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/*
* Copyright (C) 2011 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.
*/
#define LOG_TAG "Sprites"
//#define LOG_NDEBUG 0
#include "SpriteController.h"
#include <log/log.h>
#include <utils/String8.h>
#include <gui/Surface.h>
#include <SkBitmap.h>
#include <SkCanvas.h>
#include <SkColor.h>
#include <SkPaint.h>
#include <android/native_window.h>
namespace android {
// --- SpriteController ---
SpriteController::SpriteController(const sp<Looper>& looper, int32_t overlayLayer) :
mLooper(looper), mOverlayLayer(overlayLayer) {
mHandler = new WeakMessageHandler(this);
mLocked.transactionNestingCount = 0;
mLocked.deferredSpriteUpdate = false;
}
SpriteController::~SpriteController() {
mLooper->removeMessages(mHandler);
if (mSurfaceComposerClient != NULL) {
mSurfaceComposerClient->dispose();
mSurfaceComposerClient.clear();
}
}
sp<Sprite> SpriteController::createSprite() {
return new SpriteImpl(this);
}
void SpriteController::openTransaction() {
AutoMutex _l(mLock);
mLocked.transactionNestingCount += 1;
}
void SpriteController::closeTransaction() {
AutoMutex _l(mLock);
LOG_ALWAYS_FATAL_IF(mLocked.transactionNestingCount == 0,
"Sprite closeTransaction() called but there is no open sprite transaction");
mLocked.transactionNestingCount -= 1;
if (mLocked.transactionNestingCount == 0 && mLocked.deferredSpriteUpdate) {
mLocked.deferredSpriteUpdate = false;
mLooper->sendMessage(mHandler, Message(MSG_UPDATE_SPRITES));
}
}
void SpriteController::invalidateSpriteLocked(const sp<SpriteImpl>& sprite) {
bool wasEmpty = mLocked.invalidatedSprites.isEmpty();
mLocked.invalidatedSprites.push(sprite);
if (wasEmpty) {
if (mLocked.transactionNestingCount != 0) {
mLocked.deferredSpriteUpdate = true;
} else {
mLooper->sendMessage(mHandler, Message(MSG_UPDATE_SPRITES));
}
}
}
void SpriteController::disposeSurfaceLocked(const sp<SurfaceControl>& surfaceControl) {
bool wasEmpty = mLocked.disposedSurfaces.isEmpty();
mLocked.disposedSurfaces.push(surfaceControl);
if (wasEmpty) {
mLooper->sendMessage(mHandler, Message(MSG_DISPOSE_SURFACES));
}
}
void SpriteController::handleMessage(const Message& message) {
switch (message.what) {
case MSG_UPDATE_SPRITES:
doUpdateSprites();
break;
case MSG_DISPOSE_SURFACES:
doDisposeSurfaces();
break;
}
}
void SpriteController::doUpdateSprites() {
// Collect information about sprite updates.
// Each sprite update record includes a reference to its associated sprite so we can
// be certain the sprites will not be deleted while this function runs. Sprites
// may invalidate themselves again during this time but we will handle those changes
// in the next iteration.
Vector<SpriteUpdate> updates;
size_t numSprites;
{ // acquire lock
AutoMutex _l(mLock);
numSprites = mLocked.invalidatedSprites.size();
for (size_t i = 0; i < numSprites; i++) {
const sp<SpriteImpl>& sprite = mLocked.invalidatedSprites.itemAt(i);
updates.push(SpriteUpdate(sprite, sprite->getStateLocked()));
sprite->resetDirtyLocked();
}
mLocked.invalidatedSprites.clear();
} // release lock
// Create missing surfaces.
bool surfaceChanged = false;
for (size_t i = 0; i < numSprites; i++) {
SpriteUpdate& update = updates.editItemAt(i);
if (update.state.surfaceControl == NULL && update.state.wantSurfaceVisible()) {
update.state.surfaceWidth = update.state.icon.bitmap.width();
update.state.surfaceHeight = update.state.icon.bitmap.height();
update.state.surfaceDrawn = false;
update.state.surfaceVisible = false;
update.state.surfaceControl = obtainSurface(
update.state.surfaceWidth, update.state.surfaceHeight);
if (update.state.surfaceControl != NULL) {
update.surfaceChanged = surfaceChanged = true;
}
}
}
// Resize and/or reparent sprites if needed.
SurfaceComposerClient::Transaction t;
bool needApplyTransaction = false;
for (size_t i = 0; i < numSprites; i++) {
SpriteUpdate& update = updates.editItemAt(i);
if (update.state.surfaceControl == nullptr) {
continue;
}
if (update.state.wantSurfaceVisible()) {
int32_t desiredWidth = update.state.icon.bitmap.width();
int32_t desiredHeight = update.state.icon.bitmap.height();
if (update.state.surfaceWidth < desiredWidth
|| update.state.surfaceHeight < desiredHeight) {
needApplyTransaction = true;
t.setSize(update.state.surfaceControl,
desiredWidth, desiredHeight);
update.state.surfaceWidth = desiredWidth;
update.state.surfaceHeight = desiredHeight;
update.state.surfaceDrawn = false;
update.surfaceChanged = surfaceChanged = true;
if (update.state.surfaceVisible) {
t.hide(update.state.surfaceControl);
update.state.surfaceVisible = false;
}
}
}
// If surface is a new one, we have to set right layer stack.
if (update.surfaceChanged || update.state.dirty & DIRTY_DISPLAY_ID) {
t.setLayerStack(update.state.surfaceControl, update.state.displayId);
needApplyTransaction = true;
}
}
if (needApplyTransaction) {
t.apply();
}
// Redraw sprites if needed.
for (size_t i = 0; i < numSprites; i++) {
SpriteUpdate& update = updates.editItemAt(i);
if ((update.state.dirty & DIRTY_BITMAP) && update.state.surfaceDrawn) {
update.state.surfaceDrawn = false;
update.surfaceChanged = surfaceChanged = true;
}
if (update.state.surfaceControl != NULL && !update.state.surfaceDrawn
&& update.state.wantSurfaceVisible()) {
sp<Surface> surface = update.state.surfaceControl->getSurface();
ANativeWindow_Buffer outBuffer;
status_t status = surface->lock(&outBuffer, NULL);
if (status) {
ALOGE("Error %d locking sprite surface before drawing.", status);
} else {
SkBitmap surfaceBitmap;
ssize_t bpr = outBuffer.stride * bytesPerPixel(outBuffer.format);
surfaceBitmap.installPixels(SkImageInfo::MakeN32Premul(outBuffer.width, outBuffer.height),
outBuffer.bits, bpr);
SkCanvas surfaceCanvas(surfaceBitmap);
SkPaint paint;
paint.setBlendMode(SkBlendMode::kSrc);
surfaceCanvas.drawBitmap(update.state.icon.bitmap, 0, 0, &paint);
if (outBuffer.width > update.state.icon.bitmap.width()) {
paint.setColor(0); // transparent fill color
surfaceCanvas.drawRect(SkRect::MakeLTRB(update.state.icon.bitmap.width(), 0,
outBuffer.width, update.state.icon.bitmap.height()), paint);
}
if (outBuffer.height > update.state.icon.bitmap.height()) {
paint.setColor(0); // transparent fill color
surfaceCanvas.drawRect(SkRect::MakeLTRB(0, update.state.icon.bitmap.height(),
outBuffer.width, outBuffer.height), paint);
}
status = surface->unlockAndPost();
if (status) {
ALOGE("Error %d unlocking and posting sprite surface after drawing.", status);
} else {
update.state.surfaceDrawn = true;
update.surfaceChanged = surfaceChanged = true;
}
}
}
}
needApplyTransaction = false;
for (size_t i = 0; i < numSprites; i++) {
SpriteUpdate& update = updates.editItemAt(i);
bool wantSurfaceVisibleAndDrawn = update.state.wantSurfaceVisible()
&& update.state.surfaceDrawn;
bool becomingVisible = wantSurfaceVisibleAndDrawn && !update.state.surfaceVisible;
bool becomingHidden = !wantSurfaceVisibleAndDrawn && update.state.surfaceVisible;
if (update.state.surfaceControl != NULL && (becomingVisible || becomingHidden
|| (wantSurfaceVisibleAndDrawn && (update.state.dirty & (DIRTY_ALPHA
| DIRTY_POSITION | DIRTY_TRANSFORMATION_MATRIX | DIRTY_LAYER
| DIRTY_VISIBILITY | DIRTY_HOTSPOT | DIRTY_DISPLAY_ID))))) {
needApplyTransaction = true;
if (wantSurfaceVisibleAndDrawn
&& (becomingVisible || (update.state.dirty & DIRTY_ALPHA))) {
t.setAlpha(update.state.surfaceControl,
update.state.alpha);
}
if (wantSurfaceVisibleAndDrawn
&& (becomingVisible || (update.state.dirty & (DIRTY_POSITION
| DIRTY_HOTSPOT)))) {
t.setPosition(
update.state.surfaceControl,
update.state.positionX - update.state.icon.hotSpotX,
update.state.positionY - update.state.icon.hotSpotY);
}
if (wantSurfaceVisibleAndDrawn
&& (becomingVisible
|| (update.state.dirty & DIRTY_TRANSFORMATION_MATRIX))) {
t.setMatrix(
update.state.surfaceControl,
update.state.transformationMatrix.dsdx,
update.state.transformationMatrix.dtdx,
update.state.transformationMatrix.dsdy,
update.state.transformationMatrix.dtdy);
}
int32_t surfaceLayer = mOverlayLayer + update.state.layer;
if (wantSurfaceVisibleAndDrawn
&& (becomingVisible || (update.state.dirty & DIRTY_LAYER))) {
t.setLayer(update.state.surfaceControl, surfaceLayer);
}
if (becomingVisible) {
t.show(update.state.surfaceControl);
update.state.surfaceVisible = true;
update.surfaceChanged = surfaceChanged = true;
} else if (becomingHidden) {
t.hide(update.state.surfaceControl);
update.state.surfaceVisible = false;
update.surfaceChanged = surfaceChanged = true;
}
}
}
if (needApplyTransaction) {
status_t status = t.apply();
if (status) {
ALOGE("Error applying Surface transaction");
}
}
// If any surfaces were changed, write back the new surface properties to the sprites.
if (surfaceChanged) { // acquire lock
AutoMutex _l(mLock);
for (size_t i = 0; i < numSprites; i++) {
const SpriteUpdate& update = updates.itemAt(i);
if (update.surfaceChanged) {
update.sprite->setSurfaceLocked(update.state.surfaceControl,
update.state.surfaceWidth, update.state.surfaceHeight,
update.state.surfaceDrawn, update.state.surfaceVisible);
}
}
} // release lock
// Clear the sprite update vector outside the lock. It is very important that
// we do not clear sprite references inside the lock since we could be releasing
// the last remaining reference to the sprite here which would result in the
// sprite being deleted and the lock being reacquired by the sprite destructor
// while already held.
updates.clear();
}
void SpriteController::doDisposeSurfaces() {
// Collect disposed surfaces.
Vector<sp<SurfaceControl> > disposedSurfaces;
{ // acquire lock
AutoMutex _l(mLock);
disposedSurfaces = mLocked.disposedSurfaces;
mLocked.disposedSurfaces.clear();
} // release lock
// Release the last reference to each surface outside of the lock.
// We don't want the surfaces to be deleted while we are holding our lock.
disposedSurfaces.clear();
}
void SpriteController::ensureSurfaceComposerClient() {
if (mSurfaceComposerClient == NULL) {
mSurfaceComposerClient = new SurfaceComposerClient();
}
}
sp<SurfaceControl> SpriteController::obtainSurface(int32_t width, int32_t height) {
ensureSurfaceComposerClient();
sp<SurfaceControl> surfaceControl = mSurfaceComposerClient->createSurface(
String8("Sprite"), width, height, PIXEL_FORMAT_RGBA_8888,
ISurfaceComposerClient::eHidden |
ISurfaceComposerClient::eCursorWindow);
if (surfaceControl == NULL || !surfaceControl->isValid()) {
ALOGE("Error creating sprite surface.");
return NULL;
}
return surfaceControl;
}
// --- SpriteController::SpriteImpl ---
SpriteController::SpriteImpl::SpriteImpl(const sp<SpriteController> controller) :
mController(controller) {
}
SpriteController::SpriteImpl::~SpriteImpl() {
AutoMutex _m(mController->mLock);
// Let the controller take care of deleting the last reference to sprite
// surfaces so that we do not block the caller on an IPC here.
if (mLocked.state.surfaceControl != NULL) {
mController->disposeSurfaceLocked(mLocked.state.surfaceControl);
mLocked.state.surfaceControl.clear();
}
}
void SpriteController::SpriteImpl::setIcon(const SpriteIcon& icon) {
AutoMutex _l(mController->mLock);
uint32_t dirty;
if (icon.isValid()) {
SkBitmap* bitmapCopy = &mLocked.state.icon.bitmap;
if (bitmapCopy->tryAllocPixels(icon.bitmap.info().makeColorType(kN32_SkColorType))) {
icon.bitmap.readPixels(bitmapCopy->info(), bitmapCopy->getPixels(),
bitmapCopy->rowBytes(), 0, 0);
}
if (!mLocked.state.icon.isValid()
|| mLocked.state.icon.hotSpotX != icon.hotSpotX
|| mLocked.state.icon.hotSpotY != icon.hotSpotY) {
mLocked.state.icon.hotSpotX = icon.hotSpotX;
mLocked.state.icon.hotSpotY = icon.hotSpotY;
dirty = DIRTY_BITMAP | DIRTY_HOTSPOT;
} else {
dirty = DIRTY_BITMAP;
}
} else if (mLocked.state.icon.isValid()) {
mLocked.state.icon.bitmap.reset();
dirty = DIRTY_BITMAP | DIRTY_HOTSPOT;
} else {
return; // setting to invalid icon and already invalid so nothing to do
}
invalidateLocked(dirty);
}
void SpriteController::SpriteImpl::setVisible(bool visible) {
AutoMutex _l(mController->mLock);
if (mLocked.state.visible != visible) {
mLocked.state.visible = visible;
invalidateLocked(DIRTY_VISIBILITY);
}
}
void SpriteController::SpriteImpl::setPosition(float x, float y) {
AutoMutex _l(mController->mLock);
if (mLocked.state.positionX != x || mLocked.state.positionY != y) {
mLocked.state.positionX = x;
mLocked.state.positionY = y;
invalidateLocked(DIRTY_POSITION);
}
}
void SpriteController::SpriteImpl::setLayer(int32_t layer) {
AutoMutex _l(mController->mLock);
if (mLocked.state.layer != layer) {
mLocked.state.layer = layer;
invalidateLocked(DIRTY_LAYER);
}
}
void SpriteController::SpriteImpl::setAlpha(float alpha) {
AutoMutex _l(mController->mLock);
if (mLocked.state.alpha != alpha) {
mLocked.state.alpha = alpha;
invalidateLocked(DIRTY_ALPHA);
}
}
void SpriteController::SpriteImpl::setTransformationMatrix(
const SpriteTransformationMatrix& matrix) {
AutoMutex _l(mController->mLock);
if (mLocked.state.transformationMatrix != matrix) {
mLocked.state.transformationMatrix = matrix;
invalidateLocked(DIRTY_TRANSFORMATION_MATRIX);
}
}
void SpriteController::SpriteImpl::setDisplayId(int32_t displayId) {
AutoMutex _l(mController->mLock);
if (mLocked.state.displayId != displayId) {
mLocked.state.displayId = displayId;
invalidateLocked(DIRTY_DISPLAY_ID);
}
}
void SpriteController::SpriteImpl::invalidateLocked(uint32_t dirty) {
bool wasDirty = mLocked.state.dirty;
mLocked.state.dirty |= dirty;
if (!wasDirty) {
mController->invalidateSpriteLocked(this);
}
}
} // namespace android