replicant-frameworks_native/services/surfaceflinger/SurfaceFlinger.cpp

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/*
* Copyright (C) 2007 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 <stdlib.h>
#include <stdio.h>
#include <stdint.h>
#include <unistd.h>
#include <fcntl.h>
#include <errno.h>
#include <math.h>
#include <limits.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <sys/ioctl.h>
#include <cutils/log.h>
#include <cutils/properties.h>
#include <binder/IPCThreadState.h>
#include <binder/IServiceManager.h>
#include <binder/MemoryHeapBase.h>
#include <binder/PermissionCache.h>
#include <gui/IDisplayEventConnection.h>
#include <utils/String8.h>
#include <utils/String16.h>
#include <utils/StopWatch.h>
#include <ui/GraphicBufferAllocator.h>
#include <ui/PixelFormat.h>
#include <pixelflinger/pixelflinger.h>
#include <GLES/gl.h>
#include "clz.h"
#include "DisplayEventConnection.h"
#include "EventThread.h"
#include "GLExtensions.h"
#include "DdmConnection.h"
#include "Layer.h"
#include "LayerDim.h"
#include "LayerScreenshot.h"
#include "SurfaceFlinger.h"
#include "DisplayHardware/DisplayHardware.h"
#include "DisplayHardware/HWComposer.h"
#include <private/android_filesystem_config.h>
#include <private/surfaceflinger/SharedBufferStack.h>
#define EGL_VERSION_HW_ANDROID 0x3143
#define DISPLAY_COUNT 1
namespace android {
// ---------------------------------------------------------------------------
const String16 sHardwareTest("android.permission.HARDWARE_TEST");
const String16 sAccessSurfaceFlinger("android.permission.ACCESS_SURFACE_FLINGER");
const String16 sReadFramebuffer("android.permission.READ_FRAME_BUFFER");
const String16 sDump("android.permission.DUMP");
// ---------------------------------------------------------------------------
SurfaceFlinger::SurfaceFlinger()
: BnSurfaceComposer(), Thread(false),
mTransactionFlags(0),
mTransationPending(false),
mLayersRemoved(false),
mBootTime(systemTime()),
mVisibleRegionsDirty(false),
mHwWorkListDirty(false),
mElectronBeamAnimationMode(0),
mDebugRegion(0),
mDebugBackground(0),
mDebugDDMS(0),
mDebugDisableHWC(0),
mDebugDisableTransformHint(0),
mDebugInSwapBuffers(0),
mLastSwapBufferTime(0),
mDebugInTransaction(0),
mLastTransactionTime(0),
mBootFinished(false),
mConsoleSignals(0),
mSecureFrameBuffer(0)
{
init();
}
void SurfaceFlinger::init()
{
ALOGI("SurfaceFlinger is starting");
// debugging stuff...
char value[PROPERTY_VALUE_MAX];
property_get("debug.sf.showupdates", value, "0");
mDebugRegion = atoi(value);
property_get("debug.sf.showbackground", value, "0");
mDebugBackground = atoi(value);
property_get("debug.sf.ddms", value, "0");
mDebugDDMS = atoi(value);
if (mDebugDDMS) {
DdmConnection::start(getServiceName());
}
ALOGI_IF(mDebugRegion, "showupdates enabled");
ALOGI_IF(mDebugBackground, "showbackground enabled");
ALOGI_IF(mDebugDDMS, "DDMS debugging enabled");
}
SurfaceFlinger::~SurfaceFlinger()
{
glDeleteTextures(1, &mWormholeTexName);
}
sp<IMemoryHeap> SurfaceFlinger::getCblk() const
{
return mServerHeap;
}
sp<ISurfaceComposerClient> SurfaceFlinger::createConnection()
{
sp<ISurfaceComposerClient> bclient;
sp<Client> client(new Client(this));
status_t err = client->initCheck();
if (err == NO_ERROR) {
bclient = client;
}
return bclient;
}
sp<IGraphicBufferAlloc> SurfaceFlinger::createGraphicBufferAlloc()
{
sp<GraphicBufferAlloc> gba(new GraphicBufferAlloc());
return gba;
}
const GraphicPlane& SurfaceFlinger::graphicPlane(int dpy) const
{
ALOGE_IF(uint32_t(dpy) >= DISPLAY_COUNT, "Invalid DisplayID %d", dpy);
const GraphicPlane& plane(mGraphicPlanes[dpy]);
return plane;
}
GraphicPlane& SurfaceFlinger::graphicPlane(int dpy)
{
return const_cast<GraphicPlane&>(
const_cast<SurfaceFlinger const *>(this)->graphicPlane(dpy));
}
void SurfaceFlinger::bootFinished()
{
const nsecs_t now = systemTime();
const nsecs_t duration = now - mBootTime;
ALOGI("Boot is finished (%ld ms)", long(ns2ms(duration)) );
mBootFinished = true;
// wait patiently for the window manager death
const String16 name("window");
sp<IBinder> window(defaultServiceManager()->getService(name));
if (window != 0) {
window->linkToDeath(this);
}
// stop boot animation
property_set("ctl.stop", "bootanim");
}
void SurfaceFlinger::binderDied(const wp<IBinder>& who)
{
// the window manager died on us. prepare its eulogy.
// reset screen orientation
setOrientation(0, eOrientationDefault, 0);
// restart the boot-animation
property_set("ctl.start", "bootanim");
}
void SurfaceFlinger::onFirstRef()
{
run("SurfaceFlinger", PRIORITY_URGENT_DISPLAY);
// Wait for the main thread to be done with its initialization
mReadyToRunBarrier.wait();
}
static inline uint16_t pack565(int r, int g, int b) {
return (r<<11)|(g<<5)|b;
}
status_t SurfaceFlinger::readyToRun()
{
ALOGI( "SurfaceFlinger's main thread ready to run. "
"Initializing graphics H/W...");
// we only support one display currently
int dpy = 0;
{
// initialize the main display
GraphicPlane& plane(graphicPlane(dpy));
DisplayHardware* const hw = new DisplayHardware(this, dpy);
plane.setDisplayHardware(hw);
}
// create the shared control-block
mServerHeap = new MemoryHeapBase(4096,
MemoryHeapBase::READ_ONLY, "SurfaceFlinger read-only heap");
ALOGE_IF(mServerHeap==0, "can't create shared memory dealer");
mServerCblk = static_cast<surface_flinger_cblk_t*>(mServerHeap->getBase());
ALOGE_IF(mServerCblk==0, "can't get to shared control block's address");
new(mServerCblk) surface_flinger_cblk_t;
// initialize primary screen
// (other display should be initialized in the same manner, but
// asynchronously, as they could come and go. None of this is supported
// yet).
const GraphicPlane& plane(graphicPlane(dpy));
const DisplayHardware& hw = plane.displayHardware();
const uint32_t w = hw.getWidth();
const uint32_t h = hw.getHeight();
const uint32_t f = hw.getFormat();
hw.makeCurrent();
// initialize the shared control block
mServerCblk->connected |= 1<<dpy;
display_cblk_t* dcblk = mServerCblk->displays + dpy;
memset(dcblk, 0, sizeof(display_cblk_t));
dcblk->w = plane.getWidth();
dcblk->h = plane.getHeight();
dcblk->format = f;
dcblk->orientation = ISurfaceComposer::eOrientationDefault;
dcblk->xdpi = hw.getDpiX();
dcblk->ydpi = hw.getDpiY();
dcblk->fps = hw.getRefreshRate();
dcblk->density = hw.getDensity();
// Initialize OpenGL|ES
glPixelStorei(GL_UNPACK_ALIGNMENT, 4);
glPixelStorei(GL_PACK_ALIGNMENT, 4);
glEnableClientState(GL_VERTEX_ARRAY);
glEnable(GL_SCISSOR_TEST);
glShadeModel(GL_FLAT);
glDisable(GL_DITHER);
glDisable(GL_CULL_FACE);
const uint16_t g0 = pack565(0x0F,0x1F,0x0F);
const uint16_t g1 = pack565(0x17,0x2f,0x17);
const uint16_t wormholeTexData[4] = { g0, g1, g1, g0 };
glGenTextures(1, &mWormholeTexName);
glBindTexture(GL_TEXTURE_2D, mWormholeTexName);
glTexParameterx(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_NEAREST);
glTexParameterx(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_NEAREST);
glTexParameterx(GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, GL_REPEAT);
glTexParameterx(GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, GL_REPEAT);
glTexImage2D(GL_TEXTURE_2D, 0, GL_RGB, 2, 2, 0,
GL_RGB, GL_UNSIGNED_SHORT_5_6_5, wormholeTexData);
const uint16_t protTexData[] = { pack565(0x03, 0x03, 0x03) };
glGenTextures(1, &mProtectedTexName);
glBindTexture(GL_TEXTURE_2D, mProtectedTexName);
glTexParameterx(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_NEAREST);
glTexParameterx(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_NEAREST);
glTexParameterx(GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, GL_REPEAT);
glTexParameterx(GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, GL_REPEAT);
glTexImage2D(GL_TEXTURE_2D, 0, GL_RGB, 1, 1, 0,
GL_RGB, GL_UNSIGNED_SHORT_5_6_5, protTexData);
glViewport(0, 0, w, h);
glMatrixMode(GL_PROJECTION);
glLoadIdentity();
// put the origin in the left-bottom corner
glOrthof(0, w, 0, h, 0, 1); // l=0, r=w ; b=0, t=h
// start the EventThread
mEventThread = new EventThread(this);
/*
* We're now ready to accept clients...
*/
mReadyToRunBarrier.open();
// start boot animation
property_set("ctl.start", "bootanim");
return NO_ERROR;
}
// ----------------------------------------------------------------------------
#if 0
#pragma mark -
#pragma mark Events Handler
#endif
void SurfaceFlinger::waitForEvent() {
mEventQueue.waitMessage();
}
void SurfaceFlinger::signalEvent() {
mEventQueue.invalidate();
}
status_t SurfaceFlinger::postMessageAsync(const sp<MessageBase>& msg,
nsecs_t reltime, uint32_t flags) {
return mEventQueue.postMessage(msg, reltime);
}
status_t SurfaceFlinger::postMessageSync(const sp<MessageBase>& msg,
nsecs_t reltime, uint32_t flags) {
status_t res = mEventQueue.postMessage(msg, reltime);
if (res == NO_ERROR) {
msg->wait();
}
return res;
}
// ----------------------------------------------------------------------------
bool SurfaceFlinger::authenticateSurfaceTexture(
const sp<ISurfaceTexture>& surfaceTexture) const {
Mutex::Autolock _l(mStateLock);
sp<IBinder> surfaceTextureBinder(surfaceTexture->asBinder());
// Check the visible layer list for the ISurface
const LayerVector& currentLayers = mCurrentState.layersSortedByZ;
size_t count = currentLayers.size();
for (size_t i=0 ; i<count ; i++) {
const sp<LayerBase>& layer(currentLayers[i]);
sp<LayerBaseClient> lbc(layer->getLayerBaseClient());
if (lbc != NULL) {
wp<IBinder> lbcBinder = lbc->getSurfaceTextureBinder();
if (lbcBinder == surfaceTextureBinder) {
return true;
}
}
}
// Check the layers in the purgatory. This check is here so that if a
// SurfaceTexture gets destroyed before all the clients are done using it,
// the error will not be reported as "surface XYZ is not authenticated", but
// will instead fail later on when the client tries to use the surface,
// which should be reported as "surface XYZ returned an -ENODEV". The
// purgatorized layers are no less authentic than the visible ones, so this
// should not cause any harm.
size_t purgatorySize = mLayerPurgatory.size();
for (size_t i=0 ; i<purgatorySize ; i++) {
const sp<LayerBase>& layer(mLayerPurgatory.itemAt(i));
sp<LayerBaseClient> lbc(layer->getLayerBaseClient());
if (lbc != NULL) {
wp<IBinder> lbcBinder = lbc->getSurfaceTextureBinder();
if (lbcBinder == surfaceTextureBinder) {
return true;
}
}
}
return false;
}
// ----------------------------------------------------------------------------
sp<IDisplayEventConnection> SurfaceFlinger::createDisplayEventConnection() {
sp<DisplayEventConnection> result(new DisplayEventConnection(mEventThread));
return result;
}
// ----------------------------------------------------------------------------
#if 0
#pragma mark -
#pragma mark Main loop
#endif
bool SurfaceFlinger::threadLoop()
{
waitForEvent();
// check for transactions
if (CC_UNLIKELY(mConsoleSignals)) {
handleConsoleEvents();
}
// if we're in a global transaction, don't do anything.
const uint32_t mask = eTransactionNeeded | eTraversalNeeded;
uint32_t transactionFlags = peekTransactionFlags(mask);
if (CC_UNLIKELY(transactionFlags)) {
handleTransaction(transactionFlags);
}
// post surfaces (if needed)
handlePageFlip();
if (mDirtyRegion.isEmpty()) {
// nothing new to do.
return true;
}
if (CC_UNLIKELY(mHwWorkListDirty)) {
// build the h/w work list
handleWorkList();
}
const DisplayHardware& hw(graphicPlane(0).displayHardware());
if (CC_LIKELY(hw.canDraw())) {
// repaint the framebuffer (if needed)
handleRepaint();
// inform the h/w that we're done compositing
hw.compositionComplete();
postFramebuffer();
} else {
// pretend we did the post
hw.compositionComplete();
hw.waitForVSync();
}
return true;
}
void SurfaceFlinger::postFramebuffer()
{
// this should never happen. we do the flip anyways so we don't
// risk to cause a deadlock with hwc
ALOGW_IF(mSwapRegion.isEmpty(), "mSwapRegion is empty");
const DisplayHardware& hw(graphicPlane(0).displayHardware());
const nsecs_t now = systemTime();
mDebugInSwapBuffers = now;
hw.flip(mSwapRegion);
mLastSwapBufferTime = systemTime() - now;
mDebugInSwapBuffers = 0;
mSwapRegion.clear();
}
void SurfaceFlinger::handleConsoleEvents()
{
// something to do with the console
const DisplayHardware& hw = graphicPlane(0).displayHardware();
int what = android_atomic_and(0, &mConsoleSignals);
if (what & eConsoleAcquired) {
hw.acquireScreen();
// this is a temporary work-around, eventually this should be called
// by the power-manager
SurfaceFlinger::turnElectronBeamOn(mElectronBeamAnimationMode);
}
if (what & eConsoleReleased) {
if (hw.isScreenAcquired()) {
hw.releaseScreen();
}
}
mDirtyRegion.set(hw.bounds());
}
void SurfaceFlinger::handleTransaction(uint32_t transactionFlags)
{
Mutex::Autolock _l(mStateLock);
const nsecs_t now = systemTime();
mDebugInTransaction = now;
// Here we're guaranteed that some transaction flags are set
// so we can call handleTransactionLocked() unconditionally.
// We call getTransactionFlags(), which will also clear the flags,
// with mStateLock held to guarantee that mCurrentState won't change
// until the transaction is committed.
const uint32_t mask = eTransactionNeeded | eTraversalNeeded;
transactionFlags = getTransactionFlags(mask);
handleTransactionLocked(transactionFlags);
mLastTransactionTime = systemTime() - now;
mDebugInTransaction = 0;
invalidateHwcGeometry();
// here the transaction has been committed
}
void SurfaceFlinger::handleTransactionLocked(uint32_t transactionFlags)
{
const LayerVector& currentLayers(mCurrentState.layersSortedByZ);
const size_t count = currentLayers.size();
/*
* Traversal of the children
* (perform the transaction for each of them if needed)
*/
const bool layersNeedTransaction = transactionFlags & eTraversalNeeded;
if (layersNeedTransaction) {
for (size_t i=0 ; i<count ; i++) {
const sp<LayerBase>& layer = currentLayers[i];
uint32_t trFlags = layer->getTransactionFlags(eTransactionNeeded);
if (!trFlags) continue;
const uint32_t flags = layer->doTransaction(0);
if (flags & Layer::eVisibleRegion)
mVisibleRegionsDirty = true;
}
}
/*
* Perform our own transaction if needed
*/
if (transactionFlags & eTransactionNeeded) {
if (mCurrentState.orientation != mDrawingState.orientation) {
// the orientation has changed, recompute all visible regions
// and invalidate everything.
const int dpy = 0;
const int orientation = mCurrentState.orientation;
Handle orientation changes more systematically. Bug: 4981385 Simplify the orientation changing code path in the WindowManager. Instead of the policy calling setRotation() when the sensor determined orientation changes, it calls updateRotation(), which figures everything out. For the most part, the rotation actually passed to setRotation() was more or less ignored and just added confusion, particularly when handling deferred orientation changes. Ensure that 180 degree rotations are disallowed even when the application specifies SCREEN_ORIENTATION_SENSOR_*. These rotations are only enabled when docked upside-down for some reason or when the application specifies SCREEN_ORIENTATION_FULL_SENSOR. Ensure that special modes like HDMI connected, lid switch, dock and rotation lock all cause the sensor to be ignored even when the application asks for sensor-based orientation changes. The sensor is not relevant in these modes because some external factor (or the user) is determining the preferred rotation. Currently, applications can still override the preferred rotation even when there are special modes in play that might say otherwise. We could tweak this so that some special modes trump application choices completely (resulting in a letter-boxed application, perhaps). I tested this sort of tweak (not included in the patch) and it seems to work fine, including transitions between applications with varying orientation. Delete dead code related to animFlags. Handle pausing/resuming orientation changes more precisely. Ensure that a deferred orientation change is performed when a drag completes, even if endDragLw() is not called because the drag was aborted before the drop happened. We pause the orientation change in register() and resume in unregister() because those methods appear to always be called as needed. Change-Id: If0a31de3d057251e581fdee64819f2b19e676e9a
2011-09-20 22:08:29 +00:00
// Currently unused: const uint32_t flags = mCurrentState.orientationFlags;
GraphicPlane& plane(graphicPlane(dpy));
plane.setOrientation(orientation);
// update the shared control block
const DisplayHardware& hw(plane.displayHardware());
volatile display_cblk_t* dcblk = mServerCblk->displays + dpy;
dcblk->orientation = orientation;
dcblk->w = plane.getWidth();
dcblk->h = plane.getHeight();
mVisibleRegionsDirty = true;
mDirtyRegion.set(hw.bounds());
}
if (currentLayers.size() > mDrawingState.layersSortedByZ.size()) {
// layers have been added
mVisibleRegionsDirty = true;
}
// some layers might have been removed, so
// we need to update the regions they're exposing.
if (mLayersRemoved) {
mLayersRemoved = false;
mVisibleRegionsDirty = true;
const LayerVector& previousLayers(mDrawingState.layersSortedByZ);
const size_t count = previousLayers.size();
for (size_t i=0 ; i<count ; i++) {
const sp<LayerBase>& layer(previousLayers[i]);
if (currentLayers.indexOf( layer ) < 0) {
// this layer is not visible anymore
mDirtyRegionRemovedLayer.orSelf(layer->visibleRegionScreen);
}
}
}
}
commitTransaction();
}
void SurfaceFlinger::computeVisibleRegions(
const LayerVector& currentLayers, Region& dirtyRegion, Region& opaqueRegion)
{
const GraphicPlane& plane(graphicPlane(0));
const Transform& planeTransform(plane.transform());
const DisplayHardware& hw(plane.displayHardware());
const Region screenRegion(hw.bounds());
Region aboveOpaqueLayers;
Region aboveCoveredLayers;
Region dirty;
bool secureFrameBuffer = false;
size_t i = currentLayers.size();
while (i--) {
const sp<LayerBase>& layer = currentLayers[i];
layer->validateVisibility(planeTransform);
// start with the whole surface at its current location
const Layer::State& s(layer->drawingState());
/*
* opaqueRegion: area of a surface that is fully opaque.
*/
Region opaqueRegion;
/*
* visibleRegion: area of a surface that is visible on screen
* and not fully transparent. This is essentially the layer's
* footprint minus the opaque regions above it.
* Areas covered by a translucent surface are considered visible.
*/
Region visibleRegion;
/*
* coveredRegion: area of a surface that is covered by all
* visible regions above it (which includes the translucent areas).
*/
Region coveredRegion;
// handle hidden surfaces by setting the visible region to empty
if (CC_LIKELY(!(s.flags & ISurfaceComposer::eLayerHidden) && s.alpha)) {
const bool translucent = !layer->isOpaque();
const Rect bounds(layer->visibleBounds());
visibleRegion.set(bounds);
visibleRegion.andSelf(screenRegion);
if (!visibleRegion.isEmpty()) {
// Remove the transparent area from the visible region
if (translucent) {
visibleRegion.subtractSelf(layer->transparentRegionScreen);
}
// compute the opaque region
const int32_t layerOrientation = layer->getOrientation();
if (s.alpha==255 && !translucent &&
((layerOrientation & Transform::ROT_INVALID) == false)) {
// the opaque region is the layer's footprint
opaqueRegion = visibleRegion;
}
}
}
// Clip the covered region to the visible region
coveredRegion = aboveCoveredLayers.intersect(visibleRegion);
// Update aboveCoveredLayers for next (lower) layer
aboveCoveredLayers.orSelf(visibleRegion);
// subtract the opaque region covered by the layers above us
visibleRegion.subtractSelf(aboveOpaqueLayers);
// compute this layer's dirty region
if (layer->contentDirty) {
// we need to invalidate the whole region
dirty = visibleRegion;
// as well, as the old visible region
dirty.orSelf(layer->visibleRegionScreen);
layer->contentDirty = false;
} else {
/* compute the exposed region:
* the exposed region consists of two components:
* 1) what's VISIBLE now and was COVERED before
* 2) what's EXPOSED now less what was EXPOSED before
*
* note that (1) is conservative, we start with the whole
* visible region but only keep what used to be covered by
* something -- which mean it may have been exposed.
*
* (2) handles areas that were not covered by anything but got
* exposed because of a resize.
*/
const Region newExposed = visibleRegion - coveredRegion;
const Region oldVisibleRegion = layer->visibleRegionScreen;
const Region oldCoveredRegion = layer->coveredRegionScreen;
const Region oldExposed = oldVisibleRegion - oldCoveredRegion;
dirty = (visibleRegion&oldCoveredRegion) | (newExposed-oldExposed);
}
dirty.subtractSelf(aboveOpaqueLayers);
// accumulate to the screen dirty region
dirtyRegion.orSelf(dirty);
// Update aboveOpaqueLayers for next (lower) layer
aboveOpaqueLayers.orSelf(opaqueRegion);
// Store the visible region is screen space
layer->setVisibleRegion(visibleRegion);
layer->setCoveredRegion(coveredRegion);
// If a secure layer is partially visible, lock-down the screen!
if (layer->isSecure() && !visibleRegion.isEmpty()) {
secureFrameBuffer = true;
}
}
// invalidate the areas where a layer was removed
dirtyRegion.orSelf(mDirtyRegionRemovedLayer);
mDirtyRegionRemovedLayer.clear();
mSecureFrameBuffer = secureFrameBuffer;
opaqueRegion = aboveOpaqueLayers;
}
void SurfaceFlinger::commitTransaction()
{
if (!mLayersPendingRemoval.isEmpty()) {
// Notify removed layers now that they can't be drawn from
for (size_t i = 0; i < mLayersPendingRemoval.size(); i++) {
mLayersPendingRemoval[i]->onRemoved();
}
mLayersPendingRemoval.clear();
}
mDrawingState = mCurrentState;
mTransationPending = false;
mTransactionCV.broadcast();
}
void SurfaceFlinger::handlePageFlip()
{
bool visibleRegions = mVisibleRegionsDirty;
const LayerVector& currentLayers(mDrawingState.layersSortedByZ);
visibleRegions |= lockPageFlip(currentLayers);
const DisplayHardware& hw = graphicPlane(0).displayHardware();
const Region screenRegion(hw.bounds());
if (visibleRegions) {
Region opaqueRegion;
computeVisibleRegions(currentLayers, mDirtyRegion, opaqueRegion);
/*
* rebuild the visible layer list
*/
const size_t count = currentLayers.size();
mVisibleLayersSortedByZ.clear();
mVisibleLayersSortedByZ.setCapacity(count);
for (size_t i=0 ; i<count ; i++) {
if (!currentLayers[i]->visibleRegionScreen.isEmpty())
mVisibleLayersSortedByZ.add(currentLayers[i]);
}
mWormholeRegion = screenRegion.subtract(opaqueRegion);
mVisibleRegionsDirty = false;
invalidateHwcGeometry();
}
unlockPageFlip(currentLayers);
mDirtyRegion.orSelf(getAndClearInvalidateRegion());
mDirtyRegion.andSelf(screenRegion);
}
void SurfaceFlinger::invalidateHwcGeometry()
{
mHwWorkListDirty = true;
}
bool SurfaceFlinger::lockPageFlip(const LayerVector& currentLayers)
{
bool recomputeVisibleRegions = false;
size_t count = currentLayers.size();
sp<LayerBase> const* layers = currentLayers.array();
for (size_t i=0 ; i<count ; i++) {
const sp<LayerBase>& layer(layers[i]);
layer->lockPageFlip(recomputeVisibleRegions);
}
return recomputeVisibleRegions;
}
void SurfaceFlinger::unlockPageFlip(const LayerVector& currentLayers)
{
const GraphicPlane& plane(graphicPlane(0));
const Transform& planeTransform(plane.transform());
size_t count = currentLayers.size();
sp<LayerBase> const* layers = currentLayers.array();
for (size_t i=0 ; i<count ; i++) {
const sp<LayerBase>& layer(layers[i]);
layer->unlockPageFlip(planeTransform, mDirtyRegion);
}
}
void SurfaceFlinger::handleWorkList()
{
mHwWorkListDirty = false;
HWComposer& hwc(graphicPlane(0).displayHardware().getHwComposer());
if (hwc.initCheck() == NO_ERROR) {
const Vector< sp<LayerBase> >& currentLayers(mVisibleLayersSortedByZ);
const size_t count = currentLayers.size();
hwc.createWorkList(count);
hwc_layer_t* const cur(hwc.getLayers());
for (size_t i=0 ; cur && i<count ; i++) {
currentLayers[i]->setGeometry(&cur[i]);
if (mDebugDisableHWC || mDebugRegion) {
cur[i].compositionType = HWC_FRAMEBUFFER;
cur[i].flags |= HWC_SKIP_LAYER;
}
}
}
}
void SurfaceFlinger::handleRepaint()
{
// compute the invalid region
mSwapRegion.orSelf(mDirtyRegion);
if (CC_UNLIKELY(mDebugRegion)) {
debugFlashRegions();
}
// set the frame buffer
const DisplayHardware& hw(graphicPlane(0).displayHardware());
glMatrixMode(GL_MODELVIEW);
glLoadIdentity();
uint32_t flags = hw.getFlags();
if ((flags & DisplayHardware::SWAP_RECTANGLE) ||
(flags & DisplayHardware::BUFFER_PRESERVED))
{
// we can redraw only what's dirty, but since SWAP_RECTANGLE only
// takes a rectangle, we must make sure to update that whole
// rectangle in that case
if (flags & DisplayHardware::SWAP_RECTANGLE) {
// TODO: we really should be able to pass a region to
// SWAP_RECTANGLE so that we don't have to redraw all this.
mDirtyRegion.set(mSwapRegion.bounds());
} else {
// in the BUFFER_PRESERVED case, obviously, we can update only
// what's needed and nothing more.
// NOTE: this is NOT a common case, as preserving the backbuffer
// is costly and usually involves copying the whole update back.
}
} else {
if (flags & DisplayHardware::PARTIAL_UPDATES) {
// We need to redraw the rectangle that will be updated
// (pushed to the framebuffer).
// This is needed because PARTIAL_UPDATES only takes one
// rectangle instead of a region (see DisplayHardware::flip())
mDirtyRegion.set(mSwapRegion.bounds());
} else {
// we need to redraw everything (the whole screen)
mDirtyRegion.set(hw.bounds());
mSwapRegion = mDirtyRegion;
}
}
setupHardwareComposer(mDirtyRegion);
composeSurfaces(mDirtyRegion);
// update the swap region and clear the dirty region
mSwapRegion.orSelf(mDirtyRegion);
mDirtyRegion.clear();
}
void SurfaceFlinger::setupHardwareComposer(Region& dirtyInOut)
{
const DisplayHardware& hw(graphicPlane(0).displayHardware());
HWComposer& hwc(hw.getHwComposer());
hwc_layer_t* const cur(hwc.getLayers());
if (!cur) {
return;
}
const Vector< sp<LayerBase> >& layers(mVisibleLayersSortedByZ);
size_t count = layers.size();
ALOGE_IF(hwc.getNumLayers() != count,
"HAL number of layers (%d) doesn't match surfaceflinger (%d)",
hwc.getNumLayers(), count);
// just to be extra-safe, use the smallest count
if (hwc.initCheck() == NO_ERROR) {
count = count < hwc.getNumLayers() ? count : hwc.getNumLayers();
}
/*
* update the per-frame h/w composer data for each layer
* and build the transparent region of the FB
*/
for (size_t i=0 ; i<count ; i++) {
const sp<LayerBase>& layer(layers[i]);
layer->setPerFrameData(&cur[i]);
}
const size_t fbLayerCount = hwc.getLayerCount(HWC_FRAMEBUFFER);
status_t err = hwc.prepare();
ALOGE_IF(err, "HWComposer::prepare failed (%s)", strerror(-err));
if (err == NO_ERROR) {
// what's happening here is tricky.
// we want to clear all the layers with the CLEAR_FB flags
// that are opaque.
// however, since some GPU are efficient at preserving
// the backbuffer, we want to take advantage of that so we do the
// clear only in the dirty region (other areas will be preserved
// on those GPUs).
// NOTE: on non backbuffer preserving GPU, the dirty region
// has already been expanded as needed, so the code is correct
// there too.
//
// However, the content of the framebuffer cannot be trusted when
// we switch to/from FB/OVERLAY, in which case we need to
// expand the dirty region to those areas too.
//
// Note also that there is a special case when switching from
// "no layers in FB" to "some layers in FB", where we need to redraw
// the entire FB, since some areas might contain uninitialized
// data.
//
// Also we want to make sure to not clear areas that belong to
// layers above that won't redraw (we would just be erasing them),
// that is, we can't erase anything outside the dirty region.
Region transparent;
if (!fbLayerCount && hwc.getLayerCount(HWC_FRAMEBUFFER)) {
transparent.set(hw.getBounds());
dirtyInOut = transparent;
} else {
for (size_t i=0 ; i<count ; i++) {
const sp<LayerBase>& layer(layers[i]);
if ((cur[i].hints & HWC_HINT_CLEAR_FB) && layer->isOpaque()) {
transparent.orSelf(layer->visibleRegionScreen);
}
bool isOverlay = (cur[i].compositionType != HWC_FRAMEBUFFER);
if (isOverlay != layer->isOverlay()) {
// we transitioned to/from overlay, so add this layer
// to the dirty region so the framebuffer can be either
// cleared or redrawn.
dirtyInOut.orSelf(layer->visibleRegionScreen);
}
layer->setOverlay(isOverlay);
}
// don't erase stuff outside the dirty region
transparent.andSelf(dirtyInOut);
}
/*
* clear the area of the FB that need to be transparent
*/
if (!transparent.isEmpty()) {
glClearColor(0,0,0,0);
Region::const_iterator it = transparent.begin();
Region::const_iterator const end = transparent.end();
const int32_t height = hw.getHeight();
while (it != end) {
const Rect& r(*it++);
const GLint sy = height - (r.top + r.height());
glScissor(r.left, sy, r.width(), r.height());
glClear(GL_COLOR_BUFFER_BIT);
}
}
}
}
void SurfaceFlinger::composeSurfaces(const Region& dirty)
{
const DisplayHardware& hw(graphicPlane(0).displayHardware());
HWComposer& hwc(hw.getHwComposer());
const size_t fbLayerCount = hwc.getLayerCount(HWC_FRAMEBUFFER);
if (CC_UNLIKELY(fbLayerCount && !mWormholeRegion.isEmpty())) {
// should never happen unless the window manager has a bug
// draw something...
drawWormhole();
}
/*
* and then, render the layers targeted at the framebuffer
*/
hwc_layer_t* const cur(hwc.getLayers());
const Vector< sp<LayerBase> >& layers(mVisibleLayersSortedByZ);
size_t count = layers.size();
for (size_t i=0 ; i<count ; i++) {
if (cur && (cur[i].compositionType != HWC_FRAMEBUFFER)) {
continue;
}
const sp<LayerBase>& layer(layers[i]);
const Region clip(dirty.intersect(layer->visibleRegionScreen));
if (!clip.isEmpty()) {
layer->draw(clip);
}
}
}
void SurfaceFlinger::debugFlashRegions()
{
const DisplayHardware& hw(graphicPlane(0).displayHardware());
const uint32_t flags = hw.getFlags();
const int32_t height = hw.getHeight();
if (mSwapRegion.isEmpty()) {
return;
}
if (!((flags & DisplayHardware::SWAP_RECTANGLE) ||
(flags & DisplayHardware::BUFFER_PRESERVED))) {
const Region repaint((flags & DisplayHardware::PARTIAL_UPDATES) ?
mDirtyRegion.bounds() : hw.bounds());
composeSurfaces(repaint);
}
glDisable(GL_TEXTURE_EXTERNAL_OES);
glDisable(GL_TEXTURE_2D);
glDisable(GL_BLEND);
glDisable(GL_SCISSOR_TEST);
static int toggle = 0;
toggle = 1 - toggle;
if (toggle) {
glColor4f(1, 0, 1, 1);
} else {
glColor4f(1, 1, 0, 1);
}
Region::const_iterator it = mDirtyRegion.begin();
Region::const_iterator const end = mDirtyRegion.end();
while (it != end) {
const Rect& r = *it++;
GLfloat vertices[][2] = {
{ r.left, height - r.top },
{ r.left, height - r.bottom },
{ r.right, height - r.bottom },
{ r.right, height - r.top }
};
glVertexPointer(2, GL_FLOAT, 0, vertices);
glDrawArrays(GL_TRIANGLE_FAN, 0, 4);
}
hw.flip(mSwapRegion);
if (mDebugRegion > 1)
usleep(mDebugRegion * 1000);
glEnable(GL_SCISSOR_TEST);
}
void SurfaceFlinger::drawWormhole() const
{
const Region region(mWormholeRegion.intersect(mDirtyRegion));
if (region.isEmpty())
return;
const DisplayHardware& hw(graphicPlane(0).displayHardware());
const int32_t width = hw.getWidth();
const int32_t height = hw.getHeight();
if (CC_LIKELY(!mDebugBackground)) {
glClearColor(0,0,0,0);
Region::const_iterator it = region.begin();
Region::const_iterator const end = region.end();
while (it != end) {
const Rect& r = *it++;
const GLint sy = height - (r.top + r.height());
glScissor(r.left, sy, r.width(), r.height());
glClear(GL_COLOR_BUFFER_BIT);
}
} else {
const GLshort vertices[][2] = { { 0, 0 }, { width, 0 },
{ width, height }, { 0, height } };
const GLshort tcoords[][2] = { { 0, 0 }, { 1, 0 }, { 1, 1 }, { 0, 1 } };
glVertexPointer(2, GL_SHORT, 0, vertices);
glTexCoordPointer(2, GL_SHORT, 0, tcoords);
glEnableClientState(GL_TEXTURE_COORD_ARRAY);
glDisable(GL_TEXTURE_EXTERNAL_OES);
glEnable(GL_TEXTURE_2D);
glBindTexture(GL_TEXTURE_2D, mWormholeTexName);
glTexEnvx(GL_TEXTURE_ENV, GL_TEXTURE_ENV_MODE, GL_REPLACE);
glMatrixMode(GL_TEXTURE);
glLoadIdentity();
glDisable(GL_BLEND);
glScalef(width*(1.0f/32.0f), height*(1.0f/32.0f), 1);
Region::const_iterator it = region.begin();
Region::const_iterator const end = region.end();
while (it != end) {
const Rect& r = *it++;
const GLint sy = height - (r.top + r.height());
glScissor(r.left, sy, r.width(), r.height());
glDrawArrays(GL_TRIANGLE_FAN, 0, 4);
}
glDisableClientState(GL_TEXTURE_COORD_ARRAY);
glDisable(GL_TEXTURE_2D);
glLoadIdentity();
glMatrixMode(GL_MODELVIEW);
}
}
status_t SurfaceFlinger::addLayer(const sp<LayerBase>& layer)
{
Mutex::Autolock _l(mStateLock);
addLayer_l(layer);
setTransactionFlags(eTransactionNeeded|eTraversalNeeded);
return NO_ERROR;
}
status_t SurfaceFlinger::addLayer_l(const sp<LayerBase>& layer)
{
ssize_t i = mCurrentState.layersSortedByZ.add(layer);
return (i < 0) ? status_t(i) : status_t(NO_ERROR);
}
ssize_t SurfaceFlinger::addClientLayer(const sp<Client>& client,
const sp<LayerBaseClient>& lbc)
{
// attach this layer to the client
size_t name = client->attachLayer(lbc);
Mutex::Autolock _l(mStateLock);
// add this layer to the current state list
addLayer_l(lbc);
return ssize_t(name);
}
status_t SurfaceFlinger::removeLayer(const sp<LayerBase>& layer)
{
Mutex::Autolock _l(mStateLock);
status_t err = purgatorizeLayer_l(layer);
if (err == NO_ERROR)
setTransactionFlags(eTransactionNeeded);
return err;
}
status_t SurfaceFlinger::removeLayer_l(const sp<LayerBase>& layerBase)
{
sp<LayerBaseClient> lbc(layerBase->getLayerBaseClient());
if (lbc != 0) {
mLayerMap.removeItem( lbc->getSurfaceBinder() );
}
ssize_t index = mCurrentState.layersSortedByZ.remove(layerBase);
if (index >= 0) {
mLayersRemoved = true;
return NO_ERROR;
}
return status_t(index);
}
status_t SurfaceFlinger::purgatorizeLayer_l(const sp<LayerBase>& layerBase)
{
// First add the layer to the purgatory list, which makes sure it won't
// go away, then remove it from the main list (through a transaction).
ssize_t err = removeLayer_l(layerBase);
if (err >= 0) {
mLayerPurgatory.add(layerBase);
}
mLayersPendingRemoval.push(layerBase);
// it's possible that we don't find a layer, because it might
// have been destroyed already -- this is not technically an error
// from the user because there is a race between Client::destroySurface(),
// ~Client() and ~ISurface().
return (err == NAME_NOT_FOUND) ? status_t(NO_ERROR) : err;
}
status_t SurfaceFlinger::invalidateLayerVisibility(const sp<LayerBase>& layer)
{
layer->forceVisibilityTransaction();
setTransactionFlags(eTraversalNeeded);
return NO_ERROR;
}
uint32_t SurfaceFlinger::peekTransactionFlags(uint32_t flags)
{
return android_atomic_release_load(&mTransactionFlags);
}
uint32_t SurfaceFlinger::getTransactionFlags(uint32_t flags)
{
return android_atomic_and(~flags, &mTransactionFlags) & flags;
}
uint32_t SurfaceFlinger::setTransactionFlags(uint32_t flags)
{
uint32_t old = android_atomic_or(flags, &mTransactionFlags);
if ((old & flags)==0) { // wake the server up
signalEvent();
}
return old;
}
void SurfaceFlinger::setTransactionState(const Vector<ComposerState>& state,
int orientation, uint32_t flags) {
Mutex::Autolock _l(mStateLock);
uint32_t transactionFlags = 0;
if (mCurrentState.orientation != orientation) {
if (uint32_t(orientation)<=eOrientation270 || orientation==42) {
mCurrentState.orientation = orientation;
transactionFlags |= eTransactionNeeded;
} else if (orientation != eOrientationUnchanged) {
ALOGW("setTransactionState: ignoring unrecognized orientation: %d",
orientation);
}
}
const size_t count = state.size();
for (size_t i=0 ; i<count ; i++) {
const ComposerState& s(state[i]);
sp<Client> client( static_cast<Client *>(s.client.get()) );
transactionFlags |= setClientStateLocked(client, s.state);
}
if (transactionFlags) {
// this triggers the transaction
setTransactionFlags(transactionFlags);
// if this is a synchronous transaction, wait for it to take effect
// before returning.
if (flags & eSynchronous) {
mTransationPending = true;
}
while (mTransationPending) {
status_t err = mTransactionCV.waitRelative(mStateLock, s2ns(5));
if (CC_UNLIKELY(err != NO_ERROR)) {
// just in case something goes wrong in SF, return to the
// called after a few seconds.
ALOGW_IF(err == TIMED_OUT, "closeGlobalTransaction timed out!");
mTransationPending = false;
break;
}
}
}
}
int SurfaceFlinger::setOrientation(DisplayID dpy,
int orientation, uint32_t flags)
{
if (CC_UNLIKELY(uint32_t(dpy) >= DISPLAY_COUNT))
return BAD_VALUE;
Mutex::Autolock _l(mStateLock);
if (mCurrentState.orientation != orientation) {
if (uint32_t(orientation)<=eOrientation270 || orientation==42) {
Handle orientation changes more systematically. Bug: 4981385 Simplify the orientation changing code path in the WindowManager. Instead of the policy calling setRotation() when the sensor determined orientation changes, it calls updateRotation(), which figures everything out. For the most part, the rotation actually passed to setRotation() was more or less ignored and just added confusion, particularly when handling deferred orientation changes. Ensure that 180 degree rotations are disallowed even when the application specifies SCREEN_ORIENTATION_SENSOR_*. These rotations are only enabled when docked upside-down for some reason or when the application specifies SCREEN_ORIENTATION_FULL_SENSOR. Ensure that special modes like HDMI connected, lid switch, dock and rotation lock all cause the sensor to be ignored even when the application asks for sensor-based orientation changes. The sensor is not relevant in these modes because some external factor (or the user) is determining the preferred rotation. Currently, applications can still override the preferred rotation even when there are special modes in play that might say otherwise. We could tweak this so that some special modes trump application choices completely (resulting in a letter-boxed application, perhaps). I tested this sort of tweak (not included in the patch) and it seems to work fine, including transitions between applications with varying orientation. Delete dead code related to animFlags. Handle pausing/resuming orientation changes more precisely. Ensure that a deferred orientation change is performed when a drag completes, even if endDragLw() is not called because the drag was aborted before the drop happened. We pause the orientation change in register() and resume in unregister() because those methods appear to always be called as needed. Change-Id: If0a31de3d057251e581fdee64819f2b19e676e9a
2011-09-20 22:08:29 +00:00
mCurrentState.orientationFlags = flags;
mCurrentState.orientation = orientation;
setTransactionFlags(eTransactionNeeded);
mTransactionCV.wait(mStateLock);
} else {
orientation = BAD_VALUE;
}
}
return orientation;
}
sp<ISurface> SurfaceFlinger::createSurface(
ISurfaceComposerClient::surface_data_t* params,
const String8& name,
const sp<Client>& client,
DisplayID d, uint32_t w, uint32_t h, PixelFormat format,
uint32_t flags)
{
sp<LayerBaseClient> layer;
sp<ISurface> surfaceHandle;
if (int32_t(w|h) < 0) {
ALOGE("createSurface() failed, w or h is negative (w=%d, h=%d)",
int(w), int(h));
return surfaceHandle;
}
//ALOGD("createSurface for pid %d (%d x %d)", pid, w, h);
sp<Layer> normalLayer;
switch (flags & eFXSurfaceMask) {
case eFXSurfaceNormal:
normalLayer = createNormalSurface(client, d, w, h, flags, format);
layer = normalLayer;
break;
case eFXSurfaceBlur:
// for now we treat Blur as Dim, until we can implement it
// efficiently.
case eFXSurfaceDim:
layer = createDimSurface(client, d, w, h, flags);
break;
case eFXSurfaceScreenshot:
layer = createScreenshotSurface(client, d, w, h, flags);
break;
}
if (layer != 0) {
layer->initStates(w, h, flags);
layer->setName(name);
ssize_t token = addClientLayer(client, layer);
surfaceHandle = layer->getSurface();
if (surfaceHandle != 0) {
params->token = token;
params->identity = layer->getIdentity();
if (normalLayer != 0) {
Mutex::Autolock _l(mStateLock);
mLayerMap.add(layer->getSurfaceBinder(), normalLayer);
}
}
setTransactionFlags(eTransactionNeeded);
}
return surfaceHandle;
}
sp<Layer> SurfaceFlinger::createNormalSurface(
const sp<Client>& client, DisplayID display,
uint32_t w, uint32_t h, uint32_t flags,
PixelFormat& format)
{
// initialize the surfaces
switch (format) { // TODO: take h/w into account
case PIXEL_FORMAT_TRANSPARENT:
case PIXEL_FORMAT_TRANSLUCENT:
format = PIXEL_FORMAT_RGBA_8888;
break;
case PIXEL_FORMAT_OPAQUE:
#ifdef NO_RGBX_8888
format = PIXEL_FORMAT_RGB_565;
#else
format = PIXEL_FORMAT_RGBX_8888;
#endif
break;
}
#ifdef NO_RGBX_8888
if (format == PIXEL_FORMAT_RGBX_8888)
format = PIXEL_FORMAT_RGBA_8888;
#endif
sp<Layer> layer = new Layer(this, display, client);
status_t err = layer->setBuffers(w, h, format, flags);
if (CC_LIKELY(err != NO_ERROR)) {
ALOGE("createNormalSurfaceLocked() failed (%s)", strerror(-err));
layer.clear();
}
return layer;
}
sp<LayerDim> SurfaceFlinger::createDimSurface(
const sp<Client>& client, DisplayID display,
uint32_t w, uint32_t h, uint32_t flags)
{
sp<LayerDim> layer = new LayerDim(this, display, client);
return layer;
}
sp<LayerScreenshot> SurfaceFlinger::createScreenshotSurface(
const sp<Client>& client, DisplayID display,
uint32_t w, uint32_t h, uint32_t flags)
{
sp<LayerScreenshot> layer = new LayerScreenshot(this, display, client);
return layer;
}
status_t SurfaceFlinger::removeSurface(const sp<Client>& client, SurfaceID sid)
{
/*
* called by the window manager, when a surface should be marked for
* destruction.
*
* The surface is removed from the current and drawing lists, but placed
* in the purgatory queue, so it's not destroyed right-away (we need
* to wait for all client's references to go away first).
*/
status_t err = NAME_NOT_FOUND;
Mutex::Autolock _l(mStateLock);
sp<LayerBaseClient> layer = client->getLayerUser(sid);
if (layer != 0) {
err = purgatorizeLayer_l(layer);
if (err == NO_ERROR) {
setTransactionFlags(eTransactionNeeded);
}
}
return err;
}
status_t SurfaceFlinger::destroySurface(const wp<LayerBaseClient>& layer)
{
// called by ~ISurface() when all references are gone
status_t err = NO_ERROR;
sp<LayerBaseClient> l(layer.promote());
if (l != NULL) {
Mutex::Autolock _l(mStateLock);
err = removeLayer_l(l);
if (err == NAME_NOT_FOUND) {
// The surface wasn't in the current list, which means it was
// removed already, which means it is in the purgatory,
// and need to be removed from there.
ssize_t idx = mLayerPurgatory.remove(l);
ALOGE_IF(idx < 0,
"layer=%p is not in the purgatory list", l.get());
}
ALOGE_IF(err<0 && err != NAME_NOT_FOUND,
"error removing layer=%p (%s)", l.get(), strerror(-err));
}
return err;
}
uint32_t SurfaceFlinger::setClientStateLocked(
const sp<Client>& client,
const layer_state_t& s)
{
uint32_t flags = 0;
sp<LayerBaseClient> layer(client->getLayerUser(s.surface));
if (layer != 0) {
const uint32_t what = s.what;
if (what & ePositionChanged) {
if (layer->setPosition(s.x, s.y))
flags |= eTraversalNeeded;
}
if (what & eLayerChanged) {
ssize_t idx = mCurrentState.layersSortedByZ.indexOf(layer);
if (layer->setLayer(s.z)) {
mCurrentState.layersSortedByZ.removeAt(idx);
mCurrentState.layersSortedByZ.add(layer);
// we need traversal (state changed)
// AND transaction (list changed)
flags |= eTransactionNeeded|eTraversalNeeded;
}
}
if (what & eSizeChanged) {
if (layer->setSize(s.w, s.h)) {
flags |= eTraversalNeeded;
}
}
if (what & eAlphaChanged) {
if (layer->setAlpha(uint8_t(255.0f*s.alpha+0.5f)))
flags |= eTraversalNeeded;
}
if (what & eMatrixChanged) {
if (layer->setMatrix(s.matrix))
flags |= eTraversalNeeded;
}
if (what & eTransparentRegionChanged) {
if (layer->setTransparentRegionHint(s.transparentRegion))
flags |= eTraversalNeeded;
}
if (what & eVisibilityChanged) {
if (layer->setFlags(s.flags, s.mask))
flags |= eTraversalNeeded;
}
}
return flags;
}
void SurfaceFlinger::screenReleased(int dpy)
{
// this may be called by a signal handler, we can't do too much in here
android_atomic_or(eConsoleReleased, &mConsoleSignals);
signalEvent();
}
void SurfaceFlinger::screenAcquired(int dpy)
{
// this may be called by a signal handler, we can't do too much in here
android_atomic_or(eConsoleAcquired, &mConsoleSignals);
signalEvent();
}
status_t SurfaceFlinger::dump(int fd, const Vector<String16>& args)
{
const size_t SIZE = 4096;
char buffer[SIZE];
String8 result;
if (!PermissionCache::checkCallingPermission(sDump)) {
snprintf(buffer, SIZE, "Permission Denial: "
"can't dump SurfaceFlinger from pid=%d, uid=%d\n",
IPCThreadState::self()->getCallingPid(),
IPCThreadState::self()->getCallingUid());
result.append(buffer);
} else {
// figure out if we're stuck somewhere
const nsecs_t now = systemTime();
const nsecs_t inSwapBuffers(mDebugInSwapBuffers);
const nsecs_t inTransaction(mDebugInTransaction);
nsecs_t inSwapBuffersDuration = (inSwapBuffers) ? now-inSwapBuffers : 0;
nsecs_t inTransactionDuration = (inTransaction) ? now-inTransaction : 0;
// Try to get the main lock, but don't insist if we can't
// (this would indicate SF is stuck, but we want to be able to
// print something in dumpsys).
int retry = 3;
while (mStateLock.tryLock()<0 && --retry>=0) {
usleep(1000000);
}
const bool locked(retry >= 0);
if (!locked) {
snprintf(buffer, SIZE,
"SurfaceFlinger appears to be unresponsive, "
"dumping anyways (no locks held)\n");
result.append(buffer);
}
/*
* Dump the visible layer list
*/
const LayerVector& currentLayers = mCurrentState.layersSortedByZ;
const size_t count = currentLayers.size();
snprintf(buffer, SIZE, "Visible layers (count = %d)\n", count);
result.append(buffer);
for (size_t i=0 ; i<count ; i++) {
const sp<LayerBase>& layer(currentLayers[i]);
layer->dump(result, buffer, SIZE);
const Layer::State& s(layer->drawingState());
s.transparentRegion.dump(result, "transparentRegion");
layer->transparentRegionScreen.dump(result, "transparentRegionScreen");
layer->visibleRegionScreen.dump(result, "visibleRegionScreen");
}
/*
* Dump the layers in the purgatory
*/
const size_t purgatorySize = mLayerPurgatory.size();
snprintf(buffer, SIZE, "Purgatory state (%d entries)\n", purgatorySize);
result.append(buffer);
for (size_t i=0 ; i<purgatorySize ; i++) {
const sp<LayerBase>& layer(mLayerPurgatory.itemAt(i));
layer->shortDump(result, buffer, SIZE);
}
/*
* Dump SurfaceFlinger global state
*/
snprintf(buffer, SIZE, "SurfaceFlinger global state:\n");
result.append(buffer);
const GLExtensions& extensions(GLExtensions::getInstance());
snprintf(buffer, SIZE, "GLES: %s, %s, %s\n",
extensions.getVendor(),
extensions.getRenderer(),
extensions.getVersion());
result.append(buffer);
snprintf(buffer, SIZE, "EGL : %s\n",
eglQueryString(graphicPlane(0).getEGLDisplay(),
EGL_VERSION_HW_ANDROID));
result.append(buffer);
snprintf(buffer, SIZE, "EXTS: %s\n", extensions.getExtension());
result.append(buffer);
mWormholeRegion.dump(result, "WormholeRegion");
const DisplayHardware& hw(graphicPlane(0).displayHardware());
snprintf(buffer, SIZE,
" orientation=%d, canDraw=%d\n",
mCurrentState.orientation, hw.canDraw());
result.append(buffer);
snprintf(buffer, SIZE,
" last eglSwapBuffers() time: %f us\n"
" last transaction time : %f us\n"
" refresh-rate : %f fps\n"
" x-dpi : %f\n"
" y-dpi : %f\n",
mLastSwapBufferTime/1000.0,
mLastTransactionTime/1000.0,
hw.getRefreshRate(),
hw.getDpiX(),
hw.getDpiY());
result.append(buffer);
if (inSwapBuffersDuration || !locked) {
snprintf(buffer, SIZE, " eglSwapBuffers time: %f us\n",
inSwapBuffersDuration/1000.0);
result.append(buffer);
}
if (inTransactionDuration || !locked) {
snprintf(buffer, SIZE, " transaction time: %f us\n",
inTransactionDuration/1000.0);
result.append(buffer);
}
/*
* VSYNC state
*/
mEventThread->dump(result, buffer, SIZE);
/*
* Dump HWComposer state
*/
HWComposer& hwc(hw.getHwComposer());
snprintf(buffer, SIZE, "h/w composer state:\n");
result.append(buffer);
snprintf(buffer, SIZE, " h/w composer %s and %s\n",
hwc.initCheck()==NO_ERROR ? "present" : "not present",
(mDebugDisableHWC || mDebugRegion) ? "disabled" : "enabled");
result.append(buffer);
hwc.dump(result, buffer, SIZE, mVisibleLayersSortedByZ);
/*
* Dump gralloc state
*/
const GraphicBufferAllocator& alloc(GraphicBufferAllocator::get());
alloc.dump(result);
hw.dump(result);
if (locked) {
mStateLock.unlock();
}
}
write(fd, result.string(), result.size());
return NO_ERROR;
}
status_t SurfaceFlinger::onTransact(
uint32_t code, const Parcel& data, Parcel* reply, uint32_t flags)
{
switch (code) {
case CREATE_CONNECTION:
case SET_TRANSACTION_STATE:
case SET_ORIENTATION:
case BOOT_FINISHED:
case TURN_ELECTRON_BEAM_OFF:
case TURN_ELECTRON_BEAM_ON:
{
// codes that require permission check
IPCThreadState* ipc = IPCThreadState::self();
const int pid = ipc->getCallingPid();
const int uid = ipc->getCallingUid();
if ((uid != AID_GRAPHICS) &&
!PermissionCache::checkPermission(sAccessSurfaceFlinger, pid, uid)) {
ALOGE("Permission Denial: "
"can't access SurfaceFlinger pid=%d, uid=%d", pid, uid);
return PERMISSION_DENIED;
}
break;
}
case CAPTURE_SCREEN:
{
// codes that require permission check
IPCThreadState* ipc = IPCThreadState::self();
const int pid = ipc->getCallingPid();
const int uid = ipc->getCallingUid();
if ((uid != AID_GRAPHICS) &&
!PermissionCache::checkPermission(sReadFramebuffer, pid, uid)) {
ALOGE("Permission Denial: "
"can't read framebuffer pid=%d, uid=%d", pid, uid);
return PERMISSION_DENIED;
}
break;
}
}
status_t err = BnSurfaceComposer::onTransact(code, data, reply, flags);
if (err == UNKNOWN_TRANSACTION || err == PERMISSION_DENIED) {
CHECK_INTERFACE(ISurfaceComposer, data, reply);
if (CC_UNLIKELY(!PermissionCache::checkCallingPermission(sHardwareTest))) {
IPCThreadState* ipc = IPCThreadState::self();
const int pid = ipc->getCallingPid();
const int uid = ipc->getCallingUid();
ALOGE("Permission Denial: "
"can't access SurfaceFlinger pid=%d, uid=%d", pid, uid);
return PERMISSION_DENIED;
}
int n;
switch (code) {
case 1000: // SHOW_CPU, NOT SUPPORTED ANYMORE
case 1001: // SHOW_FPS, NOT SUPPORTED ANYMORE
return NO_ERROR;
case 1002: // SHOW_UPDATES
n = data.readInt32();
mDebugRegion = n ? n : (mDebugRegion ? 0 : 1);
invalidateHwcGeometry();
repaintEverything();
return NO_ERROR;
case 1003: // SHOW_BACKGROUND
n = data.readInt32();
mDebugBackground = n ? 1 : 0;
return NO_ERROR;
case 1004:{ // repaint everything
repaintEverything();
return NO_ERROR;
}
case 1005:{ // force transaction
setTransactionFlags(eTransactionNeeded|eTraversalNeeded);
return NO_ERROR;
}
case 1008: // toggle use of hw composer
n = data.readInt32();
mDebugDisableHWC = n ? 1 : 0;
invalidateHwcGeometry();
repaintEverything();
return NO_ERROR;
case 1009: // toggle use of transform hint
n = data.readInt32();
mDebugDisableTransformHint = n ? 1 : 0;
invalidateHwcGeometry();
repaintEverything();
return NO_ERROR;
case 1010: // interrogate.
reply->writeInt32(0);
reply->writeInt32(0);
reply->writeInt32(mDebugRegion);
reply->writeInt32(mDebugBackground);
return NO_ERROR;
case 1013: {
Mutex::Autolock _l(mStateLock);
const DisplayHardware& hw(graphicPlane(0).displayHardware());
reply->writeInt32(hw.getPageFlipCount());
}
return NO_ERROR;
}
}
return err;
}
void SurfaceFlinger::repaintEverything() {
const DisplayHardware& hw(graphicPlane(0).displayHardware());
const Rect bounds(hw.getBounds());
setInvalidateRegion(Region(bounds));
signalEvent();
}
void SurfaceFlinger::setInvalidateRegion(const Region& reg) {
Mutex::Autolock _l(mInvalidateLock);
mInvalidateRegion = reg;
}
Region SurfaceFlinger::getAndClearInvalidateRegion() {
Mutex::Autolock _l(mInvalidateLock);
Region reg(mInvalidateRegion);
mInvalidateRegion.clear();
return reg;
}
// ---------------------------------------------------------------------------
status_t SurfaceFlinger::renderScreenToTexture(DisplayID dpy,
GLuint* textureName, GLfloat* uOut, GLfloat* vOut)
{
Mutex::Autolock _l(mStateLock);
return renderScreenToTextureLocked(dpy, textureName, uOut, vOut);
}
status_t SurfaceFlinger::renderScreenToTextureLocked(DisplayID dpy,
GLuint* textureName, GLfloat* uOut, GLfloat* vOut)
{
if (!GLExtensions::getInstance().haveFramebufferObject())
return INVALID_OPERATION;
// get screen geometry
const DisplayHardware& hw(graphicPlane(dpy).displayHardware());
const uint32_t hw_w = hw.getWidth();
const uint32_t hw_h = hw.getHeight();
GLfloat u = 1;
GLfloat v = 1;
// make sure to clear all GL error flags
while ( glGetError() != GL_NO_ERROR ) ;
// create a FBO
GLuint name, tname;
glGenTextures(1, &tname);
glBindTexture(GL_TEXTURE_2D, tname);
glTexImage2D(GL_TEXTURE_2D, 0, GL_RGB,
hw_w, hw_h, 0, GL_RGB, GL_UNSIGNED_BYTE, 0);
if (glGetError() != GL_NO_ERROR) {
while ( glGetError() != GL_NO_ERROR ) ;
GLint tw = (2 << (31 - clz(hw_w)));
GLint th = (2 << (31 - clz(hw_h)));
glTexImage2D(GL_TEXTURE_2D, 0, GL_RGB,
tw, th, 0, GL_RGB, GL_UNSIGNED_BYTE, 0);
u = GLfloat(hw_w) / tw;
v = GLfloat(hw_h) / th;
}
glGenFramebuffersOES(1, &name);
glBindFramebufferOES(GL_FRAMEBUFFER_OES, name);
glFramebufferTexture2DOES(GL_FRAMEBUFFER_OES,
GL_COLOR_ATTACHMENT0_OES, GL_TEXTURE_2D, tname, 0);
// redraw the screen entirely...
glDisable(GL_TEXTURE_EXTERNAL_OES);
glDisable(GL_TEXTURE_2D);
glDisable(GL_SCISSOR_TEST);
glClearColor(0,0,0,1);
glClear(GL_COLOR_BUFFER_BIT);
glEnable(GL_SCISSOR_TEST);
glMatrixMode(GL_MODELVIEW);
glLoadIdentity();
const Vector< sp<LayerBase> >& layers(mVisibleLayersSortedByZ);
const size_t count = layers.size();
for (size_t i=0 ; i<count ; ++i) {
const sp<LayerBase>& layer(layers[i]);
layer->drawForSreenShot();
}
hw.compositionComplete();
// back to main framebuffer
glBindFramebufferOES(GL_FRAMEBUFFER_OES, 0);
glDisable(GL_SCISSOR_TEST);
glDeleteFramebuffersOES(1, &name);
*textureName = tname;
*uOut = u;
*vOut = v;
return NO_ERROR;
}
// ---------------------------------------------------------------------------
status_t SurfaceFlinger::electronBeamOffAnimationImplLocked()
{
// get screen geometry
const DisplayHardware& hw(graphicPlane(0).displayHardware());
const uint32_t hw_w = hw.getWidth();
const uint32_t hw_h = hw.getHeight();
const Region screenBounds(hw.getBounds());
GLfloat u, v;
GLuint tname;
status_t result = renderScreenToTextureLocked(0, &tname, &u, &v);
if (result != NO_ERROR) {
return result;
}
GLfloat vtx[8];
const GLfloat texCoords[4][2] = { {0,0}, {0,v}, {u,v}, {u,0} };
glBindTexture(GL_TEXTURE_2D, tname);
glTexEnvx(GL_TEXTURE_ENV, GL_TEXTURE_ENV_MODE, GL_REPLACE);
glTexParameterx(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_LINEAR);
glTexParameterx(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR);
glTexCoordPointer(2, GL_FLOAT, 0, texCoords);
glEnableClientState(GL_TEXTURE_COORD_ARRAY);
glVertexPointer(2, GL_FLOAT, 0, vtx);
/*
* Texture coordinate mapping
*
* u
* 1 +----------+---+
* | | | | image is inverted
* | V | | w.r.t. the texture
* 1-v +----------+ | coordinates
* | |
* | |
* | |
* 0 +--------------+
* 0 1
*
*/
class s_curve_interpolator {
const float nbFrames, s, v;
public:
s_curve_interpolator(int nbFrames, float s)
: nbFrames(1.0f / (nbFrames-1)), s(s),
v(1.0f + expf(-s + 0.5f*s)) {
}
float operator()(int f) {
const float x = f * nbFrames;
return ((1.0f/(1.0f + expf(-x*s + 0.5f*s))) - 0.5f) * v + 0.5f;
}
};
class v_stretch {
const GLfloat hw_w, hw_h;
public:
v_stretch(uint32_t hw_w, uint32_t hw_h)
: hw_w(hw_w), hw_h(hw_h) {
}
void operator()(GLfloat* vtx, float v) {
const GLfloat w = hw_w + (hw_w * v);
const GLfloat h = hw_h - (hw_h * v);
const GLfloat x = (hw_w - w) * 0.5f;
const GLfloat y = (hw_h - h) * 0.5f;
vtx[0] = x; vtx[1] = y;
vtx[2] = x; vtx[3] = y + h;
vtx[4] = x + w; vtx[5] = y + h;
vtx[6] = x + w; vtx[7] = y;
}
};
class h_stretch {
const GLfloat hw_w, hw_h;
public:
h_stretch(uint32_t hw_w, uint32_t hw_h)
: hw_w(hw_w), hw_h(hw_h) {
}
void operator()(GLfloat* vtx, float v) {
const GLfloat w = hw_w - (hw_w * v);
const GLfloat h = 1.0f;
const GLfloat x = (hw_w - w) * 0.5f;
const GLfloat y = (hw_h - h) * 0.5f;
vtx[0] = x; vtx[1] = y;
vtx[2] = x; vtx[3] = y + h;
vtx[4] = x + w; vtx[5] = y + h;
vtx[6] = x + w; vtx[7] = y;
}
};
// the full animation is 24 frames
char value[PROPERTY_VALUE_MAX];
property_get("debug.sf.electron_frames", value, "24");
int nbFrames = (atoi(value) + 1) >> 1;
if (nbFrames <= 0) // just in case
nbFrames = 24;
s_curve_interpolator itr(nbFrames, 7.5f);
s_curve_interpolator itg(nbFrames, 8.0f);
s_curve_interpolator itb(nbFrames, 8.5f);
v_stretch vverts(hw_w, hw_h);
glMatrixMode(GL_TEXTURE);
glLoadIdentity();
glMatrixMode(GL_MODELVIEW);
glLoadIdentity();
glEnable(GL_BLEND);
glBlendFunc(GL_ONE, GL_ONE);
for (int i=0 ; i<nbFrames ; i++) {
float x, y, w, h;
const float vr = itr(i);
const float vg = itg(i);
const float vb = itb(i);
// clear screen
glColorMask(1,1,1,1);
glClear(GL_COLOR_BUFFER_BIT);
glEnable(GL_TEXTURE_2D);
// draw the red plane
vverts(vtx, vr);
glColorMask(1,0,0,1);
glDrawArrays(GL_TRIANGLE_FAN, 0, 4);
// draw the green plane
vverts(vtx, vg);
glColorMask(0,1,0,1);
glDrawArrays(GL_TRIANGLE_FAN, 0, 4);
// draw the blue plane
vverts(vtx, vb);
glColorMask(0,0,1,1);
glDrawArrays(GL_TRIANGLE_FAN, 0, 4);
// draw the white highlight (we use the last vertices)
glDisable(GL_TEXTURE_2D);
glColorMask(1,1,1,1);
glColor4f(vg, vg, vg, 1);
glDrawArrays(GL_TRIANGLE_FAN, 0, 4);
hw.flip(screenBounds);
}
h_stretch hverts(hw_w, hw_h);
glDisable(GL_BLEND);
glDisable(GL_TEXTURE_2D);
glColorMask(1,1,1,1);
for (int i=0 ; i<nbFrames ; i++) {
const float v = itg(i);
hverts(vtx, v);
glClear(GL_COLOR_BUFFER_BIT);
glColor4f(1-v, 1-v, 1-v, 1);
glDrawArrays(GL_TRIANGLE_FAN, 0, 4);
hw.flip(screenBounds);
}
glColorMask(1,1,1,1);
glEnable(GL_SCISSOR_TEST);
glDisableClientState(GL_TEXTURE_COORD_ARRAY);
glDeleteTextures(1, &tname);
glDisable(GL_TEXTURE_2D);
glDisable(GL_BLEND);
return NO_ERROR;
}
status_t SurfaceFlinger::electronBeamOnAnimationImplLocked()
{
status_t result = PERMISSION_DENIED;
if (!GLExtensions::getInstance().haveFramebufferObject())
return INVALID_OPERATION;
// get screen geometry
const DisplayHardware& hw(graphicPlane(0).displayHardware());
const uint32_t hw_w = hw.getWidth();
const uint32_t hw_h = hw.getHeight();
const Region screenBounds(hw.bounds());
GLfloat u, v;
GLuint tname;
result = renderScreenToTextureLocked(0, &tname, &u, &v);
if (result != NO_ERROR) {
return result;
}
GLfloat vtx[8];
const GLfloat texCoords[4][2] = { {0,v}, {0,0}, {u,0}, {u,v} };
glBindTexture(GL_TEXTURE_2D, tname);
glTexEnvx(GL_TEXTURE_ENV, GL_TEXTURE_ENV_MODE, GL_MODULATE);
glTexParameterx(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_LINEAR);
glTexParameterx(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR);
glTexCoordPointer(2, GL_FLOAT, 0, texCoords);
glEnableClientState(GL_TEXTURE_COORD_ARRAY);
glVertexPointer(2, GL_FLOAT, 0, vtx);
class s_curve_interpolator {
const float nbFrames, s, v;
public:
s_curve_interpolator(int nbFrames, float s)
: nbFrames(1.0f / (nbFrames-1)), s(s),
v(1.0f + expf(-s + 0.5f*s)) {
}
float operator()(int f) {
const float x = f * nbFrames;
return ((1.0f/(1.0f + expf(-x*s + 0.5f*s))) - 0.5f) * v + 0.5f;
}
};
class v_stretch {
const GLfloat hw_w, hw_h;
public:
v_stretch(uint32_t hw_w, uint32_t hw_h)
: hw_w(hw_w), hw_h(hw_h) {
}
void operator()(GLfloat* vtx, float v) {
const GLfloat w = hw_w + (hw_w * v);
const GLfloat h = hw_h - (hw_h * v);
const GLfloat x = (hw_w - w) * 0.5f;
const GLfloat y = (hw_h - h) * 0.5f;
vtx[0] = x; vtx[1] = y;
vtx[2] = x; vtx[3] = y + h;
vtx[4] = x + w; vtx[5] = y + h;
vtx[6] = x + w; vtx[7] = y;
}
};
class h_stretch {
const GLfloat hw_w, hw_h;
public:
h_stretch(uint32_t hw_w, uint32_t hw_h)
: hw_w(hw_w), hw_h(hw_h) {
}
void operator()(GLfloat* vtx, float v) {
const GLfloat w = hw_w - (hw_w * v);
const GLfloat h = 1.0f;
const GLfloat x = (hw_w - w) * 0.5f;
const GLfloat y = (hw_h - h) * 0.5f;
vtx[0] = x; vtx[1] = y;
vtx[2] = x; vtx[3] = y + h;
vtx[4] = x + w; vtx[5] = y + h;
vtx[6] = x + w; vtx[7] = y;
}
};
// the full animation is 12 frames
int nbFrames = 8;
s_curve_interpolator itr(nbFrames, 7.5f);
s_curve_interpolator itg(nbFrames, 8.0f);
s_curve_interpolator itb(nbFrames, 8.5f);
h_stretch hverts(hw_w, hw_h);
glDisable(GL_BLEND);
glDisable(GL_TEXTURE_2D);
glColorMask(1,1,1,1);
for (int i=nbFrames-1 ; i>=0 ; i--) {
const float v = itg(i);
hverts(vtx, v);
glClear(GL_COLOR_BUFFER_BIT);
glColor4f(1-v, 1-v, 1-v, 1);
glDrawArrays(GL_TRIANGLE_FAN, 0, 4);
hw.flip(screenBounds);
}
nbFrames = 4;
v_stretch vverts(hw_w, hw_h);
glEnable(GL_BLEND);
glBlendFunc(GL_ONE, GL_ONE);
for (int i=nbFrames-1 ; i>=0 ; i--) {
float x, y, w, h;
const float vr = itr(i);
const float vg = itg(i);
const float vb = itb(i);
// clear screen
glColorMask(1,1,1,1);
glClear(GL_COLOR_BUFFER_BIT);
glEnable(GL_TEXTURE_2D);
// draw the red plane
vverts(vtx, vr);
glColorMask(1,0,0,1);
glDrawArrays(GL_TRIANGLE_FAN, 0, 4);
// draw the green plane
vverts(vtx, vg);
glColorMask(0,1,0,1);
glDrawArrays(GL_TRIANGLE_FAN, 0, 4);
// draw the blue plane
vverts(vtx, vb);
glColorMask(0,0,1,1);
glDrawArrays(GL_TRIANGLE_FAN, 0, 4);
hw.flip(screenBounds);
}
glColorMask(1,1,1,1);
glEnable(GL_SCISSOR_TEST);
glDisableClientState(GL_TEXTURE_COORD_ARRAY);
glDeleteTextures(1, &tname);
glDisable(GL_TEXTURE_2D);
glDisable(GL_BLEND);
return NO_ERROR;
}
// ---------------------------------------------------------------------------
status_t SurfaceFlinger::turnElectronBeamOffImplLocked(int32_t mode)
{
DisplayHardware& hw(graphicPlane(0).editDisplayHardware());
if (!hw.canDraw()) {
// we're already off
return NO_ERROR;
}
// turn off hwc while we're doing the animation
hw.getHwComposer().disable();
// and make sure to turn it back on (if needed) next time we compose
invalidateHwcGeometry();
if (mode & ISurfaceComposer::eElectronBeamAnimationOff) {
electronBeamOffAnimationImplLocked();
}
// always clear the whole screen at the end of the animation
glClearColor(0,0,0,1);
glDisable(GL_SCISSOR_TEST);
glClear(GL_COLOR_BUFFER_BIT);
glEnable(GL_SCISSOR_TEST);
hw.flip( Region(hw.bounds()) );
return NO_ERROR;
}
status_t SurfaceFlinger::turnElectronBeamOff(int32_t mode)
{
class MessageTurnElectronBeamOff : public MessageBase {
SurfaceFlinger* flinger;
int32_t mode;
status_t result;
public:
MessageTurnElectronBeamOff(SurfaceFlinger* flinger, int32_t mode)
: flinger(flinger), mode(mode), result(PERMISSION_DENIED) {
}
status_t getResult() const {
return result;
}
virtual bool handler() {
Mutex::Autolock _l(flinger->mStateLock);
result = flinger->turnElectronBeamOffImplLocked(mode);
return true;
}
};
sp<MessageBase> msg = new MessageTurnElectronBeamOff(this, mode);
status_t res = postMessageSync(msg);
if (res == NO_ERROR) {
res = static_cast<MessageTurnElectronBeamOff*>( msg.get() )->getResult();
// work-around: when the power-manager calls us we activate the
// animation. eventually, the "on" animation will be called
// by the power-manager itself
mElectronBeamAnimationMode = mode;
}
return res;
}
// ---------------------------------------------------------------------------
status_t SurfaceFlinger::turnElectronBeamOnImplLocked(int32_t mode)
{
DisplayHardware& hw(graphicPlane(0).editDisplayHardware());
if (hw.canDraw()) {
// we're already on
return NO_ERROR;
}
if (mode & ISurfaceComposer::eElectronBeamAnimationOn) {
electronBeamOnAnimationImplLocked();
}
// make sure to redraw the whole screen when the animation is done
mDirtyRegion.set(hw.bounds());
signalEvent();
return NO_ERROR;
}
status_t SurfaceFlinger::turnElectronBeamOn(int32_t mode)
{
class MessageTurnElectronBeamOn : public MessageBase {
SurfaceFlinger* flinger;
int32_t mode;
status_t result;
public:
MessageTurnElectronBeamOn(SurfaceFlinger* flinger, int32_t mode)
: flinger(flinger), mode(mode), result(PERMISSION_DENIED) {
}
status_t getResult() const {
return result;
}
virtual bool handler() {
Mutex::Autolock _l(flinger->mStateLock);
result = flinger->turnElectronBeamOnImplLocked(mode);
return true;
}
};
postMessageAsync( new MessageTurnElectronBeamOn(this, mode) );
return NO_ERROR;
}
// ---------------------------------------------------------------------------
status_t SurfaceFlinger::captureScreenImplLocked(DisplayID dpy,
sp<IMemoryHeap>* heap,
uint32_t* w, uint32_t* h, PixelFormat* f,
uint32_t sw, uint32_t sh,
uint32_t minLayerZ, uint32_t maxLayerZ)
{
status_t result = PERMISSION_DENIED;
// only one display supported for now
if (CC_UNLIKELY(uint32_t(dpy) >= DISPLAY_COUNT))
return BAD_VALUE;
if (!GLExtensions::getInstance().haveFramebufferObject())
return INVALID_OPERATION;
// get screen geometry
const DisplayHardware& hw(graphicPlane(dpy).displayHardware());
const uint32_t hw_w = hw.getWidth();
const uint32_t hw_h = hw.getHeight();
if ((sw > hw_w) || (sh > hw_h))
return BAD_VALUE;
sw = (!sw) ? hw_w : sw;
sh = (!sh) ? hw_h : sh;
const size_t size = sw * sh * 4;
//ALOGD("screenshot: sw=%d, sh=%d, minZ=%d, maxZ=%d",
// sw, sh, minLayerZ, maxLayerZ);
// make sure to clear all GL error flags
while ( glGetError() != GL_NO_ERROR ) ;
// create a FBO
GLuint name, tname;
glGenRenderbuffersOES(1, &tname);
glBindRenderbufferOES(GL_RENDERBUFFER_OES, tname);
glRenderbufferStorageOES(GL_RENDERBUFFER_OES, GL_RGBA8_OES, sw, sh);
glGenFramebuffersOES(1, &name);
glBindFramebufferOES(GL_FRAMEBUFFER_OES, name);
glFramebufferRenderbufferOES(GL_FRAMEBUFFER_OES,
GL_COLOR_ATTACHMENT0_OES, GL_RENDERBUFFER_OES, tname);
GLenum status = glCheckFramebufferStatusOES(GL_FRAMEBUFFER_OES);
if (status == GL_FRAMEBUFFER_COMPLETE_OES) {
// invert everything, b/c glReadPixel() below will invert the FB
glViewport(0, 0, sw, sh);
glScissor(0, 0, sw, sh);
glEnable(GL_SCISSOR_TEST);
glMatrixMode(GL_PROJECTION);
glPushMatrix();
glLoadIdentity();
glOrthof(0, hw_w, hw_h, 0, 0, 1);
glMatrixMode(GL_MODELVIEW);
// redraw the screen entirely...
glClearColor(0,0,0,1);
glClear(GL_COLOR_BUFFER_BIT);
const LayerVector& layers(mDrawingState.layersSortedByZ);
const size_t count = layers.size();
for (size_t i=0 ; i<count ; ++i) {
const sp<LayerBase>& layer(layers[i]);
const uint32_t flags = layer->drawingState().flags;
if (!(flags & ISurfaceComposer::eLayerHidden)) {
const uint32_t z = layer->drawingState().z;
if (z >= minLayerZ && z <= maxLayerZ) {
layer->drawForSreenShot();
}
}
}
// XXX: this is needed on tegra
glEnable(GL_SCISSOR_TEST);
glScissor(0, 0, sw, sh);
// check for errors and return screen capture
if (glGetError() != GL_NO_ERROR) {
// error while rendering
result = INVALID_OPERATION;
} else {
// allocate shared memory large enough to hold the
// screen capture
sp<MemoryHeapBase> base(
new MemoryHeapBase(size, 0, "screen-capture") );
void* const ptr = base->getBase();
if (ptr) {
// capture the screen with glReadPixels()
glReadPixels(0, 0, sw, sh, GL_RGBA, GL_UNSIGNED_BYTE, ptr);
if (glGetError() == GL_NO_ERROR) {
*heap = base;
*w = sw;
*h = sh;
*f = PIXEL_FORMAT_RGBA_8888;
result = NO_ERROR;
}
} else {
result = NO_MEMORY;
}
}
glEnable(GL_SCISSOR_TEST);
glViewport(0, 0, hw_w, hw_h);
glMatrixMode(GL_PROJECTION);
glPopMatrix();
glMatrixMode(GL_MODELVIEW);
} else {
result = BAD_VALUE;
}
// release FBO resources
glBindFramebufferOES(GL_FRAMEBUFFER_OES, 0);
glDeleteRenderbuffersOES(1, &tname);
glDeleteFramebuffersOES(1, &name);
hw.compositionComplete();
// ALOGD("screenshot: result = %s", result<0 ? strerror(result) : "OK");
return result;
}
status_t SurfaceFlinger::captureScreen(DisplayID dpy,
sp<IMemoryHeap>* heap,
uint32_t* width, uint32_t* height, PixelFormat* format,
uint32_t sw, uint32_t sh,
uint32_t minLayerZ, uint32_t maxLayerZ)
{
// only one display supported for now
if (CC_UNLIKELY(uint32_t(dpy) >= DISPLAY_COUNT))
return BAD_VALUE;
if (!GLExtensions::getInstance().haveFramebufferObject())
return INVALID_OPERATION;
class MessageCaptureScreen : public MessageBase {
SurfaceFlinger* flinger;
DisplayID dpy;
sp<IMemoryHeap>* heap;
uint32_t* w;
uint32_t* h;
PixelFormat* f;
uint32_t sw;
uint32_t sh;
uint32_t minLayerZ;
uint32_t maxLayerZ;
status_t result;
public:
MessageCaptureScreen(SurfaceFlinger* flinger, DisplayID dpy,
sp<IMemoryHeap>* heap, uint32_t* w, uint32_t* h, PixelFormat* f,
uint32_t sw, uint32_t sh,
uint32_t minLayerZ, uint32_t maxLayerZ)
: flinger(flinger), dpy(dpy),
heap(heap), w(w), h(h), f(f), sw(sw), sh(sh),
minLayerZ(minLayerZ), maxLayerZ(maxLayerZ),
result(PERMISSION_DENIED)
{
}
status_t getResult() const {
return result;
}
virtual bool handler() {
Mutex::Autolock _l(flinger->mStateLock);
// if we have secure windows, never allow the screen capture
if (flinger->mSecureFrameBuffer)
return true;
result = flinger->captureScreenImplLocked(dpy,
heap, w, h, f, sw, sh, minLayerZ, maxLayerZ);
return true;
}
};
sp<MessageBase> msg = new MessageCaptureScreen(this,
dpy, heap, width, height, format, sw, sh, minLayerZ, maxLayerZ);
status_t res = postMessageSync(msg);
if (res == NO_ERROR) {
res = static_cast<MessageCaptureScreen*>( msg.get() )->getResult();
}
return res;
}
// ---------------------------------------------------------------------------
sp<Layer> SurfaceFlinger::getLayer(const sp<ISurface>& sur) const
{
sp<Layer> result;
Mutex::Autolock _l(mStateLock);
result = mLayerMap.valueFor( sur->asBinder() ).promote();
return result;
}
// ---------------------------------------------------------------------------
Client::Client(const sp<SurfaceFlinger>& flinger)
: mFlinger(flinger), mNameGenerator(1)
{
}
Client::~Client()
{
const size_t count = mLayers.size();
for (size_t i=0 ; i<count ; i++) {
sp<LayerBaseClient> layer(mLayers.valueAt(i).promote());
if (layer != 0) {
mFlinger->removeLayer(layer);
}
}
}
status_t Client::initCheck() const {
return NO_ERROR;
}
size_t Client::attachLayer(const sp<LayerBaseClient>& layer)
{
Mutex::Autolock _l(mLock);
size_t name = mNameGenerator++;
mLayers.add(name, layer);
return name;
}
void Client::detachLayer(const LayerBaseClient* layer)
{
Mutex::Autolock _l(mLock);
// we do a linear search here, because this doesn't happen often
const size_t count = mLayers.size();
for (size_t i=0 ; i<count ; i++) {
if (mLayers.valueAt(i) == layer) {
mLayers.removeItemsAt(i, 1);
break;
}
}
}
sp<LayerBaseClient> Client::getLayerUser(int32_t i) const
{
Mutex::Autolock _l(mLock);
sp<LayerBaseClient> lbc;
wp<LayerBaseClient> layer(mLayers.valueFor(i));
if (layer != 0) {
lbc = layer.promote();
ALOGE_IF(lbc==0, "getLayerUser(name=%d) is dead", int(i));
}
return lbc;
}
status_t Client::onTransact(
uint32_t code, const Parcel& data, Parcel* reply, uint32_t flags)
{
// these must be checked
IPCThreadState* ipc = IPCThreadState::self();
const int pid = ipc->getCallingPid();
const int uid = ipc->getCallingUid();
const int self_pid = getpid();
if (CC_UNLIKELY(pid != self_pid && uid != AID_GRAPHICS && uid != 0)) {
// we're called from a different process, do the real check
if (!PermissionCache::checkCallingPermission(sAccessSurfaceFlinger))
{
ALOGE("Permission Denial: "
"can't openGlobalTransaction pid=%d, uid=%d", pid, uid);
return PERMISSION_DENIED;
}
}
return BnSurfaceComposerClient::onTransact(code, data, reply, flags);
}
sp<ISurface> Client::createSurface(
ISurfaceComposerClient::surface_data_t* params,
const String8& name,
DisplayID display, uint32_t w, uint32_t h, PixelFormat format,
uint32_t flags)
{
/*
* createSurface must be called from the GL thread so that it can
* have access to the GL context.
*/
class MessageCreateSurface : public MessageBase {
sp<ISurface> result;
SurfaceFlinger* flinger;
ISurfaceComposerClient::surface_data_t* params;
Client* client;
const String8& name;
DisplayID display;
uint32_t w, h;
PixelFormat format;
uint32_t flags;
public:
MessageCreateSurface(SurfaceFlinger* flinger,
ISurfaceComposerClient::surface_data_t* params,
const String8& name, Client* client,
DisplayID display, uint32_t w, uint32_t h, PixelFormat format,
uint32_t flags)
: flinger(flinger), params(params), client(client), name(name),
display(display), w(w), h(h), format(format), flags(flags)
{
}
sp<ISurface> getResult() const { return result; }
virtual bool handler() {
result = flinger->createSurface(params, name, client,
display, w, h, format, flags);
return true;
}
};
sp<MessageBase> msg = new MessageCreateSurface(mFlinger.get(),
params, name, this, display, w, h, format, flags);
mFlinger->postMessageSync(msg);
return static_cast<MessageCreateSurface*>( msg.get() )->getResult();
}
status_t Client::destroySurface(SurfaceID sid) {
return mFlinger->removeSurface(this, sid);
}
// ---------------------------------------------------------------------------
GraphicBufferAlloc::GraphicBufferAlloc() {}
GraphicBufferAlloc::~GraphicBufferAlloc() {}
sp<GraphicBuffer> GraphicBufferAlloc::createGraphicBuffer(uint32_t w, uint32_t h,
PixelFormat format, uint32_t usage, status_t* error) {
sp<GraphicBuffer> graphicBuffer(new GraphicBuffer(w, h, format, usage));
status_t err = graphicBuffer->initCheck();
*error = err;
if (err != 0 || graphicBuffer->handle == 0) {
if (err == NO_MEMORY) {
GraphicBuffer::dumpAllocationsToSystemLog();
}
ALOGE("GraphicBufferAlloc::createGraphicBuffer(w=%d, h=%d) "
"failed (%s), handle=%p",
w, h, strerror(-err), graphicBuffer->handle);
return 0;
}
return graphicBuffer;
}
// ---------------------------------------------------------------------------
GraphicPlane::GraphicPlane()
: mHw(0)
{
}
GraphicPlane::~GraphicPlane() {
delete mHw;
}
bool GraphicPlane::initialized() const {
return mHw ? true : false;
}
int GraphicPlane::getWidth() const {
return mWidth;
}
int GraphicPlane::getHeight() const {
return mHeight;
}
void GraphicPlane::setDisplayHardware(DisplayHardware *hw)
{
mHw = hw;
// initialize the display orientation transform.
// it's a constant that should come from the display driver.
int displayOrientation = ISurfaceComposer::eOrientationDefault;
char property[PROPERTY_VALUE_MAX];
if (property_get("ro.sf.hwrotation", property, NULL) > 0) {
//displayOrientation
switch (atoi(property)) {
case 90:
displayOrientation = ISurfaceComposer::eOrientation90;
break;
case 270:
displayOrientation = ISurfaceComposer::eOrientation270;
break;
}
}
const float w = hw->getWidth();
const float h = hw->getHeight();
GraphicPlane::orientationToTransfrom(displayOrientation, w, h,
&mDisplayTransform);
if (displayOrientation & ISurfaceComposer::eOrientationSwapMask) {
mDisplayWidth = h;
mDisplayHeight = w;
} else {
mDisplayWidth = w;
mDisplayHeight = h;
}
setOrientation(ISurfaceComposer::eOrientationDefault);
}
status_t GraphicPlane::orientationToTransfrom(
int orientation, int w, int h, Transform* tr)
{
uint32_t flags = 0;
switch (orientation) {
case ISurfaceComposer::eOrientationDefault:
flags = Transform::ROT_0;
break;
case ISurfaceComposer::eOrientation90:
flags = Transform::ROT_90;
break;
case ISurfaceComposer::eOrientation180:
flags = Transform::ROT_180;
break;
case ISurfaceComposer::eOrientation270:
flags = Transform::ROT_270;
break;
default:
return BAD_VALUE;
}
tr->set(flags, w, h);
return NO_ERROR;
}
status_t GraphicPlane::setOrientation(int orientation)
{
// If the rotation can be handled in hardware, this is where
// the magic should happen.
const DisplayHardware& hw(displayHardware());
const float w = mDisplayWidth;
const float h = mDisplayHeight;
mWidth = int(w);
mHeight = int(h);
Transform orientationTransform;
GraphicPlane::orientationToTransfrom(orientation, w, h,
&orientationTransform);
if (orientation & ISurfaceComposer::eOrientationSwapMask) {
mWidth = int(h);
mHeight = int(w);
}
mOrientation = orientation;
mGlobalTransform = mDisplayTransform * orientationTransform;
return NO_ERROR;
}
const DisplayHardware& GraphicPlane::displayHardware() const {
return *mHw;
}
DisplayHardware& GraphicPlane::editDisplayHardware() {
return *mHw;
}
const Transform& GraphicPlane::transform() const {
return mGlobalTransform;
}
EGLDisplay GraphicPlane::getEGLDisplay() const {
return mHw->getEGLDisplay();
}
// ---------------------------------------------------------------------------
}; // namespace android