/* * Copyright 2012 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #include "GrReducedClip.h" typedef SkClipStack::Element Element; static void reduced_stack_walker(const SkClipStack& stack, const SkRect& queryBounds, GrReducedClip::ElementList* result, int32_t* resultGenID, GrReducedClip::InitialState* initialState, bool* requiresAA) { // walk backwards until we get to: // a) the beginning // b) an operation that is known to make the bounds all inside/outside // c) a replace operation static const GrReducedClip::InitialState kUnknown_InitialState = static_cast(-1); *initialState = kUnknown_InitialState; // During our backwards walk, track whether we've seen ops that either grow or shrink the clip. // TODO: track these per saved clip so that we can consider them on the forward pass. bool embiggens = false; bool emsmallens = false; SkClipStack::Iter iter(stack, SkClipStack::Iter::kTop_IterStart); int numAAElements = 0; while ((kUnknown_InitialState == *initialState)) { const Element* element = iter.prev(); if (nullptr == element) { *initialState = GrReducedClip::kAllIn_InitialState; break; } if (SkClipStack::kEmptyGenID == element->getGenID()) { *initialState = GrReducedClip::kAllOut_InitialState; break; } if (SkClipStack::kWideOpenGenID == element->getGenID()) { *initialState = GrReducedClip::kAllIn_InitialState; break; } bool skippable = false; bool isFlip = false; // does this op just flip the in/out state of every point in the bounds switch (element->getOp()) { case SkRegion::kDifference_Op: // check if the shape subtracted either contains the entire bounds (and makes // the clip empty) or is outside the bounds and therefore can be skipped. if (element->isInverseFilled()) { if (element->contains(queryBounds)) { skippable = true; } else if (!SkRect::Intersects(element->getBounds(), queryBounds)) { *initialState = GrReducedClip::kAllOut_InitialState; skippable = true; } } else { if (element->contains(queryBounds)) { *initialState = GrReducedClip::kAllOut_InitialState; skippable = true; } else if (!SkRect::Intersects(element->getBounds(), queryBounds)) { skippable = true; } } if (!skippable) { emsmallens = true; } break; case SkRegion::kIntersect_Op: // check if the shape intersected contains the entire bounds and therefore can // be skipped or it is outside the entire bounds and therefore makes the clip // empty. if (element->isInverseFilled()) { if (element->contains(queryBounds)) { *initialState = GrReducedClip::kAllOut_InitialState; skippable = true; } else if (!SkRect::Intersects(element->getBounds(), queryBounds)) { skippable = true; } } else { if (element->contains(queryBounds)) { skippable = true; } else if (!SkRect::Intersects(element->getBounds(), queryBounds)) { *initialState = GrReducedClip::kAllOut_InitialState; skippable = true; } } if (!skippable) { emsmallens = true; } break; case SkRegion::kUnion_Op: // If the union-ed shape contains the entire bounds then after this element // the bounds is entirely inside the clip. If the union-ed shape is outside the // bounds then this op can be skipped. if (element->isInverseFilled()) { if (element->contains(queryBounds)) { skippable = true; } else if (!SkRect::Intersects(element->getBounds(), queryBounds)) { *initialState = GrReducedClip::kAllIn_InitialState; skippable = true; } } else { if (element->contains(queryBounds)) { *initialState = GrReducedClip::kAllIn_InitialState; skippable = true; } else if (!SkRect::Intersects(element->getBounds(), queryBounds)) { skippable = true; } } if (!skippable) { embiggens = true; } break; case SkRegion::kXOR_Op: // If the bounds is entirely inside the shape being xor-ed then the effect is // to flip the inside/outside state of every point in the bounds. We may be // able to take advantage of this in the forward pass. If the xor-ed shape // doesn't intersect the bounds then it can be skipped. if (element->isInverseFilled()) { if (element->contains(queryBounds)) { skippable = true; } else if (!SkRect::Intersects(element->getBounds(), queryBounds)) { isFlip = true; } } else { if (element->contains(queryBounds)) { isFlip = true; } else if (!SkRect::Intersects(element->getBounds(), queryBounds)) { skippable = true; } } if (!skippable) { emsmallens = embiggens = true; } break; case SkRegion::kReverseDifference_Op: // When the bounds is entirely within the rev-diff shape then this behaves like xor // and reverses every point inside the bounds. If the shape is completely outside // the bounds then we know after this element is applied that the bounds will be // all outside the current clip.B if (element->isInverseFilled()) { if (element->contains(queryBounds)) { *initialState = GrReducedClip::kAllOut_InitialState; skippable = true; } else if (!SkRect::Intersects(element->getBounds(), queryBounds)) { isFlip = true; } } else { if (element->contains(queryBounds)) { isFlip = true; } else if (!SkRect::Intersects(element->getBounds(), queryBounds)) { *initialState = GrReducedClip::kAllOut_InitialState; skippable = true; } } if (!skippable) { emsmallens = embiggens = true; } break; case SkRegion::kReplace_Op: // Replace will always terminate our walk. We will either begin the forward walk // at the replace op or detect here than the shape is either completely inside // or completely outside the bounds. In this latter case it can be skipped by // setting the correct value for initialState. if (element->isInverseFilled()) { if (element->contains(queryBounds)) { *initialState = GrReducedClip::kAllOut_InitialState; skippable = true; } else if (!SkRect::Intersects(element->getBounds(), queryBounds)) { *initialState = GrReducedClip::kAllIn_InitialState; skippable = true; } } else { if (element->contains(queryBounds)) { *initialState = GrReducedClip::kAllIn_InitialState; skippable = true; } else if (!SkRect::Intersects(element->getBounds(), queryBounds)) { *initialState = GrReducedClip::kAllOut_InitialState; skippable = true; } } if (!skippable) { *initialState = GrReducedClip::kAllOut_InitialState; embiggens = emsmallens = true; } break; default: SkDEBUGFAIL("Unexpected op."); break; } if (!skippable) { if (0 == result->count()) { // This will be the last element. Record the stricter genID. *resultGenID = element->getGenID(); } // if it is a flip, change it to a bounds-filling rect if (isFlip) { SkASSERT(SkRegion::kXOR_Op == element->getOp() || SkRegion::kReverseDifference_Op == element->getOp()); result->addToHead(queryBounds, SkRegion::kReverseDifference_Op, false); } else { Element* newElement = result->addToHead(*element); if (newElement->isAA()) { ++numAAElements; } // Intersecting an inverse shape is the same as differencing the non-inverse shape. // Replacing with an inverse shape is the same as setting initialState=kAllIn and // differencing the non-inverse shape. bool isReplace = SkRegion::kReplace_Op == newElement->getOp(); if (newElement->isInverseFilled() && (SkRegion::kIntersect_Op == newElement->getOp() || isReplace)) { newElement->invertShapeFillType(); newElement->setOp(SkRegion::kDifference_Op); if (isReplace) { SkASSERT(GrReducedClip::kAllOut_InitialState == *initialState); *initialState = GrReducedClip::kAllIn_InitialState; } } } } } if ((GrReducedClip::kAllOut_InitialState == *initialState && !embiggens) || (GrReducedClip::kAllIn_InitialState == *initialState && !emsmallens)) { result->reset(); } else { Element* element = result->headIter().get(); while (element) { bool skippable = false; switch (element->getOp()) { case SkRegion::kDifference_Op: // subtracting from the empty set yields the empty set. skippable = GrReducedClip::kAllOut_InitialState == *initialState; break; case SkRegion::kIntersect_Op: // intersecting with the empty set yields the empty set if (GrReducedClip::kAllOut_InitialState == *initialState) { skippable = true; } else { // We can clear to zero and then simply draw the clip element. *initialState = GrReducedClip::kAllOut_InitialState; element->setOp(SkRegion::kReplace_Op); } break; case SkRegion::kUnion_Op: if (GrReducedClip::kAllIn_InitialState == *initialState) { // unioning the infinite plane with anything is a no-op. skippable = true; } else { // unioning the empty set with a shape is the shape. element->setOp(SkRegion::kReplace_Op); } break; case SkRegion::kXOR_Op: if (GrReducedClip::kAllOut_InitialState == *initialState) { // xor could be changed to diff in the kAllIn case, not sure it's a win. element->setOp(SkRegion::kReplace_Op); } break; case SkRegion::kReverseDifference_Op: if (GrReducedClip::kAllIn_InitialState == *initialState) { // subtracting the whole plane will yield the empty set. skippable = true; *initialState = GrReducedClip::kAllOut_InitialState; } else { // this picks up flips inserted in the backwards pass. skippable = element->isInverseFilled() ? !SkRect::Intersects(element->getBounds(), queryBounds) : element->contains(queryBounds); if (skippable) { *initialState = GrReducedClip::kAllIn_InitialState; } else { element->setOp(SkRegion::kReplace_Op); } } break; case SkRegion::kReplace_Op: skippable = false; // we would have skipped it in the backwards walk if we // could've. break; default: SkDEBUGFAIL("Unexpected op."); break; } if (!skippable) { break; } else { if (element->isAA()) { --numAAElements; } result->popHead(); element = result->headIter().get(); } } } if (requiresAA) { *requiresAA = numAAElements > 0; } if (0 == result->count()) { if (*initialState == GrReducedClip::kAllIn_InitialState) { *resultGenID = SkClipStack::kWideOpenGenID; } else { *resultGenID = SkClipStack::kEmptyGenID; } } } /* There are plenty of optimizations that could be added here. Maybe flips could be folded into earlier operations. Or would inserting flips and reversing earlier ops ever be a win? Perhaps for the case where the bounds are kInsideOut_BoundsType. We could restrict earlier operations based on later intersect operations, and perhaps remove intersect-rects. We could optionally take a rect in case the caller knows a bound on what is to be drawn through this clip. */ void GrReducedClip::ReduceClipStack(const SkClipStack& stack, const SkIRect& queryBounds, ElementList* result, int32_t* resultGenID, InitialState* initialState, SkIRect* tighterBounds, bool* requiresAA) { result->reset(); // The clip established by the element list might be cached based on the last // generation id. When we make early returns, we do not know what was the generation // id that lead to the state. Make a conservative guess. *resultGenID = stack.getTopmostGenID(); if (stack.isWideOpen()) { *initialState = kAllIn_InitialState; return; } // We initially look at whether the bounds alone is sufficient. We also use the stack bounds to // attempt to compute the tighterBounds. SkClipStack::BoundsType stackBoundsType; SkRect stackBounds; bool iior; stack.getBounds(&stackBounds, &stackBoundsType, &iior); const SkIRect* bounds = &queryBounds; SkRect scalarQueryBounds = SkRect::Make(queryBounds); if (iior) { SkASSERT(SkClipStack::kNormal_BoundsType == stackBoundsType); SkRect isectRect; if (stackBounds.contains(scalarQueryBounds)) { *initialState = GrReducedClip::kAllIn_InitialState; if (tighterBounds) { *tighterBounds = queryBounds; } if (requiresAA) { *requiresAA = false; } } else if (isectRect.intersect(stackBounds, scalarQueryBounds)) { // If the caller asked for tighter integer bounds we may be able to // return kAllIn and give the bounds with no elements if (tighterBounds) { isectRect.roundOut(tighterBounds); SkRect scalarTighterBounds = SkRect::Make(*tighterBounds); if (scalarTighterBounds == isectRect) { // the round-out didn't add any area outside the clip rect. if (requiresAA) { *requiresAA = false; } *initialState = GrReducedClip::kAllIn_InitialState; return; } } *initialState = kAllOut_InitialState; // iior should only be true if aa/non-aa status matches among all elements. SkClipStack::Iter iter(stack, SkClipStack::Iter::kTop_IterStart); bool doAA = iter.prev()->isAA(); result->addToHead(isectRect, SkRegion::kReplace_Op, doAA); if (requiresAA) { *requiresAA = doAA; } } else { *initialState = kAllOut_InitialState; if (requiresAA) { *requiresAA = false; } } return; } else { if (SkClipStack::kNormal_BoundsType == stackBoundsType) { if (!SkRect::Intersects(stackBounds, scalarQueryBounds)) { *initialState = kAllOut_InitialState; if (requiresAA) { *requiresAA = false; } return; } if (tighterBounds) { SkIRect stackIBounds; stackBounds.roundOut(&stackIBounds); if (!tighterBounds->intersect(queryBounds, stackIBounds)) { SkASSERT(0); tighterBounds->setEmpty(); } bounds = tighterBounds; } } else { if (stackBounds.contains(scalarQueryBounds)) { *initialState = kAllOut_InitialState; if (requiresAA) { *requiresAA = false; } return; } if (tighterBounds) { *tighterBounds = queryBounds; } } } SkRect scalarBounds = SkRect::Make(*bounds); // Now that we have determined the bounds to use and filtered out the trivial cases, call the // helper that actually walks the stack. reduced_stack_walker(stack, scalarBounds, result, resultGenID, initialState, requiresAA); // The list that was computed in this function may be cached based on the gen id of the last // element. SkASSERT(SkClipStack::kInvalidGenID != *resultGenID); }