/* * Copyright (C) 2014 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include "CanvasState.h" #include "hwui/Canvas.h" #include "utils/MathUtils.h" namespace android { namespace uirenderer { CanvasState::CanvasState(CanvasStateClient& renderer) : mWidth(-1), mHeight(-1), mSaveCount(1), mCanvas(renderer), mSnapshot(&mFirstSnapshot) {} CanvasState::~CanvasState() { // First call freeSnapshot on all but mFirstSnapshot // to invoke all the dtors freeAllSnapshots(); // Now actually release the memory while (mSnapshotPool) { void* temp = mSnapshotPool; mSnapshotPool = mSnapshotPool->previous; free(temp); } } void CanvasState::initializeRecordingSaveStack(int viewportWidth, int viewportHeight) { if (mWidth != viewportWidth || mHeight != viewportHeight) { mWidth = viewportWidth; mHeight = viewportHeight; mFirstSnapshot.initializeViewport(viewportWidth, viewportHeight); mCanvas.onViewportInitialized(); } freeAllSnapshots(); mSnapshot = allocSnapshot(&mFirstSnapshot, SaveFlags::MatrixClip); mSnapshot->setRelativeLightCenter(Vector3()); mSaveCount = 1; } void CanvasState::initializeSaveStack(int viewportWidth, int viewportHeight, float clipLeft, float clipTop, float clipRight, float clipBottom, const Vector3& lightCenter) { if (mWidth != viewportWidth || mHeight != viewportHeight) { mWidth = viewportWidth; mHeight = viewportHeight; mFirstSnapshot.initializeViewport(viewportWidth, viewportHeight); mCanvas.onViewportInitialized(); } freeAllSnapshots(); mSnapshot = allocSnapshot(&mFirstSnapshot, SaveFlags::MatrixClip); mSnapshot->setClip(clipLeft, clipTop, clipRight, clipBottom); mSnapshot->fbo = mCanvas.getTargetFbo(); mSnapshot->setRelativeLightCenter(lightCenter); mSaveCount = 1; } Snapshot* CanvasState::allocSnapshot(Snapshot* previous, int savecount) { void* memory; if (mSnapshotPool) { memory = mSnapshotPool; mSnapshotPool = mSnapshotPool->previous; mSnapshotPoolCount--; } else { memory = malloc(sizeof(Snapshot)); } return new (memory) Snapshot(previous, savecount); } void CanvasState::freeSnapshot(Snapshot* snapshot) { snapshot->~Snapshot(); // Arbitrary number, just don't let this grown unbounded if (mSnapshotPoolCount > 10) { free((void*)snapshot); } else { snapshot->previous = mSnapshotPool; mSnapshotPool = snapshot; mSnapshotPoolCount++; } } void CanvasState::freeAllSnapshots() { while (mSnapshot != &mFirstSnapshot) { Snapshot* temp = mSnapshot; mSnapshot = mSnapshot->previous; freeSnapshot(temp); } } /////////////////////////////////////////////////////////////////////////////// // Save (layer) /////////////////////////////////////////////////////////////////////////////// /** * Guaranteed to save without side-effects * * This approach, here and in restoreSnapshot(), allows subclasses to directly manipulate the save * stack, and ensures restoreToCount() doesn't call back into subclass overrides. */ int CanvasState::saveSnapshot(int flags) { mSnapshot = allocSnapshot(mSnapshot, flags); return mSaveCount++; } int CanvasState::save(int flags) { return saveSnapshot(flags); } /** * Guaranteed to restore without side-effects. */ void CanvasState::restoreSnapshot() { Snapshot* toRemove = mSnapshot; Snapshot* toRestore = mSnapshot->previous; mSaveCount--; mSnapshot = toRestore; // subclass handles restore implementation mCanvas.onSnapshotRestored(*toRemove, *toRestore); freeSnapshot(toRemove); } void CanvasState::restore() { if (mSaveCount > 1) { restoreSnapshot(); } } void CanvasState::restoreToCount(int saveCount) { if (saveCount < 1) saveCount = 1; while (mSaveCount > saveCount) { restoreSnapshot(); } } /////////////////////////////////////////////////////////////////////////////// // Matrix /////////////////////////////////////////////////////////////////////////////// void CanvasState::getMatrix(SkMatrix* matrix) const { mSnapshot->transform->copyTo(*matrix); } void CanvasState::translate(float dx, float dy, float dz) { mSnapshot->transform->translate(dx, dy, dz); } void CanvasState::rotate(float degrees) { mSnapshot->transform->rotate(degrees, 0.0f, 0.0f, 1.0f); } void CanvasState::scale(float sx, float sy) { mSnapshot->transform->scale(sx, sy, 1.0f); } void CanvasState::skew(float sx, float sy) { mSnapshot->transform->skew(sx, sy); } void CanvasState::setMatrix(const SkMatrix& matrix) { mSnapshot->transform->load(matrix); } void CanvasState::setMatrix(const Matrix4& matrix) { *(mSnapshot->transform) = matrix; } void CanvasState::concatMatrix(const SkMatrix& matrix) { mat4 transform(matrix); mSnapshot->transform->multiply(transform); } void CanvasState::concatMatrix(const Matrix4& matrix) { mSnapshot->transform->multiply(matrix); } /////////////////////////////////////////////////////////////////////////////// // Clip /////////////////////////////////////////////////////////////////////////////// bool CanvasState::clipRect(float left, float top, float right, float bottom, SkClipOp op) { mSnapshot->clip(Rect(left, top, right, bottom), op); return !mSnapshot->clipIsEmpty(); } bool CanvasState::clipPath(const SkPath* path, SkClipOp op) { mSnapshot->clipPath(*path, op); return !mSnapshot->clipIsEmpty(); } void CanvasState::setClippingOutline(LinearAllocator& allocator, const Outline* outline) { Rect bounds; float radius; if (!outline->getAsRoundRect(&bounds, &radius)) return; // only RR supported bool outlineIsRounded = MathUtils::isPositive(radius); if (!outlineIsRounded || currentTransform()->isSimple()) { // TODO: consider storing this rect separately, so that this can't be replaced with clip ops clipRect(bounds.left, bounds.top, bounds.right, bounds.bottom, SkClipOp::kIntersect); } if (outlineIsRounded) { setClippingRoundRect(allocator, bounds, radius, false); } } /////////////////////////////////////////////////////////////////////////////// // Quick Rejection /////////////////////////////////////////////////////////////////////////////// /** * Calculates whether content drawn within the passed bounds would be outside of, or intersect with * the clipRect. Does not modify the scissor. * * @param clipRequired if not null, will be set to true if element intersects clip * (and wasn't rejected) * * @param snapOut if set, the geometry will be treated as having an AA ramp. * See Rect::snapGeometryToPixelBoundaries() */ bool CanvasState::calculateQuickRejectForScissor(float left, float top, float right, float bottom, bool* clipRequired, bool* roundRectClipRequired, bool snapOut) const { if (bottom <= top || right <= left) { return true; } Rect r(left, top, right, bottom); currentTransform()->mapRect(r); r.snapGeometryToPixelBoundaries(snapOut); Rect clipRect(currentRenderTargetClip()); clipRect.snapToPixelBoundaries(); if (!clipRect.intersects(r)) return true; // clip is required if geometry intersects clip rect if (clipRequired) { *clipRequired = !clipRect.contains(r); } // round rect clip is required if RR clip exists, and geometry intersects its corners if (roundRectClipRequired) { *roundRectClipRequired = mSnapshot->roundRectClipState != nullptr && mSnapshot->roundRectClipState->areaRequiresRoundRectClip(r); } return false; } bool CanvasState::quickRejectConservative(float left, float top, float right, float bottom) const { if (bottom <= top || right <= left) { return true; } Rect r(left, top, right, bottom); currentTransform()->mapRect(r); r.roundOut(); // rounded out to be conservative Rect clipRect(currentRenderTargetClip()); clipRect.snapToPixelBoundaries(); if (!clipRect.intersects(r)) return true; return false; } } // namespace uirenderer } // namespace android