/* * Copyright (C) 2014 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific languag`e governing permissions and * limitations under the License. */ package android.support.v7.widget; import static android.support.v7.widget.RecyclerView.NO_POSITION; import android.content.Context; import android.graphics.PointF; import android.os.Parcel; import android.os.Parcelable; import android.support.v4.view.ViewCompat; import android.support.v4.view.accessibility.AccessibilityEventCompat; import android.support.v4.view.accessibility.AccessibilityRecordCompat; import android.support.v7.widget.RecyclerView.LayoutParams; import android.support.v7.widget.helper.ItemTouchHelper; import android.util.AttributeSet; import android.util.Log; import android.view.View; import android.view.ViewGroup; import android.view.accessibility.AccessibilityEvent; import java.util.List; /** * A {@link android.support.v7.widget.RecyclerView.LayoutManager} implementation which provides * similar functionality to {@link android.widget.ListView}. */ public class LinearLayoutManager extends RecyclerView.LayoutManager implements ItemTouchHelper.ViewDropHandler { private static final String TAG = "LinearLayoutManager"; private static final boolean DEBUG = false; public static final int HORIZONTAL = OrientationHelper.HORIZONTAL; public static final int VERTICAL = OrientationHelper.VERTICAL; public static final int INVALID_OFFSET = Integer.MIN_VALUE; /** * While trying to find next view to focus, LayoutManager will not try to scroll more * than this factor times the total space of the list. If layout is vertical, total space is the * height minus padding, if layout is horizontal, total space is the width minus padding. */ private static final float MAX_SCROLL_FACTOR = 1 / 3f; /** * Current orientation. Either {@link #HORIZONTAL} or {@link #VERTICAL} */ int mOrientation; /** * Helper class that keeps temporary layout state. * It does not keep state after layout is complete but we still keep a reference to re-use * the same object. */ private LayoutState mLayoutState; /** * Many calculations are made depending on orientation. To keep it clean, this interface * helps {@link LinearLayoutManager} make those decisions. * Based on {@link #mOrientation}, an implementation is lazily created in * {@link #ensureLayoutState} method. */ OrientationHelper mOrientationHelper; /** * We need to track this so that we can ignore current position when it changes. */ private boolean mLastStackFromEnd; /** * Defines if layout should be calculated from end to start. * * @see #mShouldReverseLayout */ private boolean mReverseLayout = false; /** * This keeps the final value for how LayoutManager should start laying out views. * It is calculated by checking {@link #getReverseLayout()} and View's layout direction. * {@link #onLayoutChildren(RecyclerView.Recycler, RecyclerView.State)} is run. */ boolean mShouldReverseLayout = false; /** * Works the same way as {@link android.widget.AbsListView#setStackFromBottom(boolean)} and * it supports both orientations. * see {@link android.widget.AbsListView#setStackFromBottom(boolean)} */ private boolean mStackFromEnd = false; /** * Works the same way as {@link android.widget.AbsListView#setSmoothScrollbarEnabled(boolean)}. * see {@link android.widget.AbsListView#setSmoothScrollbarEnabled(boolean)} */ private boolean mSmoothScrollbarEnabled = true; /** * When LayoutManager needs to scroll to a position, it sets this variable and requests a * layout which will check this variable and re-layout accordingly. */ int mPendingScrollPosition = NO_POSITION; /** * Used to keep the offset value when {@link #scrollToPositionWithOffset(int, int)} is * called. */ int mPendingScrollPositionOffset = INVALID_OFFSET; private boolean mRecycleChildrenOnDetach; SavedState mPendingSavedState = null; /** * Re-used variable to keep anchor information on re-layout. * Anchor position and coordinate defines the reference point for LLM while doing a layout. * */ final AnchorInfo mAnchorInfo = new AnchorInfo(); /** * Creates a vertical LinearLayoutManager * * @param context Current context, will be used to access resources. */ public LinearLayoutManager(Context context) { this(context, VERTICAL, false); } /** * @param context Current context, will be used to access resources. * @param orientation Layout orientation. Should be {@link #HORIZONTAL} or {@link * #VERTICAL}. * @param reverseLayout When set to true, layouts from end to start. */ public LinearLayoutManager(Context context, int orientation, boolean reverseLayout) { setOrientation(orientation); setReverseLayout(reverseLayout); setAutoMeasureEnabled(true); } /** * Constructor used when layout manager is set in XML by RecyclerView attribute * "layoutManager". Defaults to vertical orientation. * * @attr ref android.support.v7.recyclerview.R.styleable#RecyclerView_android_orientation * @attr ref android.support.v7.recyclerview.R.styleable#RecyclerView_reverseLayout * @attr ref android.support.v7.recyclerview.R.styleable#RecyclerView_stackFromEnd */ public LinearLayoutManager(Context context, AttributeSet attrs, int defStyleAttr, int defStyleRes) { Properties properties = getProperties(context, attrs, defStyleAttr, defStyleRes); setOrientation(properties.orientation); setReverseLayout(properties.reverseLayout); setStackFromEnd(properties.stackFromEnd); setAutoMeasureEnabled(true); } /** * {@inheritDoc} */ @Override public LayoutParams generateDefaultLayoutParams() { return new LayoutParams(ViewGroup.LayoutParams.WRAP_CONTENT, ViewGroup.LayoutParams.WRAP_CONTENT); } /** * Returns whether LayoutManager will recycle its children when it is detached from * RecyclerView. * * @return true if LayoutManager will recycle its children when it is detached from * RecyclerView. */ public boolean getRecycleChildrenOnDetach() { return mRecycleChildrenOnDetach; } /** * Set whether LayoutManager will recycle its children when it is detached from * RecyclerView. *
* If you are using a {@link RecyclerView.RecycledViewPool}, it might be a good idea to set
* this flag to true
so that views will be avilable to other RecyclerViews
* immediately.
*
* Note that, setting this flag will result in a performance drop if RecyclerView * is restored. * * @param recycleChildrenOnDetach Whether children should be recycled in detach or not. */ public void setRecycleChildrenOnDetach(boolean recycleChildrenOnDetach) { mRecycleChildrenOnDetach = recycleChildrenOnDetach; } @Override public void onDetachedFromWindow(RecyclerView view, RecyclerView.Recycler recycler) { super.onDetachedFromWindow(view, recycler); if (mRecycleChildrenOnDetach) { removeAndRecycleAllViews(recycler); recycler.clear(); } } @Override public void onInitializeAccessibilityEvent(AccessibilityEvent event) { super.onInitializeAccessibilityEvent(event); if (getChildCount() > 0) { final AccessibilityRecordCompat record = AccessibilityEventCompat .asRecord(event); record.setFromIndex(findFirstVisibleItemPosition()); record.setToIndex(findLastVisibleItemPosition()); } } @Override public Parcelable onSaveInstanceState() { if (mPendingSavedState != null) { return new SavedState(mPendingSavedState); } SavedState state = new SavedState(); if (getChildCount() > 0) { ensureLayoutState(); boolean didLayoutFromEnd = mLastStackFromEnd ^ mShouldReverseLayout; state.mAnchorLayoutFromEnd = didLayoutFromEnd; if (didLayoutFromEnd) { final View refChild = getChildClosestToEnd(); state.mAnchorOffset = mOrientationHelper.getEndAfterPadding() - mOrientationHelper.getDecoratedEnd(refChild); state.mAnchorPosition = getPosition(refChild); } else { final View refChild = getChildClosestToStart(); state.mAnchorPosition = getPosition(refChild); state.mAnchorOffset = mOrientationHelper.getDecoratedStart(refChild) - mOrientationHelper.getStartAfterPadding(); } } else { state.invalidateAnchor(); } return state; } @Override public void onRestoreInstanceState(Parcelable state) { if (state instanceof SavedState) { mPendingSavedState = (SavedState) state; requestLayout(); if (DEBUG) { Log.d(TAG, "loaded saved state"); } } else if (DEBUG) { Log.d(TAG, "invalid saved state class"); } } /** * @return true if {@link #getOrientation()} is {@link #HORIZONTAL} */ @Override public boolean canScrollHorizontally() { return mOrientation == HORIZONTAL; } /** * @return true if {@link #getOrientation()} is {@link #VERTICAL} */ @Override public boolean canScrollVertically() { return mOrientation == VERTICAL; } /** * Compatibility support for {@link android.widget.AbsListView#setStackFromBottom(boolean)} */ public void setStackFromEnd(boolean stackFromEnd) { assertNotInLayoutOrScroll(null); if (mStackFromEnd == stackFromEnd) { return; } mStackFromEnd = stackFromEnd; requestLayout(); } public boolean getStackFromEnd() { return mStackFromEnd; } /** * Returns the current orientaion of the layout. * * @return Current orientation, either {@link #HORIZONTAL} or {@link #VERTICAL} * @see #setOrientation(int) */ public int getOrientation() { return mOrientation; } /** * Sets the orientation of the layout. {@link android.support.v7.widget.LinearLayoutManager} * will do its best to keep scroll position. * * @param orientation {@link #HORIZONTAL} or {@link #VERTICAL} */ public void setOrientation(int orientation) { if (orientation != HORIZONTAL && orientation != VERTICAL) { throw new IllegalArgumentException("invalid orientation:" + orientation); } assertNotInLayoutOrScroll(null); if (orientation == mOrientation) { return; } mOrientation = orientation; mOrientationHelper = null; requestLayout(); } /** * Calculates the view layout order. (e.g. from end to start or start to end) * RTL layout support is applied automatically. So if layout is RTL and * {@link #getReverseLayout()} is {@code true}, elements will be laid out starting from left. */ private void resolveShouldLayoutReverse() { // A == B is the same result, but we rather keep it readable if (mOrientation == VERTICAL || !isLayoutRTL()) { mShouldReverseLayout = mReverseLayout; } else { mShouldReverseLayout = !mReverseLayout; } } /** * Returns if views are laid out from the opposite direction of the layout. * * @return If layout is reversed or not. * @see #setReverseLayout(boolean) */ public boolean getReverseLayout() { return mReverseLayout; } /** * Used to reverse item traversal and layout order. * This behaves similar to the layout change for RTL views. When set to true, first item is * laid out at the end of the UI, second item is laid out before it etc. * * For horizontal layouts, it depends on the layout direction. * When set to true, If {@link android.support.v7.widget.RecyclerView} is LTR, than it will * layout from RTL, if {@link android.support.v7.widget.RecyclerView}} is RTL, it will layout * from LTR. * * If you are looking for the exact same behavior of * {@link android.widget.AbsListView#setStackFromBottom(boolean)}, use * {@link #setStackFromEnd(boolean)} */ public void setReverseLayout(boolean reverseLayout) { assertNotInLayoutOrScroll(null); if (reverseLayout == mReverseLayout) { return; } mReverseLayout = reverseLayout; requestLayout(); } /** * {@inheritDoc} */ @Override public View findViewByPosition(int position) { final int childCount = getChildCount(); if (childCount == 0) { return null; } final int firstChild = getPosition(getChildAt(0)); final int viewPosition = position - firstChild; if (viewPosition >= 0 && viewPosition < childCount) { final View child = getChildAt(viewPosition); if (getPosition(child) == position) { return child; // in pre-layout, this may not match } } // fallback to traversal. This might be necessary in pre-layout. return super.findViewByPosition(position); } /** *
Returns the amount of extra space that should be laid out by LayoutManager. * By default, {@link android.support.v7.widget.LinearLayoutManager} lays out 1 extra page of * items while smooth scrolling and 0 otherwise. You can override this method to implement your * custom layout pre-cache logic.
*Laying out invisible elements will eventually come with performance cost. On the other * hand, in places like smooth scrolling to an unknown location, this extra content helps * LayoutManager to calculate a much smoother scrolling; which improves user experience.
*You can also use this if you are trying to pre-layout your upcoming views.
* * @return The extra space that should be laid out (in pixels). */ protected int getExtraLayoutSpace(RecyclerView.State state) { if (state.hasTargetScrollPosition()) { return mOrientationHelper.getTotalSpace(); } else { return 0; } } @Override public void smoothScrollToPosition(RecyclerView recyclerView, RecyclerView.State state, int position) { LinearSmoothScroller linearSmoothScroller = new LinearSmoothScroller(recyclerView.getContext()) { @Override public PointF computeScrollVectorForPosition(int targetPosition) { return LinearLayoutManager.this .computeScrollVectorForPosition(targetPosition); } }; linearSmoothScroller.setTargetPosition(position); startSmoothScroll(linearSmoothScroller); } public PointF computeScrollVectorForPosition(int targetPosition) { if (getChildCount() == 0) { return null; } final int firstChildPos = getPosition(getChildAt(0)); final int direction = targetPosition < firstChildPos != mShouldReverseLayout ? -1 : 1; if (mOrientation == HORIZONTAL) { return new PointF(direction, 0); } else { return new PointF(0, direction); } } /** * {@inheritDoc} */ @Override public void onLayoutChildren(RecyclerView.Recycler recycler, RecyclerView.State state) { // layout algorithm: // 1) by checking children and other variables, find an anchor coordinate and an anchor // item position. // 2) fill towards start, stacking from bottom // 3) fill towards end, stacking from top // 4) scroll to fulfill requirements like stack from bottom. // create layout state if (DEBUG) { Log.d(TAG, "is pre layout:" + state.isPreLayout()); } if (mPendingSavedState != null || mPendingScrollPosition != NO_POSITION) { if (state.getItemCount() == 0) { removeAndRecycleAllViews(recycler); return; } } if (mPendingSavedState != null && mPendingSavedState.hasValidAnchor()) { mPendingScrollPosition = mPendingSavedState.mAnchorPosition; } ensureLayoutState(); mLayoutState.mRecycle = false; // resolve layout direction resolveShouldLayoutReverse(); if (!mAnchorInfo.mValid || mPendingScrollPosition != NO_POSITION || mPendingSavedState != null) { mAnchorInfo.reset(); mAnchorInfo.mLayoutFromEnd = mShouldReverseLayout ^ mStackFromEnd; // calculate anchor position and coordinate updateAnchorInfoForLayout(recycler, state, mAnchorInfo); mAnchorInfo.mValid = true; } if (DEBUG) { Log.d(TAG, "Anchor info:" + mAnchorInfo); } // LLM may decide to layout items for "extra" pixels to account for scrolling target, // caching or predictive animations. int extraForStart; int extraForEnd; final int extra = getExtraLayoutSpace(state); // If the previous scroll delta was less than zero, the extra space should be laid out // at the start. Otherwise, it should be at the end. if (mLayoutState.mLastScrollDelta >= 0) { extraForEnd = extra; extraForStart = 0; } else { extraForStart = extra; extraForEnd = 0; } extraForStart += mOrientationHelper.getStartAfterPadding(); extraForEnd += mOrientationHelper.getEndPadding(); if (state.isPreLayout() && mPendingScrollPosition != NO_POSITION && mPendingScrollPositionOffset != INVALID_OFFSET) { // if the child is visible and we are going to move it around, we should layout // extra items in the opposite direction to make sure new items animate nicely // instead of just fading in final View existing = findViewByPosition(mPendingScrollPosition); if (existing != null) { final int current; final int upcomingOffset; if (mShouldReverseLayout) { current = mOrientationHelper.getEndAfterPadding() - mOrientationHelper.getDecoratedEnd(existing); upcomingOffset = current - mPendingScrollPositionOffset; } else { current = mOrientationHelper.getDecoratedStart(existing) - mOrientationHelper.getStartAfterPadding(); upcomingOffset = mPendingScrollPositionOffset - current; } if (upcomingOffset > 0) { extraForStart += upcomingOffset; } else { extraForEnd -= upcomingOffset; } } } int startOffset; int endOffset; final int firstLayoutDirection; if (mAnchorInfo.mLayoutFromEnd) { firstLayoutDirection = mShouldReverseLayout ? LayoutState.ITEM_DIRECTION_TAIL : LayoutState.ITEM_DIRECTION_HEAD; } else { firstLayoutDirection = mShouldReverseLayout ? LayoutState.ITEM_DIRECTION_HEAD : LayoutState.ITEM_DIRECTION_TAIL; } onAnchorReady(recycler, state, mAnchorInfo, firstLayoutDirection); detachAndScrapAttachedViews(recycler); mLayoutState.mInfinite = resolveIsInfinite(); mLayoutState.mIsPreLayout = state.isPreLayout(); if (mAnchorInfo.mLayoutFromEnd) { // fill towards start updateLayoutStateToFillStart(mAnchorInfo); mLayoutState.mExtra = extraForStart; fill(recycler, mLayoutState, state, false); startOffset = mLayoutState.mOffset; final int firstElement = mLayoutState.mCurrentPosition; if (mLayoutState.mAvailable > 0) { extraForEnd += mLayoutState.mAvailable; } // fill towards end updateLayoutStateToFillEnd(mAnchorInfo); mLayoutState.mExtra = extraForEnd; mLayoutState.mCurrentPosition += mLayoutState.mItemDirection; fill(recycler, mLayoutState, state, false); endOffset = mLayoutState.mOffset; if (mLayoutState.mAvailable > 0) { // end could not consume all. add more items towards start extraForStart = mLayoutState.mAvailable; updateLayoutStateToFillStart(firstElement, startOffset); mLayoutState.mExtra = extraForStart; fill(recycler, mLayoutState, state, false); startOffset = mLayoutState.mOffset; } } else { // fill towards end updateLayoutStateToFillEnd(mAnchorInfo); mLayoutState.mExtra = extraForEnd; fill(recycler, mLayoutState, state, false); endOffset = mLayoutState.mOffset; final int lastElement = mLayoutState.mCurrentPosition; if (mLayoutState.mAvailable > 0) { extraForStart += mLayoutState.mAvailable; } // fill towards start updateLayoutStateToFillStart(mAnchorInfo); mLayoutState.mExtra = extraForStart; mLayoutState.mCurrentPosition += mLayoutState.mItemDirection; fill(recycler, mLayoutState, state, false); startOffset = mLayoutState.mOffset; if (mLayoutState.mAvailable > 0) { extraForEnd = mLayoutState.mAvailable; // start could not consume all it should. add more items towards end updateLayoutStateToFillEnd(lastElement, endOffset); mLayoutState.mExtra = extraForEnd; fill(recycler, mLayoutState, state, false); endOffset = mLayoutState.mOffset; } } // changes may cause gaps on the UI, try to fix them. // TODO we can probably avoid this if neither stackFromEnd/reverseLayout/RTL values have // changed if (getChildCount() > 0) { // because layout from end may be changed by scroll to position // we re-calculate it. // find which side we should check for gaps. if (mShouldReverseLayout ^ mStackFromEnd) { int fixOffset = fixLayoutEndGap(endOffset, recycler, state, true); startOffset += fixOffset; endOffset += fixOffset; fixOffset = fixLayoutStartGap(startOffset, recycler, state, false); startOffset += fixOffset; endOffset += fixOffset; } else { int fixOffset = fixLayoutStartGap(startOffset, recycler, state, true); startOffset += fixOffset; endOffset += fixOffset; fixOffset = fixLayoutEndGap(endOffset, recycler, state, false); startOffset += fixOffset; endOffset += fixOffset; } } layoutForPredictiveAnimations(recycler, state, startOffset, endOffset); if (!state.isPreLayout()) { mOrientationHelper.onLayoutComplete(); } else { mAnchorInfo.reset(); } mLastStackFromEnd = mStackFromEnd; if (DEBUG) { validateChildOrder(); } } @Override public void onLayoutCompleted(RecyclerView.State state) { super.onLayoutCompleted(state); mPendingSavedState = null; // we don't need this anymore mPendingScrollPosition = NO_POSITION; mPendingScrollPositionOffset = INVALID_OFFSET; mAnchorInfo.reset(); } /** * Method called when Anchor position is decided. Extending class can setup accordingly or * even update anchor info if necessary. * @param recycler The recycler for the layout * @param state The layout state * @param anchorInfo The mutable POJO that keeps the position and offset. * @param firstLayoutItemDirection The direction of the first layout filling in terms of adapter * indices. */ void onAnchorReady(RecyclerView.Recycler recycler, RecyclerView.State state, AnchorInfo anchorInfo, int firstLayoutItemDirection) { } /** * If necessary, layouts new items for predictive animations */ private void layoutForPredictiveAnimations(RecyclerView.Recycler recycler, RecyclerView.State state, int startOffset, int endOffset) { // If there are scrap children that we did not layout, we need to find where they did go // and layout them accordingly so that animations can work as expected. // This case may happen if new views are added or an existing view expands and pushes // another view out of bounds. if (!state.willRunPredictiveAnimations() || getChildCount() == 0 || state.isPreLayout() || !supportsPredictiveItemAnimations()) { return; } // to make the logic simpler, we calculate the size of children and call fill. int scrapExtraStart = 0, scrapExtraEnd = 0; final List* If a child has focus, it is given priority. */ private boolean updateAnchorFromChildren(RecyclerView.Recycler recycler, RecyclerView.State state, AnchorInfo anchorInfo) { if (getChildCount() == 0) { return false; } final View focused = getFocusedChild(); if (focused != null && anchorInfo.isViewValidAsAnchor(focused, state)) { anchorInfo.assignFromViewAndKeepVisibleRect(focused); return true; } if (mLastStackFromEnd != mStackFromEnd) { return false; } View referenceChild = anchorInfo.mLayoutFromEnd ? findReferenceChildClosestToEnd(recycler, state) : findReferenceChildClosestToStart(recycler, state); if (referenceChild != null) { anchorInfo.assignFromView(referenceChild); // If all visible views are removed in 1 pass, reference child might be out of bounds. // If that is the case, offset it back to 0 so that we use these pre-layout children. if (!state.isPreLayout() && supportsPredictiveItemAnimations()) { // validate this child is at least partially visible. if not, offset it to start final boolean notVisible = mOrientationHelper.getDecoratedStart(referenceChild) >= mOrientationHelper .getEndAfterPadding() || mOrientationHelper.getDecoratedEnd(referenceChild) < mOrientationHelper.getStartAfterPadding(); if (notVisible) { anchorInfo.mCoordinate = anchorInfo.mLayoutFromEnd ? mOrientationHelper.getEndAfterPadding() : mOrientationHelper.getStartAfterPadding(); } } return true; } return false; } /** * If there is a pending scroll position or saved states, updates the anchor info from that * data and returns true */ private boolean updateAnchorFromPendingData(RecyclerView.State state, AnchorInfo anchorInfo) { if (state.isPreLayout() || mPendingScrollPosition == NO_POSITION) { return false; } // validate scroll position if (mPendingScrollPosition < 0 || mPendingScrollPosition >= state.getItemCount()) { mPendingScrollPosition = NO_POSITION; mPendingScrollPositionOffset = INVALID_OFFSET; if (DEBUG) { Log.e(TAG, "ignoring invalid scroll position " + mPendingScrollPosition); } return false; } // if child is visible, try to make it a reference child and ensure it is fully visible. // if child is not visible, align it depending on its virtual position. anchorInfo.mPosition = mPendingScrollPosition; if (mPendingSavedState != null && mPendingSavedState.hasValidAnchor()) { // Anchor offset depends on how that child was laid out. Here, we update it // according to our current view bounds anchorInfo.mLayoutFromEnd = mPendingSavedState.mAnchorLayoutFromEnd; if (anchorInfo.mLayoutFromEnd) { anchorInfo.mCoordinate = mOrientationHelper.getEndAfterPadding() - mPendingSavedState.mAnchorOffset; } else { anchorInfo.mCoordinate = mOrientationHelper.getStartAfterPadding() + mPendingSavedState.mAnchorOffset; } return true; } if (mPendingScrollPositionOffset == INVALID_OFFSET) { View child = findViewByPosition(mPendingScrollPosition); if (child != null) { final int childSize = mOrientationHelper.getDecoratedMeasurement(child); if (childSize > mOrientationHelper.getTotalSpace()) { // item does not fit. fix depending on layout direction anchorInfo.assignCoordinateFromPadding(); return true; } final int startGap = mOrientationHelper.getDecoratedStart(child) - mOrientationHelper.getStartAfterPadding(); if (startGap < 0) { anchorInfo.mCoordinate = mOrientationHelper.getStartAfterPadding(); anchorInfo.mLayoutFromEnd = false; return true; } final int endGap = mOrientationHelper.getEndAfterPadding() - mOrientationHelper.getDecoratedEnd(child); if (endGap < 0) { anchorInfo.mCoordinate = mOrientationHelper.getEndAfterPadding(); anchorInfo.mLayoutFromEnd = true; return true; } anchorInfo.mCoordinate = anchorInfo.mLayoutFromEnd ? (mOrientationHelper.getDecoratedEnd(child) + mOrientationHelper .getTotalSpaceChange()) : mOrientationHelper.getDecoratedStart(child); } else { // item is not visible. if (getChildCount() > 0) { // get position of any child, does not matter int pos = getPosition(getChildAt(0)); anchorInfo.mLayoutFromEnd = mPendingScrollPosition < pos == mShouldReverseLayout; } anchorInfo.assignCoordinateFromPadding(); } return true; } // override layout from end values for consistency anchorInfo.mLayoutFromEnd = mShouldReverseLayout; // if this changes, we should update prepareForDrop as well if (mShouldReverseLayout) { anchorInfo.mCoordinate = mOrientationHelper.getEndAfterPadding() - mPendingScrollPositionOffset; } else { anchorInfo.mCoordinate = mOrientationHelper.getStartAfterPadding() + mPendingScrollPositionOffset; } return true; } /** * @return The final offset amount for children */ private int fixLayoutEndGap(int endOffset, RecyclerView.Recycler recycler, RecyclerView.State state, boolean canOffsetChildren) { int gap = mOrientationHelper.getEndAfterPadding() - endOffset; int fixOffset = 0; if (gap > 0) { fixOffset = -scrollBy(-gap, recycler, state); } else { return 0; // nothing to fix } // move offset according to scroll amount endOffset += fixOffset; if (canOffsetChildren) { // re-calculate gap, see if we could fix it gap = mOrientationHelper.getEndAfterPadding() - endOffset; if (gap > 0) { mOrientationHelper.offsetChildren(gap); return gap + fixOffset; } } return fixOffset; } /** * @return The final offset amount for children */ private int fixLayoutStartGap(int startOffset, RecyclerView.Recycler recycler, RecyclerView.State state, boolean canOffsetChildren) { int gap = startOffset - mOrientationHelper.getStartAfterPadding(); int fixOffset = 0; if (gap > 0) { // check if we should fix this gap. fixOffset = -scrollBy(gap, recycler, state); } else { return 0; // nothing to fix } startOffset += fixOffset; if (canOffsetChildren) { // re-calculate gap, see if we could fix it gap = startOffset - mOrientationHelper.getStartAfterPadding(); if (gap > 0) { mOrientationHelper.offsetChildren(-gap); return fixOffset - gap; } } return fixOffset; } private void updateLayoutStateToFillEnd(AnchorInfo anchorInfo) { updateLayoutStateToFillEnd(anchorInfo.mPosition, anchorInfo.mCoordinate); } private void updateLayoutStateToFillEnd(int itemPosition, int offset) { mLayoutState.mAvailable = mOrientationHelper.getEndAfterPadding() - offset; mLayoutState.mItemDirection = mShouldReverseLayout ? LayoutState.ITEM_DIRECTION_HEAD : LayoutState.ITEM_DIRECTION_TAIL; mLayoutState.mCurrentPosition = itemPosition; mLayoutState.mLayoutDirection = LayoutState.LAYOUT_END; mLayoutState.mOffset = offset; mLayoutState.mScrollingOffset = LayoutState.SCOLLING_OFFSET_NaN; } private void updateLayoutStateToFillStart(AnchorInfo anchorInfo) { updateLayoutStateToFillStart(anchorInfo.mPosition, anchorInfo.mCoordinate); } private void updateLayoutStateToFillStart(int itemPosition, int offset) { mLayoutState.mAvailable = offset - mOrientationHelper.getStartAfterPadding(); mLayoutState.mCurrentPosition = itemPosition; mLayoutState.mItemDirection = mShouldReverseLayout ? LayoutState.ITEM_DIRECTION_TAIL : LayoutState.ITEM_DIRECTION_HEAD; mLayoutState.mLayoutDirection = LayoutState.LAYOUT_START; mLayoutState.mOffset = offset; mLayoutState.mScrollingOffset = LayoutState.SCOLLING_OFFSET_NaN; } protected boolean isLayoutRTL() { return getLayoutDirection() == ViewCompat.LAYOUT_DIRECTION_RTL; } void ensureLayoutState() { if (mLayoutState == null) { mLayoutState = createLayoutState(); } if (mOrientationHelper == null) { mOrientationHelper = OrientationHelper.createOrientationHelper(this, mOrientation); } } /** * Test overrides this to plug some tracking and verification. * * @return A new LayoutState */ LayoutState createLayoutState() { return new LayoutState(); } /** *
Scroll the RecyclerView to make the position visible.
* *RecyclerView will scroll the minimum amount that is necessary to make the * target position visible. If you are looking for a similar behavior to * {@link android.widget.ListView#setSelection(int)} or * {@link android.widget.ListView#setSelectionFromTop(int, int)}, use * {@link #scrollToPositionWithOffset(int, int)}.
* *Note that scroll position change will not be reflected until the next layout call.
* * @param position Scroll to this adapter position * @see #scrollToPositionWithOffset(int, int) */ @Override public void scrollToPosition(int position) { mPendingScrollPosition = position; mPendingScrollPositionOffset = INVALID_OFFSET; if (mPendingSavedState != null) { mPendingSavedState.invalidateAnchor(); } requestLayout(); } /** * Scroll to the specified adapter position with the given offset from resolved layout * start. Resolved layout start depends on {@link #getReverseLayout()}, * {@link ViewCompat#getLayoutDirection(android.view.View)} and {@link #getStackFromEnd()}. *
* For example, if layout is {@link #VERTICAL} and {@link #getStackFromEnd()} is true, calling
* scrollToPositionWithOffset(10, 20)
will layout such that
* item[10]
's bottom is 20 pixels above the RecyclerView's bottom.
*
* Note that scroll position change will not be reflected until the next layout call. *
* If you are just trying to make a position visible, use {@link #scrollToPosition(int)}. * * @param position Index (starting at 0) of the reference item. * @param offset The distance (in pixels) between the start edge of the item view and * start edge of the RecyclerView. * @see #setReverseLayout(boolean) * @see #scrollToPosition(int) */ public void scrollToPositionWithOffset(int position, int offset) { mPendingScrollPosition = position; mPendingScrollPositionOffset = offset; if (mPendingSavedState != null) { mPendingSavedState.invalidateAnchor(); } requestLayout(); } /** * {@inheritDoc} */ @Override public int scrollHorizontallyBy(int dx, RecyclerView.Recycler recycler, RecyclerView.State state) { if (mOrientation == VERTICAL) { return 0; } return scrollBy(dx, recycler, state); } /** * {@inheritDoc} */ @Override public int scrollVerticallyBy(int dy, RecyclerView.Recycler recycler, RecyclerView.State state) { if (mOrientation == HORIZONTAL) { return 0; } return scrollBy(dy, recycler, state); } @Override public int computeHorizontalScrollOffset(RecyclerView.State state) { return computeScrollOffset(state); } @Override public int computeVerticalScrollOffset(RecyclerView.State state) { return computeScrollOffset(state); } @Override public int computeHorizontalScrollExtent(RecyclerView.State state) { return computeScrollExtent(state); } @Override public int computeVerticalScrollExtent(RecyclerView.State state) { return computeScrollExtent(state); } @Override public int computeHorizontalScrollRange(RecyclerView.State state) { return computeScrollRange(state); } @Override public int computeVerticalScrollRange(RecyclerView.State state) { return computeScrollRange(state); } private int computeScrollOffset(RecyclerView.State state) { if (getChildCount() == 0) { return 0; } ensureLayoutState(); return ScrollbarHelper.computeScrollOffset(state, mOrientationHelper, findFirstVisibleChildClosestToStart(!mSmoothScrollbarEnabled, true), findFirstVisibleChildClosestToEnd(!mSmoothScrollbarEnabled, true), this, mSmoothScrollbarEnabled, mShouldReverseLayout); } private int computeScrollExtent(RecyclerView.State state) { if (getChildCount() == 0) { return 0; } ensureLayoutState(); return ScrollbarHelper.computeScrollExtent(state, mOrientationHelper, findFirstVisibleChildClosestToStart(!mSmoothScrollbarEnabled, true), findFirstVisibleChildClosestToEnd(!mSmoothScrollbarEnabled, true), this, mSmoothScrollbarEnabled); } private int computeScrollRange(RecyclerView.State state) { if (getChildCount() == 0) { return 0; } ensureLayoutState(); return ScrollbarHelper.computeScrollRange(state, mOrientationHelper, findFirstVisibleChildClosestToStart(!mSmoothScrollbarEnabled, true), findFirstVisibleChildClosestToEnd(!mSmoothScrollbarEnabled, true), this, mSmoothScrollbarEnabled); } /** * When smooth scrollbar is enabled, the position and size of the scrollbar thumb is computed * based on the number of visible pixels in the visible items. This however assumes that all * list items have similar or equal widths or heights (depending on list orientation). * If you use a list in which items have different dimensions, the scrollbar will change * appearance as the user scrolls through the list. To avoid this issue, you need to disable * this property. * * When smooth scrollbar is disabled, the position and size of the scrollbar thumb is based * solely on the number of items in the adapter and the position of the visible items inside * the adapter. This provides a stable scrollbar as the user navigates through a list of items * with varying widths / heights. * * @param enabled Whether or not to enable smooth scrollbar. * * @see #setSmoothScrollbarEnabled(boolean) */ public void setSmoothScrollbarEnabled(boolean enabled) { mSmoothScrollbarEnabled = enabled; } /** * Returns the current state of the smooth scrollbar feature. It is enabled by default. * * @return True if smooth scrollbar is enabled, false otherwise. * * @see #setSmoothScrollbarEnabled(boolean) */ public boolean isSmoothScrollbarEnabled() { return mSmoothScrollbarEnabled; } private void updateLayoutState(int layoutDirection, int requiredSpace, boolean canUseExistingSpace, RecyclerView.State state) { // If parent provides a hint, don't measure unlimited. mLayoutState.mInfinite = resolveIsInfinite(); mLayoutState.mExtra = getExtraLayoutSpace(state); mLayoutState.mLayoutDirection = layoutDirection; int scrollingOffset; if (layoutDirection == LayoutState.LAYOUT_END) { mLayoutState.mExtra += mOrientationHelper.getEndPadding(); // get the first child in the direction we are going final View child = getChildClosestToEnd(); // the direction in which we are traversing children mLayoutState.mItemDirection = mShouldReverseLayout ? LayoutState.ITEM_DIRECTION_HEAD : LayoutState.ITEM_DIRECTION_TAIL; mLayoutState.mCurrentPosition = getPosition(child) + mLayoutState.mItemDirection; mLayoutState.mOffset = mOrientationHelper.getDecoratedEnd(child); // calculate how much we can scroll without adding new children (independent of layout) scrollingOffset = mOrientationHelper.getDecoratedEnd(child) - mOrientationHelper.getEndAfterPadding(); } else { final View child = getChildClosestToStart(); mLayoutState.mExtra += mOrientationHelper.getStartAfterPadding(); mLayoutState.mItemDirection = mShouldReverseLayout ? LayoutState.ITEM_DIRECTION_TAIL : LayoutState.ITEM_DIRECTION_HEAD; mLayoutState.mCurrentPosition = getPosition(child) + mLayoutState.mItemDirection; mLayoutState.mOffset = mOrientationHelper.getDecoratedStart(child); scrollingOffset = -mOrientationHelper.getDecoratedStart(child) + mOrientationHelper.getStartAfterPadding(); } mLayoutState.mAvailable = requiredSpace; if (canUseExistingSpace) { mLayoutState.mAvailable -= scrollingOffset; } mLayoutState.mScrollingOffset = scrollingOffset; } boolean resolveIsInfinite() { return mOrientationHelper.getMode() == View.MeasureSpec.UNSPECIFIED && mOrientationHelper.getEnd() == 0; } int scrollBy(int dy, RecyclerView.Recycler recycler, RecyclerView.State state) { if (getChildCount() == 0 || dy == 0) { return 0; } mLayoutState.mRecycle = true; ensureLayoutState(); final int layoutDirection = dy > 0 ? LayoutState.LAYOUT_END : LayoutState.LAYOUT_START; final int absDy = Math.abs(dy); updateLayoutState(layoutDirection, absDy, true, state); final int consumed = mLayoutState.mScrollingOffset + fill(recycler, mLayoutState, state, false); if (consumed < 0) { if (DEBUG) { Log.d(TAG, "Don't have any more elements to scroll"); } return 0; } final int scrolled = absDy > consumed ? layoutDirection * consumed : dy; mOrientationHelper.offsetChildren(-scrolled); if (DEBUG) { Log.d(TAG, "scroll req: " + dy + " scrolled: " + scrolled); } mLayoutState.mLastScrollDelta = scrolled; return scrolled; } @Override public void assertNotInLayoutOrScroll(String message) { if (mPendingSavedState == null) { super.assertNotInLayoutOrScroll(message); } } /** * Recycles children between given indices. * * @param startIndex inclusive * @param endIndex exclusive */ private void recycleChildren(RecyclerView.Recycler recycler, int startIndex, int endIndex) { if (startIndex == endIndex) { return; } if (DEBUG) { Log.d(TAG, "Recycling " + Math.abs(startIndex - endIndex) + " items"); } if (endIndex > startIndex) { for (int i = endIndex - 1; i >= startIndex; i--) { removeAndRecycleViewAt(i, recycler); } } else { for (int i = startIndex; i > endIndex; i--) { removeAndRecycleViewAt(i, recycler); } } } /** * Recycles views that went out of bounds after scrolling towards the end of the layout. *
* Checks both layout position and visible position to guarantee that the view is not visible. * * @param recycler Recycler instance of {@link android.support.v7.widget.RecyclerView} * @param dt This can be used to add additional padding to the visible area. This is used * to detect children that will go out of bounds after scrolling, without * actually moving them. */ private void recycleViewsFromStart(RecyclerView.Recycler recycler, int dt) { if (dt < 0) { if (DEBUG) { Log.d(TAG, "Called recycle from start with a negative value. This might happen" + " during layout changes but may be sign of a bug"); } return; } // ignore padding, ViewGroup may not clip children. final int limit = dt; final int childCount = getChildCount(); if (mShouldReverseLayout) { for (int i = childCount - 1; i >= 0; i--) { View child = getChildAt(i); if (mOrientationHelper.getDecoratedEnd(child) > limit || mOrientationHelper.getTransformedEndWithDecoration(child) > limit) { // stop here recycleChildren(recycler, childCount - 1, i); return; } } } else { for (int i = 0; i < childCount; i++) { View child = getChildAt(i); if (mOrientationHelper.getDecoratedEnd(child) > limit || mOrientationHelper.getTransformedEndWithDecoration(child) > limit) { // stop here recycleChildren(recycler, 0, i); return; } } } } /** * Recycles views that went out of bounds after scrolling towards the start of the layout. *
* Checks both layout position and visible position to guarantee that the view is not visible. * * @param recycler Recycler instance of {@link android.support.v7.widget.RecyclerView} * @param dt This can be used to add additional padding to the visible area. This is used * to detect children that will go out of bounds after scrolling, without * actually moving them. */ private void recycleViewsFromEnd(RecyclerView.Recycler recycler, int dt) { final int childCount = getChildCount(); if (dt < 0) { if (DEBUG) { Log.d(TAG, "Called recycle from end with a negative value. This might happen" + " during layout changes but may be sign of a bug"); } return; } final int limit = mOrientationHelper.getEnd() - dt; if (mShouldReverseLayout) { for (int i = 0; i < childCount; i++) { View child = getChildAt(i); if (mOrientationHelper.getDecoratedStart(child) < limit || mOrientationHelper.getTransformedStartWithDecoration(child) < limit) { // stop here recycleChildren(recycler, 0, i); return; } } } else { for (int i = childCount - 1; i >= 0; i--) { View child = getChildAt(i); if (mOrientationHelper.getDecoratedStart(child) < limit || mOrientationHelper.getTransformedStartWithDecoration(child) < limit) { // stop here recycleChildren(recycler, childCount - 1, i); return; } } } } /** * Helper method to call appropriate recycle method depending on current layout direction * * @param recycler Current recycler that is attached to RecyclerView * @param layoutState Current layout state. Right now, this object does not change but * we may consider moving it out of this view so passing around as a * parameter for now, rather than accessing {@link #mLayoutState} * @see #recycleViewsFromStart(android.support.v7.widget.RecyclerView.Recycler, int) * @see #recycleViewsFromEnd(android.support.v7.widget.RecyclerView.Recycler, int) * @see android.support.v7.widget.LinearLayoutManager.LayoutState#mLayoutDirection */ private void recycleByLayoutState(RecyclerView.Recycler recycler, LayoutState layoutState) { if (!layoutState.mRecycle || layoutState.mInfinite) { return; } if (layoutState.mLayoutDirection == LayoutState.LAYOUT_START) { recycleViewsFromEnd(recycler, layoutState.mScrollingOffset); } else { recycleViewsFromStart(recycler, layoutState.mScrollingOffset); } } /** * The magic functions :). Fills the given layout, defined by the layoutState. This is fairly * independent from the rest of the {@link android.support.v7.widget.LinearLayoutManager} * and with little change, can be made publicly available as a helper class. * * @param recycler Current recycler that is attached to RecyclerView * @param layoutState Configuration on how we should fill out the available space. * @param state Context passed by the RecyclerView to control scroll steps. * @param stopOnFocusable If true, filling stops in the first focusable new child * @return Number of pixels that it added. Useful for scoll functions. */ int fill(RecyclerView.Recycler recycler, LayoutState layoutState, RecyclerView.State state, boolean stopOnFocusable) { // max offset we should set is mFastScroll + available final int start = layoutState.mAvailable; if (layoutState.mScrollingOffset != LayoutState.SCOLLING_OFFSET_NaN) { // TODO ugly bug fix. should not happen if (layoutState.mAvailable < 0) { layoutState.mScrollingOffset += layoutState.mAvailable; } recycleByLayoutState(recycler, layoutState); } int remainingSpace = layoutState.mAvailable + layoutState.mExtra; LayoutChunkResult layoutChunkResult = new LayoutChunkResult(); while ((layoutState.mInfinite || remainingSpace > 0) && layoutState.hasMore(state)) { layoutChunkResult.resetInternal(); layoutChunk(recycler, state, layoutState, layoutChunkResult); if (layoutChunkResult.mFinished) { break; } layoutState.mOffset += layoutChunkResult.mConsumed * layoutState.mLayoutDirection; /** * Consume the available space if: * * layoutChunk did not request to be ignored * * OR we are laying out scrap children * * OR we are not doing pre-layout */ if (!layoutChunkResult.mIgnoreConsumed || mLayoutState.mScrapList != null || !state.isPreLayout()) { layoutState.mAvailable -= layoutChunkResult.mConsumed; // we keep a separate remaining space because mAvailable is important for recycling remainingSpace -= layoutChunkResult.mConsumed; } if (layoutState.mScrollingOffset != LayoutState.SCOLLING_OFFSET_NaN) { layoutState.mScrollingOffset += layoutChunkResult.mConsumed; if (layoutState.mAvailable < 0) { layoutState.mScrollingOffset += layoutState.mAvailable; } recycleByLayoutState(recycler, layoutState); } if (stopOnFocusable && layoutChunkResult.mFocusable) { break; } } if (DEBUG) { validateChildOrder(); } return start - layoutState.mAvailable; } void layoutChunk(RecyclerView.Recycler recycler, RecyclerView.State state, LayoutState layoutState, LayoutChunkResult result) { View view = layoutState.next(recycler); if (view == null) { if (DEBUG && layoutState.mScrapList == null) { throw new RuntimeException("received null view when unexpected"); } // if we are laying out views in scrap, this may return null which means there is // no more items to layout. result.mFinished = true; return; } LayoutParams params = (LayoutParams) view.getLayoutParams(); if (layoutState.mScrapList == null) { if (mShouldReverseLayout == (layoutState.mLayoutDirection == LayoutState.LAYOUT_START)) { addView(view); } else { addView(view, 0); } } else { if (mShouldReverseLayout == (layoutState.mLayoutDirection == LayoutState.LAYOUT_START)) { addDisappearingView(view); } else { addDisappearingView(view, 0); } } measureChildWithMargins(view, 0, 0); result.mConsumed = mOrientationHelper.getDecoratedMeasurement(view); int left, top, right, bottom; if (mOrientation == VERTICAL) { if (isLayoutRTL()) { right = getWidth() - getPaddingRight(); left = right - mOrientationHelper.getDecoratedMeasurementInOther(view); } else { left = getPaddingLeft(); right = left + mOrientationHelper.getDecoratedMeasurementInOther(view); } if (layoutState.mLayoutDirection == LayoutState.LAYOUT_START) { bottom = layoutState.mOffset; top = layoutState.mOffset - result.mConsumed; } else { top = layoutState.mOffset; bottom = layoutState.mOffset + result.mConsumed; } } else { top = getPaddingTop(); bottom = top + mOrientationHelper.getDecoratedMeasurementInOther(view); if (layoutState.mLayoutDirection == LayoutState.LAYOUT_START) { right = layoutState.mOffset; left = layoutState.mOffset - result.mConsumed; } else { left = layoutState.mOffset; right = layoutState.mOffset + result.mConsumed; } } // We calculate everything with View's bounding box (which includes decor and margins) // To calculate correct layout position, we subtract margins. layoutDecoratedWithMargins(view, left, top, right, bottom); if (DEBUG) { Log.d(TAG, "laid out child at position " + getPosition(view) + ", with l:" + (left + params.leftMargin) + ", t:" + (top + params.topMargin) + ", r:" + (right - params.rightMargin) + ", b:" + (bottom - params.bottomMargin)); } // Consume the available space if the view is not removed OR changed if (params.isItemRemoved() || params.isItemChanged()) { result.mIgnoreConsumed = true; } result.mFocusable = view.isFocusable(); } @Override boolean shouldMeasureTwice() { return getHeightMode() != View.MeasureSpec.EXACTLY && getWidthMode() != View.MeasureSpec.EXACTLY && hasFlexibleChildInBothOrientations(); } /** * Converts a focusDirection to orientation. * * @param focusDirection One of {@link View#FOCUS_UP}, {@link View#FOCUS_DOWN}, * {@link View#FOCUS_LEFT}, {@link View#FOCUS_RIGHT}, * {@link View#FOCUS_BACKWARD}, {@link View#FOCUS_FORWARD} * or 0 for not applicable * @return {@link LayoutState#LAYOUT_START} or {@link LayoutState#LAYOUT_END} if focus direction * is applicable to current state, {@link LayoutState#INVALID_LAYOUT} otherwise. */ int convertFocusDirectionToLayoutDirection(int focusDirection) { switch (focusDirection) { case View.FOCUS_BACKWARD: if (mOrientation == VERTICAL) { return LayoutState.LAYOUT_START; } else if (isLayoutRTL()) { return LayoutState.LAYOUT_END; } else { return LayoutState.LAYOUT_START; } case View.FOCUS_FORWARD: if (mOrientation == VERTICAL) { return LayoutState.LAYOUT_END; } else if (isLayoutRTL()) { return LayoutState.LAYOUT_START; } else { return LayoutState.LAYOUT_END; } case View.FOCUS_UP: return mOrientation == VERTICAL ? LayoutState.LAYOUT_START : LayoutState.INVALID_LAYOUT; case View.FOCUS_DOWN: return mOrientation == VERTICAL ? LayoutState.LAYOUT_END : LayoutState.INVALID_LAYOUT; case View.FOCUS_LEFT: return mOrientation == HORIZONTAL ? LayoutState.LAYOUT_START : LayoutState.INVALID_LAYOUT; case View.FOCUS_RIGHT: return mOrientation == HORIZONTAL ? LayoutState.LAYOUT_END : LayoutState.INVALID_LAYOUT; default: if (DEBUG) { Log.d(TAG, "Unknown focus request:" + focusDirection); } return LayoutState.INVALID_LAYOUT; } } /** * Convenience method to find the child closes to start. Caller should check it has enough * children. * * @return The child closes to start of the layout from user's perspective. */ private View getChildClosestToStart() { return getChildAt(mShouldReverseLayout ? getChildCount() - 1 : 0); } /** * Convenience method to find the child closes to end. Caller should check it has enough * children. * * @return The child closes to end of the layout from user's perspective. */ private View getChildClosestToEnd() { return getChildAt(mShouldReverseLayout ? 0 : getChildCount() - 1); } /** * Convenience method to find the visible child closes to start. Caller should check if it has * enough children. * * @param completelyVisible Whether child should be completely visible or not * @return The first visible child closest to start of the layout from user's perspective. */ private View findFirstVisibleChildClosestToStart(boolean completelyVisible, boolean acceptPartiallyVisible) { if (mShouldReverseLayout) { return findOneVisibleChild(getChildCount() - 1, -1, completelyVisible, acceptPartiallyVisible); } else { return findOneVisibleChild(0, getChildCount(), completelyVisible, acceptPartiallyVisible); } } /** * Convenience method to find the visible child closes to end. Caller should check if it has * enough children. * * @param completelyVisible Whether child should be completely visible or not * @return The first visible child closest to end of the layout from user's perspective. */ private View findFirstVisibleChildClosestToEnd(boolean completelyVisible, boolean acceptPartiallyVisible) { if (mShouldReverseLayout) { return findOneVisibleChild(0, getChildCount(), completelyVisible, acceptPartiallyVisible); } else { return findOneVisibleChild(getChildCount() - 1, -1, completelyVisible, acceptPartiallyVisible); } } /** * Among the children that are suitable to be considered as an anchor child, returns the one * closest to the end of the layout. *
* Due to ambiguous adapter updates or children being removed, some children's positions may be * invalid. This method is a best effort to find a position within adapter bounds if possible. *
* It also prioritizes children that are within the visible bounds. * @return A View that can be used an an anchor View. */ private View findReferenceChildClosestToEnd(RecyclerView.Recycler recycler, RecyclerView.State state) { return mShouldReverseLayout ? findFirstReferenceChild(recycler, state) : findLastReferenceChild(recycler, state); } /** * Among the children that are suitable to be considered as an anchor child, returns the one * closest to the start of the layout. *
* Due to ambiguous adapter updates or children being removed, some children's positions may be * invalid. This method is a best effort to find a position within adapter bounds if possible. *
* It also prioritizes children that are within the visible bounds. * * @return A View that can be used an an anchor View. */ private View findReferenceChildClosestToStart(RecyclerView.Recycler recycler, RecyclerView.State state) { return mShouldReverseLayout ? findLastReferenceChild(recycler, state) : findFirstReferenceChild(recycler, state); } private View findFirstReferenceChild(RecyclerView.Recycler recycler, RecyclerView.State state) { return findReferenceChild(recycler, state, 0, getChildCount(), state.getItemCount()); } private View findLastReferenceChild(RecyclerView.Recycler recycler, RecyclerView.State state) { return findReferenceChild(recycler, state, getChildCount() - 1, -1, state.getItemCount()); } // overridden by GridLayoutManager View findReferenceChild(RecyclerView.Recycler recycler, RecyclerView.State state, int start, int end, int itemCount) { ensureLayoutState(); View invalidMatch = null; View outOfBoundsMatch = null; final int boundsStart = mOrientationHelper.getStartAfterPadding(); final int boundsEnd = mOrientationHelper.getEndAfterPadding(); final int diff = end > start ? 1 : -1; for (int i = start; i != end; i += diff) { final View view = getChildAt(i); final int position = getPosition(view); if (position >= 0 && position < itemCount) { if (((LayoutParams) view.getLayoutParams()).isItemRemoved()) { if (invalidMatch == null) { invalidMatch = view; // removed item, least preferred } } else if (mOrientationHelper.getDecoratedStart(view) >= boundsEnd || mOrientationHelper.getDecoratedEnd(view) < boundsStart) { if (outOfBoundsMatch == null) { outOfBoundsMatch = view; // item is not visible, less preferred } } else { return view; } } } return outOfBoundsMatch != null ? outOfBoundsMatch : invalidMatch; } /** * Returns the adapter position of the first visible view. This position does not include * adapter changes that were dispatched after the last layout pass. *
* Note that, this value is not affected by layout orientation or item order traversal. * ({@link #setReverseLayout(boolean)}). Views are sorted by their positions in the adapter, * not in the layout. *
* If RecyclerView has item decorators, they will be considered in calculations as well. *
* LayoutManager may pre-cache some views that are not necessarily visible. Those views * are ignored in this method. * * @return The adapter position of the first visible item or {@link RecyclerView#NO_POSITION} if * there aren't any visible items. * @see #findFirstCompletelyVisibleItemPosition() * @see #findLastVisibleItemPosition() */ public int findFirstVisibleItemPosition() { final View child = findOneVisibleChild(0, getChildCount(), false, true); return child == null ? NO_POSITION : getPosition(child); } /** * Returns the adapter position of the first fully visible view. This position does not include * adapter changes that were dispatched after the last layout pass. *
* Note that bounds check is only performed in the current orientation. That means, if * LayoutManager is horizontal, it will only check the view's left and right edges. * * @return The adapter position of the first fully visible item or * {@link RecyclerView#NO_POSITION} if there aren't any visible items. * @see #findFirstVisibleItemPosition() * @see #findLastCompletelyVisibleItemPosition() */ public int findFirstCompletelyVisibleItemPosition() { final View child = findOneVisibleChild(0, getChildCount(), true, false); return child == null ? NO_POSITION : getPosition(child); } /** * Returns the adapter position of the last visible view. This position does not include * adapter changes that were dispatched after the last layout pass. *
* Note that, this value is not affected by layout orientation or item order traversal. * ({@link #setReverseLayout(boolean)}). Views are sorted by their positions in the adapter, * not in the layout. *
* If RecyclerView has item decorators, they will be considered in calculations as well. *
* LayoutManager may pre-cache some views that are not necessarily visible. Those views * are ignored in this method. * * @return The adapter position of the last visible view or {@link RecyclerView#NO_POSITION} if * there aren't any visible items. * @see #findLastCompletelyVisibleItemPosition() * @see #findFirstVisibleItemPosition() */ public int findLastVisibleItemPosition() { final View child = findOneVisibleChild(getChildCount() - 1, -1, false, true); return child == null ? NO_POSITION : getPosition(child); } /** * Returns the adapter position of the last fully visible view. This position does not include * adapter changes that were dispatched after the last layout pass. *
* Note that bounds check is only performed in the current orientation. That means, if
* LayoutManager is horizontal, it will only check the view's left and right edges.
*
* @return The adapter position of the last fully visible view or
* {@link RecyclerView#NO_POSITION} if there aren't any visible items.
* @see #findLastVisibleItemPosition()
* @see #findFirstCompletelyVisibleItemPosition()
*/
public int findLastCompletelyVisibleItemPosition() {
final View child = findOneVisibleChild(getChildCount() - 1, -1, true, false);
return child == null ? NO_POSITION : getPosition(child);
}
View findOneVisibleChild(int fromIndex, int toIndex, boolean completelyVisible,
boolean acceptPartiallyVisible) {
ensureLayoutState();
final int start = mOrientationHelper.getStartAfterPadding();
final int end = mOrientationHelper.getEndAfterPadding();
final int next = toIndex > fromIndex ? 1 : -1;
View partiallyVisible = null;
for (int i = fromIndex; i != toIndex; i+=next) {
final View child = getChildAt(i);
final int childStart = mOrientationHelper.getDecoratedStart(child);
final int childEnd = mOrientationHelper.getDecoratedEnd(child);
if (childStart < end && childEnd > start) {
if (completelyVisible) {
if (childStart >= start && childEnd <= end) {
return child;
} else if (acceptPartiallyVisible && partiallyVisible == null) {
partiallyVisible = child;
}
} else {
return child;
}
}
}
return partiallyVisible;
}
@Override
public View onFocusSearchFailed(View focused, int focusDirection,
RecyclerView.Recycler recycler, RecyclerView.State state) {
resolveShouldLayoutReverse();
if (getChildCount() == 0) {
return null;
}
final int layoutDir = convertFocusDirectionToLayoutDirection(focusDirection);
if (layoutDir == LayoutState.INVALID_LAYOUT) {
return null;
}
ensureLayoutState();
final View referenceChild;
if (layoutDir == LayoutState.LAYOUT_START) {
referenceChild = findReferenceChildClosestToStart(recycler, state);
} else {
referenceChild = findReferenceChildClosestToEnd(recycler, state);
}
if (referenceChild == null) {
if (DEBUG) {
Log.d(TAG,
"Cannot find a child with a valid position to be used for focus search.");
}
return null;
}
ensureLayoutState();
final int maxScroll = (int) (MAX_SCROLL_FACTOR * mOrientationHelper.getTotalSpace());
updateLayoutState(layoutDir, maxScroll, false, state);
mLayoutState.mScrollingOffset = LayoutState.SCOLLING_OFFSET_NaN;
mLayoutState.mRecycle = false;
fill(recycler, mLayoutState, state, true);
final View nextFocus;
if (layoutDir == LayoutState.LAYOUT_START) {
nextFocus = getChildClosestToStart();
} else {
nextFocus = getChildClosestToEnd();
}
if (nextFocus == referenceChild || !nextFocus.isFocusable()) {
return null;
}
return nextFocus;
}
/**
* Used for debugging.
* Logs the internal representation of children to default logger.
*/
private void logChildren() {
Log.d(TAG, "internal representation of views on the screen");
for (int i = 0; i < getChildCount(); i++) {
View child = getChildAt(i);
Log.d(TAG, "item " + getPosition(child) + ", coord:"
+ mOrientationHelper.getDecoratedStart(child));
}
Log.d(TAG, "==============");
}
/**
* Used for debugging.
* Validates that child views are laid out in correct order. This is important because rest of
* the algorithm relies on this constraint.
*
* In default layout, child 0 should be closest to screen position 0 and last child should be
* closest to position WIDTH or HEIGHT.
* In reverse layout, last child should be closes to screen position 0 and first child should
* be closest to position WIDTH or HEIGHT
*/
void validateChildOrder() {
Log.d(TAG, "validating child count " + getChildCount());
if (getChildCount() < 1) {
return;
}
int lastPos = getPosition(getChildAt(0));
int lastScreenLoc = mOrientationHelper.getDecoratedStart(getChildAt(0));
if (mShouldReverseLayout) {
for (int i = 1; i < getChildCount(); i++) {
View child = getChildAt(i);
int pos = getPosition(child);
int screenLoc = mOrientationHelper.getDecoratedStart(child);
if (pos < lastPos) {
logChildren();
throw new RuntimeException("detected invalid position. loc invalid? " +
(screenLoc < lastScreenLoc));
}
if (screenLoc > lastScreenLoc) {
logChildren();
throw new RuntimeException("detected invalid location");
}
}
} else {
for (int i = 1; i < getChildCount(); i++) {
View child = getChildAt(i);
int pos = getPosition(child);
int screenLoc = mOrientationHelper.getDecoratedStart(child);
if (pos < lastPos) {
logChildren();
throw new RuntimeException("detected invalid position. loc invalid? " +
(screenLoc < lastScreenLoc));
}
if (screenLoc < lastScreenLoc) {
logChildren();
throw new RuntimeException("detected invalid location");
}
}
}
}
@Override
public boolean supportsPredictiveItemAnimations() {
return mPendingSavedState == null && mLastStackFromEnd == mStackFromEnd;
}
/**
* @hide This method should be called by ItemTouchHelper only.
*/
@Override
public void prepareForDrop(View view, View target, int x, int y) {
assertNotInLayoutOrScroll("Cannot drop a view during a scroll or layout calculation");
ensureLayoutState();
resolveShouldLayoutReverse();
final int myPos = getPosition(view);
final int targetPos = getPosition(target);
final int dropDirection = myPos < targetPos ? LayoutState.ITEM_DIRECTION_TAIL :
LayoutState.ITEM_DIRECTION_HEAD;
if (mShouldReverseLayout) {
if (dropDirection == LayoutState.ITEM_DIRECTION_TAIL) {
scrollToPositionWithOffset(targetPos,
mOrientationHelper.getEndAfterPadding() -
(mOrientationHelper.getDecoratedStart(target) +
mOrientationHelper.getDecoratedMeasurement(view)));
} else {
scrollToPositionWithOffset(targetPos,
mOrientationHelper.getEndAfterPadding() -
mOrientationHelper.getDecoratedEnd(target));
}
} else {
if (dropDirection == LayoutState.ITEM_DIRECTION_HEAD) {
scrollToPositionWithOffset(targetPos, mOrientationHelper.getDecoratedStart(target));
} else {
scrollToPositionWithOffset(targetPos,
mOrientationHelper.getDecoratedEnd(target) -
mOrientationHelper.getDecoratedMeasurement(view));
}
}
}
/**
* Helper class that keeps temporary state while {LayoutManager} is filling out the empty
* space.
*/
static class LayoutState {
final static String TAG = "LLM#LayoutState";
final static int LAYOUT_START = -1;
final static int LAYOUT_END = 1;
final static int INVALID_LAYOUT = Integer.MIN_VALUE;
final static int ITEM_DIRECTION_HEAD = -1;
final static int ITEM_DIRECTION_TAIL = 1;
final static int SCOLLING_OFFSET_NaN = Integer.MIN_VALUE;
/**
* We may not want to recycle children in some cases (e.g. layout)
*/
boolean mRecycle = true;
/**
* Pixel offset where layout should start
*/
int mOffset;
/**
* Number of pixels that we should fill, in the layout direction.
*/
int mAvailable;
/**
* Current position on the adapter to get the next item.
*/
int mCurrentPosition;
/**
* Defines the direction in which the data adapter is traversed.
* Should be {@link #ITEM_DIRECTION_HEAD} or {@link #ITEM_DIRECTION_TAIL}
*/
int mItemDirection;
/**
* Defines the direction in which the layout is filled.
* Should be {@link #LAYOUT_START} or {@link #LAYOUT_END}
*/
int mLayoutDirection;
/**
* Used when LayoutState is constructed in a scrolling state.
* It should be set the amount of scrolling we can make without creating a new view.
* Settings this is required for efficient view recycling.
*/
int mScrollingOffset;
/**
* Used if you want to pre-layout items that are not yet visible.
* The difference with {@link #mAvailable} is that, when recycling, distance laid out for
* {@link #mExtra} is not considered to avoid recycling visible children.
*/
int mExtra = 0;
/**
* Equal to {@link RecyclerView.State#isPreLayout()}. When consuming scrap, if this value
* is set to true, we skip removed views since they should not be laid out in post layout
* step.
*/
boolean mIsPreLayout = false;
/**
* The most recent {@link #scrollBy(int, RecyclerView.Recycler, RecyclerView.State)}
* amount.
*/
int mLastScrollDelta;
/**
* When LLM needs to layout particular views, it sets this list in which case, LayoutState
* will only return views from this list and return null if it cannot find an item.
*/
List
* Upon finding a valid VH, sets current item position to VH.itemPosition + mItemDirection
*
* @return View if an item in the current position or direction exists if not null.
*/
private View nextViewFromScrapList() {
final int size = mScrapList.size();
for (int i = 0; i < size; i++) {
final View view = mScrapList.get(i).itemView;
final LayoutParams lp = (LayoutParams) view.getLayoutParams();
if (lp.isItemRemoved()) {
continue;
}
if (mCurrentPosition == lp.getViewLayoutPosition()) {
assignPositionFromScrapList(view);
return view;
}
}
return null;
}
public void assignPositionFromScrapList() {
assignPositionFromScrapList(null);
}
public void assignPositionFromScrapList(View ignore) {
final View closest = nextViewInLimitedList(ignore);
if (closest == null) {
mCurrentPosition = NO_POSITION;
} else {
mCurrentPosition = ((LayoutParams) closest.getLayoutParams())
.getViewLayoutPosition();
}
}
public View nextViewInLimitedList(View ignore) {
int size = mScrapList.size();
View closest = null;
int closestDistance = Integer.MAX_VALUE;
if (DEBUG && mIsPreLayout) {
throw new IllegalStateException("Scrap list cannot be used in pre layout");
}
for (int i = 0; i < size; i++) {
View view = mScrapList.get(i).itemView;
final LayoutParams lp = (LayoutParams) view.getLayoutParams();
if (view == ignore || lp.isItemRemoved()) {
continue;
}
final int distance = (lp.getViewLayoutPosition() - mCurrentPosition) *
mItemDirection;
if (distance < 0) {
continue; // item is not in current direction
}
if (distance < closestDistance) {
closest = view;
closestDistance = distance;
if (distance == 0) {
break;
}
}
}
return closest;
}
void log() {
Log.d(TAG, "avail:" + mAvailable + ", ind:" + mCurrentPosition + ", dir:" +
mItemDirection + ", offset:" + mOffset + ", layoutDir:" + mLayoutDirection);
}
}
/**
* @hide
*/
public static class SavedState implements Parcelable {
int mAnchorPosition;
int mAnchorOffset;
boolean mAnchorLayoutFromEnd;
public SavedState() {
}
SavedState(Parcel in) {
mAnchorPosition = in.readInt();
mAnchorOffset = in.readInt();
mAnchorLayoutFromEnd = in.readInt() == 1;
}
public SavedState(SavedState other) {
mAnchorPosition = other.mAnchorPosition;
mAnchorOffset = other.mAnchorOffset;
mAnchorLayoutFromEnd = other.mAnchorLayoutFromEnd;
}
boolean hasValidAnchor() {
return mAnchorPosition >= 0;
}
void invalidateAnchor() {
mAnchorPosition = NO_POSITION;
}
@Override
public int describeContents() {
return 0;
}
@Override
public void writeToParcel(Parcel dest, int flags) {
dest.writeInt(mAnchorPosition);
dest.writeInt(mAnchorOffset);
dest.writeInt(mAnchorLayoutFromEnd ? 1 : 0);
}
public static final Parcelable.Creator