src/gpu/GrAuditTrail.cpp - skia - Git at Google

 /*
  * Copyright 2016 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "src/gpu/GrAuditTrail.h"
 #include "src/gpu/ops/GrOp.h"
 #include "src/utils/SkJSONWriter.h"

 const int GrAuditTrail::kGrAuditTrailInvalidID = -1;

 void GrAuditTrail::addOp(const GrOp* op, GrRenderTargetProxy::UniqueID proxyID) {
     SkASSERT(fEnabled);
     Op* auditOp = new Op;
     fOpPool.emplace_back(auditOp);
     auditOp->fName = op->name();
     auditOp->fBounds = op->bounds();
     auditOp->fClientID = kGrAuditTrailInvalidID;
     auditOp->fOpsTaskID = kGrAuditTrailInvalidID;
     auditOp->fChildID = kGrAuditTrailInvalidID;

     // consume the current stack trace if any
     auditOp->fStackTrace = fCurrentStackTrace;
     fCurrentStackTrace.reset();

     if (fClientID != kGrAuditTrailInvalidID) {
         auditOp->fClientID = fClientID;
         Ops** opsLookup = fClientIDLookup.find(fClientID);
         Ops* ops = nullptr;
         if (!opsLookup) {
             ops = new Ops;
             fClientIDLookup.set(fClientID, ops);
         } else {
             ops = *opsLookup;
         }

         ops->push_back(auditOp);
     }

     // Our algorithm doesn't bother to reorder inside of an OpNode so the ChildID will start at 0
     auditOp->fOpsTaskID = fOpsTask.count();
     auditOp->fChildID = 0;

     // We use the op pointer as a key to find the OpNode we are 'glomming' ops onto
     fIDLookup.set(op->uniqueID(), auditOp->fOpsTaskID);
     OpNode* opNode = new OpNode(proxyID);
     opNode->fBounds = op->bounds();
     opNode->fChildren.push_back(auditOp);
     fOpsTask.emplace_back(opNode);
 }

 void GrAuditTrail::opsCombined(const GrOp* consumer, const GrOp* consumed) {
     // Look up the op we are going to glom onto
     int* indexPtr = fIDLookup.find(consumer->uniqueID());
     SkASSERT(indexPtr);
     int index = *indexPtr;
     SkASSERT(index < fOpsTask.count() && fOpsTask[index]);
     OpNode& consumerOp = *fOpsTask[index];

     // Look up the op which will be glommed
     int* consumedPtr = fIDLookup.find(consumed->uniqueID());
     SkASSERT(consumedPtr);
     int consumedIndex = *consumedPtr;
     SkASSERT(consumedIndex < fOpsTask.count() && fOpsTask[consumedIndex]);
     OpNode& consumedOp = *fOpsTask[consumedIndex];

     // steal all of consumed's ops
     for (int i = 0; i < consumedOp.fChildren.count(); i++) {
         Op* childOp = consumedOp.fChildren[i];

         // set the ids for the child op
         childOp->fOpsTaskID = index;
         childOp->fChildID = consumerOp.fChildren.count();
         consumerOp.fChildren.push_back(childOp);
     }

     // Update the bounds for the combineWith node
     consumerOp.fBounds = consumer->bounds();

     // remove the old node from our opsTask and clear the combinee's lookup
     // NOTE: because we can't change the shape of the oplist, we use a sentinel
     fOpsTask[consumedIndex].reset(nullptr);
     fIDLookup.remove(consumed->uniqueID());
 }

 void GrAuditTrail::copyOutFromOpsTask(OpInfo* outOpInfo, int opsTaskID) {
     SkASSERT(opsTaskID < fOpsTask.count());
     const OpNode* bn = fOpsTask[opsTaskID].get();
     SkASSERT(bn);
     outOpInfo->fBounds = bn->fBounds;
     outOpInfo->fProxyUniqueID    = bn->fProxyUniqueID;
     for (int j = 0; j < bn->fChildren.count(); j++) {
         OpInfo::Op& outOp = outOpInfo->fOps.push_back();
         const Op* currentOp = bn->fChildren[j];
         outOp.fBounds = currentOp->fBounds;
         outOp.fClientID = currentOp->fClientID;
     }
 }

 void GrAuditTrail::getBoundsByClientID(SkTArray<OpInfo>* outInfo, int clientID) {
     Ops** opsLookup = fClientIDLookup.find(clientID);
     if (opsLookup) {
         // We track which oplistID we're currently looking at.  If it changes, then we need to push
         // back a new op info struct.  We happen to know that ops are in sequential order in the
         // oplist, otherwise we'd have to do more bookkeeping
         int currentOpsTaskID = kGrAuditTrailInvalidID;
         for (int i = 0; i < (*opsLookup)->count(); i++) {
             const Op* op = (**opsLookup)[i];

             // Because we will copy out all of the ops associated with a given op list id everytime
             // the id changes, we only have to update our struct when the id changes.
             if (kGrAuditTrailInvalidID == currentOpsTaskID || op->fOpsTaskID != currentOpsTaskID) {
                 OpInfo& outOpInfo = outInfo->push_back();

                 // copy out all of the ops so the client can display them even if they have a
                 // different clientID
                 this->copyOutFromOpsTask(&outOpInfo, op->fOpsTaskID);
             }
         }
     }
 }

 void GrAuditTrail::getBoundsByOpsTaskID(OpInfo* outInfo, int opsTaskID) {
     this->copyOutFromOpsTask(outInfo, opsTaskID);
 }

 void GrAuditTrail::fullReset() {
     SkASSERT(fEnabled);
     fOpsTask.reset();
     fIDLookup.reset();
     // free all client ops
     fClientIDLookup.foreach ([](const int&, Ops** ops) { delete *ops; });
     fClientIDLookup.reset();
     fOpPool.reset();  // must be last, frees all of the memory
 }

 template <typename T>
 void GrAuditTrail::JsonifyTArray(SkJSONWriter& writer, const char* name, const T& array) {
     if (array.count()) {
         writer.beginArray(name);
         for (int i = 0; i < array.count(); i++) {
             // Handle sentinel nullptrs
             if (array[i]) {
                 array[i]->toJson(writer);
             }
         }
         writer.endArray();
     }
 }

 void GrAuditTrail::toJson(SkJSONWriter& writer) const {
     writer.beginObject();
     JsonifyTArray(writer, "Ops", fOpsTask);
     writer.endObject();
 }

 void GrAuditTrail::toJson(SkJSONWriter& writer, int clientID) const {
     writer.beginObject();
     Ops** ops = fClientIDLookup.find(clientID);
     if (ops) {
         JsonifyTArray(writer, "Ops", **ops);
     }
     writer.endObject();
 }

 static void skrect_to_json(SkJSONWriter& writer, const char* name, const SkRect& rect) {
     writer.beginObject(name);
     writer.appendFloat("Left", rect.fLeft);
     writer.appendFloat("Right", rect.fRight);
     writer.appendFloat("Top", rect.fTop);
     writer.appendFloat("Bottom", rect.fBottom);
     writer.endObject();
 }

 void GrAuditTrail::Op::toJson(SkJSONWriter& writer) const {
     writer.beginObject();
     writer.appendString("Name", fName.c_str());
     writer.appendS32("ClientID", fClientID);
     writer.appendS32("OpsTaskID", fOpsTaskID);
     writer.appendS32("ChildID", fChildID);
     skrect_to_json(writer, "Bounds", fBounds);
     if (fStackTrace.count()) {
         writer.beginArray("Stack");
         for (int i = 0; i < fStackTrace.count(); i++) {
             writer.appendString(fStackTrace[i].c_str());
         }
         writer.endArray();
     }
     writer.endObject();
 }

 void GrAuditTrail::OpNode::toJson(SkJSONWriter& writer) const {
     writer.beginObject();
     writer.appendU32("ProxyID", fProxyUniqueID.asUInt());
     skrect_to_json(writer, "Bounds", fBounds);
     JsonifyTArray(writer, "Ops", fChildren);
     writer.endObject();
 }
	/*
	* Copyright 2016 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "src/gpu/GrAuditTrail.h"
	#include "src/gpu/ops/GrOp.h"
	#include "src/utils/SkJSONWriter.h"

	const int GrAuditTrail::kGrAuditTrailInvalidID = -1;

	void GrAuditTrail::addOp(const GrOp* op, GrRenderTargetProxy::UniqueID proxyID) {
	SkASSERT(fEnabled);
	Op* auditOp = new Op;
	fOpPool.emplace_back(auditOp);
	auditOp->fName = op->name();
	auditOp->fBounds = op->bounds();
	auditOp->fClientID = kGrAuditTrailInvalidID;
	auditOp->fOpsTaskID = kGrAuditTrailInvalidID;
	auditOp->fChildID = kGrAuditTrailInvalidID;

	// consume the current stack trace if any
	auditOp->fStackTrace = fCurrentStackTrace;
	fCurrentStackTrace.reset();

	if (fClientID != kGrAuditTrailInvalidID) {
	auditOp->fClientID = fClientID;
	Ops** opsLookup = fClientIDLookup.find(fClientID);
	Ops* ops = nullptr;
	if (!opsLookup) {
	ops = new Ops;
	fClientIDLookup.set(fClientID, ops);
	} else {
	ops = *opsLookup;
	}

	ops->push_back(auditOp);
	}

	// Our algorithm doesn't bother to reorder inside of an OpNode so the ChildID will start at 0
	auditOp->fOpsTaskID = fOpsTask.count();
	auditOp->fChildID = 0;

	// We use the op pointer as a key to find the OpNode we are 'glomming' ops onto
	fIDLookup.set(op->uniqueID(), auditOp->fOpsTaskID);
	OpNode* opNode = new OpNode(proxyID);
	opNode->fBounds = op->bounds();
	opNode->fChildren.push_back(auditOp);
	fOpsTask.emplace_back(opNode);
	}

	void GrAuditTrail::opsCombined(const GrOp* consumer, const GrOp* consumed) {
	// Look up the op we are going to glom onto
	int* indexPtr = fIDLookup.find(consumer->uniqueID());
	SkASSERT(indexPtr);
	int index = *indexPtr;
	SkASSERT(index < fOpsTask.count() && fOpsTask[index]);
	OpNode& consumerOp = *fOpsTask[index];

	// Look up the op which will be glommed
	int* consumedPtr = fIDLookup.find(consumed->uniqueID());
	SkASSERT(consumedPtr);
	int consumedIndex = *consumedPtr;
	SkASSERT(consumedIndex < fOpsTask.count() && fOpsTask[consumedIndex]);
	OpNode& consumedOp = *fOpsTask[consumedIndex];

	// steal all of consumed's ops
	for (int i = 0; i < consumedOp.fChildren.count(); i++) {
	Op* childOp = consumedOp.fChildren[i];

	// set the ids for the child op
	childOp->fOpsTaskID = index;
	childOp->fChildID = consumerOp.fChildren.count();
	consumerOp.fChildren.push_back(childOp);
	}

	// Update the bounds for the combineWith node
	consumerOp.fBounds = consumer->bounds();

	// remove the old node from our opsTask and clear the combinee's lookup
	// NOTE: because we can't change the shape of the oplist, we use a sentinel
	fOpsTask[consumedIndex].reset(nullptr);
	fIDLookup.remove(consumed->uniqueID());
	}

	void GrAuditTrail::copyOutFromOpsTask(OpInfo* outOpInfo, int opsTaskID) {
	SkASSERT(opsTaskID < fOpsTask.count());
	const OpNode* bn = fOpsTask[opsTaskID].get();
	SkASSERT(bn);
	outOpInfo->fBounds = bn->fBounds;
	outOpInfo->fProxyUniqueID = bn->fProxyUniqueID;
	for (int j = 0; j < bn->fChildren.count(); j++) {
	OpInfo::Op& outOp = outOpInfo->fOps.push_back();
	const Op* currentOp = bn->fChildren[j];
	outOp.fBounds = currentOp->fBounds;
	outOp.fClientID = currentOp->fClientID;
	}
	}

	void GrAuditTrail::getBoundsByClientID(SkTArray<OpInfo>* outInfo, int clientID) {
	Ops** opsLookup = fClientIDLookup.find(clientID);
	if (opsLookup) {
	// We track which oplistID we're currently looking at. If it changes, then we need to push
	// back a new op info struct. We happen to know that ops are in sequential order in the
	// oplist, otherwise we'd have to do more bookkeeping
	int currentOpsTaskID = kGrAuditTrailInvalidID;
	for (int i = 0; i < (*opsLookup)->count(); i++) {
	const Op* op = (**opsLookup)[i];

	// Because we will copy out all of the ops associated with a given op list id everytime
	// the id changes, we only have to update our struct when the id changes.
	if (kGrAuditTrailInvalidID == currentOpsTaskID \|\| op->fOpsTaskID != currentOpsTaskID) {
	OpInfo& outOpInfo = outInfo->push_back();

	// copy out all of the ops so the client can display them even if they have a
	// different clientID
	this->copyOutFromOpsTask(&outOpInfo, op->fOpsTaskID);
	}
	}
	}
	}

	void GrAuditTrail::getBoundsByOpsTaskID(OpInfo* outInfo, int opsTaskID) {
	this->copyOutFromOpsTask(outInfo, opsTaskID);
	}

	void GrAuditTrail::fullReset() {
	SkASSERT(fEnabled);
	fOpsTask.reset();
	fIDLookup.reset();
	// free all client ops
	fClientIDLookup.foreach ([](const int&, Ops** ops) { delete *ops; });
	fClientIDLookup.reset();
	fOpPool.reset(); // must be last, frees all of the memory
	}

	template <typename T>
	void GrAuditTrail::JsonifyTArray(SkJSONWriter& writer, const char* name, const T& array) {
	if (array.count()) {
	writer.beginArray(name);
	for (int i = 0; i < array.count(); i++) {
	// Handle sentinel nullptrs
	if (array[i]) {
	array[i]->toJson(writer);
	}
	}
	writer.endArray();
	}
	}

	void GrAuditTrail::toJson(SkJSONWriter& writer) const {
	writer.beginObject();
	JsonifyTArray(writer, "Ops", fOpsTask);
	writer.endObject();
	}

	void GrAuditTrail::toJson(SkJSONWriter& writer, int clientID) const {
	writer.beginObject();
	Ops** ops = fClientIDLookup.find(clientID);
	if (ops) {
	JsonifyTArray(writer, "Ops", **ops);
	}
	writer.endObject();
	}

	static void skrect_to_json(SkJSONWriter& writer, const char* name, const SkRect& rect) {
	writer.beginObject(name);
	writer.appendFloat("Left", rect.fLeft);
	writer.appendFloat("Right", rect.fRight);
	writer.appendFloat("Top", rect.fTop);
	writer.appendFloat("Bottom", rect.fBottom);
	writer.endObject();
	}

	void GrAuditTrail::Op::toJson(SkJSONWriter& writer) const {
	writer.beginObject();
	writer.appendString("Name", fName.c_str());
	writer.appendS32("ClientID", fClientID);
	writer.appendS32("OpsTaskID", fOpsTaskID);
	writer.appendS32("ChildID", fChildID);
	skrect_to_json(writer, "Bounds", fBounds);
	if (fStackTrace.count()) {
	writer.beginArray("Stack");
	for (int i = 0; i < fStackTrace.count(); i++) {
	writer.appendString(fStackTrace[i].c_str());
	}
	writer.endArray();
	}
	writer.endObject();
	}

	void GrAuditTrail::OpNode::toJson(SkJSONWriter& writer) const {
	writer.beginObject();
	writer.appendU32("ProxyID", fProxyUniqueID.asUInt());
	skrect_to_json(writer, "Bounds", fBounds);
	JsonifyTArray(writer, "Ops", fChildren);
	writer.endObject();
	}