blob: 66703bd69f21521a29f261c835301d9b4031ef70 [file] [log] [blame]
/*
* Copyright 2020 Google Inc.
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#ifndef GrDirectContext_DEFINED
#define GrDirectContext_DEFINED
#include "include/gpu/GrRecordingContext.h"
#include "include/gpu/GrBackendSurface.h"
// We shouldn't need this but currently Android is relying on this being include transitively.
#include "include/core/SkUnPreMultiply.h"
class GrAtlasManager;
class GrBackendSemaphore;
class GrClientMappedBufferManager;
class GrDirectContextPriv;
class GrContextThreadSafeProxy;
struct GrD3DBackendContext;
class GrFragmentProcessor;
class GrGpu;
struct GrGLInterface;
struct GrMtlBackendContext;
struct GrMockOptions;
class GrPath;
class GrResourceCache;
class GrSmallPathAtlasMgr;
class GrResourceProvider;
class GrStrikeCache;
class GrSurfaceProxy;
class GrSwizzle;
class GrTextureProxy;
struct GrVkBackendContext;
class SkImage;
class SkString;
class SkSurfaceCharacterization;
class SkSurfaceProps;
class SkTaskGroup;
class SkTraceMemoryDump;
class SK_API GrDirectContext : public GrRecordingContext {
public:
#ifdef SK_GL
/**
* Creates a GrDirectContext for a backend context. If no GrGLInterface is provided then the
* result of GrGLMakeNativeInterface() is used if it succeeds.
*/
static sk_sp<GrDirectContext> MakeGL(sk_sp<const GrGLInterface>, const GrContextOptions&);
static sk_sp<GrDirectContext> MakeGL(sk_sp<const GrGLInterface>);
static sk_sp<GrDirectContext> MakeGL(const GrContextOptions&);
static sk_sp<GrDirectContext> MakeGL();
#endif
#ifdef SK_VULKAN
/**
* The Vulkan context (VkQueue, VkDevice, VkInstance) must be kept alive until the returned
* GrDirectContext is destroyed. This also means that any objects created with this
* GrDirectContext (e.g. SkSurfaces, SkImages, etc.) must also be released as they may hold
* refs on the GrDirectContext. Once all these objects and the GrDirectContext are released,
* then it is safe to delete the vulkan objects.
*/
static sk_sp<GrDirectContext> MakeVulkan(const GrVkBackendContext&, const GrContextOptions&);
static sk_sp<GrDirectContext> MakeVulkan(const GrVkBackendContext&);
#endif
#ifdef SK_METAL
/**
* Makes a GrDirectContext which uses Metal as the backend. The GrMtlBackendContext contains a
* MTLDevice and MTLCommandQueue which should be used by the backend. These objects must
* have their own ref which will be released when the GrMtlBackendContext is destroyed.
* Ganesh will take its own ref on the objects which will be released when the GrDirectContext
* is destroyed.
*/
static sk_sp<GrDirectContext> MakeMetal(const GrMtlBackendContext&, const GrContextOptions&);
static sk_sp<GrDirectContext> MakeMetal(const GrMtlBackendContext&);
/**
* Deprecated.
*
* Makes a GrDirectContext which uses Metal as the backend. The device parameter is an
* MTLDevice and queue is an MTLCommandQueue which should be used by the backend. These objects
* must have a ref on them that can be transferred to Ganesh, which will release the ref
* when the GrDirectContext is destroyed.
*/
static sk_sp<GrDirectContext> MakeMetal(void* device, void* queue, const GrContextOptions&);
static sk_sp<GrDirectContext> MakeMetal(void* device, void* queue);
#endif
#ifdef SK_DIRECT3D
/**
* Makes a GrDirectContext which uses Direct3D as the backend. The Direct3D context
* must be kept alive until the returned GrDirectContext is first destroyed or abandoned.
*/
static sk_sp<GrDirectContext> MakeDirect3D(const GrD3DBackendContext&, const GrContextOptions&);
static sk_sp<GrDirectContext> MakeDirect3D(const GrD3DBackendContext&);
#endif
#ifdef SK_DAWN
static sk_sp<GrDirectContext> MakeDawn(const wgpu::Device&,
const GrContextOptions&);
static sk_sp<GrDirectContext> MakeDawn(const wgpu::Device&);
#endif
static sk_sp<GrDirectContext> MakeMock(const GrMockOptions*, const GrContextOptions&);
static sk_sp<GrDirectContext> MakeMock(const GrMockOptions*);
~GrDirectContext() override;
/**
* The context normally assumes that no outsider is setting state
* within the underlying 3D API's context/device/whatever. This call informs
* the context that the state was modified and it should resend. Shouldn't
* be called frequently for good performance.
* The flag bits, state, is dependent on which backend is used by the
* context, either GL or D3D (possible in future).
*/
void resetContext(uint32_t state = kAll_GrBackendState);
/**
* If the backend is GrBackendApi::kOpenGL, then all texture unit/target combinations for which
* the context has modified the bound texture will have texture id 0 bound. This does not
* flush the context. Calling resetContext() does not change the set that will be bound
* to texture id 0 on the next call to resetGLTextureBindings(). After this is called
* all unit/target combinations are considered to have unmodified bindings until the context
* subsequently modifies them (meaning if this is called twice in a row with no intervening
* context usage then the second call is a no-op.)
*/
void resetGLTextureBindings();
/**
* Abandons all GPU resources and assumes the underlying backend 3D API context is no longer
* usable. Call this if you have lost the associated GPU context, and thus internal texture,
* buffer, etc. references/IDs are now invalid. Calling this ensures that the destructors of the
* context and any of its created resource objects will not make backend 3D API calls. Content
* rendered but not previously flushed may be lost. After this function is called all subsequent
* calls on the context will fail or be no-ops.
*
* The typical use case for this function is that the underlying 3D context was lost and further
* API calls may crash.
*
* For Vulkan, even if the device becomes lost, the VkQueue, VkDevice, or VkInstance used to
* create the context must be kept alive even after abandoning the context. Those objects must
* live for the lifetime of the context object itself. The reason for this is so that
* we can continue to delete any outstanding GrBackendTextures/RenderTargets which must be
* cleaned up even in a device lost state.
*/
void abandonContext() override;
/**
* Returns true if the context was abandoned or if the if the backend specific context has
* gotten into an unrecoverarble, lost state (e.g. in Vulkan backend if we've gotten a
* VK_ERROR_DEVICE_LOST). If the backend context is lost, this call will also abandon this
* context.
*/
bool abandoned() override;
// TODO: Remove this from public after migrating Chrome.
sk_sp<GrContextThreadSafeProxy> threadSafeProxy();
/**
* Checks if the underlying 3D API reported an out-of-memory error. If this returns true it is
* reset and will return false until another out-of-memory error is reported by the 3D API. If
* the context is abandoned then this will report false.
*
* Currently this is implemented for:
*
* OpenGL [ES] - Note that client calls to glGetError() may swallow GL_OUT_OF_MEMORY errors and
* therefore hide the error from Skia. Also, it is not advised to use this in combination with
* enabling GrContextOptions::fSkipGLErrorChecks. That option may prevent the context from ever
* checking the GL context for OOM.
*
* Vulkan - Reports true if VK_ERROR_OUT_OF_HOST_MEMORY or VK_ERROR_OUT_OF_DEVICE_MEMORY has
* occurred.
*/
bool oomed();
/**
* This is similar to abandonContext() however the underlying 3D context is not yet lost and
* the context will cleanup all allocated resources before returning. After returning it will
* assume that the underlying context may no longer be valid.
*
* The typical use case for this function is that the client is going to destroy the 3D context
* but can't guarantee that context will be destroyed first (perhaps because it may be ref'ed
* elsewhere by either the client or Skia objects).
*
* For Vulkan, even if the device becomes lost, the VkQueue, VkDevice, or VkInstance used to
* create the context must be alive before calling releaseResourcesAndAbandonContext.
*/
void releaseResourcesAndAbandonContext();
///////////////////////////////////////////////////////////////////////////
// Resource Cache
/** DEPRECATED
* Return the current GPU resource cache limits.
*
* @param maxResources If non-null, will be set to -1.
* @param maxResourceBytes If non-null, returns maximum number of bytes of
* video memory that can be held in the cache.
*/
void getResourceCacheLimits(int* maxResources, size_t* maxResourceBytes) const;
/**
* Return the current GPU resource cache limit in bytes.
*/
size_t getResourceCacheLimit() const;
/**
* Gets the current GPU resource cache usage.
*
* @param resourceCount If non-null, returns the number of resources that are held in the
* cache.
* @param maxResourceBytes If non-null, returns the total number of bytes of video memory held
* in the cache.
*/
void getResourceCacheUsage(int* resourceCount, size_t* resourceBytes) const;
/**
* Gets the number of bytes in the cache consumed by purgeable (e.g. unlocked) resources.
*/
size_t getResourceCachePurgeableBytes() const;
/** DEPRECATED
* Specify the GPU resource cache limits. If the current cache exceeds the maxResourceBytes
* limit, it will be purged (LRU) to keep the cache within the limit.
*
* @param maxResources Unused.
* @param maxResourceBytes The maximum number of bytes of video memory
* that can be held in the cache.
*/
void setResourceCacheLimits(int maxResources, size_t maxResourceBytes);
/**
* Specify the GPU resource cache limit. If the cache currently exceeds this limit,
* it will be purged (LRU) to keep the cache within the limit.
*
* @param maxResourceBytes The maximum number of bytes of video memory
* that can be held in the cache.
*/
void setResourceCacheLimit(size_t maxResourceBytes);
/**
* Frees GPU created by the context. Can be called to reduce GPU memory
* pressure.
*/
void freeGpuResources();
/**
* Purge GPU resources that haven't been used in the past 'msNotUsed' milliseconds or are
* otherwise marked for deletion, regardless of whether the context is under budget.
*
* If 'scratchResourcesOnly' is true all unlocked scratch resources older than 'msNotUsed' will
* be purged but the unlocked resources with persistent data will remain. If
* 'scratchResourcesOnly' is false then all unlocked resources older than 'msNotUsed' will be
* purged.
*
* @param msNotUsed Only unlocked resources not used in these last milliseconds
* will be cleaned up.
* @param scratchResourcesOnly If true only unlocked scratch resources will be purged.
*/
void performDeferredCleanup(std::chrono::milliseconds msNotUsed,
bool scratchResourcesOnly=false);
// Temporary compatibility API for Android.
void purgeResourcesNotUsedInMs(std::chrono::milliseconds msNotUsed) {
this->performDeferredCleanup(msNotUsed);
}
/**
* Purge unlocked resources from the cache until the the provided byte count has been reached
* or we have purged all unlocked resources. The default policy is to purge in LRU order, but
* can be overridden to prefer purging scratch resources (in LRU order) prior to purging other
* resource types.
*
* @param maxBytesToPurge the desired number of bytes to be purged.
* @param preferScratchResources If true scratch resources will be purged prior to other
* resource types.
*/
void purgeUnlockedResources(size_t bytesToPurge, bool preferScratchResources);
/**
* This entry point is intended for instances where an app has been backgrounded or
* suspended.
* If 'scratchResourcesOnly' is true all unlocked scratch resources will be purged but the
* unlocked resources with persistent data will remain. If 'scratchResourcesOnly' is false
* then all unlocked resources will be purged.
* In either case, after the unlocked resources are purged a separate pass will be made to
* ensure that resource usage is under budget (i.e., even if 'scratchResourcesOnly' is true
* some resources with persistent data may be purged to be under budget).
*
* @param scratchResourcesOnly If true only unlocked scratch resources will be purged prior
* enforcing the budget requirements.
*/
void purgeUnlockedResources(bool scratchResourcesOnly);
/**
* Gets the maximum supported texture size.
*/
using GrRecordingContext::maxTextureSize;
/**
* Gets the maximum supported render target size.
*/
using GrRecordingContext::maxRenderTargetSize;
/**
* Can a SkImage be created with the given color type.
*/
using GrRecordingContext::colorTypeSupportedAsImage;
/**
* Can a SkSurface be created with the given color type. To check whether MSAA is supported
* use maxSurfaceSampleCountForColorType().
*/
using GrRecordingContext::colorTypeSupportedAsSurface;
/**
* Gets the maximum supported sample count for a color type. 1 is returned if only non-MSAA
* rendering is supported for the color type. 0 is returned if rendering to this color type
* is not supported at all.
*/
using GrRecordingContext::maxSurfaceSampleCountForColorType;
///////////////////////////////////////////////////////////////////////////
// Misc.
/**
* Inserts a list of GPU semaphores that the current GPU-backed API must wait on before
* executing any more commands on the GPU. If this call returns false, then the GPU back-end
* will not wait on any passed in semaphores, and the client will still own the semaphores,
* regardless of the value of deleteSemaphoresAfterWait.
*
* If deleteSemaphoresAfterWait is false then Skia will not delete the semaphores. In this case
* it is the client's responsibility to not destroy or attempt to reuse the semaphores until it
* knows that Skia has finished waiting on them. This can be done by using finishedProcs on
* flush calls.
*/
bool wait(int numSemaphores, const GrBackendSemaphore* waitSemaphores,
bool deleteSemaphoresAfterWait = true);
/**
* Call to ensure all drawing to the context has been flushed and submitted to the underlying 3D
* API. This is equivalent to calling GrContext::flush with a default GrFlushInfo followed by
* GrContext::submit(syncCpu).
*/
void flushAndSubmit(bool syncCpu = false) {
this->flush(GrFlushInfo());
this->submit(syncCpu);
}
/**
* Call to ensure all drawing to the context has been flushed to underlying 3D API specific
* objects. A call to `submit` is always required to ensure work is actually sent to
* the gpu. Some specific API details:
* GL: Commands are actually sent to the driver, but glFlush is never called. Thus some
* sync objects from the flush will not be valid until a submission occurs.
*
* Vulkan/Metal/D3D/Dawn: Commands are recorded to the backend APIs corresponding command
* buffer or encoder objects. However, these objects are not sent to the gpu until a
* submission occurs.
*
* If the return is GrSemaphoresSubmitted::kYes, only initialized GrBackendSemaphores will be
* submitted to the gpu during the next submit call (it is possible Skia failed to create a
* subset of the semaphores). The client should not wait on these semaphores until after submit
* has been called, and must keep them alive until then. If this call returns
* GrSemaphoresSubmitted::kNo, the GPU backend will not submit any semaphores to be signaled on
* the GPU. Thus the client should not have the GPU wait on any of the semaphores passed in with
* the GrFlushInfo. Regardless of whether semaphores were submitted to the GPU or not, the
* client is still responsible for deleting any initialized semaphores.
* Regardleess of semaphore submission the context will still be flushed. It should be
* emphasized that a return value of GrSemaphoresSubmitted::kNo does not mean the flush did not
* happen. It simply means there were no semaphores submitted to the GPU. A caller should only
* take this as a failure if they passed in semaphores to be submitted.
*/
GrSemaphoresSubmitted flush(const GrFlushInfo& info);
void flush() { this->flush({}); }
/**
* Submit outstanding work to the gpu from all previously un-submitted flushes. The return
* value of the submit will indicate whether or not the submission to the GPU was successful.
*
* If the call returns true, all previously passed in semaphores in flush calls will have been
* submitted to the GPU and they can safely be waited on. The caller should wait on those
* semaphores or perform some other global synchronization before deleting the semaphores.
*
* If it returns false, then those same semaphores will not have been submitted and we will not
* try to submit them again. The caller is free to delete the semaphores at any time.
*
* If the syncCpu flag is true this function will return once the gpu has finished with all
* submitted work.
*/
bool submit(bool syncCpu = false);
/**
* Checks whether any asynchronous work is complete and if so calls related callbacks.
*/
void checkAsyncWorkCompletion();
/** Enumerates all cached GPU resources and dumps their memory to traceMemoryDump. */
// Chrome is using this!
void dumpMemoryStatistics(SkTraceMemoryDump* traceMemoryDump) const;
bool supportsDistanceFieldText() const;
void storeVkPipelineCacheData();
/**
* Retrieve the default GrBackendFormat for a given SkColorType and renderability.
* It is guaranteed that this backend format will be the one used by the following
* SkColorType and SkSurfaceCharacterization-based createBackendTexture methods.
*
* The caller should check that the returned format is valid.
*/
using GrRecordingContext::defaultBackendFormat;
/**
* The explicitly allocated backend texture API allows clients to use Skia to create backend
* objects outside of Skia proper (i.e., Skia's caching system will not know about them.)
*
* It is the client's responsibility to delete all these objects (using deleteBackendTexture)
* before deleting the context used to create them. If the backend is Vulkan, the textures must
* be deleted before abandoning the context as well. Additionally, clients should only delete
* these objects on the thread for which that context is active.
*
* The client is responsible for ensuring synchronization between different uses
* of the backend object (i.e., wrapping it in a surface, rendering to it, deleting the
* surface, rewrapping it in a image and drawing the image will require explicit
* synchronization on the client's part).
*/
/**
* If possible, create an uninitialized backend texture. The client should ensure that the
* returned backend texture is valid.
* For the Vulkan backend the layout of the created VkImage will be:
* VK_IMAGE_LAYOUT_UNDEFINED.
*/
GrBackendTexture createBackendTexture(int width, int height,
const GrBackendFormat&,
GrMipmapped,
GrRenderable,
GrProtected = GrProtected::kNo);
/**
* If possible, create an uninitialized backend texture. The client should ensure that the
* returned backend texture is valid.
* If successful, the created backend texture will be compatible with the provided
* SkColorType.
* For the Vulkan backend the layout of the created VkImage will be:
* VK_IMAGE_LAYOUT_UNDEFINED.
*/
GrBackendTexture createBackendTexture(int width, int height,
SkColorType,
GrMipmapped,
GrRenderable,
GrProtected = GrProtected::kNo);
/**
* If possible, create a backend texture initialized to a particular color. The client should
* ensure that the returned backend texture is valid. The client can pass in a finishedProc
* to be notified when the data has been uploaded by the gpu and the texture can be deleted. The
* client is required to call `submit` to send the upload work to the gpu. The
* finishedProc will always get called even if we failed to create the GrBackendTexture.
* For the Vulkan backend the layout of the created VkImage will be:
* VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL
*/
GrBackendTexture createBackendTexture(int width, int height,
const GrBackendFormat&,
const SkColor4f& color,
GrMipmapped,
GrRenderable,
GrProtected = GrProtected::kNo,
GrGpuFinishedProc finishedProc = nullptr,
GrGpuFinishedContext finishedContext = nullptr);
/**
* If possible, create a backend texture initialized to a particular color. The client should
* ensure that the returned backend texture is valid. The client can pass in a finishedProc
* to be notified when the data has been uploaded by the gpu and the texture can be deleted. The
* client is required to call `submit` to send the upload work to the gpu. The
* finishedProc will always get called even if we failed to create the GrBackendTexture.
* If successful, the created backend texture will be compatible with the provided
* SkColorType.
* For the Vulkan backend the layout of the created VkImage will be:
* VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL
*/
GrBackendTexture createBackendTexture(int width, int height,
SkColorType,
const SkColor4f& color,
GrMipmapped,
GrRenderable,
GrProtected = GrProtected::kNo,
GrGpuFinishedProc finishedProc = nullptr,
GrGpuFinishedContext finishedContext = nullptr);
/**
* If possible, create a backend texture initialized with the provided pixmap data. The client
* should ensure that the returned backend texture is valid. The client can pass in a
* finishedProc to be notified when the data has been uploaded by the gpu and the texture can be
* deleted. The client is required to call `submit` to send the upload work to the gpu.
* The finishedProc will always get called even if we failed to create the GrBackendTexture.
* If successful, the created backend texture will be compatible with the provided
* pixmap(s). Compatible, in this case, means that the backend format will be the result
* of calling defaultBackendFormat on the base pixmap's colortype. The src data can be deleted
* when this call returns.
* If numLevels is 1 a non-mipMapped texture will result. If a mipMapped texture is desired
* the data for all the mipmap levels must be provided. In the mipmapped case all the
* colortypes of the provided pixmaps must be the same. Additionally, all the miplevels
* must be sized correctly (please see SkMipmap::ComputeLevelSize and ComputeLevelCount). The
* GrSurfaceOrigin controls whether the pixmap data is vertically flipped in the texture.
* Note: the pixmap's alphatypes and colorspaces are ignored.
* For the Vulkan backend the layout of the created VkImage will be:
* VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL
*/
GrBackendTexture createBackendTexture(const SkPixmap srcData[],
int numLevels,
GrSurfaceOrigin,
GrRenderable,
GrProtected,
GrGpuFinishedProc finishedProc = nullptr,
GrGpuFinishedContext finishedContext = nullptr);
/**
* Convenience version createBackendTexture() that takes just a base level pixmap.
*/
GrBackendTexture createBackendTexture(const SkPixmap& srcData,
GrSurfaceOrigin textureOrigin,
GrRenderable renderable,
GrProtected isProtected,
GrGpuFinishedProc finishedProc = nullptr,
GrGpuFinishedContext finishedContext = nullptr) {
return this->createBackendTexture(&srcData, 1, textureOrigin, renderable, isProtected,
finishedProc, finishedContext);
}
// Deprecated versions that do not take origin and assume top-left.
GrBackendTexture createBackendTexture(const SkPixmap srcData[],
int numLevels,
GrRenderable renderable,
GrProtected isProtected,
GrGpuFinishedProc finishedProc = nullptr,
GrGpuFinishedContext finishedContext = nullptr) {
return this->createBackendTexture(srcData,
numLevels,
kTopLeft_GrSurfaceOrigin,
renderable,
isProtected,
finishedProc,
finishedContext);
}
GrBackendTexture createBackendTexture(const SkPixmap& srcData,
GrRenderable renderable,
GrProtected isProtected,
GrGpuFinishedProc finishedProc = nullptr,
GrGpuFinishedContext finishedContext = nullptr) {
return this->createBackendTexture(&srcData,
1,
renderable,
isProtected,
finishedProc,
finishedContext);
}
/**
* If possible, updates a backend texture to be filled to a particular color. The client should
* check the return value to see if the update was successful. The client can pass in a
* finishedProc to be notified when the data has been uploaded by the gpu and the texture can be
* deleted. The client is required to call `submit` to send the upload work to the gpu.
* The finishedProc will always get called even if we failed to update the GrBackendTexture.
* For the Vulkan backend after a successful update the layout of the created VkImage will be:
* VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL
*/
bool updateBackendTexture(const GrBackendTexture&,
const SkColor4f& color,
GrGpuFinishedProc finishedProc,
GrGpuFinishedContext finishedContext);
/**
* If possible, updates a backend texture to be filled to a particular color. The data in
* GrBackendTexture and passed in color is interpreted with respect to the passed in
* SkColorType. The client should check the return value to see if the update was successful.
* The client can pass in a finishedProc to be notified when the data has been uploaded by the
* gpu and the texture can be deleted. The client is required to call `submit` to send
* the upload work to the gpu. The finishedProc will always get called even if we failed to
* update the GrBackendTexture.
* For the Vulkan backend after a successful update the layout of the created VkImage will be:
* VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL
*/
bool updateBackendTexture(const GrBackendTexture&,
SkColorType skColorType,
const SkColor4f& color,
GrGpuFinishedProc finishedProc,
GrGpuFinishedContext finishedContext);
/**
* If possible, updates a backend texture filled with the provided pixmap data. The client
* should check the return value to see if the update was successful. The client can pass in a
* finishedProc to be notified when the data has been uploaded by the gpu and the texture can be
* deleted. The client is required to call `submit` to send the upload work to the gpu.
* The finishedProc will always get called even if we failed to create the GrBackendTexture.
* The backend texture must be compatible with the provided pixmap(s). Compatible, in this case,
* means that the backend format is compatible with the base pixmap's colortype. The src data
* can be deleted when this call returns.
* If the backend texture is mip mapped, the data for all the mipmap levels must be provided.
* In the mipmapped case all the colortypes of the provided pixmaps must be the same.
* Additionally, all the miplevels must be sized correctly (please see
* SkMipmap::ComputeLevelSize and ComputeLevelCount). The GrSurfaceOrigin controls whether the
* pixmap data is vertically flipped in the texture.
* Note: the pixmap's alphatypes and colorspaces are ignored.
* For the Vulkan backend after a successful update the layout of the created VkImage will be:
* VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL
*/
bool updateBackendTexture(const GrBackendTexture&,
const SkPixmap srcData[],
int numLevels,
GrSurfaceOrigin = kTopLeft_GrSurfaceOrigin,
GrGpuFinishedProc finishedProc = nullptr,
GrGpuFinishedContext finishedContext = nullptr);
/**
* Convenience version of updateBackendTexture that takes just a base level pixmap.
*/
bool updateBackendTexture(const GrBackendTexture& texture,
const SkPixmap& srcData,
GrSurfaceOrigin textureOrigin = kTopLeft_GrSurfaceOrigin,
GrGpuFinishedProc finishedProc = nullptr,
GrGpuFinishedContext finishedContext = nullptr) {
return this->updateBackendTexture(texture,
&srcData,
1,
textureOrigin,
finishedProc,
finishedContext);
}
// Deprecated version that does not take origin and assumes top-left.
bool updateBackendTexture(const GrBackendTexture& texture,
const SkPixmap srcData[],
int numLevels,
GrGpuFinishedProc finishedProc,
GrGpuFinishedContext finishedContext) {
return this->updateBackendTexture(texture,
srcData,
numLevels,
kTopLeft_GrSurfaceOrigin,
finishedProc,
finishedContext);
}
/**
* Retrieve the GrBackendFormat for a given SkImage::CompressionType. This is
* guaranteed to match the backend format used by the following
* createCompressedBackendTexture methods that take a CompressionType.
*
* The caller should check that the returned format is valid.
*/
using GrRecordingContext::compressedBackendFormat;
/**
*If possible, create a compressed backend texture initialized to a particular color. The
* client should ensure that the returned backend texture is valid. The client can pass in a
* finishedProc to be notified when the data has been uploaded by the gpu and the texture can be
* deleted. The client is required to call `submit` to send the upload work to the gpu.
* The finishedProc will always get called even if we failed to create the GrBackendTexture.
* For the Vulkan backend the layout of the created VkImage will be:
* VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL
*/
GrBackendTexture createCompressedBackendTexture(int width, int height,
const GrBackendFormat&,
const SkColor4f& color,
GrMipmapped,
GrProtected = GrProtected::kNo,
GrGpuFinishedProc finishedProc = nullptr,
GrGpuFinishedContext finishedContext = nullptr);
GrBackendTexture createCompressedBackendTexture(int width, int height,
SkImage::CompressionType,
const SkColor4f& color,
GrMipmapped,
GrProtected = GrProtected::kNo,
GrGpuFinishedProc finishedProc = nullptr,
GrGpuFinishedContext finishedContext = nullptr);
/**
* If possible, create a backend texture initialized with the provided raw data. The client
* should ensure that the returned backend texture is valid. The client can pass in a
* finishedProc to be notified when the data has been uploaded by the gpu and the texture can be
* deleted. The client is required to call `submit` to send the upload work to the gpu.
* The finishedProc will always get called even if we failed to create the GrBackendTexture
* If numLevels is 1 a non-mipMapped texture will result. If a mipMapped texture is desired
* the data for all the mipmap levels must be provided. Additionally, all the miplevels
* must be sized correctly (please see SkMipmap::ComputeLevelSize and ComputeLevelCount).
* For the Vulkan backend the layout of the created VkImage will be:
* VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL
*/
GrBackendTexture createCompressedBackendTexture(int width, int height,
const GrBackendFormat&,
const void* data, size_t dataSize,
GrMipmapped,
GrProtected = GrProtected::kNo,
GrGpuFinishedProc finishedProc = nullptr,
GrGpuFinishedContext finishedContext = nullptr);
GrBackendTexture createCompressedBackendTexture(int width, int height,
SkImage::CompressionType,
const void* data, size_t dataSize,
GrMipmapped,
GrProtected = GrProtected::kNo,
GrGpuFinishedProc finishedProc = nullptr,
GrGpuFinishedContext finishedContext = nullptr);
/**
* If possible, updates a backend texture filled with the provided color. If the texture is
* mipmapped, all levels of the mip chain will be updated to have the supplied color. The client
* should check the return value to see if the update was successful. The client can pass in a
* finishedProc to be notified when the data has been uploaded by the gpu and the texture can be
* deleted. The client is required to call `submit` to send the upload work to the gpu.
* The finishedProc will always get called even if we failed to create the GrBackendTexture.
* For the Vulkan backend after a successful update the layout of the created VkImage will be:
* VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL
*/
bool updateCompressedBackendTexture(const GrBackendTexture&,
const SkColor4f& color,
GrGpuFinishedProc finishedProc,
GrGpuFinishedContext finishedContext);
/**
* If possible, updates a backend texture filled with the provided raw data. The client
* should check the return value to see if the update was successful. The client can pass in a
* finishedProc to be notified when the data has been uploaded by the gpu and the texture can be
* deleted. The client is required to call `submit` to send the upload work to the gpu.
* The finishedProc will always get called even if we failed to create the GrBackendTexture.
* If a mipMapped texture is passed in, the data for all the mipmap levels must be provided.
* Additionally, all the miplevels must be sized correctly (please see
* SkMipMap::ComputeLevelSize and ComputeLevelCount).
* For the Vulkan backend after a successful update the layout of the created VkImage will be:
* VK_IMAGE_LAYOUT_SHADER_READ_ONLY_OPTIMAL
*/
bool updateCompressedBackendTexture(const GrBackendTexture&,
const void* data,
size_t dataSize,
GrGpuFinishedProc finishedProc,
GrGpuFinishedContext finishedContext);
/**
* Updates the state of the GrBackendTexture/RenderTarget to have the passed in
* GrBackendSurfaceMutableState. All objects that wrap the backend surface (i.e. SkSurfaces and
* SkImages) will also be aware of this state change. This call does not submit the state change
* to the gpu, but requires the client to call `submit` to send it to the GPU. The work
* for this call is ordered linearly with all other calls that require GrContext::submit to be
* called (e.g updateBackendTexture and flush). If finishedProc is not null then it will be
* called with finishedContext after the state transition is known to have occurred on the GPU.
*
* See GrBackendSurfaceMutableState to see what state can be set via this call.
*
* If the backend API is Vulkan, the caller can set the GrBackendSurfaceMutableState's
* VkImageLayout to VK_IMAGE_LAYOUT_UNDEFINED or queueFamilyIndex to VK_QUEUE_FAMILY_IGNORED to
* tell Skia to not change those respective states.
*
* If previousState is not null and this returns true, then Skia will have filled in
* previousState to have the values of the state before this call.
*/
bool setBackendTextureState(const GrBackendTexture&,
const GrBackendSurfaceMutableState&,
GrBackendSurfaceMutableState* previousState = nullptr,
GrGpuFinishedProc finishedProc = nullptr,
GrGpuFinishedContext finishedContext = nullptr);
bool setBackendRenderTargetState(const GrBackendRenderTarget&,
const GrBackendSurfaceMutableState&,
GrBackendSurfaceMutableState* previousState = nullptr,
GrGpuFinishedProc finishedProc = nullptr,
GrGpuFinishedContext finishedContext = nullptr);
void deleteBackendTexture(GrBackendTexture);
// This interface allows clients to pre-compile shaders and populate the runtime program cache.
// The key and data blobs should be the ones passed to the PersistentCache, in SkSL format.
//
// Steps to use this API:
//
// 1) Create a GrDirectContext as normal, but set fPersistentCache on GrContextOptions to
// something that will save the cached shader blobs. Set fShaderCacheStrategy to kSkSL. This
// will ensure that the blobs are SkSL, and are suitable for pre-compilation.
// 2) Run your application, and save all of the key/data pairs that are fed to the cache.
//
// 3) Switch over to shipping your application. Include the key/data pairs from above.
// 4) At startup (or any convenient time), call precompileShader for each key/data pair.
// This will compile the SkSL to create a GL program, and populate the runtime cache.
//
// This is only guaranteed to work if the context/device used in step #2 are created in the
// same way as the one used in step #4, and the same GrContextOptions are specified.
// Using cached shader blobs on a different device or driver are undefined.
bool precompileShader(const SkData& key, const SkData& data);
#ifdef SK_ENABLE_DUMP_GPU
/** Returns a string with detailed information about the context & GPU, in JSON format. */
SkString dump() const;
#endif
class DirectContextID {
public:
static GrDirectContext::DirectContextID Next();
DirectContextID() : fID(SK_InvalidUniqueID) {}
bool operator==(const DirectContextID& that) const { return fID == that.fID; }
bool operator!=(const DirectContextID& that) const { return !(*this == that); }
void makeInvalid() { fID = SK_InvalidUniqueID; }
bool isValid() const { return fID != SK_InvalidUniqueID; }
private:
constexpr DirectContextID(uint32_t id) : fID(id) {}
uint32_t fID;
};
DirectContextID directContextID() const { return fDirectContextID; }
// Provides access to functions that aren't part of the public API.
GrDirectContextPriv priv();
const GrDirectContextPriv priv() const; // NOLINT(readability-const-return-type)
protected:
GrDirectContext(GrBackendApi backend, const GrContextOptions& options);
bool init() override;
GrAtlasManager* onGetAtlasManager() { return fAtlasManager.get(); }
GrSmallPathAtlasMgr* onGetSmallPathAtlasMgr();
GrDirectContext* asDirectContext() override { return this; }
private:
// This call will make sure out work on the GPU is finished and will execute any outstanding
// asynchronous work (e.g. calling finished procs, freeing resources, etc.) related to the
// outstanding work on the gpu. The main use currently for this function is when tearing down or
// abandoning the context.
//
// When we finish up work on the GPU it could trigger callbacks to the client. In the case we
// are abandoning the context we don't want the client to be able to use the GrDirectContext to
// issue more commands during the callback. Thus before calling this function we set the
// GrDirectContext's state to be abandoned. However, we need to be able to get by the abaonded
// check in the call to know that it is safe to execute this. The shouldExecuteWhileAbandoned
// bool is used for this signal.
void syncAllOutstandingGpuWork(bool shouldExecuteWhileAbandoned);
const DirectContextID fDirectContextID;
// fTaskGroup must appear before anything that uses it (e.g. fGpu), so that it is destroyed
// after all of its users. Clients of fTaskGroup will generally want to ensure that they call
// wait() on it as they are being destroyed, to avoid the possibility of pending tasks being
// invoked after objects they depend upon have already been destroyed.
std::unique_ptr<SkTaskGroup> fTaskGroup;
std::unique_ptr<GrStrikeCache> fStrikeCache;
sk_sp<GrGpu> fGpu;
std::unique_ptr<GrResourceCache> fResourceCache;
std::unique_ptr<GrResourceProvider> fResourceProvider;
bool fDidTestPMConversions;
// true if the PM/UPM conversion succeeded; false otherwise
bool fPMUPMConversionsRoundTrip;
GrContextOptions::PersistentCache* fPersistentCache;
std::unique_ptr<GrClientMappedBufferManager> fMappedBufferManager;
std::unique_ptr<GrAtlasManager> fAtlasManager;
std::unique_ptr<GrSmallPathAtlasMgr> fSmallPathAtlasMgr;
friend class GrDirectContextPriv;
using INHERITED = GrRecordingContext;
};
#endif