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A library jar that provides APIs for Applications written for the Google Android Platform.
/*
* Copyright (C) 2020 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.
*/
package com.android.wm.shell.pip;
import static com.android.wm.shell.pip.PipBoundsState.STASH_TYPE_LEFT;
import static com.android.wm.shell.pip.PipBoundsState.STASH_TYPE_NONE;
import static com.android.wm.shell.pip.PipBoundsState.STASH_TYPE_RIGHT;
import android.graphics.Rect;
import com.android.internal.annotations.VisibleForTesting;
/**
* Calculates the snap targets and the snap position for the PIP given a position and a velocity.
* All bounds are relative to the display top/left.
*/
public class PipSnapAlgorithm {
/**
* Returns a fraction that describes where the PiP bounds is.
* See {@link #getSnapFraction(Rect, Rect, int)}.
*/
public float getSnapFraction(Rect stackBounds, Rect movementBounds) {
return getSnapFraction(stackBounds, movementBounds, STASH_TYPE_NONE);
}
/**
* @return returns a fraction that describes where along the {@param movementBounds} the
* {@param stackBounds} are. If the {@param stackBounds} are not currently on the
* {@param movementBounds} exactly, then they will be snapped to the movement bounds.
* stashType dictates whether the PiP is stashed (off-screen) or not. If
* that's the case, we will have to do some math to calculate the snap fraction
* correctly.
*
* The fraction is defined in a clockwise fashion against the {@param movementBounds}:
*
* 0 1
* 4 +---+ 1
* | |
* 3 +---+ 2
* 3 2
*/
public float getSnapFraction(Rect stackBounds, Rect movementBounds,
@PipBoundsState.StashType int stashType) {
final Rect tmpBounds = new Rect();
snapRectToClosestEdge(stackBounds, movementBounds, tmpBounds, stashType);
final float widthFraction = (float) (tmpBounds.left - movementBounds.left) /
movementBounds.width();
final float heightFraction = (float) (tmpBounds.top - movementBounds.top) /
movementBounds.height();
if (tmpBounds.top == movementBounds.top) {
return widthFraction;
} else if (tmpBounds.left == movementBounds.right) {
return 1f + heightFraction;
} else if (tmpBounds.top == movementBounds.bottom) {
return 2f + (1f - widthFraction);
} else {
return 3f + (1f - heightFraction);
}
}
/**
* Moves the {@param stackBounds} along the {@param movementBounds} to the given snap fraction.
* See {@link #getSnapFraction(Rect, Rect)}.
*
* The fraction is define in a clockwise fashion against the {@param movementBounds}:
*
* 0 1
* 4 +---+ 1
* | |
* 3 +---+ 2
* 3 2
*/
public void applySnapFraction(Rect stackBounds, Rect movementBounds, float snapFraction) {
if (snapFraction < 1f) {
int offset = movementBounds.left + (int) (snapFraction * movementBounds.width());
stackBounds.offsetTo(offset, movementBounds.top);
} else if (snapFraction < 2f) {
snapFraction -= 1f;
int offset = movementBounds.top + (int) (snapFraction * movementBounds.height());
stackBounds.offsetTo(movementBounds.right, offset);
} else if (snapFraction < 3f) {
snapFraction -= 2f;
int offset = movementBounds.left + (int) ((1f - snapFraction) * movementBounds.width());
stackBounds.offsetTo(offset, movementBounds.bottom);
} else {
snapFraction -= 3f;
int offset = movementBounds.top + (int) ((1f - snapFraction) * movementBounds.height());
stackBounds.offsetTo(movementBounds.left, offset);
}
}
/**
* Same as {@link #applySnapFraction(Rect, Rect, float)}, but take stash state into
* consideration.
*/
public void applySnapFraction(Rect stackBounds, Rect movementBounds, float snapFraction,
@PipBoundsState.StashType int stashType, int stashOffset, Rect displayBounds,
Rect insetBounds) {
applySnapFraction(stackBounds, movementBounds, snapFraction);
if (stashType != STASH_TYPE_NONE) {
stackBounds.offsetTo(stashType == STASH_TYPE_LEFT
? stashOffset - stackBounds.width() + insetBounds.left
: displayBounds.right - stashOffset - insetBounds.right,
stackBounds.top);
}
}
/**
* Snaps the {@param stackBounds} to the closest edge of the {@param movementBounds} and writes
* the new bounds out to {@param boundsOut}.
*/
@VisibleForTesting
void snapRectToClosestEdge(Rect stackBounds, Rect movementBounds, Rect boundsOut,
@PipBoundsState.StashType int stashType) {
int leftEdge = stackBounds.left;
if (stashType == STASH_TYPE_LEFT) {
leftEdge = movementBounds.left;
} else if (stashType == STASH_TYPE_RIGHT) {
leftEdge = movementBounds.right;
}
final int boundedLeft = Math.max(movementBounds.left, Math.min(movementBounds.right,
leftEdge));
final int boundedTop = Math.max(movementBounds.top, Math.min(movementBounds.bottom,
stackBounds.top));
boundsOut.set(stackBounds);
// Otherwise, just find the closest edge
final int fromLeft = Math.abs(leftEdge - movementBounds.left);
final int fromTop = Math.abs(stackBounds.top - movementBounds.top);
final int fromRight = Math.abs(movementBounds.right - leftEdge);
final int fromBottom = Math.abs(movementBounds.bottom - stackBounds.top);
final int shortest = Math.min(Math.min(fromLeft, fromRight), Math.min(fromTop, fromBottom));
if (shortest == fromLeft) {
boundsOut.offsetTo(movementBounds.left, boundedTop);
} else if (shortest == fromTop) {
boundsOut.offsetTo(boundedLeft, movementBounds.top);
} else if (shortest == fromRight) {
boundsOut.offsetTo(movementBounds.right, boundedTop);
} else {
boundsOut.offsetTo(boundedLeft, movementBounds.bottom);
}
}
}
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