/* * 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 "GrAuditTrail.h" #include "ops/GrOp.h" #include "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->fOpListID = 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->fOpListID = fOpList.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->fOpListID); OpNode* opNode = new OpNode(proxyID); opNode->fBounds = op->bounds(); opNode->fChildren.push_back(auditOp); fOpList.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 < fOpList.count() && fOpList[index]); OpNode& consumerOp = *fOpList[index]; // Look up the op which will be glommed int* consumedPtr = fIDLookup.find(consumed->uniqueID()); SkASSERT(consumedPtr); int consumedIndex = *consumedPtr; SkASSERT(consumedIndex < fOpList.count() && fOpList[consumedIndex]); OpNode& consumedOp = *fOpList[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->fOpListID = 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 opList and clear the combinee's lookup // NOTE: because we can't change the shape of the oplist, we use a sentinel fOpList[consumedIndex].reset(nullptr); fIDLookup.remove(consumed->uniqueID()); } void GrAuditTrail::copyOutFromOpList(OpInfo* outOpInfo, int opListID) { SkASSERT(opListID < fOpList.count()); const OpNode* bn = fOpList[opListID].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 currentOpListID = 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 == currentOpListID || op->fOpListID != currentOpListID) { 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->copyOutFromOpList(&outOpInfo, op->fOpListID); } } } } void GrAuditTrail::getBoundsByOpListID(OpInfo* outInfo, int opListID) { this->copyOutFromOpList(outInfo, opListID); } void GrAuditTrail::fullReset() { SkASSERT(fEnabled); fOpList.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", fOpList); 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("OpListID", fOpListID); 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(); }