffsetForArgs
&& m_device->features().core.features.multiDrawIndirect;
if (useMultiDraw) {
cmdData->count += 1;
} else {
cmdData = EmitCsCmd<D3D11CmdDrawIndirectData>(
[] (DxvkContext* ctx, const D3D11CmdDrawIndirectData* data) {
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ctx->drawIndexedIndirect(data->offset, data->count,
sizeof(VkDrawIndexedIndirectCommand));
});
cmdData->type = D3D11CmdType::DrawIndirectIndexed;
cmdData->offset = AlignedByteOffsetForArgs;
cmdData->count = 1;
}
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::DrawInstancedIndirect(
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ID3D11Buffer* pBufferForArgs,
UINT AlignedByteOffsetForArgs) {
D3D10DeviceLock lock = LockContext();
SetDrawBuffers(pBufferForArgs, nullptr);
// If possible, batch up multiple indirect draw calls of
// the same type into one single multiDrawIndirect call
constexpr VkDeviceSize stride = sizeof(VkDrawIndirectCommand);
auto cmdData = static_cast<D3D11CmdDrawIndirectData*>(m_cmdData);
bool useMultiDraw = cmdData && cmdData->type == D3D11CmdType::DrawIndirect
&& cmdData->offset + cmdData->count * stride == AlignedByteOffsetForArgs
&& m_device->features().core.features.multiDrawIndirect;
if (useMultiDraw) {
cmdData->count += 1;
} else {
cmdData = EmitCsCmd<D3D11CmdDrawIndirectData>(
[] (DxvkContext* ctx, const D3D11CmdDrawIndirectData* data) {
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ctx->drawIndirect(data->offset, data->count,
sizeof(VkDrawIndirectCommand));
});
cmdData->type = D3D11CmdType::DrawIndirect;
cmdData->offset = AlignedByteOffsetForArgs;
cmdData->count = 1;
}
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::Dispatch(
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UINT ThreadGroupCountX,
UINT ThreadGroupCountY,
UINT ThreadGroupCountZ) {
D3D10DeviceLock lock = LockContext();
EmitCs([=] (DxvkContext* ctx) {
ctx->dispatch(
ThreadGroupCountX,
ThreadGroupCountY,
ThreadGroupCountZ);
});
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::DispatchIndirect(
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ID3D11Buffer* pBufferForArgs,
UINT AlignedByteOffsetForArgs) {
D3D10DeviceLock lock = LockContext();
SetDrawBuffers(pBufferForArgs, nullptr);
EmitCs([cOffset = AlignedByteOffsetForArgs]
(DxvkContext* ctx) {
ctx->dispatchIndirect(cOffset);
});
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::IASetInputLayout(ID3D11InputLayout* pInputLayout) {
D3D10DeviceLock lock = LockContext();
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auto inputLayout = static_cast<D3D11InputLayout*>(pInputLayout);
if (m_state.ia.inputLayout != inputLayout) {
bool equal = false;
// Some games (e.g. Grim Dawn) create lots and lots of
// identical input layouts, so we'll only apply the state
// if the input layouts has actually changed between calls.
if (m_state.ia.inputLayout != nullptr && inputLayout != nullptr)
equal = m_state.ia.inputLayout->Compare(inputLayout);
m_state.ia.inputLayout = inputLayout;
if (!equal)
ApplyInputLayout();
}
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::IASetPrimitiveTopology(D3D11_PRIMITIVE_TOPOLOGY Topology) {
D3D10DeviceLock lock = LockContext();
if (m_state.ia.primitiveTopology != Topology) {
m_state.ia.primitiveTopology = Topology;
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ApplyPrimitiveTopology();
}
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::IASetVertexBuffers(
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UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer* const* ppVertexBuffers,
const UINT* pStrides,
const UINT* pOffsets) {
D3D10DeviceLock lock = LockContext();
for (uint32_t i = 0; i < NumBuffers; i++) {
auto newBuffer = static_cast<D3D11Buffer*>(ppVertexBuffers[i]);
bool needsUpdate = m_state.ia.vertexBuffers[StartSlot + i].buffer != newBuffer;
if (needsUpdate)
m_state.ia.vertexBuffers[StartSlot + i].buffer = newBuffer;
needsUpdate |= m_state.ia.vertexBuffers[StartSlot + i].offset != pOffsets[i]
|| m_state.ia.vertexBuffers[StartSlot + i].stride != pStrides[i];
if (needsUpdate) {
m_state.ia.vertexBuffers[StartSlot + i].offset = pOffsets[i];
m_state.ia.vertexBuffers[StartSlot + i].stride = pStrides[i];
BindVertexBuffer(StartSlot + i, newBuffer, pOffsets[i], pStrides[i]);
}
}
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::IASetIndexBuffer(
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ID3D11Buffer* pIndexBuffer,
DXGI_FORMAT Format,
UINT Offset) {
D3D10DeviceLock lock = LockContext();
auto newBuffer = static_cast<D3D11Buffer*>(pIndexBuffer);
bool needsUpdate = m_state.ia.indexBuffer.buffer != newBuffer;
if (needsUpdate)
m_state.ia.indexBuffer.buffer = newBuffer;
needsUpdate |= m_state.ia.indexBuffer.offset != Offset
|| m_state.ia.indexBuffer.format != Format;
if (needsUpdate) {
m_state.ia.indexBuffer.offset = Offset;
m_state.ia.indexBuffer.format = Format;
BindIndexBuffer(newBuffer, Offset, Format);
}
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::IAGetInputLayout(ID3D11InputLayout** ppInputLayout) {
D3D10DeviceLock lock = LockContext();
*ppInputLayout = m_state.ia.inputLayout.ref();
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::IAGetPrimitiveTopology(D3D11_PRIMITIVE_TOPOLOGY* pTopology) {
D3D10DeviceLock lock = LockContext();
*pTopology = m_state.ia.primitiveTopology;
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::IAGetVertexBuffers(
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UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer** ppVertexBuffers,
UINT* pStrides,
UINT* pOffsets) {
D3D10DeviceLock lock = LockContext();
for (uint32_t i = 0; i < NumBuffers; i++) {
if (ppVertexBuffers != nullptr)
ppVertexBuffers[i] = m_state.ia.vertexBuffers[StartSlot + i].buffer.ref();
if (pStrides != nullptr)
pStrides[i] = m_state.ia.vertexBuffers[StartSlot + i].stride;
if (pOffsets != nullptr)
pOffsets[i] = m_state.ia.vertexBuffers[StartSlot + i].offset;
}
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::IAGetIndexBuffer(
ID3D11Buffer** ppIndexBuffer,
DXGI_FORMAT* pFormat,
UINT* pOffset) {
D3D10DeviceLock lock = LockContext();
if (ppIndexBuffer != nullptr)
*ppIndexBuffer = m_state.ia.indexBuffer.buffer.ref();
if (pFormat != nullptr)
*pFormat = m_state.ia.indexBuffer.format;
if (pOffset != nullptr)
*pOffset = m_state.ia.indexBuffer.offset;
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::VSSetShader(
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ID3D11VertexShader* pVertexShader,
ID3D11ClassInstance* const* ppClassInstances,
UINT NumClassInstances) {
D3D10DeviceLock lock = LockContext();
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auto shader = static_cast<D3D11VertexShader*>(pVertexShader);
if (NumClassInstances != 0)
Logger::err("D3D11: Class instances not supported");
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if (m_state.vs.shader != shader) {
m_state.vs.shader = shader;
BindShader<DxbcProgramType::VertexShader>(GetCommonShader(shader));
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}
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::VSSetConstantBuffers(
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UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer* const* ppConstantBuffers) {
D3D10DeviceLock lock = LockContext();
SetConstantBuffers<DxbcProgramType::VertexShader>(
m_state.vs.constantBuffers,
StartSlot, NumBuffers,
ppConstantBuffers);
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}
void STDMETHODCALLTYPE D3D11DeviceContext::VSSetConstantBuffers1(
UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer* const* ppConstantBuffers,
const UINT* pFirstConstant,
const UINT* pNumConstants) {
D3D10DeviceLock lock = LockContext();
SetConstantBuffers1<DxbcProgramType::VertexShader>(
m_state.vs.constantBuffers,
StartSlot, NumBuffers,
ppConstantBuffers,
pFirstConstant,
pNumConstants);
}
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void STDMETHODCALLTYPE D3D11DeviceContext::VSSetShaderResources(
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UINT StartSlot,
UINT NumViews,
ID3D11ShaderResourceView* const* ppShaderResourceViews) {
D3D10DeviceLock lock = LockContext();
SetShaderResources<DxbcProgramType::VertexShader>(
m_state.vs.shaderResources,
StartSlot, NumViews,
ppShaderResourceViews);
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::VSSetSamplers(
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UINT StartSlot,
UINT NumSamplers,
ID3D11SamplerState* const* ppSamplers) {
D3D10DeviceLock lock = LockContext();
SetSamplers<DxbcProgramType::VertexShader>(
m_state.vs.samplers,
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StartSlot, NumSamplers,
ppSamplers);
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::VSGetShader(
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ID3D11VertexShader** ppVertexShader,
ID3D11ClassInstance** ppClassInstances,
UINT* pNumClassInstances) {
D3D10DeviceLock lock = LockContext();
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if (ppVertexShader != nullptr)
*ppVertexShader = m_state.vs.shader.ref();
if (pNumClassInstances != nullptr)
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*pNumClassInstances = 0;
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::VSGetConstantBuffers(
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UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer** ppConstantBuffers) {
D3D10DeviceLock lock = LockContext();
GetConstantBuffers(
m_state.vs.constantBuffers,
StartSlot, NumBuffers,
ppConstantBuffers,
nullptr, nullptr);
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}
void STDMETHODCALLTYPE D3D11DeviceContext::VSGetConstantBuffers1(
UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer** ppConstantBuffers,
UINT* pFirstConstant,
UINT* pNumConstants) {
D3D10DeviceLock lock = LockContext();
GetConstantBuffers(
m_state.vs.constantBuffers,
StartSlot, NumBuffers,
ppConstantBuffers,
pFirstConstant,
pNumConstants);
}
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void STDMETHODCALLTYPE D3D11DeviceContext::VSGetShaderResources(
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UINT StartSlot,
UINT NumViews,
ID3D11ShaderResourceView** ppShaderResourceViews) {
D3D10DeviceLock lock = LockContext();
for (uint32_t i = 0; i < NumViews; i++)
ppShaderResourceViews[i] = m_state.vs.shaderResources.views[StartSlot + i].ref();
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::VSGetSamplers(
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UINT StartSlot,
UINT NumSamplers,
ID3D11SamplerState** ppSamplers) {
D3D10DeviceLock lock = LockContext();
for (uint32_t i = 0; i < NumSamplers; i++)
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ppSamplers[i] = m_state.vs.samplers[StartSlot + i].ref();
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::HSSetShader(
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ID3D11HullShader* pHullShader,
ID3D11ClassInstance* const* ppClassInstances,
UINT NumClassInstances) {
D3D10DeviceLock lock = LockContext();
auto shader = static_cast<D3D11HullShader*>(pHullShader);
if (NumClassInstances != 0)
Logger::err("D3D11: Class instances not supported");
if (m_state.hs.shader != shader) {
m_state.hs.shader = shader;
BindShader<DxbcProgramType::HullShader>(GetCommonShader(shader));
}
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::HSSetShaderResources(
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UINT StartSlot,
UINT NumViews,
ID3D11ShaderResourceView* const* ppShaderResourceViews) {
D3D10DeviceLock lock = LockContext();
SetShaderResources<DxbcProgramType::HullShader>(
m_state.hs.shaderResources,
StartSlot, NumViews,
ppShaderResourceViews);
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::HSSetConstantBuffers(
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UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer* const* ppConstantBuffers) {
D3D10DeviceLock lock = LockContext();
SetConstantBuffers<DxbcProgramType::HullShader>(
m_state.hs.constantBuffers,
StartSlot, NumBuffers,
ppConstantBuffers);
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}
void STDMETHODCALLTYPE D3D11DeviceContext::HSSetConstantBuffers1(
UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer* const* ppConstantBuffers,
const UINT* pFirstConstant,
const UINT* pNumConstants) {
D3D10DeviceLock lock = LockContext();
SetConstantBuffers1<DxbcProgramType::HullShader>(
m_state.hs.constantBuffers,
StartSlot, NumBuffers,
ppConstantBuffers,
pFirstConstant,
pNumConstants);
}
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void STDMETHODCALLTYPE D3D11DeviceContext::HSSetSamplers(
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UINT StartSlot,
UINT NumSamplers,
ID3D11SamplerState* const* ppSamplers) {
D3D10DeviceLock lock = LockContext();
SetSamplers<DxbcProgramType::HullShader>(
m_state.hs.samplers,
StartSlot, NumSamplers,
ppSamplers);
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::HSGetShader(
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ID3D11HullShader** ppHullShader,
ID3D11ClassInstance** ppClassInstances,
UINT* pNumClassInstances) {
D3D10DeviceLock lock = LockContext();
if (ppHullShader != nullptr)
*ppHullShader = m_state.hs.shader.ref();
if (pNumClassInstances != nullptr)
*pNumClassInstances = 0;
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::HSGetConstantBuffers(
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UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer** ppConstantBuffers) {
D3D10DeviceLock lock = LockContext();
GetConstantBuffers(
m_state.hs.constantBuffers,
StartSlot, NumBuffers,
ppConstantBuffers,
nullptr, nullptr);
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}
void D3D11DeviceContext::HSGetConstantBuffers1(
UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer** ppConstantBuffers,
UINT* pFirstConstant,
UINT* pNumConstants) {
D3D10DeviceLock lock = LockContext();
GetConstantBuffers(
m_state.hs.constantBuffers,
StartSlot, NumBuffers,
ppConstantBuffers,
pFirstConstant,
pNumConstants);
}
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void STDMETHODCALLTYPE D3D11DeviceContext::HSGetShaderResources(
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UINT StartSlot,
UINT NumViews,
ID3D11ShaderResourceView** ppShaderResourceViews) {
D3D10DeviceLock lock = LockContext();
for (uint32_t i = 0; i < NumViews; i++)
ppShaderResourceViews[i] = m_state.hs.shaderResources.views[StartSlot + i].ref();
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::HSGetSamplers(
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UINT StartSlot,
UINT NumSamplers,
ID3D11SamplerState** ppSamplers) {
D3D10DeviceLock lock = LockContext();
for (uint32_t i = 0; i < NumSamplers; i++)
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ppSamplers[i] = m_state.hs.samplers[StartSlot + i].ref();
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::DSSetShader(
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ID3D11DomainShader* pDomainShader,
ID3D11ClassInstance* const* ppClassInstances,
UINT NumClassInstances) {
D3D10DeviceLock lock = LockContext();
auto shader = static_cast<D3D11DomainShader*>(pDomainShader);
if (NumClassInstances != 0)
Logger::err("D3D11: Class instances not supported");
if (m_state.ds.shader != shader) {
m_state.ds.shader = shader;
BindShader<DxbcProgramType::DomainShader>(GetCommonShader(shader));
}
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::DSSetShaderResources(
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UINT StartSlot,
UINT NumViews,
ID3D11ShaderResourceView* const* ppShaderResourceViews) {
D3D10DeviceLock lock = LockContext();
SetShaderResources<DxbcProgramType::DomainShader>(
m_state.ds.shaderResources,
StartSlot, NumViews,
ppShaderResourceViews);
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::DSSetConstantBuffers(
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UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer* const* ppConstantBuffers) {
D3D10DeviceLock lock = LockContext();
SetConstantBuffers<DxbcProgramType::DomainShader>(
m_state.ds.constantBuffers,
StartSlot, NumBuffers,
ppConstantBuffers);
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}
void STDMETHODCALLTYPE D3D11DeviceContext::DSSetConstantBuffers1(
UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer* const* ppConstantBuffers,
const UINT* pFirstConstant,
const UINT* pNumConstants) {
D3D10DeviceLock lock = LockContext();
SetConstantBuffers1<DxbcProgramType::DomainShader>(
m_state.ds.constantBuffers,
StartSlot, NumBuffers,
ppConstantBuffers,
pFirstConstant,
pNumConstants);
}
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void STDMETHODCALLTYPE D3D11DeviceContext::DSSetSamplers(
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UINT StartSlot,
UINT NumSamplers,
ID3D11SamplerState* const* ppSamplers) {
D3D10DeviceLock lock = LockContext();
SetSamplers<DxbcProgramType::DomainShader>(
m_state.ds.samplers,
StartSlot, NumSamplers,
ppSamplers);
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::DSGetShader(
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ID3D11DomainShader** ppDomainShader,
ID3D11ClassInstance** ppClassInstances,
UINT* pNumClassInstances) {
D3D10DeviceLock lock = LockContext();
if (ppDomainShader != nullptr)
*ppDomainShader = m_state.ds.shader.ref();
if (pNumClassInstances != nullptr)
*pNumClassInstances = 0;
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::DSGetConstantBuffers(
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UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer** ppConstantBuffers) {
D3D10DeviceLock lock = LockContext();
GetConstantBuffers(
m_state.ds.constantBuffers,
StartSlot, NumBuffers,
ppConstantBuffers,
nullptr, nullptr);
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}
void STDMETHODCALLTYPE D3D11DeviceContext::DSGetConstantBuffers1(
UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer** ppConstantBuffers,
UINT* pFirstConstant,
UINT* pNumConstants) {
D3D10DeviceLock lock = LockContext();
GetConstantBuffers(
m_state.ds.constantBuffers,
StartSlot, NumBuffers,
ppConstantBuffers,
pFirstConstant,
pNumConstants);
}
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void STDMETHODCALLTYPE D3D11DeviceContext::DSGetShaderResources(
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UINT StartSlot,
UINT NumViews,
ID3D11ShaderResourceView** ppShaderResourceViews) {
D3D10DeviceLock lock = LockContext();
for (uint32_t i = 0; i < NumViews; i++)
ppShaderResourceViews[i] = m_state.ds.shaderResources.views[StartSlot + i].ref();
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::DSGetSamplers(
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UINT StartSlot,
UINT NumSamplers,
ID3D11SamplerState** ppSamplers) {
D3D10DeviceLock lock = LockContext();
for (uint32_t i = 0; i < NumSamplers; i++)
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ppSamplers[i] = m_state.ds.samplers[StartSlot + i].ref();
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::GSSetShader(
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ID3D11GeometryShader* pShader,
ID3D11ClassInstance* const* ppClassInstances,
UINT NumClassInstances) {
D3D10DeviceLock lock = LockContext();
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auto shader = static_cast<D3D11GeometryShader*>(pShader);
if (NumClassInstances != 0)
Logger::err("D3D11: Class instances not supported");
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if (m_state.gs.shader != shader) {
m_state.gs.shader = shader;
BindShader<DxbcProgramType::GeometryShader>(GetCommonShader(shader));
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}
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::GSSetConstantBuffers(
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UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer* const* ppConstantBuffers) {
D3D10DeviceLock lock = LockContext();
SetConstantBuffers<DxbcProgramType::GeometryShader>(
m_state.gs.constantBuffers,
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StartSlot, NumBuffers,
ppConstantBuffers);
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}
void D3D11DeviceContext::GSSetConstantBuffers1(
UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer* const* ppConstantBuffers,
const UINT* pFirstConstant,
const UINT* pNumConstants) {
D3D10DeviceLock lock = LockContext();
SetConstantBuffers1<DxbcProgramType::GeometryShader>(
m_state.gs.constantBuffers,
StartSlot, NumBuffers,
ppConstantBuffers,
pFirstConstant,
pNumConstants);
}
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void STDMETHODCALLTYPE D3D11DeviceContext::GSSetShaderResources(
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UINT StartSlot,
UINT NumViews,
ID3D11ShaderResourceView* const* ppShaderResourceViews) {
D3D10DeviceLock lock = LockContext();
SetShaderResources<DxbcProgramType::GeometryShader>(
m_state.gs.shaderResources,
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StartSlot, NumViews,
ppShaderResourceViews);
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::GSSetSamplers(
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UINT StartSlot,
UINT NumSamplers,
ID3D11SamplerState* const* ppSamplers) {
D3D10DeviceLock lock = LockContext();
SetSamplers<DxbcProgramType::GeometryShader>(
m_state.gs.samplers,
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StartSlot, NumSamplers,
ppSamplers);
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::GSGetShader(
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ID3D11GeometryShader** ppGeometryShader,
ID3D11ClassInstance** ppClassInstances,
UINT* pNumClassInstances) {
D3D10DeviceLock lock = LockContext();
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if (ppGeometryShader != nullptr)
*ppGeometryShader = m_state.gs.shader.ref();
if (pNumClassInstances != nullptr)
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*pNumClassInstances = 0;
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::GSGetConstantBuffers(
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UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer** ppConstantBuffers) {
D3D10DeviceLock lock = LockContext();
GetConstantBuffers(
m_state.gs.constantBuffers,
StartSlot, NumBuffers,
ppConstantBuffers,
nullptr, nullptr);
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}
void D3D11DeviceContext::GSGetConstantBuffers1(
UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer** ppConstantBuffers,
UINT* pFirstConstant,
UINT* pNumConstants) {
D3D10DeviceLock lock = LockContext();
GetConstantBuffers(
m_state.gs.constantBuffers,
StartSlot, NumBuffers,
ppConstantBuffers,
pFirstConstant,
pNumConstants);
}
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void STDMETHODCALLTYPE D3D11DeviceContext::GSGetShaderResources(
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UINT StartSlot,
UINT NumViews,
ID3D11ShaderResourceView** ppShaderResourceViews) {
D3D10DeviceLock lock = LockContext();
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for (uint32_t i = 0; i < NumViews; i++)
ppShaderResourceViews[i] = m_state.gs.shaderResources.views[StartSlot + i].ref();
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::GSGetSamplers(
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UINT StartSlot,
UINT NumSamplers,
ID3D11SamplerState** ppSamplers) {
D3D10DeviceLock lock = LockContext();
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for (uint32_t i = 0; i < NumSamplers; i++)
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ppSamplers[i] = m_state.gs.samplers[StartSlot + i].ref();
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::PSSetShader(
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ID3D11PixelShader* pPixelShader,
ID3D11ClassInstance* const* ppClassInstances,
UINT NumClassInstances) {
D3D10DeviceLock lock = LockContext();
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auto shader = static_cast<D3D11PixelShader*>(pPixelShader);
if (NumClassInstances != 0)
Logger::err("D3D11: Class instances not supported");
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if (m_state.ps.shader != shader) {
m_state.ps.shader = shader;
BindShader<DxbcProgramType::PixelShader>(GetCommonShader(shader));
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}
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::PSSetConstantBuffers(
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UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer* const* ppConstantBuffers) {
D3D10DeviceLock lock = LockContext();
SetConstantBuffers<DxbcProgramType::PixelShader>(
m_state.ps.constantBuffers,
StartSlot, NumBuffers,
ppConstantBuffers);
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}
void D3D11DeviceContext::PSSetConstantBuffers1(
UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer* const* ppConstantBuffers,
const UINT* pFirstConstant,
const UINT* pNumConstants) {
D3D10DeviceLock lock = LockContext();
SetConstantBuffers1<DxbcProgramType::PixelShader>(
m_state.ps.constantBuffers,
StartSlot, NumBuffers,
ppConstantBuffers,
pFirstConstant,
pNumConstants);
}
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void STDMETHODCALLTYPE D3D11DeviceContext::PSSetShaderResources(
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UINT StartSlot,
UINT NumViews,
ID3D11ShaderResourceView* const* ppShaderResourceViews) {
D3D10DeviceLock lock = LockContext();
SetShaderResources<DxbcProgramType::PixelShader>(
m_state.ps.shaderResources,
StartSlot, NumViews,
ppShaderResourceViews);
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::PSSetSamplers(
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UINT StartSlot,
UINT NumSamplers,
ID3D11SamplerState* const* ppSamplers) {
D3D10DeviceLock lock = LockContext();
SetSamplers<DxbcProgramType::PixelShader>(
m_state.ps.samplers,
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StartSlot, NumSamplers,
ppSamplers);
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::PSGetShader(
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ID3D11PixelShader** ppPixelShader,
ID3D11ClassInstance** ppClassInstances,
UINT* pNumClassInstances) {
D3D10DeviceLock lock = LockContext();
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if (ppPixelShader != nullptr)
*ppPixelShader = m_state.ps.shader.ref();
if (pNumClassInstances != nullptr)
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*pNumClassInstances = 0;
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::PSGetConstantBuffers(
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UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer** ppConstantBuffers) {
D3D10DeviceLock lock = LockContext();
GetConstantBuffers(
m_state.ps.constantBuffers,
StartSlot, NumBuffers,
ppConstantBuffers,
nullptr, nullptr);
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}
void D3D11DeviceContext::PSGetConstantBuffers1(
UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer** ppConstantBuffers,
UINT* pFirstConstant,
UINT* pNumConstants) {
D3D10DeviceLock lock = LockContext();
GetConstantBuffers(
m_state.ps.constantBuffers,
StartSlot, NumBuffers,
ppConstantBuffers,
pFirstConstant,
pNumConstants);
}
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void STDMETHODCALLTYPE D3D11DeviceContext::PSGetShaderResources(
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UINT StartSlot,
UINT NumViews,
ID3D11ShaderResourceView** ppShaderResourceViews) {
D3D10DeviceLock lock = LockContext();
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for (uint32_t i = 0; i < NumViews; i++)
ppShaderResourceViews[i] = m_state.ps.shaderResources.views[StartSlot + i].ref();
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::PSGetSamplers(
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UINT StartSlot,
UINT NumSamplers,
ID3D11SamplerState** ppSamplers) {
D3D10DeviceLock lock = LockContext();
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for (uint32_t i = 0; i < NumSamplers; i++)
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ppSamplers[i] = m_state.ps.samplers[StartSlot + i].ref();
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::CSSetShader(
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ID3D11ComputeShader* pComputeShader,
ID3D11ClassInstance* const* ppClassInstances,
UINT NumClassInstances) {
D3D10DeviceLock lock = LockContext();
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auto shader = static_cast<D3D11ComputeShader*>(pComputeShader);
if (NumClassInstances != 0)
Logger::err("D3D11: Class instances not supported");
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if (m_state.cs.shader != shader) {
m_state.cs.shader = shader;
BindShader<DxbcProgramType::ComputeShader>(GetCommonShader(shader));
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}
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::CSSetConstantBuffers(
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UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer* const* ppConstantBuffers) {
D3D10DeviceLock lock = LockContext();
SetConstantBuffers<DxbcProgramType::ComputeShader>(
m_state.cs.constantBuffers,
StartSlot, NumBuffers,
ppConstantBuffers);
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}
void STDMETHODCALLTYPE D3D11DeviceContext::CSSetConstantBuffers1(
UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer* const* ppConstantBuffers,
const UINT* pFirstConstant,
const UINT* pNumConstants) {
D3D10DeviceLock lock = LockContext();
SetConstantBuffers1<DxbcProgramType::ComputeShader>(
m_state.cs.constantBuffers,
StartSlot, NumBuffers,
ppConstantBuffers,
pFirstConstant,
pNumConstants);
}
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void STDMETHODCALLTYPE D3D11DeviceContext::CSSetShaderResources(
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UINT StartSlot,
UINT NumViews,
ID3D11ShaderResourceView* const* ppShaderResourceViews) {
D3D10DeviceLock lock = LockContext();
SetShaderResources<DxbcProgramType::ComputeShader>(
m_state.cs.shaderResources,
StartSlot, NumViews,
ppShaderResourceViews);
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::CSSetSamplers(
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UINT StartSlot,
UINT NumSamplers,
ID3D11SamplerState* const* ppSamplers) {
D3D10DeviceLock lock = LockContext();
SetSamplers<DxbcProgramType::ComputeShader>(
m_state.cs.samplers,
StartSlot, NumSamplers,
ppSamplers);
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::CSSetUnorderedAccessViews(
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UINT StartSlot,
UINT NumUAVs,
ID3D11UnorderedAccessView* const* ppUnorderedAccessViews,
const UINT* pUAVInitialCounts) {
D3D10DeviceLock lock = LockContext();
// Unbind previously bound conflicting UAVs
uint32_t uavSlotId = computeUavBinding (DxbcProgramType::ComputeShader, 0);
uint32_t ctrSlotId = computeUavCounterBinding(DxbcProgramType::ComputeShader, 0);
int32_t uavId = m_state.cs.uavMask.findNext(0);
while (uavId >= 0) {
if (uint32_t(uavId) < StartSlot || uint32_t(uavId) >= StartSlot + NumUAVs) {
for (uint32_t i = 0; i < NumUAVs; i++) {
auto uav = static_cast<D3D11UnorderedAccessView*>(ppUnorderedAccessViews[i]);
if (CheckViewOverlap(uav, m_state.cs.unorderedAccessViews[uavId].ptr())) {
m_state.cs.unorderedAccessViews[uavId] = nullptr;
m_state.cs.uavMask.clr(uavId);
BindUnorderedAccessView(
uavSlotId + uavId, nullptr,
ctrSlotId + uavId, ~0u);
}
}
uavId = m_state.cs.uavMask.findNext(uavId + 1);
} else {
uavId = m_state.cs.uavMask.findNext(StartSlot + NumUAVs);
}
}
// Actually bind the given UAVs
for (uint32_t i = 0; i < NumUAVs; i++) {
auto uav = static_cast<D3D11UnorderedAccessView*>(ppUnorderedAccessViews[i]);
auto ctr = pUAVInitialCounts ? pUAVInitialCounts[i] : ~0u;
if (m_state.cs.unorderedAccessViews[StartSlot + i] != uav || ctr != ~0u) {
m_state.cs.unorderedAccessViews[StartSlot + i] = uav;
m_state.cs.uavMask.set(StartSlot + i, uav != nullptr);
BindUnorderedAccessView(
uavSlotId + StartSlot + i, uav,
ctrSlotId + StartSlot + i, ctr);
TestCsSrvHazards(uav);
}
}
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::CSGetShader(
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ID3D11ComputeShader** ppComputeShader,
ID3D11ClassInstance** ppClassInstances,
UINT* pNumClassInstances) {
D3D10DeviceLock lock = LockContext();
if (ppComputeShader != nullptr)
*ppComputeShader = m_state.cs.shader.ref();
if (pNumClassInstances != nullptr)
*pNumClassInstances = 0;
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::CSGetConstantBuffers(
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UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer** ppConstantBuffers) {
D3D10DeviceLock lock = LockContext();
GetConstantBuffers(
m_state.cs.constantBuffers,
StartSlot, NumBuffers,
ppConstantBuffers,
nullptr, nullptr);
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}
void STDMETHODCALLTYPE D3D11DeviceContext::CSGetConstantBuffers1(
UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer** ppConstantBuffers,
UINT* pFirstConstant,
UINT* pNumConstants) {
D3D10DeviceLock lock = LockContext();
GetConstantBuffers(
m_state.cs.constantBuffers,
StartSlot, NumBuffers,
ppConstantBuffers,
pFirstConstant,
pNumConstants);
}
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void STDMETHODCALLTYPE D3D11DeviceContext::CSGetShaderResources(
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UINT StartSlot,
UINT NumViews,
ID3D11ShaderResourceView** ppShaderResourceViews) {
D3D10DeviceLock lock = LockContext();
for (uint32_t i = 0; i < NumViews; i++)
ppShaderResourceViews[i] = m_state.cs.shaderResources.views[StartSlot + i].ref();
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::CSGetSamplers(
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UINT StartSlot,
UINT NumSamplers,
ID3D11SamplerState** ppSamplers) {
D3D10DeviceLock lock = LockContext();
for (uint32_t i = 0; i < NumSamplers; i++)
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ppSamplers[i] = m_state.cs.samplers[StartSlot + i].ref();
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::CSGetUnorderedAccessViews(
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UINT StartSlot,
UINT NumUAVs,
ID3D11UnorderedAccessView** ppUnorderedAccessViews) {
D3D10DeviceLock lock = LockContext();
for (uint32_t i = 0; i < NumUAVs; i++)
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ppUnorderedAccessViews[i] = m_state.cs.unorderedAccessViews[StartSlot + i].ref();
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::OMSetRenderTargets(
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UINT NumViews,
ID3D11RenderTargetView* const* ppRenderTargetViews,
ID3D11DepthStencilView* pDepthStencilView) {
OMSetRenderTargetsAndUnorderedAccessViews(
NumViews, ppRenderTargetViews, pDepthStencilView,
NumViews, 0, nullptr, nullptr);
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::OMSetRenderTargetsAndUnorderedAccessViews(
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UINT NumRTVs,
ID3D11RenderTargetView* const* ppRenderTargetViews,
ID3D11DepthStencilView* pDepthStencilView,
UINT UAVStartSlot,
UINT NumUAVs,
ID3D11UnorderedAccessView* const* ppUnorderedAccessViews,
const UINT* pUAVInitialCounts) {
D3D10DeviceLock lock = LockContext();
bool needsUpdate = false;
bool needsSpill = false;
if (likely(NumRTVs != D3D11_KEEP_RENDER_TARGETS_AND_DEPTH_STENCIL)) {
// Native D3D11 does not change the render targets if
// the parameters passed to this method are invalid.
if (!ValidateRenderTargets(NumRTVs, ppRenderTargetViews, pDepthStencilView))
return;
for (uint32_t i = 0; i < m_state.om.renderTargetViews.size(); i++) {
auto rtv = i < NumRTVs
? static_cast<D3D11RenderTargetView*>(ppRenderTargetViews[i])
: nullptr;
if (m_state.om.renderTargetViews[i] != rtv) {
m_state.om.renderTargetViews[i] = rtv;
needsUpdate = true;
TestOmSrvHazards(rtv);
if (NumUAVs == D3D11_KEEP_UNORDERED_ACCESS_VIEWS)
TestOmUavHazards(rtv);
}
}
auto dsv = static_cast<D3D11DepthStencilView*>(pDepthStencilView);
if (m_state.om.depthStencilView != dsv) {
m_state.om.depthStencilView = dsv;
needsUpdate = true;
TestOmSrvHazards(dsv);
}
m_state.om.maxRtv = NumRTVs;
}
if (unlikely(NumUAVs || m_state.om.maxUav)) {
uint32_t uavSlotId = computeUavBinding (DxbcProgramType::PixelShader, 0);
uint32_t ctrSlotId = computeUavCounterBinding(DxbcProgramType::PixelShader, 0);
if (likely(NumUAVs != D3D11_KEEP_UNORDERED_ACCESS_VIEWS)) {
uint32_t newMaxUav = NumUAVs ? UAVStartSlot + NumUAVs : 0;
uint32_t oldMaxUav = std::exchange(m_state.om.maxUav, newMaxUav);
for (uint32_t i = 0; i < std::max(oldMaxUav, newMaxUav); i++) {
D3D11UnorderedAccessView* uav = nullptr;
uint32_t ctr = ~0u;
if (i >= UAVStartSlot && i < UAVStartSlot + NumUAVs) {
uav = static_cast<D3D11UnorderedAccessView*>(ppUnorderedAccessViews[i - UAVStartSlot]);
ctr = pUAVInitialCounts ? pUAVInitialCounts[i - UAVStartSlot] : ~0u;
}
if (m_state.ps.unorderedAccessViews[i] != uav || ctr != ~0u) {
m_state.ps.unorderedAccessViews[i] = uav;
BindUnorderedAccessView(
uavSlotId + i, uav,
ctrSlotId + i, ctr);
TestOmSrvHazards(uav);
if (NumRTVs == D3D11_KEEP_RENDER_TARGETS_AND_DEPTH_STENCIL)
needsUpdate |= TestOmRtvHazards(uav);
needsSpill = true;
}
}
}
}
if (needsUpdate || needsSpill)
BindFramebuffer(needsSpill);
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::OMSetBlendState(
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ID3D11BlendState* pBlendState,
const FLOAT BlendFactor[4],
UINT SampleMask) {
D3D10DeviceLock lock = LockContext();
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auto blendState = static_cast<D3D11BlendState*>(pBlendState);
if (m_state.om.cbState != blendState
|| m_state.om.sampleMask != SampleMask) {
m_state.om.cbState = blendState;
m_state.om.sampleMask = SampleMask;
ApplyBlendState();
}
if (BlendFactor != nullptr) {
for (uint32_t i = 0; i < 4; i++)
m_state.om.blendFactor[i] = BlendFactor[i];
ApplyBlendFactor();
}
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::OMSetDepthStencilState(
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ID3D11DepthStencilState* pDepthStencilState,
UINT StencilRef) {
D3D10DeviceLock lock = LockContext();
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auto depthStencilState = static_cast<D3D11DepthStencilState*>(pDepthStencilState);
if (m_state.om.dsState != depthStencilState) {
m_state.om.dsState = depthStencilState;
ApplyDepthStencilState();
}
if (m_state.om.stencilRef != StencilRef) {
m_state.om.stencilRef = StencilRef;
ApplyStencilRef();
}
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::OMGetRenderTargets(
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UINT NumViews,
ID3D11RenderTargetView** ppRenderTargetViews,
ID3D11DepthStencilView** ppDepthStencilView) {
D3D10DeviceLock lock = LockContext();
if (ppRenderTargetViews != nullptr) {
for (UINT i = 0; i < NumViews; i++)
ppRenderTargetViews[i] = m_state.om.renderTargetViews[i].ref();
}
if (ppDepthStencilView != nullptr)
*ppDepthStencilView = m_state.om.depthStencilView.ref();
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::OMGetRenderTargetsAndUnorderedAccessViews(
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UINT NumRTVs,
ID3D11RenderTargetView** ppRenderTargetViews,
ID3D11DepthStencilView** ppDepthStencilView,
UINT UAVStartSlot,
UINT NumUAVs,
ID3D11UnorderedAccessView** ppUnorderedAccessViews) {
OMGetRenderTargets(NumRTVs, ppRenderTargetViews, ppDepthStencilView);
D3D10DeviceLock lock = LockContext();
if (ppUnorderedAccessViews != nullptr) {
for (UINT i = 0; i < NumUAVs; i++)
ppUnorderedAccessViews[i] = m_state.ps.unorderedAccessViews[UAVStartSlot + i].ref();
}
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::OMGetBlendState(
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ID3D11BlendState** ppBlendState,
FLOAT BlendFactor[4],
UINT* pSampleMask) {
D3D10DeviceLock lock = LockContext();
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if (ppBlendState != nullptr)
*ppBlendState = m_state.om.cbState.ref();
if (BlendFactor != nullptr)
std::memcpy(BlendFactor, m_state.om.blendFactor, sizeof(FLOAT) * 4);
if (pSampleMask != nullptr)
*pSampleMask = m_state.om.sampleMask;
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::OMGetDepthStencilState(
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ID3D11DepthStencilState** ppDepthStencilState,
UINT* pStencilRef) {
D3D10DeviceLock lock = LockContext();
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if (ppDepthStencilState != nullptr)
*ppDepthStencilState = m_state.om.dsState.ref();
if (pStencilRef != nullptr)
*pStencilRef = m_state.om.stencilRef;
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::RSSetState(ID3D11RasterizerState* pRasterizerState) {
D3D10DeviceLock lock = LockContext();
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auto rasterizerState = static_cast<D3D11RasterizerState*>(pRasterizerState);
bool currScissorEnable = m_state.rs.state != nullptr
? m_state.rs.state->Desc()->ScissorEnable
: false;
bool nextScissorEnable = rasterizerState != nullptr
? rasterizerState->Desc()->ScissorEnable
: false;
if (m_state.rs.state != rasterizerState) {
m_state.rs.state = rasterizerState;
// In D3D11, the rasterizer state defines whether the
// scissor test is enabled, so we have to update the
// scissor rectangles as well.
ApplyRasterizerState();
if (currScissorEnable != nextScissorEnable)
ApplyViewportState();
}
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::RSSetViewports(
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UINT NumViewports,
const D3D11_VIEWPORT* pViewports) {
D3D10DeviceLock lock = LockContext();
if (NumViewports > m_state.rs.viewports.size())
return;
bool dirty = m_state.rs.numViewports != NumViewports;
m_state.rs.numViewports = NumViewports;
for (uint32_t i = 0; i < NumViewports; i++) {
const D3D11_VIEWPORT& vp = m_state.rs.viewports[i];
dirty |= vp.TopLeftX != pViewports[i].TopLeftX
|| vp.TopLeftY != pViewports[i].TopLeftY
|| vp.Width != pViewports[i].Width
|| vp.Height != pViewports[i].Height
|| vp.MinDepth != pViewports[i].MinDepth
|| vp.MaxDepth != pViewports[i].MaxDepth;
m_state.rs.viewports[i] = pViewports[i];
}
if (dirty)
ApplyViewportState();
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::RSSetScissorRects(
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UINT NumRects,
const D3D11_RECT* pRects) {
D3D10DeviceLock lock = LockContext();
bool dirty = m_state.rs.numScissors != NumRects;
m_state.rs.numScissors = NumRects;
for (uint32_t i = 0; i < NumRects; i++) {
if (pRects[i].bottom >= pRects[i].top
&& pRects[i].right >= pRects[i].left) {
const D3D11_RECT& sr = m_state.rs.scissors[i];
dirty |= sr.top != pRects[i].top
|| sr.left != pRects[i].left
|| sr.bottom != pRects[i].bottom
|| sr.right != pRects[i].right;
m_state.rs.scissors[i] = pRects[i];
}
}
if (m_state.rs.state != nullptr && dirty) {
D3D11_RASTERIZER_DESC rsDesc;
m_state.rs.state->GetDesc(&rsDesc);
if (rsDesc.ScissorEnable)
ApplyViewportState();
}
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::RSGetState(ID3D11RasterizerState** ppRasterizerState) {
D3D10DeviceLock lock = LockContext();
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if (ppRasterizerState != nullptr)
*ppRasterizerState = m_state.rs.state.ref();
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::RSGetViewports(
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UINT* pNumViewports,
D3D11_VIEWPORT* pViewports) {
D3D10DeviceLock lock = LockContext();
if (pViewports != nullptr) {
for (uint32_t i = 0; i < *pNumViewports; i++) {
if (i < m_state.rs.numViewports) {
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pViewports[i] = m_state.rs.viewports[i];
} else {
pViewports[i].TopLeftX = 0.0f;
pViewports[i].TopLeftY = 0.0f;
pViewports[i].Width = 0.0f;
pViewports[i].Height = 0.0f;
pViewports[i].MinDepth = 0.0f;
pViewports[i].MaxDepth = 0.0f;
}
}
} else {
*pNumViewports = m_state.rs.numViewports;
}
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::RSGetScissorRects(
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UINT* pNumRects,
D3D11_RECT* pRects) {
D3D10DeviceLock lock = LockContext();
if (pRects != nullptr) {
for (uint32_t i = 0; i < *pNumRects; i++) {
if (i < m_state.rs.numScissors) {
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pRects[i] = m_state.rs.scissors[i];
} else {
pRects[i].left = 0;
pRects[i].top = 0;
pRects[i].right = 0;
pRects[i].bottom = 0;
}
}
} else {
*pNumRects = m_state.rs.numScissors;
}
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::SOSetTargets(
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UINT NumBuffers,
ID3D11Buffer* const* ppSOTargets,
const UINT* pOffsets) {
D3D10DeviceLock lock = LockContext();
for (uint32_t i = 0; i < NumBuffers; i++) {
D3D11Buffer* buffer = static_cast<D3D11Buffer*>(ppSOTargets[i]);
UINT offset = pOffsets != nullptr ? pOffsets[i] : 0;
m_state.so.targets[i].buffer = buffer;
m_state.so.targets[i].offset = offset;
}
for (uint32_t i = NumBuffers; i < D3D11_SO_BUFFER_SLOT_COUNT; i++) {
m_state.so.targets[i].buffer = nullptr;
m_state.so.targets[i].offset = 0;
}
for (uint32_t i = 0; i < D3D11_SO_BUFFER_SLOT_COUNT; i++) {
BindXfbBuffer(i,
m_state.so.targets[i].buffer.ptr(),
m_state.so.targets[i].offset);
}
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}
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void STDMETHODCALLTYPE D3D11DeviceContext::SOGetTargets(
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UINT NumBuffers,
ID3D11Buffer** ppSOTargets) {
D3D10DeviceLock lock = LockContext();
for (uint32_t i = 0; i < NumBuffers; i++)
ppSOTargets[i] = m_state.so.targets[i].buffer.ref();
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}
void STDMETHODCALLTYPE D3D11DeviceContext::SOGetTargetsWithOffsets(
UINT NumBuffers,
ID3D11Buffer** ppSOTargets,
UINT* pOffsets) {
D3D10DeviceLock lock = LockContext();
for (uint32_t i = 0; i < NumBuffers; i++) {
if (ppSOTargets != nullptr)
ppSOTargets[i] = m_state.so.targets[i].buffer.ref();
if (pOffsets != nullptr)
pOffsets[i] = m_state.so.targets[i].offset;
}
}
void STDMETHODCALLTYPE D3D11DeviceContext::TransitionSurfaceLayout(
IDXGIVkInteropSurface* pSurface,
const VkImageSubresourceRange* pSubresources,
VkImageLayout OldLayout,
VkImageLayout NewLayout) {
D3D10DeviceLock lock = LockContext();
// Get the underlying D3D11 resource
Com<ID3D11Resource> resource;
pSurface->QueryInterface(__uuidof(ID3D11Resource),
reinterpret_cast<void**>(&resource));
// Get the texture from that resource
D3D11CommonTexture* texture = GetCommonTexture(resource.ptr());
EmitCs([
cImage = texture->GetImage(),
cSubresources = *pSubresources,
cOldLayout = OldLayout,
cNewLayout = NewLayout
] (DxvkContext* ctx) {
ctx->transformImage(
cImage, cSubresources,
cOldLayout, cNewLayout);
});
}
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void D3D11DeviceContext::ApplyInputLayout() {
auto inputLayout = m_state.ia.inputLayout.prvRef();
if (likely(inputLayout != nullptr)) {
EmitCs([
cInputLayout = std::move(inputLayout)
] (DxvkContext* ctx) {
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cInputLayout->BindToContext(ctx);
});
} else {
EmitCs([] (DxvkContext* ctx) {
ctx->setInputLayout(0, nullptr, 0, nullptr);
});
}
}
void D3D11DeviceContext::ApplyPrimitiveTopology() {
D3D11_PRIMITIVE_TOPOLOGY topology = m_state.ia.primitiveTopology;
DxvkInputAssemblyState iaState = { };
if (topology <= D3D_PRIMITIVE_TOPOLOGY_TRIANGLESTRIP_ADJ) {
static const std::array<DxvkInputAssemblyState, 14> s_iaStates = {{
{ }, // D3D_PRIMITIVE_TOPOLOGY_UNDEFINED
{ VK_PRIMITIVE_TOPOLOGY_POINT_LIST, VK_FALSE, 0 },
{ VK_PRIMITIVE_TOPOLOGY_LINE_LIST, VK_FALSE, 0 },
{ VK_PRIMITIVE_TOPOLOGY_LINE_STRIP, VK_TRUE, 0 },
{ VK_PRIMITIVE_TOPOLOGY_TRIANGLE_LIST, VK_FALSE, 0 },
{ VK_PRIMITIVE_TOPOLOGY_TRIANGLE_STRIP, VK_TRUE, 0 },
{ }, { }, { }, { }, // Random gap that exists for no reason
{ VK_PRIMITIVE_TOPOLOGY_LINE_LIST_WITH_ADJACENCY, VK_FALSE, 0 },
{ VK_PRIMITIVE_TOPOLOGY_LINE_STRIP_WITH_ADJACENCY, VK_TRUE, 0 },
{ VK_PRIMITIVE_TOPOLOGY_TRIANGLE_LIST_WITH_ADJACENCY, VK_FALSE, 0 },
{ VK_PRIMITIVE_TOPOLOGY_TRIANGLE_STRIP_WITH_ADJACENCY, VK_TRUE, 0 },
}};
iaState = s_iaStates[uint32_t(topology)];
} else if (topology >= D3D11_PRIMITIVE_TOPOLOGY_1_CONTROL_POINT_PATCHLIST
&& topology <= D3D11_PRIMITIVE_TOPOLOGY_32_CONTROL_POINT_PATCHLIST) {
// The number of control points per patch can be inferred from the enum value in D3D11
uint32_t vertexCount = uint32_t(topology - D3D11_PRIMITIVE_TOPOLOGY_1_CONTROL_POINT_PATCHLIST + 1);
iaState = { VK_PRIMITIVE_TOPOLOGY_PATCH_LIST, VK_FALSE, vertexCount };
}
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EmitCs([iaState] (DxvkContext* ctx) {
ctx->setInputAssemblyState(iaState);
});
}
void D3D11DeviceContext::ApplyBlendState() {
auto cbState = m_state.om.cbState.prvRef();
if (unlikely(cbState == nullptr))
cbState = m_defaultBlendState.prvRef();
EmitCs([
cBlendState = std::move(cbState),
cSampleMask = m_state.om.sampleMask
] (DxvkContext* ctx) {
cBlendState->BindToContext(ctx, cSampleMask);
});
}
void D3D11DeviceContext::ApplyBlendFactor() {
EmitCs([
cBlendConstants = DxvkBlendConstants {
m_state.om.blendFactor[0], m_state.om.blendFactor[1],
m_state.om.blendFactor[2], m_state.om.blendFactor[3] }
] (DxvkContext* ctx) {
ctx->setBlendConstants(cBlendConstants);
});
}
void D3D11DeviceContext::ApplyDepthStencilState() {
auto dsState = m_state.om.dsState.prvRef();
if (unlikely(dsState == nullptr))
dsState = m_defaultDepthStencilState.prvRef();
EmitCs([
cDepthStencilState = std::move(dsState)
] (DxvkContext* ctx) {
cDepthStencilState->BindToContext(ctx);
});
}
void D3D11DeviceContext::ApplyStencilRef() {
EmitCs([
cStencilRef = m_state.om.stencilRef
] (DxvkContext* ctx) {
ctx->setStencilReference(cStencilRef);
});
}
void D3D11DeviceContext::ApplyRasterizerState() {
auto rsState = m_state.rs.state.prvRef();
if (unlikely(rsState == nullptr))
rsState = m_defaultRasterizerState.prvRef();
EmitCs([
cRasterizerState = std::move(rsState)
] (DxvkContext* ctx) {
cRasterizerState->BindToContext(ctx);
});
}
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void D3D11DeviceContext::ApplyViewportState() {
std::array<VkViewport, D3D11_VIEWPORT_AND_SCISSORRECT_OBJECT_COUNT_PER_PIPELINE> viewports;
std::array<VkRect2D, D3D11_VIEWPORT_AND_SCISSORRECT_OBJECT_COUNT_PER_PIPELINE> scissors;
// The backend can't handle a viewport count of zero,
// so we should at least specify one empty viewport
uint32_t viewportCount = m_state.rs.numViewports;
if (unlikely(!viewportCount)) {
viewportCount = 1;
viewports[0] = VkViewport();
scissors [0] = VkRect2D();
}
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// D3D11's coordinate system has its origin in the bottom left,
// but the viewport coordinates are aligned to the top-left
// corner so we can get away with flipping the viewport.
for (uint32_t i = 0; i < m_state.rs.numViewports; i++) {
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const D3D11_VIEWPORT& vp = m_state.rs.viewports[i];
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viewports[i] = VkViewport {
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vp.TopLeftX, vp.Height + vp.TopLeftY,
vp.Width, -vp.Height,
vp.MinDepth, vp.MaxDepth,
};
}
// Scissor rectangles. Vulkan does not provide an easy way
// to disable the scissor test, so we'll have to set scissor
// rects that are at least as large as the framebuffer.
bool enableScissorTest = false;
if (m_state.rs.state != nullptr) {
D3D11_RASTERIZER_DESC rsDesc;
m_state.rs.state->GetDesc(&rsDesc);
enableScissorTest = rsDesc.ScissorEnable;
}
for (uint32_t i = 0; i < m_state.rs.numViewports; i++) {
if (!enableScissorTest) {
scissors[i] = VkRect2D {
VkOffset2D { 0, 0 },
VkExtent2D {
D3D11_VIEWPORT_BOUNDS_MAX,
D3D11_VIEWPORT_BOUNDS_MAX } };
} else if (i >= m_state.rs.numScissors) {
scissors[i] = VkRect2D {
VkOffset2D { 0, 0 },
VkExtent2D { 0, 0 } };
} else {
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D3D11_RECT sr = m_state.rs.scissors[i];
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VkOffset2D srPosA;
srPosA.x = std::max<int32_t>(0, sr.left);
srPosA.y = std::max<int32_t>(0, sr.top);
VkOffset2D srPosB;
srPosB.x = std::max<int32_t>(srPosA.x, sr.right);
srPosB.y = std::max<int32_t>(srPosA.y, sr.bottom);
VkExtent2D srSize;
srSize.width = uint32_t(srPosB.x - srPosA.x);
srSize.height = uint32_t(srPosB.y - srPosA.y);
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scissors[i] = VkRect2D { srPosA, srSize };
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}
}
EmitCs([
cViewportCount = viewportCount,
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cViewports = viewports,
cScissors = scissors
] (DxvkContext* ctx) {
ctx->setViewports(
cViewportCount,
cViewports.data(),
cScissors.data());
});
}
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template<DxbcProgramType ShaderStage>
void D3D11DeviceContext::BindShader(
const D3D11CommonShader* pShaderModule) {
// Bind the shader and the ICB at once
uint32_t slotId = computeConstantBufferBinding(ShaderStage,
D3D11_COMMONSHADER_CONSTANT_BUFFER_API_SLOT_COUNT);
EmitCs([
cSlotId = slotId,
cStage = GetShaderStage(ShaderStage),
cSlice = pShaderModule != nullptr
&& pShaderModule->GetIcb() != nullptr
? DxvkBufferSlice(pShaderModule->GetIcb())
: DxvkBufferSlice(),
cShader = pShaderModule != nullptr
? pShaderModule->GetShader()
: nullptr
] (DxvkContext* ctx) {
ctx->bindShader (cStage, cShader);
ctx->bindResourceBuffer(cSlotId, cSlice);
});
}
void D3D11DeviceContext::BindFramebuffer(BOOL Spill) {
DxvkRenderTargets attachments;
// D3D11 doesn't have the concept of a framebuffer object,
// so we'll just create a new one every time the render
// target bindings are updated. Set up the attachments.
for (UINT i = 0; i < m_state.om.renderTargetViews.size(); i++) {
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if (m_state.om.renderTargetViews[i] != nullptr) {
attachments.color[i] = {
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m_state.om.renderTargetViews[i]->GetImageView(),
m_state.om.renderTargetViews[i]->GetRenderLayout() };
}
}
if (m_state.om.depthStencilView != nullptr) {
attachments.depth = {
m_state.om.depthStencilView->GetImageView(),
m_state.om.depthStencilView->GetRenderLayout() };
}
// Create and bind the framebuffer object to the context
EmitCs([
cAttachments = std::move(attachments),
cSpill = Spill
] (DxvkContext* ctx) {
ctx->bindRenderTargets(cAttachments, cSpill);
});
}
void D3D11DeviceContext::BindDrawBuffers(
D3D11Buffer* pBufferForArgs,
D3D11Buffer* pBufferForCount) {
EmitCs([
cArgBuffer = pBufferForArgs ? pBufferForArgs->GetBufferSlice() : DxvkBufferSlice(),
cCntBuffer = pBufferForCount ? pBufferForCount->GetBufferSlice() : DxvkBufferSlice()
] (DxvkContext* ctx) {
ctx->bindDrawBuffers(cArgBuffer, cCntBuffer);
});
}
void D3D11DeviceContext::BindVertexBuffer(
UINT Slot,
D3D11Buffer* pBuffer,
UINT Offset,
UINT Stride) {
EmitCs([
cSlotId = Slot,
cBufferSlice = pBuffer != nullptr ? pBuffer->GetBufferSlice(Offset) : DxvkBufferSlice(),
cStride = Stride
] (DxvkContext* ctx) {
ctx->bindVertexBuffer(cSlotId, cBufferSlice, cStride);
});
}
void D3D11DeviceContext::BindIndexBuffer(
D3D11Buffer* pBuffer,
UINT Offset,
DXGI_FORMAT Format) {
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VkIndexType indexType = Format == DXGI_FORMAT_R16_UINT
? VK_INDEX_TYPE_UINT16
: VK_INDEX_TYPE_UINT32;
EmitCs([
cBufferSlice = pBuffer != nullptr ? pBuffer->GetBufferSlice(Offset) : DxvkBufferSlice(),
cIndexType = indexType
] (DxvkContext* ctx) {
ctx->bindIndexBuffer(cBufferSlice, cIndexType);
});
}
void D3D11DeviceContext::BindXfbBuffer(
UINT Slot,
D3D11Buffer* pBuffer,
UINT Offset) {
DxvkBufferSlice bufferSlice;
DxvkBufferSlice counterSlice;
if (pBuffer != nullptr) {
bufferSlice = pBuffer->GetBufferSlice();
counterSlice = pBuffer->GetSOCounter();
}
EmitCs([
cSlotId = Slot,
cOffset = Offset,
cBufferSlice = bufferSlice,
cCounterSlice = counterSlice
] (DxvkContext* ctx) {
if (cCounterSlice.defined() && cOffset != ~0u) {
ctx->updateBuffer(
cCounterSlice.buffer(),
cCounterSlice.offset(),
sizeof(cOffset),
&cOffset);
}
ctx->bindXfbBuffer(cSlotId, cBufferSlice, cCounterSlice);
});
}
void D3D11DeviceContext::BindConstantBuffer(
UINT Slot,
D3D11Buffer* pBuffer) {
EmitCs([
cSlotId = Slot,
cBufferSlice = pBuffer ? pBuffer->GetBufferSlice() : DxvkBufferSlice()
] (DxvkContext* ctx) {
ctx->bindResourceBuffer(cSlotId, cBufferSlice);
});
}
void D3D11DeviceContext::BindConstantBuffer1(
UINT Slot,
D3D11Buffer* pBuffer,
UINT Offset,
UINT Length) {
EmitCs([
cSlotId = Slot,
cBufferSlice = Length ? pBuffer->GetBufferSlice(16 * Offset, 16 * Length) : DxvkBufferSlice()
] (DxvkContext* ctx) {
ctx->bindResourceBuffer(cSlotId, cBufferSlice);
});
}
void D3D11DeviceContext::BindSampler(
UINT Slot,
D3D11SamplerState* pSampler) {
EmitCs([
cSlotId = Slot,
cSampler = pSampler != nullptr ? pSampler->GetDXVKSampler() : nullptr
] (DxvkContext* ctx) {
ctx->bindResourceSampler(cSlotId, cSampler);
});
}
void D3D11DeviceContext::BindShaderResource(
UINT Slot,
D3D11ShaderResourceView* pResource) {
EmitCs([
cSlotId = Slot,
cImageView = pResource != nullptr ? pResource->GetImageView() : nullptr,
cBufferView = pResource != nullptr ? pResource->GetBufferView() : nullptr
] (DxvkContext* ctx) {
ctx->bindResourceView(cSlotId, cImageView, cBufferView);
});
}
void D3D11DeviceContext::BindUnorderedAccessView(
UINT UavSlot,
D3D11UnorderedAccessView* pUav,
UINT CtrSlot,
UINT Counter) {
EmitCs([
cUavSlotId = UavSlot,
cCtrSlotId = CtrSlot,
cImageView = pUav != nullptr ? pUav->GetImageView() : nullptr,
cBufferView = pUav != nullptr ? pUav->GetBufferView() : nullptr,
cCounterSlice = pUav != nullptr ? pUav->GetCounterSlice() : DxvkBufferSlice(),
cCounterValue = Counter
] (DxvkContext* ctx) {
if (cCounterSlice.defined() && cCounterValue != ~0u) {
ctx->updateBuffer(
cCounterSlice.buffer(),
cCounterSlice.offset(),
sizeof(uint32_t),
&cCounterValue);
}
ctx->bindResourceView (cUavSlotId, cImageView, cBufferView);
ctx->bindResourceBuffer (cCtrSlotId, cCounterSlice);
});
}
void D3D11DeviceContext::DiscardBuffer(
D3D11Buffer* pBuffer) {
EmitCs([cBuffer = pBuffer->GetBuffer()] (DxvkContext* ctx) {
ctx->discardBuffer(cBuffer);
});
}
void D3D11DeviceContext::DiscardTexture(
D3D11CommonTexture* pTexture) {
EmitCs([cImage = pTexture->GetImage()] (DxvkContext* ctx) {
VkImageSubresourceRange subresources = {
cImage->formatInfo()->aspectMask,
0, cImage->info().mipLevels,
0, cImage->info().numLayers };
ctx->discardImage(cImage, subresources);
});
}
void D3D11DeviceContext::SetDrawBuffers(
ID3D11Buffer* pBufferForArgs,
ID3D11Buffer* pBufferForCount) {
auto argBuffer = static_cast<D3D11Buffer*>(pBufferForArgs);
auto cntBuffer = static_cast<D3D11Buffer*>(pBufferForCount);
if (m_state.id.argBuffer != argBuffer
|| m_state.id.cntBuffer != cntBuffer) {
m_state.id.argBuffer = argBuffer;
m_state.id.cntBuffer = cntBuffer;
BindDrawBuffers(argBuffer, cntBuffer);
}
}
template<DxbcProgramType ShaderStage>
void D3D11DeviceContext::SetConstantBuffers(
D3D11ConstantBufferBindings& Bindings,
UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer* const* ppConstantBuffers) {
uint32_t slotId = computeConstantBufferBinding(ShaderStage, StartSlot);
for (uint32_t i = 0; i < NumBuffers; i++) {
auto newBuffer = static_cast<D3D11Buffer*>(ppConstantBuffers[i]);
UINT constantBound = 0;
if (likely(newBuffer != nullptr))
constantBound = newBuffer->Desc()->ByteWidth / 16;
if (Bindings[StartSlot + i].buffer != newBuffer
|| Bindings[StartSlot + i].constantBound != constantBound) {
Bindings[StartSlot + i].buffer = newBuffer;
Bindings[StartSlot + i].constantOffset = 0;
Bindings[StartSlot + i].constantCount = constantBound;
Bindings[StartSlot + i].constantBound = constantBound;
BindConstantBuffer(slotId + i, newBuffer);
}
}
}
template<DxbcProgramType ShaderStage>
void D3D11DeviceContext::SetConstantBuffers1(
D3D11ConstantBufferBindings& Bindings,
UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer* const* ppConstantBuffers,
const UINT* pFirstConstant,
const UINT* pNumConstants) {
uint32_t slotId = computeConstantBufferBinding(ShaderStage, StartSlot);
for (uint32_t i = 0; i < NumBuffers; i++) {
auto newBuffer = static_cast<D3D11Buffer*>(ppConstantBuffers[i]);
UINT constantOffset;
UINT constantCount;
UINT constantBound;
if (likely(newBuffer != nullptr)) {
constantBound = newBuffer->Desc()->ByteWidth / 16;
if (likely(pFirstConstant && pNumConstants)) {
constantOffset = pFirstConstant[i];
constantCount = pNumConstants [i];
constantBound = (constantOffset + constantCount > constantBound)
? constantBound - std::min(constantOffset, constantBound)
: constantCount;
} else {
constantOffset = 0;
constantCount = constantBound;
}
} else {
constantOffset = 0;
constantCount = 0;
constantBound = 0;
}
bool needsUpdate = Bindings[StartSlot + i].buffer != newBuffer;
if (needsUpdate)
Bindings[StartSlot + i].buffer = newBuffer;
needsUpdate |= Bindings[StartSlot + i].constantOffset != constantOffset
|| Bindings[StartSlot + i].constantCount != constantCount;
if (needsUpdate) {
Bindings[StartSlot + i].constantOffset = constantOffset;
Bindings[StartSlot + i].constantCount = constantCount;
Bindings[StartSlot + i].constantBound = constantBound;
BindConstantBuffer1(slotId + i, newBuffer, constantOffset, constantBound);
}
}
}
template<DxbcProgramType ShaderStage>
void D3D11DeviceContext::SetSamplers(
D3D11SamplerBindings& Bindings,
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UINT StartSlot,
UINT NumSamplers,
ID3D11SamplerState* const* ppSamplers) {
uint32_t slotId = computeSamplerBinding(ShaderStage, StartSlot);
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for (uint32_t i = 0; i < NumSamplers; i++) {
auto sampler = static_cast<D3D11SamplerState*>(ppSamplers[i]);
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if (Bindings[StartSlot + i] != sampler) {
Bindings[StartSlot + i] = sampler;
BindSampler(slotId + i, sampler);
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}
}
}
template<DxbcProgramType ShaderStage>
void D3D11DeviceContext::SetShaderResources(
D3D11ShaderResourceBindings& Bindings,
UINT StartSlot,
UINT NumResources,
ID3D11ShaderResourceView* const* ppResources) {
uint32_t slotId = computeSrvBinding(ShaderStage, StartSlot);
for (uint32_t i = 0; i < NumResources; i++) {
auto resView = static_cast<D3D11ShaderResourceView*>(ppResources[i]);
if (Bindings.views[StartSlot + i] != resView) {
if (unlikely(resView && resView->TestHazards())) {
if (TestSrvHazards<ShaderStage>(resView))
resView = nullptr;
// Only set if necessary, but don't reset it on every
// bind as this would be more expensive than a few
// redundant checks in OMSetRenderTargets and friends.
Bindings.hazardous.set(StartSlot + i, resView);
}
Bindings.views[StartSlot + i] = resView;
BindShaderResource(slotId + i, resView);
}
}
}
void D3D11DeviceContext::GetConstantBuffers(
const D3D11ConstantBufferBindings& Bindings,
UINT StartSlot,
UINT NumBuffers,
ID3D11Buffer** ppConstantBuffers,
UINT* pFirstConstant,
UINT* pNumConstants) {
for (uint32_t i = 0; i < NumBuffers; i++) {
if (ppConstantBuffers != nullptr)
ppConstantBuffers[i] = Bindings[StartSlot + i].buffer.ref();
if (pFirstConstant != nullptr)
pFirstConstant[i] = Bindings[StartSlot + i].constantOffset;
if (pNumConstants != nullptr)
pNumConstants[i] = Bindings[StartSlot + i].constantCount;
}
}
void D3D11DeviceContext::RestoreState() {
BindFramebuffer(m_state.om.maxUav > 0);
BindShader<DxbcProgramType::VertexShader> (GetCommonShader(m_state.vs.shader.ptr()));
BindShader<DxbcProgramType::HullShader> (GetCommonShader(m_state.hs.shader.ptr()));
BindShader<DxbcProgramType::DomainShader> (GetCommonShader(m_state.ds.shader.ptr()));
BindShader<DxbcProgramType::GeometryShader> (GetCommonShader(m_state.gs.shader.ptr()));
BindShader<DxbcProgramType::PixelShader> (GetCommonShader(m_state.ps.shader.ptr()));
BindShader<DxbcProgramType::ComputeShader> (GetCommonShader(m_state.cs.shader.ptr()));
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ApplyInputLayout();
ApplyPrimitiveTopology();
ApplyBlendState();
ApplyBlendFactor();
ApplyDepthStencilState();
ApplyStencilRef();
ApplyRasterizerState();
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ApplyViewportState();
BindDrawBuffers(
m_state.id.argBuffer.ptr(),
m_state.id.cntBuffer.ptr());
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BindIndexBuffer(
m_state.ia.indexBuffer.buffer.ptr(),
m_state.ia.indexBuffer.offset,
m_state.ia.indexBuffer.format);
for (uint32_t i = 0; i < m_state.ia.vertexBuffers.size(); i++) {
BindVertexBuffer(i,
m_state.ia.vertexBuffers[i].buffer.ptr(),
m_state.ia.vertexBuffers[i].offset,
m_state.ia.vertexBuffers[i].stride);
}
for (uint32_t i = 0; i < m_state.so.targets.size(); i++)
BindXfbBuffer(i, m_state.so.targets[i].buffer.ptr(), ~0u);
RestoreConstantBuffers<DxbcProgramType::VertexShader> (m_state.vs.constantBuffers);
RestoreConstantBuffers<DxbcProgramType::HullShader> (m_state.hs.constantBuffers);
RestoreConstantBuffers<DxbcProgramType::DomainShader> (m_state.ds.constantBuffers);
RestoreConstantBuffers<DxbcProgramType::GeometryShader> (m_state.gs.constantBuffers);
RestoreConstantBuffers<DxbcProgramType::PixelShader> (m_state.ps.constantBuffers);
RestoreConstantBuffers<DxbcProgramType::ComputeShader> (m_state.cs.constantBuffers);
RestoreSamplers<DxbcProgramType::VertexShader> (m_state.vs.samplers);
RestoreSamplers<DxbcProgramType::HullShader> (m_state.hs.samplers);
RestoreSamplers<DxbcProgramType::DomainShader> (m_state.ds.samplers);
RestoreSamplers<DxbcProgramType::GeometryShader>(m_state.gs.samplers);
RestoreSamplers<DxbcProgramType::PixelShader> (m_state.ps.samplers);
RestoreSamplers<DxbcProgramType::ComputeShader> (m_state.cs.samplers);
RestoreShaderResources<DxbcProgramType::VertexShader> (m_state.vs.shaderResources);
RestoreShaderResources<DxbcProgramType::HullShader> (m_state.hs.shaderResources);
RestoreShaderResources<DxbcProgramType::DomainShader> (m_state.ds.shaderResources);
RestoreShaderResources<DxbcProgramType::GeometryShader> (m_state.gs.shaderResources);
RestoreShaderResources<DxbcProgramType::PixelShader> (m_state.ps.shaderResources);
RestoreShaderResources<DxbcProgramType::ComputeShader> (m_state.cs.shaderResources);
RestoreUnorderedAccessViews<DxbcProgramType::PixelShader> (m_state.ps.unorderedAccessViews);
RestoreUnorderedAccessViews<DxbcProgramType::ComputeShader> (m_state.cs.unorderedAccessViews);
}
template<DxbcProgramType Stage>
void D3D11DeviceContext::RestoreConstantBuffers(
D3D11ConstantBufferBindings& Bindings) {
uint32_t slotId = computeConstantBufferBinding(Stage, 0);
for (uint32_t i = 0; i < Bindings.size(); i++) {
BindConstantBuffer1(slotId + i, Bindings[i].buffer.ptr(),
Bindings[i].constantOffset, Bindings[i].constantBound);
}
}
template<DxbcProgramType Stage>
void D3D11DeviceContext::RestoreSamplers(
D3D11SamplerBindings& Bindings) {
uint32_t slotId = computeSamplerBinding(Stage, 0);
for (uint32_t i = 0; i < Bindings.size(); i++)
BindSampler(slotId + i, Bindings[i].ptr());
}
template<DxbcProgramType Stage>
void D3D11DeviceContext::RestoreShaderResources(
D3D11ShaderResourceBindings& Bindings) {
uint32_t slotId = computeSrvBinding(Stage, 0);
for (uint32_t i = 0; i < Bindings.views.size(); i++)
BindShaderResource(slotId + i, Bindings.views[i].ptr());
}
template<DxbcProgramType Stage>
void D3D11DeviceContext::RestoreUnorderedAccessViews(
D3D11UnorderedAccessBindings& Bindings) {
uint32_t uavSlotId = computeUavBinding (Stage, 0);
uint32_t ctrSlotId = computeUavCounterBinding(Stage, 0);
for (uint32_t i = 0; i < Bindings.size(); i++) {
BindUnorderedAccessView(
uavSlotId + i,
Bindings[i].ptr(),
ctrSlotId + i, ~0u);
}
}
void D3D11DeviceContext::UpdateMappedBuffer(
const D3D11CommonTexture* pTexture,
VkImageSubresource Subresource) {
UINT SubresourceIndex = D3D11CalcSubresource(
Subresource.mipLevel, Subresource.arrayLayer,
pTexture->Desc()->MipLevels);
Rc<DxvkImage> mappedImage = pTexture->GetImage();
Rc<DxvkBuffer> mappedBuffer = pTexture->GetMappedBuffer(SubresourceIndex);
VkFormat packedFormat = m_parent->LookupPackedFormat(
pTexture->Desc()->Format, pTexture->GetFormatMode()).Format;
VkExtent3D levelExtent = mappedImage->mipLevelExtent(Subresource.mipLevel);
EmitCs([
cImageBuffer = std::move(mappedBuffer),
cImage = std::move(mappedImage),
cSubresources = vk::makeSubresourceLayers(Subresource),
cLevelExtent = levelExtent,
cPackedFormat = packedFormat
] (DxvkContext* ctx) {
if (cSubresources.aspectMask != (VK_IMAGE_ASPECT_DEPTH_BIT | VK_IMAGE_ASPECT_STENCIL_BIT)) {
ctx->copyImageToBuffer(
cImageBuffer, 0, VkExtent2D { 0u, 0u },
cImage, cSubresources, VkOffset3D { 0, 0, 0 },
cLevelExtent);
} else {
ctx->copyDepthStencilImageToPackedBuffer(
cImageBuffer, 0, cImage, cSubresources,
VkOffset2D { 0, 0 },
VkExtent2D { cLevelExtent.width, cLevelExtent.height },
cPackedFormat);
}
});
}
template<DxbcProgramType ShaderStage>
bool D3D11DeviceContext::TestSrvHazards(
D3D11ShaderResourceView* pView) {
bool hazard = false;
if (ShaderStage == DxbcProgramType::ComputeShader) {
int32_t uav = m_state.cs.uavMask.findNext(0);
while (uav >= 0 && !hazard) {
hazard = CheckViewOverlap(pView, m_state.cs.unorderedAccessViews[uav].ptr());
uav = m_state.cs.uavMask.findNext(uav + 1);
}
} else {
hazard = CheckViewOverlap(pView, m_state.om.depthStencilView.ptr());
for (uint32_t i = 0; !hazard && i < m_state.om.maxRtv; i++)
hazard = CheckViewOverlap(pView, m_state.om.renderTargetViews[i].ptr());
for (uint32_t i = 0; !hazard && i < m_state.om.maxUav; i++)
hazard = CheckViewOverlap(pView, m_state.ps.unorderedAccessViews[i].ptr());
}
return hazard;
}
template<DxbcProgramType ShaderStage, typename T>
void D3D11DeviceContext::TestSrvHazards(
T* pView,
D3D11ShaderResourceBindings& Bindings) {
uint32_t slotId = computeSrvBinding(ShaderStage, 0);
int32_t srvId = Bindings.hazardous.findNext(0);
while (srvId >= 0) {
auto srv = Bindings.views[srvId].ptr();
if (likely(srv && srv->TestHazards())) {
bool hazard = CheckViewOverlap(pView, srv);
if (unlikely(hazard)) {
Bindings.views[srvId] = nullptr;
Bindings.hazardous.clr(srvId);
BindShaderResource(slotId + srvId, nullptr);
}
} else {
// Avoid further redundant iterations
Bindings.hazardous.clr(srvId);
}
srvId = Bindings.hazardous.findNext(srvId + 1);
}
}
template<typename T>
void D3D11DeviceContext::TestOmSrvHazards(
T* pView) {
if (!pView) return;
TestSrvHazards<DxbcProgramType::VertexShader> (pView, m_state.vs.shaderResources);
TestSrvHazards<DxbcProgramType::HullShader> (pView, m_state.hs.shaderResources);
TestSrvHazards<DxbcProgramType::DomainShader> (pView, m_state.ds.shaderResources);
TestSrvHazards<DxbcProgramType::GeometryShader> (pView, m_state.gs.shaderResources);
TestSrvHazards<DxbcProgramType::PixelShader> (pView, m_state.ps.shaderResources);
}
bool D3D11DeviceContext::TestOmRtvHazards(
D3D11UnorderedAccessView* pView) {
if (!pView || !pView->HasBindFlag(D3D11_BIND_RENDER_TARGET))
return false;
bool hazard = false;
if (CheckViewOverlap(pView, m_state.om.depthStencilView.ptr())) {
m_state.om.depthStencilView = nullptr;
hazard = true;
}
for (uint32_t i = 0; i < m_state.om.maxRtv; i++) {
if (CheckViewOverlap(pView, m_state.om.renderTargetViews[i].ptr())) {
m_state.om.renderTargetViews[i] = nullptr;
hazard = true;
}
}
return hazard;
}
void D3D11DeviceContext::TestOmUavHazards(
D3D11RenderTargetView* pView) {
if (!pView || !pView->HasBindFlag(D3D11_BIND_UNORDERED_ACCESS))
return;
uint32_t uavSlotId = computeUavBinding (DxbcProgramType::PixelShader, 0);
uint32_t ctrSlotId = computeUavCounterBinding(DxbcProgramType::PixelShader, 0);
for (uint32_t i = 0; i < m_state.om.maxUav; i++) {
if (CheckViewOverlap(pView, m_state.ps.unorderedAccessViews[i].ptr())) {
m_state.ps.unorderedAccessViews[i] = nullptr;
BindUnorderedAccessView(
uavSlotId + i, nullptr,
ctrSlotId + i, ~0u);
}
}
}
template<typename T>
void D3D11DeviceContext::TestCsSrvHazards(
T* pView) {
if (!pView) return;
TestSrvHazards<DxbcProgramType::ComputeShader> (pView, m_state.cs.shaderResources);
}
bool D3D11DeviceContext::ValidateRenderTargets(
UINT NumViews,
ID3D11RenderTargetView* const* ppRenderTargetViews,
ID3D11DepthStencilView* pDepthStencilView) {
Rc<DxvkImageView> refView;
if (pDepthStencilView != nullptr) {
refView = static_cast<D3D11DepthStencilView*>(
pDepthStencilView)->GetImageView();
}
for (uint32_t i = 0; i < NumViews; i++) {
if (ppRenderTargetViews[i] != nullptr) {
auto curView = static_cast<D3D11RenderTargetView*>(
ppRenderTargetViews[i])->GetImageView();
if (refView != nullptr) {
// Render target views must all have the same
// size, sample count, layer count, and type
if (curView->info().type != refView->info().type
|| curView->info().numLayers != refView->info().numLayers)
return false;
if (curView->imageInfo().sampleCount
!= refView->imageInfo().sampleCount)
return false;
} else {
// Set reference view. All remaining views
// must be compatible to the reference view.
refView = curView;
}
}
}
return true;
}
VkClearValue D3D11DeviceContext::ConvertColorValue(
const FLOAT Color[4],
const DxvkFormatInfo* pFormatInfo) {
VkClearValue result;
if (pFormatInfo->aspectMask & VK_IMAGE_ASPECT_COLOR_BIT) {
for (uint32_t i = 0; i < 4; i++) {
if (pFormatInfo->flags.test(DxvkFormatFlag::SampledUInt))
result.color.uint32[i] = uint32_t(std::max(0.0f, Color[i]));
else if (pFormatInfo->flags.test(DxvkFormatFlag::SampledSInt))
result.color.int32[i] = int32_t(Color[i]);
else
result.color.float32[i] = Color[i];
}
} else {
result.depthStencil.depth = Color[0];
result.depthStencil.stencil = 0;
}
return result;
}
DxvkDataSlice D3D11DeviceContext::AllocUpdateBufferSlice(size_t Size) {
constexpr size_t UpdateBufferSize = 16 * 1024 * 1024;
if (Size >= UpdateBufferSize) {
Rc<DxvkDataBuffer> buffer = new DxvkDataBuffer(Size);
return buffer->alloc(Size);
} else {
if (m_updateBuffer == nullptr)
m_updateBuffer = new DxvkDataBuffer(UpdateBufferSize);
DxvkDataSlice slice = m_updateBuffer->alloc(Size);
if (slice.ptr() == nullptr) {
m_updateBuffer = new DxvkDataBuffer(UpdateBufferSize);
slice = m_updateBuffer->alloc(Size);
}
return slice;
}
}
DxvkCsChunkRef D3D11DeviceContext::AllocCsChunk() {
return m_parent->AllocCsChunk(m_csFlags);
}
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}