flow/embedded_views.h - external/github.com/flutter/engine - Git at Google

 // Copyright 2013 The Flutter Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.
 //
 #ifndef FLUTTER_FLOW_EMBEDDED_VIEWS_H_
 #define FLUTTER_FLOW_EMBEDDED_VIEWS_H_

 #include <vector>

 #include "flutter/fml/memory/ref_counted.h"
 #include "flutter/fml/raster_thread_merger.h"
 #include "third_party/skia/include/core/SkCanvas.h"
 #include "third_party/skia/include/core/SkPath.h"
 #include "third_party/skia/include/core/SkPoint.h"
 #include "third_party/skia/include/core/SkRRect.h"
 #include "third_party/skia/include/core/SkRect.h"
 #include "third_party/skia/include/core/SkSize.h"
 #include "third_party/skia/include/core/SkSurface.h"

 namespace flutter {

 // TODO(chinmaygarde): Make these enum names match the style guide.
 enum MutatorType { clip_rect, clip_rrect, clip_path, transform, opacity };

 // Stores mutation information like clipping or transform.
 //
 // The `type` indicates the type of the mutation: clip_rect, transform and etc.
 // Each `type` is paired with an object that supports the mutation. For example,
 // if the `type` is clip_rect, `rect()` is used the represent the rect to be
 // clipped. One mutation object must only contain one type of mutation.
 class Mutator {
  public:
   Mutator(const Mutator& other) {
     type_ = other.type_;
     switch (other.type_) {
       case clip_rect:
         rect_ = other.rect_;
         break;
       case clip_rrect:
         rrect_ = other.rrect_;
         break;
       case clip_path:
         path_ = new SkPath(*other.path_);
         break;
       case transform:
         matrix_ = other.matrix_;
         break;
       case opacity:
         alpha_ = other.alpha_;
         break;
       default:
         break;
     }
   }

   explicit Mutator(const SkRect& rect) : type_(clip_rect), rect_(rect) {}
   explicit Mutator(const SkRRect& rrect) : type_(clip_rrect), rrect_(rrect) {}
   explicit Mutator(const SkPath& path)
       : type_(clip_path), path_(new SkPath(path)) {}
   explicit Mutator(const SkMatrix& matrix)
       : type_(transform), matrix_(matrix) {}
   explicit Mutator(const int& alpha) : type_(opacity), alpha_(alpha) {}

   const MutatorType& GetType() const { return type_; }
   const SkRect& GetRect() const { return rect_; }
   const SkRRect& GetRRect() const { return rrect_; }
   const SkPath& GetPath() const { return *path_; }
   const SkMatrix& GetMatrix() const { return matrix_; }
   const int& GetAlpha() const { return alpha_; }
   float GetAlphaFloat() const { return (alpha_ / 255.0); }

   bool operator==(const Mutator& other) const {
     if (type_ != other.type_) {
       return false;
     }
     switch (type_) {
       case clip_rect:
         return rect_ == other.rect_;
       case clip_rrect:
         return rrect_ == other.rrect_;
       case clip_path:
         return *path_ == *other.path_;
       case transform:
         return matrix_ == other.matrix_;
       case opacity:
         return alpha_ == other.alpha_;
     }

     return false;
   }

   bool operator!=(const Mutator& other) const { return !operator==(other); }

   bool IsClipType() {
     return type_ == clip_rect || type_ == clip_rrect || type_ == clip_path;
   }

   ~Mutator() {
     if (type_ == clip_path) {
       delete path_;
     }
   };

  private:
   MutatorType type_;

   union {
     SkRect rect_;
     SkRRect rrect_;
     SkMatrix matrix_;
     SkPath* path_;
     int alpha_;
   };

 };  // Mutator

 // A stack of mutators that can be applied to an embedded platform view.
 //
 // The stack may include mutators like transforms and clips, each mutator
 // applies to all the mutators that are below it in the stack and to the
 // embedded view.
 //
 // For example consider the following stack: [T1, T2, T3], where T1 is the top
 // of the stack and T3 is the bottom of the stack. Applying this mutators stack
 // to a platform view P1 will result in T1(T2(T2(P1))).
 class MutatorsStack {
  public:
   MutatorsStack() = default;

   void PushClipRect(const SkRect& rect);
   void PushClipRRect(const SkRRect& rrect);
   void PushClipPath(const SkPath& path);
   void PushTransform(const SkMatrix& matrix);
   void PushOpacity(const int& alpha);

   // Removes the `Mutator` on the top of the stack
   // and destroys it.
   void Pop();

   // Returns an iterator pointing to the top of the stack.
   const std::vector<std::shared_ptr<Mutator>>::const_reverse_iterator Top()
       const;
   // Returns an iterator pointing to the bottom of the stack.
   const std::vector<std::shared_ptr<Mutator>>::const_reverse_iterator Bottom()
       const;
   bool is_empty() const { return vector_.empty(); }

   bool operator==(const MutatorsStack& other) const {
     if (vector_.size() != other.vector_.size()) {
       return false;
     }
     for (size_t i = 0; i < vector_.size(); i++) {
       if (*vector_[i] != *other.vector_[i]) {
         return false;
       }
     }
     return true;
   }

   bool operator==(const std::vector<Mutator>& other) const {
     if (vector_.size() != other.size()) {
       return false;
     }
     for (size_t i = 0; i < vector_.size(); i++) {
       if (*vector_[i] != other[i]) {
         return false;
       }
     }
     return true;
   }

   bool operator!=(const MutatorsStack& other) const {
     return !operator==(other);
   }

   bool operator!=(const std::vector<Mutator>& other) const {
     return !operator==(other);
   }

  private:
   std::vector<std::shared_ptr<Mutator>> vector_;
 };  // MutatorsStack

 class EmbeddedViewParams {
  public:
   EmbeddedViewParams() = default;

   EmbeddedViewParams(const EmbeddedViewParams& other) {
     offsetPixels = other.offsetPixels;
     sizePoints = other.sizePoints;
     mutatorsStack = other.mutatorsStack;
   };

   SkPoint offsetPixels;
   SkSize sizePoints;
   MutatorsStack mutatorsStack;

   bool operator==(const EmbeddedViewParams& other) const {
     return offsetPixels == other.offsetPixels &&
            sizePoints == other.sizePoints &&
            mutatorsStack == other.mutatorsStack;
   }
 };

 enum class PostPrerollResult { kResubmitFrame, kSuccess };

 // Facilitates embedding of platform views within the flow layer tree.
 //
 // Used on iOS, Android (hybrid composite mode), and on embedded platforms
 // that provide a system compositor as part of the project arguments.
 class ExternalViewEmbedder {
   // TODO(cyanglaz): Make embedder own the `EmbeddedViewParams`.

  public:
   ExternalViewEmbedder() = default;

   virtual ~ExternalViewEmbedder() = default;

   // Usually, the root canvas is not owned by the view embedder. However, if
   // the view embedder wants to provide a canvas to the rasterizer, it may
   // return one here. This canvas takes priority over the canvas materialized
   // from the on-screen render target.
   virtual SkCanvas* GetRootCanvas() = 0;

   // Call this in-lieu of |SubmitFrame| to clear pre-roll state and
   // sets the stage for the next pre-roll.
   virtual void CancelFrame() = 0;

   virtual void BeginFrame(SkISize frame_size,
                           GrContext* context,
                           double device_pixel_ratio) = 0;

   virtual void PrerollCompositeEmbeddedView(
       int view_id,
       std::unique_ptr<EmbeddedViewParams> params) = 0;

   // This needs to get called after |Preroll| finishes on the layer tree.
   // Returns kResubmitFrame if the frame needs to be processed again, this is
   // after it does any requisite tasks needed to bring itself to a valid state.
   // Returns kSuccess if the view embedder is already in a valid state.
   virtual PostPrerollResult PostPrerollAction(
       fml::RefPtr<fml::RasterThreadMerger> raster_thread_merger) {
     return PostPrerollResult::kSuccess;
   }

   virtual std::vector<SkCanvas*> GetCurrentCanvases() = 0;

   // Must be called on the UI thread.
   virtual SkCanvas* CompositeEmbeddedView(int view_id) = 0;

   virtual bool SubmitFrame(GrContext* context, SkCanvas* background_canvas);

   // This is called after submitting the embedder frame and the surface frame.
   virtual void FinishFrame();

   // This should only be called after |SubmitFrame|.
   // This method provides the embedder a way to do additional tasks after
   // |SubmitFrame|. After invoking this method, the current task on the
   // TaskRunner should end immediately.
   //
   // For example on the iOS embedder, threads are merged in this call.
   // A new frame on the platform thread starts immediately. If the GPU thread
   // still has some task running, there could be two frames being rendered
   // concurrently, which causes undefined behaviors.
   virtual void EndFrame(
       fml::RefPtr<fml::RasterThreadMerger> raster_thread_merger) {}

   FML_DISALLOW_COPY_AND_ASSIGN(ExternalViewEmbedder);

 };  // ExternalViewEmbedder

 }  // namespace flutter

 #endif  // FLUTTER_FLOW_EMBEDDED_VIEWS_H_
	// Copyright 2013 The Flutter Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.
	//
	#ifndef FLUTTER_FLOW_EMBEDDED_VIEWS_H_
	#define FLUTTER_FLOW_EMBEDDED_VIEWS_H_

	#include <vector>

	#include "flutter/fml/memory/ref_counted.h"
	#include "flutter/fml/raster_thread_merger.h"
	#include "third_party/skia/include/core/SkCanvas.h"
	#include "third_party/skia/include/core/SkPath.h"
	#include "third_party/skia/include/core/SkPoint.h"
	#include "third_party/skia/include/core/SkRRect.h"
	#include "third_party/skia/include/core/SkRect.h"
	#include "third_party/skia/include/core/SkSize.h"
	#include "third_party/skia/include/core/SkSurface.h"

	namespace flutter {

	// TODO(chinmaygarde): Make these enum names match the style guide.
	enum MutatorType { clip_rect, clip_rrect, clip_path, transform, opacity };

	// Stores mutation information like clipping or transform.
	//
	// The `type` indicates the type of the mutation: clip_rect, transform and etc.
	// Each `type` is paired with an object that supports the mutation. For example,
	// if the `type` is clip_rect, `rect()` is used the represent the rect to be
	// clipped. One mutation object must only contain one type of mutation.
	class Mutator {
	public:
	Mutator(const Mutator& other) {
	type_ = other.type_;
	switch (other.type_) {
	case clip_rect:
	rect_ = other.rect_;
	break;
	case clip_rrect:
	rrect_ = other.rrect_;
	break;
	case clip_path:
	path_ = new SkPath(*other.path_);
	break;
	case transform:
	matrix_ = other.matrix_;
	break;
	case opacity:
	alpha_ = other.alpha_;
	break;
	default:
	break;
	}
	}

	explicit Mutator(const SkRect& rect) : type_(clip_rect), rect_(rect) {}
	explicit Mutator(const SkRRect& rrect) : type_(clip_rrect), rrect_(rrect) {}
	explicit Mutator(const SkPath& path)
	: type_(clip_path), path_(new SkPath(path)) {}
	explicit Mutator(const SkMatrix& matrix)
	: type_(transform), matrix_(matrix) {}
	explicit Mutator(const int& alpha) : type_(opacity), alpha_(alpha) {}

	const MutatorType& GetType() const { return type_; }
	const SkRect& GetRect() const { return rect_; }
	const SkRRect& GetRRect() const { return rrect_; }
	const SkPath& GetPath() const { return *path_; }
	const SkMatrix& GetMatrix() const { return matrix_; }
	const int& GetAlpha() const { return alpha_; }
	float GetAlphaFloat() const { return (alpha_ / 255.0); }

	bool operator==(const Mutator& other) const {
	if (type_ != other.type_) {
	return false;
	}
	switch (type_) {
	case clip_rect:
	return rect_ == other.rect_;
	case clip_rrect:
	return rrect_ == other.rrect_;
	case clip_path:
	return path_ == other.path_;
	case transform:
	return matrix_ == other.matrix_;
	case opacity:
	return alpha_ == other.alpha_;
	}

	return false;
	}

	bool operator!=(const Mutator& other) const { return !operator==(other); }

	bool IsClipType() {
	return type_ == clip_rect \|\| type_ == clip_rrect \|\| type_ == clip_path;
	}

	~Mutator() {
	if (type_ == clip_path) {
	delete path_;
	}
	};

	private:
	MutatorType type_;

	union {
	SkRect rect_;
	SkRRect rrect_;
	SkMatrix matrix_;
	SkPath* path_;
	int alpha_;
	};

	}; // Mutator

	// A stack of mutators that can be applied to an embedded platform view.
	//
	// The stack may include mutators like transforms and clips, each mutator
	// applies to all the mutators that are below it in the stack and to the
	// embedded view.
	//
	// For example consider the following stack: [T1, T2, T3], where T1 is the top
	// of the stack and T3 is the bottom of the stack. Applying this mutators stack
	// to a platform view P1 will result in T1(T2(T2(P1))).
	class MutatorsStack {
	public:
	MutatorsStack() = default;

	void PushClipRect(const SkRect& rect);
	void PushClipRRect(const SkRRect& rrect);
	void PushClipPath(const SkPath& path);
	void PushTransform(const SkMatrix& matrix);
	void PushOpacity(const int& alpha);

	// Removes the `Mutator` on the top of the stack
	// and destroys it.
	void Pop();

	// Returns an iterator pointing to the top of the stack.
	const std::vector<std::shared_ptr<Mutator>>::const_reverse_iterator Top()
	const;
	// Returns an iterator pointing to the bottom of the stack.
	const std::vector<std::shared_ptr<Mutator>>::const_reverse_iterator Bottom()
	const;
	bool is_empty() const { return vector_.empty(); }

	bool operator==(const MutatorsStack& other) const {
	if (vector_.size() != other.vector_.size()) {
	return false;
	}
	for (size_t i = 0; i < vector_.size(); i++) {
	if (vector_[i] != other.vector_[i]) {
	return false;
	}
	}
	return true;
	}

	bool operator==(const std::vector<Mutator>& other) const {
	if (vector_.size() != other.size()) {
	return false;
	}
	for (size_t i = 0; i < vector_.size(); i++) {
	if (*vector_[i] != other[i]) {
	return false;
	}
	}
	return true;
	}

	bool operator!=(const MutatorsStack& other) const {
	return !operator==(other);
	}

	bool operator!=(const std::vector<Mutator>& other) const {
	return !operator==(other);
	}

	private:
	std::vector<std::shared_ptr<Mutator>> vector_;
	}; // MutatorsStack

	class EmbeddedViewParams {
	public:
	EmbeddedViewParams() = default;

	EmbeddedViewParams(const EmbeddedViewParams& other) {
	offsetPixels = other.offsetPixels;
	sizePoints = other.sizePoints;
	mutatorsStack = other.mutatorsStack;
	};

	SkPoint offsetPixels;
	SkSize sizePoints;
	MutatorsStack mutatorsStack;

	bool operator==(const EmbeddedViewParams& other) const {
	return offsetPixels == other.offsetPixels &&
	sizePoints == other.sizePoints &&
	mutatorsStack == other.mutatorsStack;
	}
	};

	enum class PostPrerollResult { kResubmitFrame, kSuccess };

	// Facilitates embedding of platform views within the flow layer tree.
	//
	// Used on iOS, Android (hybrid composite mode), and on embedded platforms
	// that provide a system compositor as part of the project arguments.
	class ExternalViewEmbedder {
	// TODO(cyanglaz): Make embedder own the `EmbeddedViewParams`.

	public:
	ExternalViewEmbedder() = default;

	virtual ~ExternalViewEmbedder() = default;

	// Usually, the root canvas is not owned by the view embedder. However, if
	// the view embedder wants to provide a canvas to the rasterizer, it may
	// return one here. This canvas takes priority over the canvas materialized
	// from the on-screen render target.
	virtual SkCanvas* GetRootCanvas() = 0;

	// Call this in-lieu of \|SubmitFrame\| to clear pre-roll state and
	// sets the stage for the next pre-roll.
	virtual void CancelFrame() = 0;

	virtual void BeginFrame(SkISize frame_size,
	GrContext* context,
	double device_pixel_ratio) = 0;

	virtual void PrerollCompositeEmbeddedView(
	int view_id,
	std::unique_ptr<EmbeddedViewParams> params) = 0;

	// This needs to get called after \|Preroll\| finishes on the layer tree.
	// Returns kResubmitFrame if the frame needs to be processed again, this is
	// after it does any requisite tasks needed to bring itself to a valid state.
	// Returns kSuccess if the view embedder is already in a valid state.
	virtual PostPrerollResult PostPrerollAction(
	fml::RefPtr<fml::RasterThreadMerger> raster_thread_merger) {
	return PostPrerollResult::kSuccess;
	}

	virtual std::vector<SkCanvas*> GetCurrentCanvases() = 0;

	// Must be called on the UI thread.
	virtual SkCanvas* CompositeEmbeddedView(int view_id) = 0;

	virtual bool SubmitFrame(GrContext* context, SkCanvas* background_canvas);

	// This is called after submitting the embedder frame and the surface frame.
	virtual void FinishFrame();

	// This should only be called after \|SubmitFrame\|.
	// This method provides the embedder a way to do additional tasks after
	// \|SubmitFrame\|. After invoking this method, the current task on the
	// TaskRunner should end immediately.
	//
	// For example on the iOS embedder, threads are merged in this call.
	// A new frame on the platform thread starts immediately. If the GPU thread
	// still has some task running, there could be two frames being rendered
	// concurrently, which causes undefined behaviors.
	virtual void EndFrame(
	fml::RefPtr<fml::RasterThreadMerger> raster_thread_merger) {}

	FML_DISALLOW_COPY_AND_ASSIGN(ExternalViewEmbedder);

	}; // ExternalViewEmbedder

	} // namespace flutter

	#endif // FLUTTER_FLOW_EMBEDDED_VIEWS_H_