src/gpu/GrResourceAllocator.h - skia - Git at Google

 /*
  * Copyright 2017 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef GrResourceAllocator_DEFINED
 #define GrResourceAllocator_DEFINED

 #include "GrGpuResourcePriv.h"
 #include "GrSurface.h"
 #include "GrSurfaceProxy.h"

 #include "SkArenaAlloc.h"
 #include "SkTDynamicHash.h"
 #include "SkTMultiMap.h"

 class GrResourceProvider;
 class GrUninstantiateProxyTracker;

 /*
  * The ResourceAllocator explicitly distributes GPU resources at flush time. It operates by
  * being given the usage intervals of the various proxies. It keeps these intervals in a singly
  * linked list sorted by increasing start index. (It also maintains a hash table from proxyID
  * to interval to find proxy reuse). When it comes time to allocate the resources it
  * traverses the sorted list and:
  *     removes intervals from the active list that have completed (returning their GrSurfaces
  *     to the free pool)

  *     allocates a new resource (preferably from the free pool) for the new interval
  *     adds the new interval to the active list (that is sorted by increasing end index)
  *
  * Note: the op indices (used in the usage intervals) come from the order of the ops in
  * their opLists after the opList DAG has been linearized.
  */
 class GrResourceAllocator {
 public:
     GrResourceAllocator(GrResourceProvider* resourceProvider)
             : fResourceProvider(resourceProvider) {
     }

     ~GrResourceAllocator();

     unsigned int curOp() const { return fNumOps; }
     void incOps() { fNumOps++; }
     unsigned int numOps() const { return fNumOps; }

     // Add a usage interval from 'start' to 'end' inclusive. This is usually used for renderTargets.
     // If an existing interval already exists it will be expanded to include the new range.
     void addInterval(GrSurfaceProxy*, unsigned int start, unsigned int end
                      SkDEBUGCODE(, bool isDirectDstRead = false));

     // Add an interval that spans just the current op. Usually this is for texture uses.
     // If an existing interval already exists it will be expanded to include the new operation.
     void addInterval(GrSurfaceProxy* proxy
                      SkDEBUGCODE(, bool isDirectDstRead = false)) {
         this->addInterval(proxy, fNumOps, fNumOps SkDEBUGCODE(, isDirectDstRead));
     }

     enum class AssignError {
         kNoError,
         kFailedProxyInstantiation
     };

     // Returns true when the opLists from 'startIndex' to 'stopIndex' should be executed;
     // false when nothing remains to be executed.
     // If any proxy fails to instantiate, the AssignError will be set to kFailedProxyInstantiation.
     // If this happens, the caller should remove all ops which reference an uninstantiated proxy.
     // This is used to execute a portion of the queued opLists in order to reduce the total
     // amount of GPU resources required.
     bool assign(int* startIndex, int* stopIndex, GrUninstantiateProxyTracker*,
                 AssignError* outError);

     void markEndOfOpList(int opListIndex);

 private:
     class Interval;

     // Remove dead intervals from the active list
     void expire(unsigned int curIndex);

     // These two methods wrap the interactions with the free pool
     void freeUpSurface(sk_sp<GrSurface> surface);
     sk_sp<GrSurface> findSurfaceFor(const GrSurfaceProxy* proxy, bool needsStencil);

     struct FreePoolTraits {
         static const GrScratchKey& GetKey(const GrSurface& s) {
             return s.resourcePriv().getScratchKey();
         }

         static uint32_t Hash(const GrScratchKey& key) { return key.hash(); }
         static void OnFree(GrSurface* s) { s->unref(); }
     };
     typedef SkTMultiMap<GrSurface, GrScratchKey, FreePoolTraits> FreePoolMultiMap;

     typedef SkTDynamicHash<Interval, unsigned int> IntvlHash;

     class Interval {
     public:
         Interval(GrSurfaceProxy* proxy, unsigned int start, unsigned int end)
             : fProxy(proxy)
             , fProxyID(proxy->uniqueID().asUInt())
             , fStart(start)
             , fEnd(end)
             , fNext(nullptr) {
             SkASSERT(proxy);
         }

         void resetTo(GrSurfaceProxy* proxy, unsigned int start, unsigned int end) {
             SkASSERT(proxy);

             fProxy = proxy;
             fProxyID = proxy->uniqueID().asUInt();
             fStart = start;
             fEnd = end;
             fNext = nullptr;
         }

         ~Interval() {
             SkASSERT(!fAssignedSurface);
         }

         const GrSurfaceProxy* proxy() const { return fProxy; }
         GrSurfaceProxy* proxy() { return fProxy; }
         unsigned int start() const { return fStart; }
         unsigned int end() const { return fEnd; }
         const Interval* next() const { return fNext; }
         Interval* next() { return fNext; }

         void setNext(Interval* next) { fNext = next; }

         void extendEnd(unsigned int newEnd) {
             if (newEnd > fEnd) {
                 fEnd = newEnd;
             }
         }

         void assign(sk_sp<GrSurface>);
         bool wasAssignedSurface() const { return fAssignedSurface != nullptr; }
         sk_sp<GrSurface> detachSurface() { return std::move(fAssignedSurface); }

         // for SkTDynamicHash
         static const uint32_t& GetKey(const Interval& intvl) {
             return intvl.fProxyID;
         }
         static uint32_t Hash(const uint32_t& key) { return key; }

     private:
         sk_sp<GrSurface> fAssignedSurface;
         GrSurfaceProxy*  fProxy;
         uint32_t         fProxyID; // This is here b.c. DynamicHash requires a ref to the key
         unsigned int     fStart;
         unsigned int     fEnd;
         Interval*        fNext;
     };

     class IntervalList {
     public:
         IntervalList() = default;
         ~IntervalList() {
             // The only time we delete an IntervalList is in the GrResourceAllocator dtor.
             // Since the arena allocator will clean up for us we don't bother here.
         }

         bool empty() const { return !SkToBool(fHead); }
         const Interval* peekHead() const { return fHead; }
         Interval* popHead();
         void insertByIncreasingStart(Interval*);
         void insertByIncreasingEnd(Interval*);
         Interval* detachAll();

     private:
         Interval* fHead = nullptr;
     };

     // Gathered statistics indicate that 99% of flushes will be covered by <= 12 Intervals
     static const int kInitialArenaSize = 12 * sizeof(Interval);

     GrResourceProvider*    fResourceProvider;
     FreePoolMultiMap       fFreePool;          // Recently created/used GrSurfaces
     IntvlHash              fIntvlHash;         // All the intervals, hashed by proxyID

     IntervalList           fIntvlList;         // All the intervals sorted by increasing start
     IntervalList           fActiveIntvls;      // List of live intervals during assignment
                                                // (sorted by increasing end)
     unsigned int           fNumOps = 1;        // op # 0 is reserved for uploads at the start
                                                // of a flush
     SkTArray<unsigned int> fEndOfOpListOpIndices;
     int                    fCurOpListIndex = 0;

     SkDEBUGCODE(bool       fAssigned = false;)

     char                   fStorage[kInitialArenaSize];
     SkArenaAlloc           fIntervalAllocator { fStorage, kInitialArenaSize, 0 };
     Interval*              fFreeIntervalList = nullptr;
 };

 #endif // GrResourceAllocator_DEFINED
	/*
	* Copyright 2017 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef GrResourceAllocator_DEFINED
	#define GrResourceAllocator_DEFINED

	#include "GrGpuResourcePriv.h"
	#include "GrSurface.h"
	#include "GrSurfaceProxy.h"

	#include "SkArenaAlloc.h"
	#include "SkTDynamicHash.h"
	#include "SkTMultiMap.h"

	class GrResourceProvider;
	class GrUninstantiateProxyTracker;

	/*
	* The ResourceAllocator explicitly distributes GPU resources at flush time. It operates by
	* being given the usage intervals of the various proxies. It keeps these intervals in a singly
	* linked list sorted by increasing start index. (It also maintains a hash table from proxyID
	* to interval to find proxy reuse). When it comes time to allocate the resources it
	* traverses the sorted list and:
	* removes intervals from the active list that have completed (returning their GrSurfaces
	* to the free pool)

	* allocates a new resource (preferably from the free pool) for the new interval
	* adds the new interval to the active list (that is sorted by increasing end index)
	*
	* Note: the op indices (used in the usage intervals) come from the order of the ops in
	* their opLists after the opList DAG has been linearized.
	*/
	class GrResourceAllocator {
	public:
	GrResourceAllocator(GrResourceProvider* resourceProvider)
	: fResourceProvider(resourceProvider) {
	}

	~GrResourceAllocator();

	unsigned int curOp() const { return fNumOps; }
	void incOps() { fNumOps++; }
	unsigned int numOps() const { return fNumOps; }

	// Add a usage interval from 'start' to 'end' inclusive. This is usually used for renderTargets.
	// If an existing interval already exists it will be expanded to include the new range.
	void addInterval(GrSurfaceProxy*, unsigned int start, unsigned int end
	SkDEBUGCODE(, bool isDirectDstRead = false));

	// Add an interval that spans just the current op. Usually this is for texture uses.
	// If an existing interval already exists it will be expanded to include the new operation.
	void addInterval(GrSurfaceProxy* proxy
	SkDEBUGCODE(, bool isDirectDstRead = false)) {
	this->addInterval(proxy, fNumOps, fNumOps SkDEBUGCODE(, isDirectDstRead));
	}

	enum class AssignError {
	kNoError,
	kFailedProxyInstantiation
	};

	// Returns true when the opLists from 'startIndex' to 'stopIndex' should be executed;
	// false when nothing remains to be executed.
	// If any proxy fails to instantiate, the AssignError will be set to kFailedProxyInstantiation.
	// If this happens, the caller should remove all ops which reference an uninstantiated proxy.
	// This is used to execute a portion of the queued opLists in order to reduce the total
	// amount of GPU resources required.
	bool assign(int* startIndex, int* stopIndex, GrUninstantiateProxyTracker*,
	AssignError* outError);

	void markEndOfOpList(int opListIndex);

	private:
	class Interval;

	// Remove dead intervals from the active list
	void expire(unsigned int curIndex);

	// These two methods wrap the interactions with the free pool
	void freeUpSurface(sk_sp<GrSurface> surface);
	sk_sp<GrSurface> findSurfaceFor(const GrSurfaceProxy* proxy, bool needsStencil);

	struct FreePoolTraits {
	static const GrScratchKey& GetKey(const GrSurface& s) {
	return s.resourcePriv().getScratchKey();
	}

	static uint32_t Hash(const GrScratchKey& key) { return key.hash(); }
	static void OnFree(GrSurface* s) { s->unref(); }
	};
	typedef SkTMultiMap<GrSurface, GrScratchKey, FreePoolTraits> FreePoolMultiMap;

	typedef SkTDynamicHash<Interval, unsigned int> IntvlHash;

	class Interval {
	public:
	Interval(GrSurfaceProxy* proxy, unsigned int start, unsigned int end)
	: fProxy(proxy)
	, fProxyID(proxy->uniqueID().asUInt())
	, fStart(start)
	, fEnd(end)
	, fNext(nullptr) {
	SkASSERT(proxy);
	}

	void resetTo(GrSurfaceProxy* proxy, unsigned int start, unsigned int end) {
	SkASSERT(proxy);

	fProxy = proxy;
	fProxyID = proxy->uniqueID().asUInt();
	fStart = start;
	fEnd = end;
	fNext = nullptr;
	}

	~Interval() {
	SkASSERT(!fAssignedSurface);
	}

	const GrSurfaceProxy* proxy() const { return fProxy; }
	GrSurfaceProxy* proxy() { return fProxy; }
	unsigned int start() const { return fStart; }
	unsigned int end() const { return fEnd; }
	const Interval* next() const { return fNext; }
	Interval* next() { return fNext; }

	void setNext(Interval* next) { fNext = next; }

	void extendEnd(unsigned int newEnd) {
	if (newEnd > fEnd) {
	fEnd = newEnd;
	}
	}

	void assign(sk_sp<GrSurface>);
	bool wasAssignedSurface() const { return fAssignedSurface != nullptr; }
	sk_sp<GrSurface> detachSurface() { return std::move(fAssignedSurface); }

	// for SkTDynamicHash
	static const uint32_t& GetKey(const Interval& intvl) {
	return intvl.fProxyID;
	}
	static uint32_t Hash(const uint32_t& key) { return key; }

	private:
	sk_sp<GrSurface> fAssignedSurface;
	GrSurfaceProxy* fProxy;
	uint32_t fProxyID; // This is here b.c. DynamicHash requires a ref to the key
	unsigned int fStart;
	unsigned int fEnd;
	Interval* fNext;
	};

	class IntervalList {
	public:
	IntervalList() = default;
	~IntervalList() {
	// The only time we delete an IntervalList is in the GrResourceAllocator dtor.
	// Since the arena allocator will clean up for us we don't bother here.
	}

	bool empty() const { return !SkToBool(fHead); }
	const Interval* peekHead() const { return fHead; }
	Interval* popHead();
	void insertByIncreasingStart(Interval*);
	void insertByIncreasingEnd(Interval*);
	Interval* detachAll();

	private:
	Interval* fHead = nullptr;
	};

	// Gathered statistics indicate that 99% of flushes will be covered by <= 12 Intervals
	static const int kInitialArenaSize = 12 * sizeof(Interval);

	GrResourceProvider* fResourceProvider;
	FreePoolMultiMap fFreePool; // Recently created/used GrSurfaces
	IntvlHash fIntvlHash; // All the intervals, hashed by proxyID

	IntervalList fIntvlList; // All the intervals sorted by increasing start
	IntervalList fActiveIntvls; // List of live intervals during assignment
	// (sorted by increasing end)
	unsigned int fNumOps = 1; // op # 0 is reserved for uploads at the start
	// of a flush
	SkTArray<unsigned int> fEndOfOpListOpIndices;
	int fCurOpListIndex = 0;

	SkDEBUGCODE(bool fAssigned = false;)

	char fStorage[kInitialArenaSize];
	SkArenaAlloc fIntervalAllocator { fStorage, kInitialArenaSize, 0 };
	Interval* fFreeIntervalList = nullptr;
	};

	#endif // GrResourceAllocator_DEFINED