/* * Copyright 2016 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #ifndef GrTextureProxy_DEFINED #define GrTextureProxy_DEFINED #include "GrSamplerState.h" #include "GrSurfaceProxy.h" class GrCaps; class GrDeferredProxyUploader; class GrProxyProvider; class GrResourceProvider; class GrTextureOpList; class GrTextureProxyPriv; // This class delays the acquisition of textures until they are actually required class GrTextureProxy : virtual public GrSurfaceProxy { public: GrTextureProxy* asTextureProxy() override { return this; } const GrTextureProxy* asTextureProxy() const override { return this; } // Actually instantiate the backing texture, if necessary bool instantiate(GrResourceProvider*, bool dontForceNoPendingIO = false) override; GrSamplerState::Filter highestFilterMode() const; // If we are instantiated and have a target, return the mip state of that target. Otherwise // returns the proxy's mip state from creation time. This is useful for lazy proxies which may // claim to not need mips at creation time, but the instantiation happens to give us a mipped // target. In that case we should use that for our benefit to avoid possible copies/mip // generation later. GrMipMapped mipMapped() const; // Returns the GrMipMapped value of the proxy from creation time regardless of whether it has // been instantiated or not. GrMipMapped proxyMipMapped() const { return fMipMapped; } GrTextureType textureType() const { return this->backendFormat().textureType(); } /** If true then the texture does not support MIP maps and only supports clamp wrap mode. */ bool hasRestrictedSampling() const { return GrTextureTypeHasRestrictedSampling(this->textureType()); } // Returns true if the passed in proxies can be used as dynamic state together when flushing // draws to the gpu. static bool ProxiesAreCompatibleAsDynamicState(const GrTextureProxy* first, const GrTextureProxy* second); /** * Return the texture proxy's unique key. It will be invalid if the proxy doesn't have one. */ const GrUniqueKey& getUniqueKey() const { #ifdef SK_DEBUG if (fTarget && fUniqueKey.isValid() && fSyncTargetKey) { SkASSERT(fTarget->getUniqueKey().isValid()); // It is possible for a non-keyed proxy to have a uniquely keyed resource assigned to // it. This just means that a future user of the resource will be filling it with unique // data. However, if the proxy has a unique key its attached resource should also // have that key. SkASSERT(fUniqueKey == fTarget->getUniqueKey()); } #endif return fUniqueKey; } /** * Internal-only helper class used for manipulations of the resource by the cache. */ class CacheAccess; inline CacheAccess cacheAccess(); inline const CacheAccess cacheAccess() const; // Provides access to special purpose functions. GrTextureProxyPriv texPriv(); const GrTextureProxyPriv texPriv() const; protected: // DDL TODO: rm the GrSurfaceProxy friending friend class GrSurfaceProxy; // for ctors friend class GrProxyProvider; // for ctors friend class GrTextureProxyPriv; friend class GrSurfaceProxyPriv; // ability to change key sync state after lazy instantiation. // Deferred version - when constructed with data the origin is always kTopLeft. GrTextureProxy(const GrBackendFormat&, const GrSurfaceDesc& srcDesc, GrMipMapped, SkBackingFit, SkBudgeted, const void* srcData, size_t srcRowBytes, GrInternalSurfaceFlags); // Deferred version - no data. GrTextureProxy(const GrBackendFormat&, const GrSurfaceDesc& srcDesc, GrSurfaceOrigin, GrMipMapped, SkBackingFit, SkBudgeted, GrInternalSurfaceFlags); // Lazy-callback version // There are two main use cases for lazily-instantiated proxies: // basic knowledge - width, height, config, origin are known // minimal knowledge - only config is known. // // The basic knowledge version is used for DDL where we know the type of proxy we are going to // use, but we don't have access to the GPU yet to instantiate it. // // The minimal knowledge version is used for CCPR where we are generating an atlas but we do not // know the final size until flush time. GrTextureProxy(LazyInstantiateCallback&&, LazyInstantiationType, const GrBackendFormat&, const GrSurfaceDesc& desc, GrSurfaceOrigin, GrMipMapped, SkBackingFit, SkBudgeted, GrInternalSurfaceFlags); // Wrapped version GrTextureProxy(sk_sp, GrSurfaceOrigin); ~GrTextureProxy() override; sk_sp createSurface(GrResourceProvider*) const override; void setTargetKeySync(bool sync) { fSyncTargetKey = sync; } private: // WARNING: Be careful when adding or removing fields here. ASAN is likely to trigger warnings // when instantiating GrTextureRenderTargetProxy. The std::function in GrSurfaceProxy makes // each class in the diamond require 16 byte alignment. Clang appears to layout the fields for // each class to achieve the necessary alignment. However, ASAN checks the alignment of 'this' // in the constructors, and always looks for the full 16 byte alignment, even if the fields in // that particular class don't require it. Changing the size of this object can move the start // address of other types, leading to this problem. GrMipMapped fMipMapped; bool fSyncTargetKey = true; // Should target's unique key be sync'ed with ours. GrUniqueKey fUniqueKey; GrProxyProvider* fProxyProvider; // only set when fUniqueKey is valid // Only used for proxies whose contents are being prepared on a worker thread. This object // stores the texture data, allowing the proxy to remain uninstantiated until flush. At that // point, the proxy is instantiated, and this data is used to perform an ASAP upload. std::unique_ptr fDeferredUploader; size_t onUninstantiatedGpuMemorySize() const override; // Methods made available via GrTextureProxy::CacheAccess void setUniqueKey(GrProxyProvider*, const GrUniqueKey&); void clearUniqueKey(); SkDEBUGCODE(void onValidateSurface(const GrSurface*) override;) // For wrapped proxies the GrTexture pointer is stored in GrIORefProxy. // For deferred proxies that pointer will be filled in when we need to instantiate // the deferred resource typedef GrSurfaceProxy INHERITED; }; #endif