gecko-dev/gfx/2d/RecordedEvent.h

518 lines
15 KiB
C++

/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim: set ts=8 sts=2 et sw=2 tw=80: */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#ifndef MOZILLA_GFX_RECORDEDEVENT_H_
#define MOZILLA_GFX_RECORDEDEVENT_H_
#include <ostream>
#include <sstream>
#include <cstring>
#include <functional>
#include <vector>
#include "RecordingTypes.h"
#include "mozilla/gfx/Point.h"
#include "mozilla/gfx/Types.h"
#include "mozilla/ipc/ByteBuf.h"
#include "nsRefPtrHashtable.h"
namespace mozilla {
namespace gfx {
const uint32_t kMagicInt = 0xc001feed;
// A change in major revision means a change in event binary format, causing
// loss of backwards compatibility. Old streams will not work in a player
// using a newer major revision. And new streams will not work in a player
// using an older major revision.
const uint16_t kMajorRevision = 10;
// A change in minor revision means additions of new events. New streams will
// not play in older players.
const uint16_t kMinorRevision = 3;
struct ReferencePtr {
ReferencePtr() : mLongPtr(0) {}
MOZ_IMPLICIT ReferencePtr(const void* aLongPtr)
: mLongPtr(uint64_t(aLongPtr)) {}
template <typename T>
MOZ_IMPLICIT ReferencePtr(const RefPtr<T>& aPtr)
: mLongPtr(uint64_t(aPtr.get())) {}
ReferencePtr& operator=(const void* aLongPtr) {
mLongPtr = uint64_t(aLongPtr);
return *this;
}
template <typename T>
ReferencePtr& operator=(const RefPtr<T>& aPtr) {
mLongPtr = uint64_t(aPtr.get());
return *this;
}
operator void*() const { return (void*)mLongPtr; }
uint64_t mLongPtr;
};
struct RecordedFontDetails {
uint64_t fontDataKey = 0;
uint32_t size = 0;
uint32_t index = 0;
};
struct RecordedDependentSurface {
NS_INLINE_DECL_REFCOUNTING(RecordedDependentSurface);
RecordedDependentSurface(const IntSize& aSize,
mozilla::ipc::ByteBuf&& aRecording)
: mSize(aSize), mRecording(std::move(aRecording)) {}
IntSize mSize;
mozilla::ipc::ByteBuf mRecording;
private:
~RecordedDependentSurface() = default;
};
// Used by the Azure drawing debugger (player2d)
inline std::string StringFromPtr(ReferencePtr aPtr) {
std::stringstream stream;
stream << aPtr;
return stream.str();
}
class Translator {
public:
virtual ~Translator() = default;
virtual DrawTarget* LookupDrawTarget(ReferencePtr aRefPtr) = 0;
virtual Path* LookupPath(ReferencePtr aRefPtr) = 0;
virtual SourceSurface* LookupSourceSurface(ReferencePtr aRefPtr) = 0;
virtual FilterNode* LookupFilterNode(ReferencePtr aRefPtr) = 0;
virtual already_AddRefed<GradientStops> LookupGradientStops(
ReferencePtr aRefPtr) = 0;
virtual ScaledFont* LookupScaledFont(ReferencePtr aRefPtr) = 0;
virtual UnscaledFont* LookupUnscaledFont(ReferencePtr aRefPtr) = 0;
virtual NativeFontResource* LookupNativeFontResource(uint64_t aKey) = 0;
virtual already_AddRefed<SourceSurface> LookupExternalSurface(uint64_t aKey) {
return nullptr;
}
void DrawDependentSurface(ReferencePtr aDrawTarget, uint64_t aKey,
const Rect& aRect);
virtual void AddDrawTarget(ReferencePtr aRefPtr, DrawTarget* aDT) = 0;
virtual void RemoveDrawTarget(ReferencePtr aRefPtr) = 0;
virtual void AddPath(ReferencePtr aRefPtr, Path* aPath) = 0;
virtual void RemovePath(ReferencePtr aRefPtr) = 0;
virtual void AddSourceSurface(ReferencePtr aRefPtr, SourceSurface* aPath) = 0;
virtual void RemoveSourceSurface(ReferencePtr aRefPtr) = 0;
virtual void AddFilterNode(mozilla::gfx::ReferencePtr aRefPtr,
FilterNode* aSurface) = 0;
virtual void RemoveFilterNode(mozilla::gfx::ReferencePtr aRefPtr) = 0;
/**
* Get GradientStops compatible with the translation DrawTarget type.
* @param aRawStops array of raw gradient stops required
* @param aNumStops length of aRawStops
* @param aExtendMode extend mode required
* @return an already addrefed GradientStops for our DrawTarget type
*/
virtual already_AddRefed<GradientStops> GetOrCreateGradientStops(
GradientStop* aRawStops, uint32_t aNumStops, ExtendMode aExtendMode) {
return GetReferenceDrawTarget()->CreateGradientStops(aRawStops, aNumStops,
aExtendMode);
}
virtual void AddGradientStops(ReferencePtr aRefPtr, GradientStops* aPath) = 0;
virtual void RemoveGradientStops(ReferencePtr aRefPtr) = 0;
virtual void AddScaledFont(ReferencePtr aRefPtr, ScaledFont* aScaledFont) = 0;
virtual void RemoveScaledFont(ReferencePtr aRefPtr) = 0;
virtual void AddUnscaledFont(ReferencePtr aRefPtr,
UnscaledFont* aUnscaledFont) = 0;
virtual void RemoveUnscaledFont(ReferencePtr aRefPtr) = 0;
virtual void AddNativeFontResource(
uint64_t aKey, NativeFontResource* aNativeFontResource) = 0;
virtual already_AddRefed<DrawTarget> CreateDrawTarget(ReferencePtr aRefPtr,
const IntSize& aSize,
SurfaceFormat aFormat);
virtual DrawTarget* GetReferenceDrawTarget() = 0;
virtual Matrix GetReferenceDrawTargetTransform() { return Matrix(); }
virtual void* GetFontContext() { return nullptr; }
void SetDependentSurfaces(
nsRefPtrHashtable<nsUint64HashKey, RecordedDependentSurface>*
aDependentSurfaces) {
mDependentSurfaces = aDependentSurfaces;
}
nsRefPtrHashtable<nsUint64HashKey, RecordedDependentSurface>*
mDependentSurfaces = nullptr;
};
struct ColorPatternStorage {
DeviceColor mColor;
};
struct LinearGradientPatternStorage {
Point mBegin;
Point mEnd;
ReferencePtr mStops;
Matrix mMatrix;
};
struct RadialGradientPatternStorage {
Point mCenter1;
Point mCenter2;
Float mRadius1;
Float mRadius2;
ReferencePtr mStops;
Matrix mMatrix;
};
struct ConicGradientPatternStorage {
Point mCenter;
Float mAngle;
Float mStartOffset;
Float mEndOffset;
ReferencePtr mStops;
Matrix mMatrix;
};
struct SurfacePatternStorage {
ExtendMode mExtend;
SamplingFilter mSamplingFilter;
ReferencePtr mSurface;
Matrix mMatrix;
IntRect mSamplingRect;
};
struct PatternStorage {
PatternType mType;
union {
char* mStorage;
char mColor[sizeof(ColorPatternStorage)];
char mLinear[sizeof(LinearGradientPatternStorage)];
char mRadial[sizeof(RadialGradientPatternStorage)];
char mConic[sizeof(ConicGradientPatternStorage)];
char mSurface[sizeof(SurfacePatternStorage)];
};
};
/* SizeCollector and MemWriter are used
* in a pair to first collect the size of the
* event that we're going to write and then
* to write it without checking each individual
* size. */
struct SizeCollector {
SizeCollector() : mTotalSize(0) {}
void write(const char*, size_t s) { mTotalSize += s; }
size_t mTotalSize;
};
struct MemWriter {
explicit MemWriter(char* aPtr) : mPtr(aPtr) {}
void write(const char* aData, size_t aSize) {
memcpy(mPtr, aData, aSize);
mPtr += aSize;
}
char* mPtr;
};
// This is a simple interface for an EventRingBuffer, so we can use it in the
// RecordedEvent reading and writing machinery.
class EventRingBuffer {
public:
/**
* Templated RecordEvent function so that when we have enough contiguous
* space we can record into the buffer quickly using MemWriter.
*
* @param aRecordedEvent the event to record
*/
template <class RE>
void RecordEvent(const RE* aRecordedEvent) {
SizeCollector size;
WriteElement(size, aRecordedEvent->GetType());
aRecordedEvent->Record(size);
if (size.mTotalSize > mAvailable) {
WaitForAndRecalculateAvailableSpace();
}
if (size.mTotalSize <= mAvailable) {
MemWriter writer(mBufPos);
WriteElement(writer, aRecordedEvent->GetType());
aRecordedEvent->Record(writer);
UpdateWriteTotalsBy(size.mTotalSize);
} else {
WriteElement(*this, aRecordedEvent->GetType());
aRecordedEvent->Record(*this);
}
}
/**
* Simple write function required by WriteElement.
*
* @param aData the data to be written to the buffer
* @param aSize the number of chars to write
*/
virtual void write(const char* const aData, const size_t aSize) = 0;
/**
* Simple read function required by ReadElement.
*
* @param aOut the pointer to read into
* @param aSize the number of chars to read
*/
virtual void read(char* const aOut, const size_t aSize) = 0;
virtual bool good() const = 0;
virtual void SetIsBad() = 0;
protected:
/**
* Wait until space is available for writing and then set mBufPos and
* mAvailable.
*/
virtual bool WaitForAndRecalculateAvailableSpace() = 0;
/**
* Update write count, mBufPos and mAvailable.
*
* @param aCount number of bytes written
*/
virtual void UpdateWriteTotalsBy(uint32_t aCount) = 0;
char* mBufPos = nullptr;
uint32_t mAvailable = 0;
};
struct MemStream {
char* mData;
size_t mLength;
size_t mCapacity;
bool mValid = true;
bool Resize(size_t aSize) {
if (!mValid) {
return false;
}
mLength = aSize;
if (mLength > mCapacity) {
mCapacity = mCapacity * 2;
// check if the doubled capacity is enough
// otherwise use double mLength
if (mLength > mCapacity) {
mCapacity = mLength * 2;
}
char* data = (char*)realloc(mData, mCapacity);
if (!data) {
free(mData);
}
mData = data;
}
if (mData) {
return true;
}
NS_ERROR("Failed to allocate MemStream!");
mValid = false;
mLength = 0;
mCapacity = 0;
return false;
}
void reset() {
free(mData);
mData = nullptr;
mValid = true;
mLength = 0;
mCapacity = 0;
}
MemStream(const MemStream&) = delete;
MemStream(MemStream&&) = delete;
MemStream& operator=(const MemStream&) = delete;
MemStream& operator=(MemStream&&) = delete;
void write(const char* aData, size_t aSize) {
if (Resize(mLength + aSize)) {
memcpy(mData + mLength - aSize, aData, aSize);
}
}
MemStream() : mData(nullptr), mLength(0), mCapacity(0) {}
~MemStream() { free(mData); }
};
class EventStream {
public:
virtual void write(const char* aData, size_t aSize) = 0;
virtual void read(char* aOut, size_t aSize) = 0;
virtual bool good() = 0;
virtual void SetIsBad() = 0;
};
class RecordedEvent {
public:
enum EventType {
DRAWTARGETCREATION = 0,
DRAWTARGETDESTRUCTION,
FILLRECT,
STROKERECT,
STROKELINE,
CLEARRECT,
COPYSURFACE,
SETTRANSFORM,
PUSHCLIP,
PUSHCLIPRECT,
POPCLIP,
FILL,
FILLGLYPHS,
MASK,
STROKE,
DRAWSURFACE,
DRAWDEPENDENTSURFACE,
DRAWSURFACEWITHSHADOW,
PATHCREATION,
PATHDESTRUCTION,
SOURCESURFACECREATION,
SOURCESURFACEDESTRUCTION,
GRADIENTSTOPSCREATION,
GRADIENTSTOPSDESTRUCTION,
SNAPSHOT,
SCALEDFONTCREATION,
SCALEDFONTDESTRUCTION,
MASKSURFACE,
FILTERNODECREATION,
FILTERNODEDESTRUCTION,
DRAWFILTER,
FILTERNODESETATTRIBUTE,
FILTERNODESETINPUT,
CREATESIMILARDRAWTARGET,
CREATECLIPPEDDRAWTARGET,
CREATEDRAWTARGETFORFILTER,
FONTDATA,
FONTDESC,
PUSHLAYER,
PUSHLAYERWITHBLEND,
POPLAYER,
UNSCALEDFONTCREATION,
UNSCALEDFONTDESTRUCTION,
INTOLUMINANCE,
EXTERNALSURFACECREATION,
FLUSH,
DETACHALLSNAPSHOTS,
OPTIMIZESOURCESURFACE,
LINK,
DESTINATION,
LAST,
};
virtual ~RecordedEvent() = default;
static std::string GetEventName(EventType aType);
/**
* Play back this event using the translator. Note that derived classes
* should
* only return false when there is a fatal error, as it will probably mean
* the
* translation will abort.
* @param aTranslator Translator to be used for retrieving other referenced
* objects and making playback decisions.
* @return true unless a fatal problem has occurred and playback should
* abort.
*/
virtual bool PlayEvent(Translator* aTranslator) const { return true; }
virtual void RecordToStream(std::ostream& aStream) const = 0;
virtual void RecordToStream(EventStream& aStream) const = 0;
virtual void RecordToStream(EventRingBuffer& aStream) const = 0;
virtual void RecordToStream(MemStream& aStream) const = 0;
virtual void OutputSimpleEventInfo(std::stringstream& aStringStream) const {}
template <class S>
void RecordPatternData(S& aStream,
const PatternStorage& aPatternStorage) const;
template <class S>
void ReadPatternData(S& aStream, PatternStorage& aPatternStorage) const;
void StorePattern(PatternStorage& aDestination, const Pattern& aSource) const;
template <class S>
void RecordStrokeOptions(S& aStream,
const StrokeOptions& aStrokeOptions) const;
template <class S>
void ReadStrokeOptions(S& aStream, StrokeOptions& aStrokeOptions);
virtual std::string GetName() const = 0;
virtual ReferencePtr GetDestinedDT() { return nullptr; }
void OutputSimplePatternInfo(const PatternStorage& aStorage,
std::stringstream& aOutput) const;
template <class S>
static bool DoWithEvent(S& aStream, EventType aType,
const std::function<bool(RecordedEvent*)>& aAction);
static bool DoWithEventFromStream(
EventStream& aStream, EventType aType,
const std::function<bool(RecordedEvent*)>& aAction);
static bool DoWithEventFromStream(
EventRingBuffer& aStream, EventType aType,
const std::function<bool(RecordedEvent*)>& aAction);
EventType GetType() const { return (EventType)mType; }
protected:
friend class DrawEventRecorderPrivate;
friend class DrawEventRecorderMemory;
static void RecordUnscaledFont(UnscaledFont* aUnscaledFont,
std::ostream* aOutput);
static void RecordUnscaledFont(UnscaledFont* aUnscaledFont,
MemStream& aOutput);
template <class S>
static void RecordUnscaledFontImpl(UnscaledFont* aUnscaledFont, S& aOutput);
MOZ_IMPLICIT RecordedEvent(int32_t aType) : mType(aType) {}
int32_t mType;
std::vector<Float> mDashPatternStorage;
};
template <class Derived>
class RecordedEventDerived : public RecordedEvent {
using RecordedEvent::RecordedEvent;
public:
void RecordToStream(std::ostream& aStream) const override {
WriteElement(aStream, this->mType);
static_cast<const Derived*>(this)->Record(aStream);
}
void RecordToStream(EventStream& aStream) const override {
WriteElement(aStream, this->mType);
static_cast<const Derived*>(this)->Record(aStream);
}
void RecordToStream(EventRingBuffer& aStream) const final {
aStream.RecordEvent(static_cast<const Derived*>(this));
}
void RecordToStream(MemStream& aStream) const override {
SizeCollector size;
WriteElement(size, this->mType);
static_cast<const Derived*>(this)->Record(size);
if (!aStream.Resize(aStream.mLength + size.mTotalSize)) {
return;
}
MemWriter writer(aStream.mData + aStream.mLength - size.mTotalSize);
WriteElement(writer, this->mType);
static_cast<const Derived*>(this)->Record(writer);
}
};
} // namespace gfx
} // namespace mozilla
#endif