IntRect TiledBackingStore::tileRectForCoordinate(const Tile::Coordinate& coordinate) const
{
IntRect rect(coordinate.x() * m_tileSize.width(),
coordinate.y() * m_tileSize.height(),
m_tileSize.width(),
m_tileSize.height());
rect.intersect(contentsRect());
return rect;
}
double TiledBackingStore::tileDistance(const IntRect& viewport, const Tile::Coordinate& tileCoordinate) const
{
if (viewport.intersects(tileRectForCoordinate(tileCoordinate)))
return 0;
IntPoint viewCenter = viewport.location() + IntSize(viewport.width() / 2, viewport.height() / 2);
Tile::Coordinate centerCoordinate = tileCoordinateForPoint(viewCenter);
return std::max(abs(centerCoordinate.y() - tileCoordinate.y()), abs(centerCoordinate.x() - tileCoordinate.x()));
}
double TiledBackingStore::tileDistance(const IntRect& viewport, const Tile::Coordinate& tileCoordinate) const
{
if (viewport.intersects(tileRectForCoordinate(tileCoordinate)))
return 0;
IntPoint viewCenter = viewport.location() + IntSize(viewport.width() / 2, viewport.height() / 2);
Tile::Coordinate centerCoordinate = tileCoordinateForPoint(viewCenter);
// Manhattan distance, biased so that vertical distances are shorter.
const double horizontalBias = 1.3;
return abs(centerCoordinate.y() - tileCoordinate.y()) + horizontalBias * abs(centerCoordinate.x() - tileCoordinate.x());
}
void TiledBackingStore::paint(GraphicsContext* context, const IntRect& rect)
{
context->save();
// Assumes the backing store is painted with the scale transform applied.
// Since tile content is already scaled, first revert the scaling from the painter.
context->scale(FloatSize(1.f / m_contentsScale, 1.f / m_contentsScale));
IntRect dirtyRect = mapFromContents(rect);
Tile::Coordinate topLeft = tileCoordinateForPoint(dirtyRect.location());
Tile::Coordinate bottomRight = tileCoordinateForPoint(innerBottomRight(dirtyRect));
for (unsigned yCoordinate = topLeft.y(); yCoordinate <= bottomRight.y(); ++yCoordinate) {
for (unsigned xCoordinate = topLeft.x(); xCoordinate <= bottomRight.x(); ++xCoordinate) {
Tile::Coordinate currentCoordinate(xCoordinate, yCoordinate);
RefPtr<Tile> currentTile = tileAt(currentCoordinate);
if (currentTile && currentTile->isReadyToPaint())
currentTile->paint(context, dirtyRect);
else {
IntRect tileRect = tileRectForCoordinate(currentCoordinate);
IntRect target = intersection(tileRect, dirtyRect);
if (target.isEmpty())
continue;
m_backend->paintCheckerPattern(context, FloatRect(target));
}
}
}
context->restore();
}
void TiledBackingStore::invalidate(const IntRect& contentsDirtyRect)
{
IntRect dirtyRect(mapFromContents(contentsDirtyRect));
IntRect keepRectFitToTileSize = tileRectForCoordinate(tileCoordinateForPoint(m_keepRect.location()));
keepRectFitToTileSize.unite(tileRectForCoordinate(tileCoordinateForPoint(innerBottomRight(m_keepRect))));
// Only iterate on the part of the rect that we know we might have tiles.
IntRect coveredDirtyRect = intersection(dirtyRect, keepRectFitToTileSize);
Tile::Coordinate topLeft = tileCoordinateForPoint(coveredDirtyRect.location());
Tile::Coordinate bottomRight = tileCoordinateForPoint(innerBottomRight(coveredDirtyRect));
for (int yCoordinate = topLeft.y(); yCoordinate <= bottomRight.y(); ++yCoordinate) {
for (int xCoordinate = topLeft.x(); xCoordinate <= bottomRight.x(); ++xCoordinate) {
RefPtr<Tile> currentTile = tileAt(Tile::Coordinate(xCoordinate, yCoordinate));
if (!currentTile)
continue;
// Pass the full rect to each tile as coveredDirtyRect might not
// contain them completely and we don't want partial tile redraws.
#if PLATFORM(JS)
fprintf(stderr, "WebKit: TiledBackingStore: invalidate: invalidating currentTile (x,y,w,h): %i %i %i %i\n",dirtyRect.x(),dirtyRect.y(),dirtyRect.width(),dirtyRect.height());
#endif
currentTile->invalidate(dirtyRect);
}
}
startTileBufferUpdateTimer();
}
void TiledBackingStore::invalidate(const IntRect& contentsDirtyRect)
{
IntRect dirtyRect(mapFromContents(contentsDirtyRect));
Tile::Coordinate topLeft = tileCoordinateForPoint(dirtyRect.location());
Tile::Coordinate bottomRight = tileCoordinateForPoint(innerBottomRight(dirtyRect));
for (unsigned yCoordinate = topLeft.y(); yCoordinate <= bottomRight.y(); ++yCoordinate) {
for (unsigned xCoordinate = topLeft.x(); xCoordinate <= bottomRight.x(); ++xCoordinate) {
RefPtr<Tile> currentTile = tileAt(Tile::Coordinate(xCoordinate, yCoordinate));
if (!currentTile)
continue;
currentTile->invalidate(dirtyRect);
}
}
startTileBufferUpdateTimer();
}
// Returns a ratio between 0.0f and 1.0f of the surface of contentsRect covered by rendered tiles.
float TiledBackingStore::coverageRatio(const WebCore::IntRect& contentsRect) const
{
IntRect dirtyRect = mapFromContents(contentsRect);
float rectArea = dirtyRect.width() * dirtyRect.height();
float coverArea = 0.0f;
Tile::Coordinate topLeft = tileCoordinateForPoint(dirtyRect.location());
Tile::Coordinate bottomRight = tileCoordinateForPoint(innerBottomRight(dirtyRect));
for (unsigned yCoordinate = topLeft.y(); yCoordinate <= bottomRight.y(); ++yCoordinate) {
for (unsigned xCoordinate = topLeft.x(); xCoordinate <= bottomRight.x(); ++xCoordinate) {
Tile::Coordinate currentCoordinate(xCoordinate, yCoordinate);
RefPtr<Tile> currentTile = tileAt(Tile::Coordinate(xCoordinate, yCoordinate));
if (currentTile && currentTile->isReadyToPaint()) {
IntRect coverRect = intersection(dirtyRect, currentTile->rect());
coverArea += coverRect.width() * coverRect.height();
}
}
}
return coverArea / rectArea;
}
void TiledBackingStore::createTiles()
{
if (m_contentsFrozen)
return;
IntRect visibleRect = visibleContentsRect();
m_previousVisibleRect = visibleRect;
if (visibleRect.isEmpty())
return;
// Resize tiles on edges in case the contents size has changed.
bool didResizeTiles = resizeEdgeTiles();
IntRect keepRect;
IntRect coverRect;
computeCoverAndKeepRect(visibleRect, coverRect, keepRect);
dropTilesOutsideRect(keepRect);
// Search for the tile position closest to the viewport center that does not yet contain a tile.
// Which position is considered the closest depends on the tileDistance function.
double shortestDistance = std::numeric_limits<double>::infinity();
Vector<Tile::Coordinate> tilesToCreate;
unsigned requiredTileCount = 0;
Tile::Coordinate topLeft = tileCoordinateForPoint(coverRect.location());
Tile::Coordinate bottomRight = tileCoordinateForPoint(innerBottomRight(coverRect));
for (unsigned yCoordinate = topLeft.y(); yCoordinate <= bottomRight.y(); ++yCoordinate) {
for (unsigned xCoordinate = topLeft.x(); xCoordinate <= bottomRight.x(); ++xCoordinate) {
Tile::Coordinate currentCoordinate(xCoordinate, yCoordinate);
if (tileAt(currentCoordinate))
continue;
++requiredTileCount;
// Distance is 0 for all tiles inside the visibleRect.
double distance = tileDistance(visibleRect, currentCoordinate);
if (distance > shortestDistance)
continue;
if (distance < shortestDistance) {
tilesToCreate.clear();
shortestDistance = distance;
}
tilesToCreate.append(currentCoordinate);
}
}
// Now construct the tile(s) within the shortest distance.
unsigned tilesToCreateCount = tilesToCreate.size();
for (unsigned n = 0; n < tilesToCreateCount; ++n) {
Tile::Coordinate coordinate = tilesToCreate[n];
setTile(coordinate, m_backend->createTile(this, coordinate));
}
requiredTileCount -= tilesToCreateCount;
// Paint the content of the newly created tiles.
if (tilesToCreateCount || didResizeTiles)
updateTileBuffers();
// Re-call createTiles on a timer to cover the visible area with the newest shortest distance.
if (requiredTileCount)
m_tileCreationTimer->startOneShot(m_tileCreationDelay);
}
void TiledBackingStore::createTiles()
{
// Guard here as as these can change before the timer fires.
if (isBackingStoreUpdatesSuspended())
return;
// Update our backing store geometry.
const IntRect previousRect = m_rect;
m_rect = mapFromContents(m_client->tiledBackingStoreContentsRect());
const IntRect visibleRect = this->visibleRect();
m_visibleRect = visibleRect;
if (visibleRect.isEmpty())
return;
IntRect keepRect;
IntRect coverRect;
computeCoverAndKeepRect(visibleRect, coverRect, keepRect);
setKeepRect(keepRect);
// Resize tiles at the edge in case the contents size has changed, but only do so
// after having dropped tiles outside the keep rect.
bool didResizeTiles = false;
if (previousRect != m_rect)
didResizeTiles = resizeEdgeTiles();
// Search for the tile position closest to the viewport center that does not yet contain a tile.
// Which position is considered the closest depends on the tileDistance function.
double shortestDistance = std::numeric_limits<double>::infinity();
Vector<Tile::Coordinate> tilesToCreate;
unsigned requiredTileCount = 0;
// Cover areas (in tiles) with minimum distance from the visible rect. If the visible rect is
// not covered already it will be covered first in one go, due to the distance being 0 for tiles
// inside the visible rect.
Tile::Coordinate topLeft = tileCoordinateForPoint(coverRect.location());
Tile::Coordinate bottomRight = tileCoordinateForPoint(innerBottomRight(coverRect));
for (unsigned yCoordinate = topLeft.y(); yCoordinate <= bottomRight.y(); ++yCoordinate) {
for (unsigned xCoordinate = topLeft.x(); xCoordinate <= bottomRight.x(); ++xCoordinate) {
Tile::Coordinate currentCoordinate(xCoordinate, yCoordinate);
if (tileAt(currentCoordinate))
continue;
++requiredTileCount;
double distance = tileDistance(visibleRect, currentCoordinate);
if (distance > shortestDistance)
continue;
if (distance < shortestDistance) {
tilesToCreate.clear();
shortestDistance = distance;
}
tilesToCreate.append(currentCoordinate);
}
}
// Now construct the tile(s) within the shortest distance.
unsigned tilesToCreateCount = tilesToCreate.size();
for (unsigned n = 0; n < tilesToCreateCount; ++n) {
Tile::Coordinate coordinate = tilesToCreate[n];
setTile(coordinate, m_backend->createTile(this, coordinate));
}
requiredTileCount -= tilesToCreateCount;
// Paint the content of the newly created tiles or resized tiles.
if (tilesToCreateCount || didResizeTiles)
updateTileBuffers();
// Re-call createTiles on a timer to cover the visible area with the newest shortest distance.
if (requiredTileCount)
m_backingStoreUpdateTimer.startOneShot(m_tileCreationDelay);
}
void TiledBackingStore::createTiles()
{
if (m_contentsFrozen)
return;
IntRect visibleRect = mapFromContents(m_client->tiledBackingStoreVisibleRect());
m_previousVisibleRect = visibleRect;
if (visibleRect.isEmpty())
return;
// Remove tiles that extend outside the current contents rect.
dropOverhangingTiles();
IntRect keepRect = visibleRect;
// Inflates to both sides, so divide inflate delta by 2
keepRect.inflateX(visibleRect.width() * (m_keepAreaMultiplier.width() - 1.f) / 2);
keepRect.inflateY(visibleRect.height() * (m_keepAreaMultiplier.height() - 1.f) / 2);
keepRect.intersect(contentsRect());
dropTilesOutsideRect(keepRect);
IntRect coverRect = visibleRect;
// Inflates to both sides, so divide inflate delta by 2
coverRect.inflateX(visibleRect.width() * (m_coverAreaMultiplier.width() - 1.f) / 2);
coverRect.inflateY(visibleRect.height() * (m_coverAreaMultiplier.height() - 1.f) / 2);
coverRect.intersect(contentsRect());
// Search for the tile position closest to the viewport center that does not yet contain a tile.
// Which position is considered the closest depends on the tileDistance function.
double shortestDistance = std::numeric_limits<double>::infinity();
Vector<Tile::Coordinate> tilesToCreate;
unsigned requiredTileCount = 0;
Tile::Coordinate topLeft = tileCoordinateForPoint(coverRect.location());
Tile::Coordinate bottomRight = tileCoordinateForPoint(IntPoint(coverRect.maxX(), coverRect.maxY()));
for (unsigned yCoordinate = topLeft.y(); yCoordinate <= bottomRight.y(); ++yCoordinate) {
for (unsigned xCoordinate = topLeft.x(); xCoordinate <= bottomRight.x(); ++xCoordinate) {
Tile::Coordinate currentCoordinate(xCoordinate, yCoordinate);
if (tileAt(currentCoordinate))
continue;
++requiredTileCount;
// Distance is 0 for all currently visible tiles.
double distance = tileDistance(visibleRect, currentCoordinate);
if (distance > shortestDistance)
continue;
if (distance < shortestDistance) {
tilesToCreate.clear();
shortestDistance = distance;
}
tilesToCreate.append(currentCoordinate);
}
}
// Now construct the tile(s)
unsigned tilesToCreateCount = tilesToCreate.size();
for (unsigned n = 0; n < tilesToCreateCount; ++n) {
Tile::Coordinate coordinate = tilesToCreate[n];
setTile(coordinate, Tile::create(this, coordinate));
}
requiredTileCount -= tilesToCreateCount;
// Paint the content of the newly created tiles
if (tilesToCreateCount)
updateTileBuffers();
// Keep creating tiles until the whole coverRect is covered.
if (requiredTileCount)
m_tileCreationTimer->startOneShot(m_tileCreationDelay);
}
void TiledBackingStore::createTiles()
{
// Guard here as as these can change before the timer fires.
if (isBackingStoreUpdatesSuspended())
return;
// Update our backing store geometry.
const IntRect previousRect = m_rect;
m_rect = mapFromContents(m_client->tiledBackingStoreContentsRect());
m_trajectoryVector = m_pendingTrajectoryVector;
m_visibleRect = visibleRect();
if (m_rect.isEmpty()) {
setCoverRect(IntRect());
setKeepRect(IntRect());
return;
}
/* We must compute cover and keep rects using the visibleRect, instead of the rect intersecting the visibleRect with m_rect,
* because TBS can be used as a backing store of GraphicsLayer and the visible rect usually does not intersect with m_rect.
* In the below case, the intersecting rect is an empty.
*
* +---------------+
* | |
* | m_rect |
* | +-------|-----------------------+
* | | HERE | cover or keep |
* +---------------+ rect |
* | +---------+ |
* | | visible | |
* | | rect | |
* | +---------+ |
* | |
* | |
* +-------------------------------+
*
* We must create or keep the tiles in the HERE region.
*/
IntRect coverRect;
IntRect keepRect;
computeCoverAndKeepRect(m_visibleRect, coverRect, keepRect);
setCoverRect(coverRect);
setKeepRect(keepRect);
if (coverRect.isEmpty())
return;
// Resize tiles at the edge in case the contents size has changed, but only do so
// after having dropped tiles outside the keep rect.
bool didResizeTiles = false;
if (previousRect != m_rect)
didResizeTiles = resizeEdgeTiles();
// Search for the tile position closest to the viewport center that does not yet contain a tile.
// Which position is considered the closest depends on the tileDistance function.
double shortestDistance = std::numeric_limits<double>::infinity();
Vector<Tile::Coordinate> tilesToCreate;
unsigned requiredTileCount = 0;
// Cover areas (in tiles) with minimum distance from the visible rect. If the visible rect is
// not covered already it will be covered first in one go, due to the distance being 0 for tiles
// inside the visible rect.
Tile::Coordinate topLeft = tileCoordinateForPoint(coverRect.location());
Tile::Coordinate bottomRight = tileCoordinateForPoint(innerBottomRight(coverRect));
for (int yCoordinate = topLeft.y(); yCoordinate <= bottomRight.y(); ++yCoordinate) {
for (int xCoordinate = topLeft.x(); xCoordinate <= bottomRight.x(); ++xCoordinate) {
Tile::Coordinate currentCoordinate(xCoordinate, yCoordinate);
if (tileAt(currentCoordinate))
continue;
++requiredTileCount;
double distance = tileDistance(m_visibleRect, currentCoordinate);
if (distance > shortestDistance)
continue;
if (distance < shortestDistance) {
tilesToCreate.clear();
shortestDistance = distance;
}
tilesToCreate.append(currentCoordinate);
}
}
// Now construct the tile(s) within the shortest distance.
unsigned tilesToCreateCount = tilesToCreate.size();
for (unsigned n = 0; n < tilesToCreateCount; ++n) {
Tile::Coordinate coordinate = tilesToCreate[n];
setTile(coordinate, m_backend->createTile(this, coordinate));
}
requiredTileCount -= tilesToCreateCount;
// Paint the content of the newly created tiles or resized tiles.
if (tilesToCreateCount || didResizeTiles)
updateTileBuffers();
// Re-call createTiles on a timer to cover the visible area with the newest shortest distance.
m_pendingTileCreation = requiredTileCount;
if (m_pendingTileCreation) {
if (!m_commitTileUpdatesOnIdleEventLoop) {
m_client->tiledBackingStoreHasPendingTileCreation();
return;
}
static const double tileCreationDelay = 0.01;
startBackingStoreUpdateTimer(tileCreationDelay);
}
}