/* * Copyright (C) 2017 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.internal.widget; import android.annotation.CallSuper; import android.annotation.IntDef; import android.annotation.NonNull; import android.annotation.Nullable; import android.content.Context; import android.content.res.TypedArray; import android.database.Observable; import android.graphics.Canvas; import android.graphics.Matrix; import android.graphics.PointF; import android.graphics.Rect; import android.graphics.RectF; import android.os.Build; import android.os.Bundle; import android.os.Parcel; import android.os.Parcelable; import android.os.SystemClock; import android.os.Trace; import android.util.AttributeSet; import android.util.Log; import android.util.SparseArray; import android.util.TypedValue; import android.view.AbsSavedState; import android.view.Display; import android.view.FocusFinder; import android.view.InputDevice; import android.view.MotionEvent; import android.view.VelocityTracker; import android.view.View; import android.view.ViewConfiguration; import android.view.ViewGroup; import android.view.ViewParent; import android.view.accessibility.AccessibilityEvent; import android.view.accessibility.AccessibilityManager; import android.view.accessibility.AccessibilityNodeInfo; import android.view.animation.Interpolator; import android.widget.EdgeEffect; import android.widget.OverScroller; import com.android.internal.R; import com.android.internal.annotations.VisibleForTesting; import com.android.internal.widget.RecyclerView.ItemAnimator.ItemHolderInfo; import java.lang.annotation.Retention; import java.lang.annotation.RetentionPolicy; import java.lang.ref.WeakReference; import java.lang.reflect.Constructor; import java.lang.reflect.InvocationTargetException; import java.util.ArrayList; import java.util.Collections; import java.util.List; /** * A flexible view for providing a limited window into a large data set. * *

Glossary of terms:

* * * *

Positions in RecyclerView:

*

* RecyclerView introduces an additional level of abstraction between the {@link Adapter} and * {@link LayoutManager} to be able to detect data set changes in batches during a layout * calculation. This saves LayoutManager from tracking adapter changes to calculate animations. * It also helps with performance because all view bindings happen at the same time and unnecessary * bindings are avoided. *

* For this reason, there are two types of position related methods in RecyclerView: *

*

* These two positions are the same except the time between dispatching adapter.notify* * events and calculating the updated layout. *

* Methods that return or receive *LayoutPosition* use position as of the latest * layout calculation (e.g. {@link ViewHolder#getLayoutPosition()}, * {@link #findViewHolderForLayoutPosition(int)}). These positions include all changes until the * last layout calculation. You can rely on these positions to be consistent with what user is * currently seeing on the screen. For example, if you have a list of items on the screen and user * asks for the 5th element, you should use these methods as they'll match what user * is seeing. *

* The other set of position related methods are in the form of * *AdapterPosition*. (e.g. {@link ViewHolder#getAdapterPosition()}, * {@link #findViewHolderForAdapterPosition(int)}) You should use these methods when you need to * work with up-to-date adapter positions even if they may not have been reflected to layout yet. * For example, if you want to access the item in the adapter on a ViewHolder click, you should use * {@link ViewHolder#getAdapterPosition()}. Beware that these methods may not be able to calculate * adapter positions if {@link Adapter#notifyDataSetChanged()} has been called and new layout has * not yet been calculated. For this reasons, you should carefully handle {@link #NO_POSITION} or * null results from these methods. *

* When writing a {@link LayoutManager} you almost always want to use layout positions whereas when * writing an {@link Adapter}, you probably want to use adapter positions. */ public class RecyclerView extends ViewGroup implements ScrollingView, NestedScrollingChild { static final String TAG = "RecyclerView"; static final boolean DEBUG = false; private static final int[] NESTED_SCROLLING_ATTRS = { android.R.attr.nestedScrollingEnabled }; private static final int[] CLIP_TO_PADDING_ATTR = {android.R.attr.clipToPadding}; /** * On Kitkat and JB MR2, there is a bug which prevents DisplayList from being invalidated if * a View is two levels deep(wrt to ViewHolder.itemView). DisplayList can be invalidated by * setting View's visibility to INVISIBLE when View is detached. On Kitkat and JB MR2, Recycler * recursively traverses itemView and invalidates display list for each ViewGroup that matches * this criteria. */ static final boolean FORCE_INVALIDATE_DISPLAY_LIST = Build.VERSION.SDK_INT == 18 || Build.VERSION.SDK_INT == 19 || Build.VERSION.SDK_INT == 20; /** * On M+, an unspecified measure spec may include a hint which we can use. On older platforms, * this value might be garbage. To save LayoutManagers from it, RecyclerView sets the size to * 0 when mode is unspecified. */ static final boolean ALLOW_SIZE_IN_UNSPECIFIED_SPEC = Build.VERSION.SDK_INT >= 23; static final boolean POST_UPDATES_ON_ANIMATION = Build.VERSION.SDK_INT >= 16; /** * On L+, with RenderThread, the UI thread has idle time after it has passed a frame off to * RenderThread but before the next frame begins. We schedule prefetch work in this window. */ private static final boolean ALLOW_THREAD_GAP_WORK = Build.VERSION.SDK_INT >= 21; /** * FocusFinder#findNextFocus is broken on ICS MR1 and older for View.FOCUS_BACKWARD direction. * We convert it to an absolute direction such as FOCUS_DOWN or FOCUS_LEFT. */ private static final boolean FORCE_ABS_FOCUS_SEARCH_DIRECTION = Build.VERSION.SDK_INT <= 15; /** * on API 15-, a focused child can still be considered a focused child of RV even after * it's being removed or its focusable flag is set to false. This is because when this focused * child is detached, the reference to this child is not removed in clearFocus. API 16 and above * properly handle this case by calling ensureInputFocusOnFirstFocusable or rootViewRequestFocus * to request focus on a new child, which will clear the focus on the old (detached) child as a * side-effect. */ private static final boolean IGNORE_DETACHED_FOCUSED_CHILD = Build.VERSION.SDK_INT <= 15; static final boolean DISPATCH_TEMP_DETACH = false; public static final int HORIZONTAL = 0; public static final int VERTICAL = 1; public static final int NO_POSITION = -1; public static final long NO_ID = -1; public static final int INVALID_TYPE = -1; /** * Constant for use with {@link #setScrollingTouchSlop(int)}. Indicates * that the RecyclerView should use the standard touch slop for smooth, * continuous scrolling. */ public static final int TOUCH_SLOP_DEFAULT = 0; /** * Constant for use with {@link #setScrollingTouchSlop(int)}. Indicates * that the RecyclerView should use the standard touch slop for scrolling * widgets that snap to a page or other coarse-grained barrier. */ public static final int TOUCH_SLOP_PAGING = 1; static final int MAX_SCROLL_DURATION = 2000; /** * RecyclerView is calculating a scroll. * If there are too many of these in Systrace, some Views inside RecyclerView might be causing * it. Try to avoid using EditText, focusable views or handle them with care. */ static final String TRACE_SCROLL_TAG = "RV Scroll"; /** * OnLayout has been called by the View system. * If this shows up too many times in Systrace, make sure the children of RecyclerView do not * update themselves directly. This will cause a full re-layout but when it happens via the * Adapter notifyItemChanged, RecyclerView can avoid full layout calculation. */ private static final String TRACE_ON_LAYOUT_TAG = "RV OnLayout"; /** * NotifyDataSetChanged or equal has been called. * If this is taking a long time, try sending granular notify adapter changes instead of just * calling notifyDataSetChanged or setAdapter / swapAdapter. Adding stable ids to your adapter * might help. */ private static final String TRACE_ON_DATA_SET_CHANGE_LAYOUT_TAG = "RV FullInvalidate"; /** * RecyclerView is doing a layout for partial adapter updates (we know what has changed) * If this is taking a long time, you may have dispatched too many Adapter updates causing too * many Views being rebind. Make sure all are necessary and also prefer using notify*Range * methods. */ private static final String TRACE_HANDLE_ADAPTER_UPDATES_TAG = "RV PartialInvalidate"; /** * RecyclerView is rebinding a View. * If this is taking a lot of time, consider optimizing your layout or make sure you are not * doing extra operations in onBindViewHolder call. */ static final String TRACE_BIND_VIEW_TAG = "RV OnBindView"; /** * RecyclerView is attempting to pre-populate off screen views. */ static final String TRACE_PREFETCH_TAG = "RV Prefetch"; /** * RecyclerView is attempting to pre-populate off screen itemviews within an off screen * RecyclerView. */ static final String TRACE_NESTED_PREFETCH_TAG = "RV Nested Prefetch"; /** * RecyclerView is creating a new View. * If too many of these present in Systrace: * - There might be a problem in Recycling (e.g. custom Animations that set transient state and * prevent recycling or ItemAnimator not implementing the contract properly. ({@link * > Adapter#onFailedToRecycleView(ViewHolder)}) * * - There might be too many item view types. * > Try merging them * * - There might be too many itemChange animations and not enough space in RecyclerPool. * >Try increasing your pool size and item cache size. */ static final String TRACE_CREATE_VIEW_TAG = "RV CreateView"; private static final Class[] LAYOUT_MANAGER_CONSTRUCTOR_SIGNATURE = new Class[]{Context.class, AttributeSet.class, int.class, int.class}; private final RecyclerViewDataObserver mObserver = new RecyclerViewDataObserver(); final Recycler mRecycler = new Recycler(); private SavedState mPendingSavedState; /** * Handles adapter updates */ AdapterHelper mAdapterHelper; /** * Handles abstraction between LayoutManager children and RecyclerView children */ ChildHelper mChildHelper; /** * Keeps data about views to be used for animations */ final ViewInfoStore mViewInfoStore = new ViewInfoStore(); /** * Prior to L, there is no way to query this variable which is why we override the setter and * track it here. */ boolean mClipToPadding; /** * Note: this Runnable is only ever posted if: * 1) We've been through first layout * 2) We know we have a fixed size (mHasFixedSize) * 3) We're attached */ final Runnable mUpdateChildViewsRunnable = new Runnable() { @Override public void run() { if (!mFirstLayoutComplete || isLayoutRequested()) { // a layout request will happen, we should not do layout here. return; } if (!mIsAttached) { requestLayout(); // if we are not attached yet, mark us as requiring layout and skip return; } if (mLayoutFrozen) { mLayoutRequestEaten = true; return; //we'll process updates when ice age ends. } consumePendingUpdateOperations(); } }; final Rect mTempRect = new Rect(); private final Rect mTempRect2 = new Rect(); final RectF mTempRectF = new RectF(); Adapter mAdapter; @VisibleForTesting LayoutManager mLayout; RecyclerListener mRecyclerListener; final ArrayList mItemDecorations = new ArrayList<>(); private final ArrayList mOnItemTouchListeners = new ArrayList<>(); private OnItemTouchListener mActiveOnItemTouchListener; boolean mIsAttached; boolean mHasFixedSize; @VisibleForTesting boolean mFirstLayoutComplete; // Counting lock to control whether we should ignore requestLayout calls from children or not. private int mEatRequestLayout = 0; boolean mLayoutRequestEaten; boolean mLayoutFrozen; private boolean mIgnoreMotionEventTillDown; // binary OR of change events that were eaten during a layout or scroll. private int mEatenAccessibilityChangeFlags; boolean mAdapterUpdateDuringMeasure; private final AccessibilityManager mAccessibilityManager; private List mOnChildAttachStateListeners; /** * Set to true when an adapter data set changed notification is received. * In that case, we cannot run any animations since we don't know what happened until layout. * * Attached items are invalid until next layout, at which point layout will animate/replace * items as necessary, building up content from the (effectively) new adapter from scratch. * * Cached items must be discarded when setting this to true, so that the cache may be freely * used by prefetching until the next layout occurs. * * @see #setDataSetChangedAfterLayout() */ boolean mDataSetHasChangedAfterLayout = false; /** * This variable is incremented during a dispatchLayout and/or scroll. * Some methods should not be called during these periods (e.g. adapter data change). * Doing so will create hard to find bugs so we better check it and throw an exception. * * @see #assertInLayoutOrScroll(String) * @see #assertNotInLayoutOrScroll(String) */ private int mLayoutOrScrollCounter = 0; /** * Similar to mLayoutOrScrollCounter but logs a warning instead of throwing an exception * (for API compatibility). *

* It is a bad practice for a developer to update the data in a scroll callback since it is * potentially called during a layout. */ private int mDispatchScrollCounter = 0; private EdgeEffect mLeftGlow, mTopGlow, mRightGlow, mBottomGlow; ItemAnimator mItemAnimator = new DefaultItemAnimator(); private static final int INVALID_POINTER = -1; /** * The RecyclerView is not currently scrolling. * @see #getScrollState() */ public static final int SCROLL_STATE_IDLE = 0; /** * The RecyclerView is currently being dragged by outside input such as user touch input. * @see #getScrollState() */ public static final int SCROLL_STATE_DRAGGING = 1; /** * The RecyclerView is currently animating to a final position while not under * outside control. * @see #getScrollState() */ public static final int SCROLL_STATE_SETTLING = 2; static final long FOREVER_NS = Long.MAX_VALUE; // Touch/scrolling handling private int mScrollState = SCROLL_STATE_IDLE; private int mScrollPointerId = INVALID_POINTER; private VelocityTracker mVelocityTracker; private int mInitialTouchX; private int mInitialTouchY; private int mLastTouchX; private int mLastTouchY; private int mTouchSlop; private OnFlingListener mOnFlingListener; private final int mMinFlingVelocity; private final int mMaxFlingVelocity; // This value is used when handling generic motion events. private float mScrollFactor = Float.MIN_VALUE; private boolean mPreserveFocusAfterLayout = true; final ViewFlinger mViewFlinger = new ViewFlinger(); GapWorker mGapWorker; GapWorker.LayoutPrefetchRegistryImpl mPrefetchRegistry = ALLOW_THREAD_GAP_WORK ? new GapWorker.LayoutPrefetchRegistryImpl() : null; final State mState = new State(); private OnScrollListener mScrollListener; private List mScrollListeners; // For use in item animations boolean mItemsAddedOrRemoved = false; boolean mItemsChanged = false; private ItemAnimator.ItemAnimatorListener mItemAnimatorListener = new ItemAnimatorRestoreListener(); boolean mPostedAnimatorRunner = false; RecyclerViewAccessibilityDelegate mAccessibilityDelegate; private ChildDrawingOrderCallback mChildDrawingOrderCallback; // simple array to keep min and max child position during a layout calculation // preserved not to create a new one in each layout pass private final int[] mMinMaxLayoutPositions = new int[2]; private final int[] mScrollOffset = new int[2]; private final int[] mScrollConsumed = new int[2]; private final int[] mNestedOffsets = new int[2]; /** * These are views that had their a11y importance changed during a layout. We defer these events * until the end of the layout because a11y service may make sync calls back to the RV while * the View's state is undefined. */ @VisibleForTesting final List mPendingAccessibilityImportanceChange = new ArrayList(); private Runnable mItemAnimatorRunner = new Runnable() { @Override public void run() { if (mItemAnimator != null) { mItemAnimator.runPendingAnimations(); } mPostedAnimatorRunner = false; } }; static final Interpolator sQuinticInterpolator = new Interpolator() { @Override public float getInterpolation(float t) { t -= 1.0f; return t * t * t * t * t + 1.0f; } }; /** * The callback to convert view info diffs into animations. */ private final ViewInfoStore.ProcessCallback mViewInfoProcessCallback = new ViewInfoStore.ProcessCallback() { @Override public void processDisappeared(ViewHolder viewHolder, @NonNull ItemHolderInfo info, @Nullable ItemHolderInfo postInfo) { mRecycler.unscrapView(viewHolder); animateDisappearance(viewHolder, info, postInfo); } @Override public void processAppeared(ViewHolder viewHolder, ItemHolderInfo preInfo, ItemHolderInfo info) { animateAppearance(viewHolder, preInfo, info); } @Override public void processPersistent(ViewHolder viewHolder, @NonNull ItemHolderInfo preInfo, @NonNull ItemHolderInfo postInfo) { viewHolder.setIsRecyclable(false); if (mDataSetHasChangedAfterLayout) { // since it was rebound, use change instead as we'll be mapping them from // stable ids. If stable ids were false, we would not be running any // animations if (mItemAnimator.animateChange(viewHolder, viewHolder, preInfo, postInfo)) { postAnimationRunner(); } } else if (mItemAnimator.animatePersistence(viewHolder, preInfo, postInfo)) { postAnimationRunner(); } } @Override public void unused(ViewHolder viewHolder) { mLayout.removeAndRecycleView(viewHolder.itemView, mRecycler); } }; public RecyclerView(Context context) { this(context, null); } public RecyclerView(Context context, @Nullable AttributeSet attrs) { this(context, attrs, 0); } public RecyclerView(Context context, @Nullable AttributeSet attrs, int defStyle) { super(context, attrs, defStyle); if (attrs != null) { TypedArray a = context.obtainStyledAttributes(attrs, CLIP_TO_PADDING_ATTR, defStyle, 0); mClipToPadding = a.getBoolean(0, true); a.recycle(); } else { mClipToPadding = true; } setScrollContainer(true); setFocusableInTouchMode(true); final ViewConfiguration vc = ViewConfiguration.get(context); mTouchSlop = vc.getScaledTouchSlop(); mMinFlingVelocity = vc.getScaledMinimumFlingVelocity(); mMaxFlingVelocity = vc.getScaledMaximumFlingVelocity(); setWillNotDraw(getOverScrollMode() == View.OVER_SCROLL_NEVER); mItemAnimator.setListener(mItemAnimatorListener); initAdapterManager(); initChildrenHelper(); // If not explicitly specified this view is important for accessibility. if (getImportantForAccessibility() == View.IMPORTANT_FOR_ACCESSIBILITY_AUTO) { setImportantForAccessibility(View.IMPORTANT_FOR_ACCESSIBILITY_YES); } mAccessibilityManager = (AccessibilityManager) getContext() .getSystemService(Context.ACCESSIBILITY_SERVICE); setAccessibilityDelegateCompat(new RecyclerViewAccessibilityDelegate(this)); // Create the layoutManager if specified. boolean nestedScrollingEnabled = true; if (attrs != null) { int defStyleRes = 0; TypedArray a = context.obtainStyledAttributes(attrs, R.styleable.RecyclerView, defStyle, defStyleRes); String layoutManagerName = a.getString(R.styleable.RecyclerView_layoutManager); int descendantFocusability = a.getInt( R.styleable.RecyclerView_descendantFocusability, -1); if (descendantFocusability == -1) { setDescendantFocusability(ViewGroup.FOCUS_AFTER_DESCENDANTS); } a.recycle(); createLayoutManager(context, layoutManagerName, attrs, defStyle, defStyleRes); if (Build.VERSION.SDK_INT >= 21) { a = context.obtainStyledAttributes(attrs, NESTED_SCROLLING_ATTRS, defStyle, defStyleRes); nestedScrollingEnabled = a.getBoolean(0, true); a.recycle(); } } else { setDescendantFocusability(ViewGroup.FOCUS_AFTER_DESCENDANTS); } // Re-set whether nested scrolling is enabled so that it is set on all API levels setNestedScrollingEnabled(nestedScrollingEnabled); } /** * Returns the accessibility delegate compatibility implementation used by the RecyclerView. * @return An instance of AccessibilityDelegateCompat used by RecyclerView */ public RecyclerViewAccessibilityDelegate getCompatAccessibilityDelegate() { return mAccessibilityDelegate; } /** * Sets the accessibility delegate compatibility implementation used by RecyclerView. * @param accessibilityDelegate The accessibility delegate to be used by RecyclerView. */ public void setAccessibilityDelegateCompat( RecyclerViewAccessibilityDelegate accessibilityDelegate) { mAccessibilityDelegate = accessibilityDelegate; setAccessibilityDelegate(mAccessibilityDelegate); } /** * Instantiate and set a LayoutManager, if specified in the attributes. */ private void createLayoutManager(Context context, String className, AttributeSet attrs, int defStyleAttr, int defStyleRes) { if (className != null) { className = className.trim(); if (className.length() != 0) { // Can't use isEmpty since it was added in API 9. className = getFullClassName(context, className); try { ClassLoader classLoader; if (isInEditMode()) { // Stupid layoutlib cannot handle simple class loaders. classLoader = this.getClass().getClassLoader(); } else { classLoader = context.getClassLoader(); } Class layoutManagerClass = classLoader.loadClass(className).asSubclass(LayoutManager.class); Constructor constructor; Object[] constructorArgs = null; try { constructor = layoutManagerClass .getConstructor(LAYOUT_MANAGER_CONSTRUCTOR_SIGNATURE); constructorArgs = new Object[]{context, attrs, defStyleAttr, defStyleRes}; } catch (NoSuchMethodException e) { try { constructor = layoutManagerClass.getConstructor(); } catch (NoSuchMethodException e1) { e1.initCause(e); throw new IllegalStateException(attrs.getPositionDescription() + ": Error creating LayoutManager " + className, e1); } } constructor.setAccessible(true); setLayoutManager(constructor.newInstance(constructorArgs)); } catch (ClassNotFoundException e) { throw new IllegalStateException(attrs.getPositionDescription() + ": Unable to find LayoutManager " + className, e); } catch (InvocationTargetException e) { throw new IllegalStateException(attrs.getPositionDescription() + ": Could not instantiate the LayoutManager: " + className, e); } catch (InstantiationException e) { throw new IllegalStateException(attrs.getPositionDescription() + ": Could not instantiate the LayoutManager: " + className, e); } catch (IllegalAccessException e) { throw new IllegalStateException(attrs.getPositionDescription() + ": Cannot access non-public constructor " + className, e); } catch (ClassCastException e) { throw new IllegalStateException(attrs.getPositionDescription() + ": Class is not a LayoutManager " + className, e); } } } } private String getFullClassName(Context context, String className) { if (className.charAt(0) == '.') { return context.getPackageName() + className; } if (className.contains(".")) { return className; } return RecyclerView.class.getPackage().getName() + '.' + className; } private void initChildrenHelper() { mChildHelper = new ChildHelper(new ChildHelper.Callback() { @Override public int getChildCount() { return RecyclerView.this.getChildCount(); } @Override public void addView(View child, int index) { RecyclerView.this.addView(child, index); dispatchChildAttached(child); } @Override public int indexOfChild(View view) { return RecyclerView.this.indexOfChild(view); } @Override public void removeViewAt(int index) { final View child = RecyclerView.this.getChildAt(index); if (child != null) { dispatchChildDetached(child); } RecyclerView.this.removeViewAt(index); } @Override public View getChildAt(int offset) { return RecyclerView.this.getChildAt(offset); } @Override public void removeAllViews() { final int count = getChildCount(); for (int i = 0; i < count; i++) { dispatchChildDetached(getChildAt(i)); } RecyclerView.this.removeAllViews(); } @Override public ViewHolder getChildViewHolder(View view) { return getChildViewHolderInt(view); } @Override public void attachViewToParent(View child, int index, ViewGroup.LayoutParams layoutParams) { final ViewHolder vh = getChildViewHolderInt(child); if (vh != null) { if (!vh.isTmpDetached() && !vh.shouldIgnore()) { throw new IllegalArgumentException("Called attach on a child which is not" + " detached: " + vh); } if (DEBUG) { Log.d(TAG, "reAttach " + vh); } vh.clearTmpDetachFlag(); } RecyclerView.this.attachViewToParent(child, index, layoutParams); } @Override public void detachViewFromParent(int offset) { final View view = getChildAt(offset); if (view != null) { final ViewHolder vh = getChildViewHolderInt(view); if (vh != null) { if (vh.isTmpDetached() && !vh.shouldIgnore()) { throw new IllegalArgumentException("called detach on an already" + " detached child " + vh); } if (DEBUG) { Log.d(TAG, "tmpDetach " + vh); } vh.addFlags(ViewHolder.FLAG_TMP_DETACHED); } } RecyclerView.this.detachViewFromParent(offset); } @Override public void onEnteredHiddenState(View child) { final ViewHolder vh = getChildViewHolderInt(child); if (vh != null) { vh.onEnteredHiddenState(RecyclerView.this); } } @Override public void onLeftHiddenState(View child) { final ViewHolder vh = getChildViewHolderInt(child); if (vh != null) { vh.onLeftHiddenState(RecyclerView.this); } } }); } void initAdapterManager() { mAdapterHelper = new AdapterHelper(new AdapterHelper.Callback() { @Override public ViewHolder findViewHolder(int position) { final ViewHolder vh = findViewHolderForPosition(position, true); if (vh == null) { return null; } // ensure it is not hidden because for adapter helper, the only thing matter is that // LM thinks view is a child. if (mChildHelper.isHidden(vh.itemView)) { if (DEBUG) { Log.d(TAG, "assuming view holder cannot be find because it is hidden"); } return null; } return vh; } @Override public void offsetPositionsForRemovingInvisible(int start, int count) { offsetPositionRecordsForRemove(start, count, true); mItemsAddedOrRemoved = true; mState.mDeletedInvisibleItemCountSincePreviousLayout += count; } @Override public void offsetPositionsForRemovingLaidOutOrNewView( int positionStart, int itemCount) { offsetPositionRecordsForRemove(positionStart, itemCount, false); mItemsAddedOrRemoved = true; } @Override public void markViewHoldersUpdated(int positionStart, int itemCount, Object payload) { viewRangeUpdate(positionStart, itemCount, payload); mItemsChanged = true; } @Override public void onDispatchFirstPass(AdapterHelper.UpdateOp op) { dispatchUpdate(op); } void dispatchUpdate(AdapterHelper.UpdateOp op) { switch (op.cmd) { case AdapterHelper.UpdateOp.ADD: mLayout.onItemsAdded(RecyclerView.this, op.positionStart, op.itemCount); break; case AdapterHelper.UpdateOp.REMOVE: mLayout.onItemsRemoved(RecyclerView.this, op.positionStart, op.itemCount); break; case AdapterHelper.UpdateOp.UPDATE: mLayout.onItemsUpdated(RecyclerView.this, op.positionStart, op.itemCount, op.payload); break; case AdapterHelper.UpdateOp.MOVE: mLayout.onItemsMoved(RecyclerView.this, op.positionStart, op.itemCount, 1); break; } } @Override public void onDispatchSecondPass(AdapterHelper.UpdateOp op) { dispatchUpdate(op); } @Override public void offsetPositionsForAdd(int positionStart, int itemCount) { offsetPositionRecordsForInsert(positionStart, itemCount); mItemsAddedOrRemoved = true; } @Override public void offsetPositionsForMove(int from, int to) { offsetPositionRecordsForMove(from, to); // should we create mItemsMoved ? mItemsAddedOrRemoved = true; } }); } /** * RecyclerView can perform several optimizations if it can know in advance that RecyclerView's * size is not affected by the adapter contents. RecyclerView can still change its size based * on other factors (e.g. its parent's size) but this size calculation cannot depend on the * size of its children or contents of its adapter (except the number of items in the adapter). *

* If your use of RecyclerView falls into this category, set this to {@code true}. It will allow * RecyclerView to avoid invalidating the whole layout when its adapter contents change. * * @param hasFixedSize true if adapter changes cannot affect the size of the RecyclerView. */ public void setHasFixedSize(boolean hasFixedSize) { mHasFixedSize = hasFixedSize; } /** * @return true if the app has specified that changes in adapter content cannot change * the size of the RecyclerView itself. */ public boolean hasFixedSize() { return mHasFixedSize; } @Override public void setClipToPadding(boolean clipToPadding) { if (clipToPadding != mClipToPadding) { invalidateGlows(); } mClipToPadding = clipToPadding; super.setClipToPadding(clipToPadding); if (mFirstLayoutComplete) { requestLayout(); } } /** * Returns whether this RecyclerView will clip its children to its padding, and resize (but * not clip) any EdgeEffect to the padded region, if padding is present. *

* By default, children are clipped to the padding of their parent * RecyclerView. This clipping behavior is only enabled if padding is non-zero. * * @return true if this RecyclerView clips children to its padding and resizes (but doesn't * clip) any EdgeEffect to the padded region, false otherwise. * * @attr name android:clipToPadding */ @Override public boolean getClipToPadding() { return mClipToPadding; } /** * Configure the scrolling touch slop for a specific use case. * * Set up the RecyclerView's scrolling motion threshold based on common usages. * Valid arguments are {@link #TOUCH_SLOP_DEFAULT} and {@link #TOUCH_SLOP_PAGING}. * * @param slopConstant One of the TOUCH_SLOP_ constants representing * the intended usage of this RecyclerView */ public void setScrollingTouchSlop(int slopConstant) { final ViewConfiguration vc = ViewConfiguration.get(getContext()); switch (slopConstant) { default: Log.w(TAG, "setScrollingTouchSlop(): bad argument constant " + slopConstant + "; using default value"); // fall-through case TOUCH_SLOP_DEFAULT: mTouchSlop = vc.getScaledTouchSlop(); break; case TOUCH_SLOP_PAGING: mTouchSlop = vc.getScaledPagingTouchSlop(); break; } } /** * Swaps the current adapter with the provided one. It is similar to * {@link #setAdapter(Adapter)} but assumes existing adapter and the new adapter uses the same * {@link ViewHolder} and does not clear the RecycledViewPool. *

* Note that it still calls onAdapterChanged callbacks. * * @param adapter The new adapter to set, or null to set no adapter. * @param removeAndRecycleExistingViews If set to true, RecyclerView will recycle all existing * Views. If adapters have stable ids and/or you want to * animate the disappearing views, you may prefer to set * this to false. * @see #setAdapter(Adapter) */ public void swapAdapter(Adapter adapter, boolean removeAndRecycleExistingViews) { // bail out if layout is frozen setLayoutFrozen(false); setAdapterInternal(adapter, true, removeAndRecycleExistingViews); setDataSetChangedAfterLayout(); requestLayout(); } /** * Set a new adapter to provide child views on demand. *

* When adapter is changed, all existing views are recycled back to the pool. If the pool has * only one adapter, it will be cleared. * * @param adapter The new adapter to set, or null to set no adapter. * @see #swapAdapter(Adapter, boolean) */ public void setAdapter(Adapter adapter) { // bail out if layout is frozen setLayoutFrozen(false); setAdapterInternal(adapter, false, true); requestLayout(); } /** * Removes and recycles all views - both those currently attached, and those in the Recycler. */ void removeAndRecycleViews() { // end all running animations if (mItemAnimator != null) { mItemAnimator.endAnimations(); } // Since animations are ended, mLayout.children should be equal to // recyclerView.children. This may not be true if item animator's end does not work as // expected. (e.g. not release children instantly). It is safer to use mLayout's child // count. if (mLayout != null) { mLayout.removeAndRecycleAllViews(mRecycler); mLayout.removeAndRecycleScrapInt(mRecycler); } // we should clear it here before adapters are swapped to ensure correct callbacks. mRecycler.clear(); } /** * Replaces the current adapter with the new one and triggers listeners. * @param adapter The new adapter * @param compatibleWithPrevious If true, the new adapter is using the same View Holders and * item types with the current adapter (helps us avoid cache * invalidation). * @param removeAndRecycleViews If true, we'll remove and recycle all existing views. If * compatibleWithPrevious is false, this parameter is ignored. */ private void setAdapterInternal(Adapter adapter, boolean compatibleWithPrevious, boolean removeAndRecycleViews) { if (mAdapter != null) { mAdapter.unregisterAdapterDataObserver(mObserver); mAdapter.onDetachedFromRecyclerView(this); } if (!compatibleWithPrevious || removeAndRecycleViews) { removeAndRecycleViews(); } mAdapterHelper.reset(); final Adapter oldAdapter = mAdapter; mAdapter = adapter; if (adapter != null) { adapter.registerAdapterDataObserver(mObserver); adapter.onAttachedToRecyclerView(this); } if (mLayout != null) { mLayout.onAdapterChanged(oldAdapter, mAdapter); } mRecycler.onAdapterChanged(oldAdapter, mAdapter, compatibleWithPrevious); mState.mStructureChanged = true; markKnownViewsInvalid(); } /** * Retrieves the previously set adapter or null if no adapter is set. * * @return The previously set adapter * @see #setAdapter(Adapter) */ public Adapter getAdapter() { return mAdapter; } /** * Register a listener that will be notified whenever a child view is recycled. * *

This listener will be called when a LayoutManager or the RecyclerView decides * that a child view is no longer needed. If an application associates expensive * or heavyweight data with item views, this may be a good place to release * or free those resources.

* * @param listener Listener to register, or null to clear */ public void setRecyclerListener(RecyclerListener listener) { mRecyclerListener = listener; } /** *

Return the offset of the RecyclerView's text baseline from the its top * boundary. If the LayoutManager of this RecyclerView does not support baseline alignment, * this method returns -1.

* * @return the offset of the baseline within the RecyclerView's bounds or -1 * if baseline alignment is not supported */ @Override public int getBaseline() { if (mLayout != null) { return mLayout.getBaseline(); } else { return super.getBaseline(); } } /** * Register a listener that will be notified whenever a child view is attached to or detached * from RecyclerView. * *

This listener will be called when a LayoutManager or the RecyclerView decides * that a child view is no longer needed. If an application associates expensive * or heavyweight data with item views, this may be a good place to release * or free those resources.

* * @param listener Listener to register */ public void addOnChildAttachStateChangeListener(OnChildAttachStateChangeListener listener) { if (mOnChildAttachStateListeners == null) { mOnChildAttachStateListeners = new ArrayList<>(); } mOnChildAttachStateListeners.add(listener); } /** * Removes the provided listener from child attached state listeners list. * * @param listener Listener to unregister */ public void removeOnChildAttachStateChangeListener(OnChildAttachStateChangeListener listener) { if (mOnChildAttachStateListeners == null) { return; } mOnChildAttachStateListeners.remove(listener); } /** * Removes all listeners that were added via * {@link #addOnChildAttachStateChangeListener(OnChildAttachStateChangeListener)}. */ public void clearOnChildAttachStateChangeListeners() { if (mOnChildAttachStateListeners != null) { mOnChildAttachStateListeners.clear(); } } /** * Set the {@link LayoutManager} that this RecyclerView will use. * *

In contrast to other adapter-backed views such as {@link android.widget.ListView} * or {@link android.widget.GridView}, RecyclerView allows client code to provide custom * layout arrangements for child views. These arrangements are controlled by the * {@link LayoutManager}. A LayoutManager must be provided for RecyclerView to function.

* *

Several default strategies are provided for common uses such as lists and grids.

* * @param layout LayoutManager to use */ public void setLayoutManager(LayoutManager layout) { if (layout == mLayout) { return; } stopScroll(); // TODO We should do this switch a dispatchLayout pass and animate children. There is a good // chance that LayoutManagers will re-use views. if (mLayout != null) { // end all running animations if (mItemAnimator != null) { mItemAnimator.endAnimations(); } mLayout.removeAndRecycleAllViews(mRecycler); mLayout.removeAndRecycleScrapInt(mRecycler); mRecycler.clear(); if (mIsAttached) { mLayout.dispatchDetachedFromWindow(this, mRecycler); } mLayout.setRecyclerView(null); mLayout = null; } else { mRecycler.clear(); } // this is just a defensive measure for faulty item animators. mChildHelper.removeAllViewsUnfiltered(); mLayout = layout; if (layout != null) { if (layout.mRecyclerView != null) { throw new IllegalArgumentException("LayoutManager " + layout + " is already attached to a RecyclerView: " + layout.mRecyclerView); } mLayout.setRecyclerView(this); if (mIsAttached) { mLayout.dispatchAttachedToWindow(this); } } mRecycler.updateViewCacheSize(); requestLayout(); } /** * Set a {@link OnFlingListener} for this {@link RecyclerView}. *

* If the {@link OnFlingListener} is set then it will receive * calls to {@link #fling(int,int)} and will be able to intercept them. * * @param onFlingListener The {@link OnFlingListener} instance. */ public void setOnFlingListener(@Nullable OnFlingListener onFlingListener) { mOnFlingListener = onFlingListener; } /** * Get the current {@link OnFlingListener} from this {@link RecyclerView}. * * @return The {@link OnFlingListener} instance currently set (can be null). */ @Nullable public OnFlingListener getOnFlingListener() { return mOnFlingListener; } @Override protected Parcelable onSaveInstanceState() { SavedState state = new SavedState(super.onSaveInstanceState()); if (mPendingSavedState != null) { state.copyFrom(mPendingSavedState); } else if (mLayout != null) { state.mLayoutState = mLayout.onSaveInstanceState(); } else { state.mLayoutState = null; } return state; } @Override protected void onRestoreInstanceState(Parcelable state) { if (!(state instanceof SavedState)) { super.onRestoreInstanceState(state); return; } mPendingSavedState = (SavedState) state; super.onRestoreInstanceState(mPendingSavedState.getSuperState()); if (mLayout != null && mPendingSavedState.mLayoutState != null) { mLayout.onRestoreInstanceState(mPendingSavedState.mLayoutState); } } /** * Override to prevent freezing of any views created by the adapter. */ @Override protected void dispatchSaveInstanceState(SparseArray container) { dispatchFreezeSelfOnly(container); } /** * Override to prevent thawing of any views created by the adapter. */ @Override protected void dispatchRestoreInstanceState(SparseArray container) { dispatchThawSelfOnly(container); } /** * Adds a view to the animatingViews list. * mAnimatingViews holds the child views that are currently being kept around * purely for the purpose of being animated out of view. They are drawn as a regular * part of the child list of the RecyclerView, but they are invisible to the LayoutManager * as they are managed separately from the regular child views. * @param viewHolder The ViewHolder to be removed */ private void addAnimatingView(ViewHolder viewHolder) { final View view = viewHolder.itemView; final boolean alreadyParented = view.getParent() == this; mRecycler.unscrapView(getChildViewHolder(view)); if (viewHolder.isTmpDetached()) { // re-attach mChildHelper.attachViewToParent(view, -1, view.getLayoutParams(), true); } else if (!alreadyParented) { mChildHelper.addView(view, true); } else { mChildHelper.hide(view); } } /** * Removes a view from the animatingViews list. * @param view The view to be removed * @see #addAnimatingView(RecyclerView.ViewHolder) * @return true if an animating view is removed */ boolean removeAnimatingView(View view) { eatRequestLayout(); final boolean removed = mChildHelper.removeViewIfHidden(view); if (removed) { final ViewHolder viewHolder = getChildViewHolderInt(view); mRecycler.unscrapView(viewHolder); mRecycler.recycleViewHolderInternal(viewHolder); if (DEBUG) { Log.d(TAG, "after removing animated view: " + view + ", " + this); } } // only clear request eaten flag if we removed the view. resumeRequestLayout(!removed); return removed; } /** * Return the {@link LayoutManager} currently responsible for * layout policy for this RecyclerView. * * @return The currently bound LayoutManager */ public LayoutManager getLayoutManager() { return mLayout; } /** * Retrieve this RecyclerView's {@link RecycledViewPool}. This method will never return null; * if no pool is set for this view a new one will be created. See * {@link #setRecycledViewPool(RecycledViewPool) setRecycledViewPool} for more information. * * @return The pool used to store recycled item views for reuse. * @see #setRecycledViewPool(RecycledViewPool) */ public RecycledViewPool getRecycledViewPool() { return mRecycler.getRecycledViewPool(); } /** * Recycled view pools allow multiple RecyclerViews to share a common pool of scrap views. * This can be useful if you have multiple RecyclerViews with adapters that use the same * view types, for example if you have several data sets with the same kinds of item views * displayed by a {@link android.support.v4.view.ViewPager ViewPager}. * * @param pool Pool to set. If this parameter is null a new pool will be created and used. */ public void setRecycledViewPool(RecycledViewPool pool) { mRecycler.setRecycledViewPool(pool); } /** * Sets a new {@link ViewCacheExtension} to be used by the Recycler. * * @param extension ViewCacheExtension to be used or null if you want to clear the existing one. * * @see {@link ViewCacheExtension#getViewForPositionAndType(Recycler, int, int)} */ public void setViewCacheExtension(ViewCacheExtension extension) { mRecycler.setViewCacheExtension(extension); } /** * Set the number of offscreen views to retain before adding them to the potentially shared * {@link #getRecycledViewPool() recycled view pool}. * *

The offscreen view cache stays aware of changes in the attached adapter, allowing * a LayoutManager to reuse those views unmodified without needing to return to the adapter * to rebind them.

* * @param size Number of views to cache offscreen before returning them to the general * recycled view pool */ public void setItemViewCacheSize(int size) { mRecycler.setViewCacheSize(size); } /** * Return the current scrolling state of the RecyclerView. * * @return {@link #SCROLL_STATE_IDLE}, {@link #SCROLL_STATE_DRAGGING} or * {@link #SCROLL_STATE_SETTLING} */ public int getScrollState() { return mScrollState; } void setScrollState(int state) { if (state == mScrollState) { return; } if (DEBUG) { Log.d(TAG, "setting scroll state to " + state + " from " + mScrollState, new Exception()); } mScrollState = state; if (state != SCROLL_STATE_SETTLING) { stopScrollersInternal(); } dispatchOnScrollStateChanged(state); } /** * Add an {@link ItemDecoration} to this RecyclerView. Item decorations can * affect both measurement and drawing of individual item views. * *

Item decorations are ordered. Decorations placed earlier in the list will * be run/queried/drawn first for their effects on item views. Padding added to views * will be nested; a padding added by an earlier decoration will mean further * item decorations in the list will be asked to draw/pad within the previous decoration's * given area.

* * @param decor Decoration to add * @param index Position in the decoration chain to insert this decoration at. If this value * is negative the decoration will be added at the end. */ public void addItemDecoration(ItemDecoration decor, int index) { if (mLayout != null) { mLayout.assertNotInLayoutOrScroll("Cannot add item decoration during a scroll or" + " layout"); } if (mItemDecorations.isEmpty()) { setWillNotDraw(false); } if (index < 0) { mItemDecorations.add(decor); } else { mItemDecorations.add(index, decor); } markItemDecorInsetsDirty(); requestLayout(); } /** * Add an {@link ItemDecoration} to this RecyclerView. Item decorations can * affect both measurement and drawing of individual item views. * *

Item decorations are ordered. Decorations placed earlier in the list will * be run/queried/drawn first for their effects on item views. Padding added to views * will be nested; a padding added by an earlier decoration will mean further * item decorations in the list will be asked to draw/pad within the previous decoration's * given area.

* * @param decor Decoration to add */ public void addItemDecoration(ItemDecoration decor) { addItemDecoration(decor, -1); } /** * Remove an {@link ItemDecoration} from this RecyclerView. * *

The given decoration will no longer impact the measurement and drawing of * item views.

* * @param decor Decoration to remove * @see #addItemDecoration(ItemDecoration) */ public void removeItemDecoration(ItemDecoration decor) { if (mLayout != null) { mLayout.assertNotInLayoutOrScroll("Cannot remove item decoration during a scroll or" + " layout"); } mItemDecorations.remove(decor); if (mItemDecorations.isEmpty()) { setWillNotDraw(getOverScrollMode() == View.OVER_SCROLL_NEVER); } markItemDecorInsetsDirty(); requestLayout(); } /** * Sets the {@link ChildDrawingOrderCallback} to be used for drawing children. *

* See {@link ViewGroup#getChildDrawingOrder(int, int)} for details. Calling this method will * always call {@link ViewGroup#setChildrenDrawingOrderEnabled(boolean)}. The parameter will be * true if childDrawingOrderCallback is not null, false otherwise. *

* Note that child drawing order may be overridden by View's elevation. * * @param childDrawingOrderCallback The ChildDrawingOrderCallback to be used by the drawing * system. */ public void setChildDrawingOrderCallback(ChildDrawingOrderCallback childDrawingOrderCallback) { if (childDrawingOrderCallback == mChildDrawingOrderCallback) { return; } mChildDrawingOrderCallback = childDrawingOrderCallback; setChildrenDrawingOrderEnabled(mChildDrawingOrderCallback != null); } /** * Set a listener that will be notified of any changes in scroll state or position. * * @param listener Listener to set or null to clear * * @deprecated Use {@link #addOnScrollListener(OnScrollListener)} and * {@link #removeOnScrollListener(OnScrollListener)} */ @Deprecated public void setOnScrollListener(OnScrollListener listener) { mScrollListener = listener; } /** * Add a listener that will be notified of any changes in scroll state or position. * *

Components that add a listener should take care to remove it when finished. * Other components that take ownership of a view may call {@link #clearOnScrollListeners()} * to remove all attached listeners.

* * @param listener listener to set or null to clear */ public void addOnScrollListener(OnScrollListener listener) { if (mScrollListeners == null) { mScrollListeners = new ArrayList<>(); } mScrollListeners.add(listener); } /** * Remove a listener that was notified of any changes in scroll state or position. * * @param listener listener to set or null to clear */ public void removeOnScrollListener(OnScrollListener listener) { if (mScrollListeners != null) { mScrollListeners.remove(listener); } } /** * Remove all secondary listener that were notified of any changes in scroll state or position. */ public void clearOnScrollListeners() { if (mScrollListeners != null) { mScrollListeners.clear(); } } /** * Convenience method to scroll to a certain position. * * RecyclerView does not implement scrolling logic, rather forwards the call to * {@link com.android.internal.widget.RecyclerView.LayoutManager#scrollToPosition(int)} * @param position Scroll to this adapter position * @see com.android.internal.widget.RecyclerView.LayoutManager#scrollToPosition(int) */ public void scrollToPosition(int position) { if (mLayoutFrozen) { return; } stopScroll(); if (mLayout == null) { Log.e(TAG, "Cannot scroll to position a LayoutManager set. " + "Call setLayoutManager with a non-null argument."); return; } mLayout.scrollToPosition(position); awakenScrollBars(); } void jumpToPositionForSmoothScroller(int position) { if (mLayout == null) { return; } mLayout.scrollToPosition(position); awakenScrollBars(); } /** * Starts a smooth scroll to an adapter position. *

* To support smooth scrolling, you must override * {@link LayoutManager#smoothScrollToPosition(RecyclerView, State, int)} and create a * {@link SmoothScroller}. *

* {@link LayoutManager} is responsible for creating the actual scroll action. If you want to * provide a custom smooth scroll logic, override * {@link LayoutManager#smoothScrollToPosition(RecyclerView, State, int)} in your * LayoutManager. * * @param position The adapter position to scroll to * @see LayoutManager#smoothScrollToPosition(RecyclerView, State, int) */ public void smoothScrollToPosition(int position) { if (mLayoutFrozen) { return; } if (mLayout == null) { Log.e(TAG, "Cannot smooth scroll without a LayoutManager set. " + "Call setLayoutManager with a non-null argument."); return; } mLayout.smoothScrollToPosition(this, mState, position); } @Override public void scrollTo(int x, int y) { Log.w(TAG, "RecyclerView does not support scrolling to an absolute position. " + "Use scrollToPosition instead"); } @Override public void scrollBy(int x, int y) { if (mLayout == null) { Log.e(TAG, "Cannot scroll without a LayoutManager set. " + "Call setLayoutManager with a non-null argument."); return; } if (mLayoutFrozen) { return; } final boolean canScrollHorizontal = mLayout.canScrollHorizontally(); final boolean canScrollVertical = mLayout.canScrollVertically(); if (canScrollHorizontal || canScrollVertical) { scrollByInternal(canScrollHorizontal ? x : 0, canScrollVertical ? y : 0, null); } } /** * Helper method reflect data changes to the state. *

* Adapter changes during a scroll may trigger a crash because scroll assumes no data change * but data actually changed. *

* This method consumes all deferred changes to avoid that case. */ void consumePendingUpdateOperations() { if (!mFirstLayoutComplete || mDataSetHasChangedAfterLayout) { Trace.beginSection(TRACE_ON_DATA_SET_CHANGE_LAYOUT_TAG); dispatchLayout(); Trace.endSection(); return; } if (!mAdapterHelper.hasPendingUpdates()) { return; } // if it is only an item change (no add-remove-notifyDataSetChanged) we can check if any // of the visible items is affected and if not, just ignore the change. if (mAdapterHelper.hasAnyUpdateTypes(AdapterHelper.UpdateOp.UPDATE) && !mAdapterHelper .hasAnyUpdateTypes(AdapterHelper.UpdateOp.ADD | AdapterHelper.UpdateOp.REMOVE | AdapterHelper.UpdateOp.MOVE)) { Trace.beginSection(TRACE_HANDLE_ADAPTER_UPDATES_TAG); eatRequestLayout(); onEnterLayoutOrScroll(); mAdapterHelper.preProcess(); if (!mLayoutRequestEaten) { if (hasUpdatedView()) { dispatchLayout(); } else { // no need to layout, clean state mAdapterHelper.consumePostponedUpdates(); } } resumeRequestLayout(true); onExitLayoutOrScroll(); Trace.endSection(); } else if (mAdapterHelper.hasPendingUpdates()) { Trace.beginSection(TRACE_ON_DATA_SET_CHANGE_LAYOUT_TAG); dispatchLayout(); Trace.endSection(); } } /** * @return True if an existing view holder needs to be updated */ private boolean hasUpdatedView() { final int childCount = mChildHelper.getChildCount(); for (int i = 0; i < childCount; i++) { final ViewHolder holder = getChildViewHolderInt(mChildHelper.getChildAt(i)); if (holder == null || holder.shouldIgnore()) { continue; } if (holder.isUpdated()) { return true; } } return false; } /** * Does not perform bounds checking. Used by internal methods that have already validated input. *

* It also reports any unused scroll request to the related EdgeEffect. * * @param x The amount of horizontal scroll request * @param y The amount of vertical scroll request * @param ev The originating MotionEvent, or null if not from a touch event. * * @return Whether any scroll was consumed in either direction. */ boolean scrollByInternal(int x, int y, MotionEvent ev) { int unconsumedX = 0, unconsumedY = 0; int consumedX = 0, consumedY = 0; consumePendingUpdateOperations(); if (mAdapter != null) { eatRequestLayout(); onEnterLayoutOrScroll(); Trace.beginSection(TRACE_SCROLL_TAG); if (x != 0) { consumedX = mLayout.scrollHorizontallyBy(x, mRecycler, mState); unconsumedX = x - consumedX; } if (y != 0) { consumedY = mLayout.scrollVerticallyBy(y, mRecycler, mState); unconsumedY = y - consumedY; } Trace.endSection(); repositionShadowingViews(); onExitLayoutOrScroll(); resumeRequestLayout(false); } if (!mItemDecorations.isEmpty()) { invalidate(); } if (dispatchNestedScroll(consumedX, consumedY, unconsumedX, unconsumedY, mScrollOffset)) { // Update the last touch co-ords, taking any scroll offset into account mLastTouchX -= mScrollOffset[0]; mLastTouchY -= mScrollOffset[1]; if (ev != null) { ev.offsetLocation(mScrollOffset[0], mScrollOffset[1]); } mNestedOffsets[0] += mScrollOffset[0]; mNestedOffsets[1] += mScrollOffset[1]; } else if (getOverScrollMode() != View.OVER_SCROLL_NEVER) { if (ev != null) { pullGlows(ev.getX(), unconsumedX, ev.getY(), unconsumedY); } considerReleasingGlowsOnScroll(x, y); } if (consumedX != 0 || consumedY != 0) { dispatchOnScrolled(consumedX, consumedY); } if (!awakenScrollBars()) { invalidate(); } return consumedX != 0 || consumedY != 0; } /** *

Compute the horizontal offset of the horizontal scrollbar's thumb within the horizontal * range. This value is used to compute the length of the thumb within the scrollbar's track. *

* *

The range is expressed in arbitrary units that must be the same as the units used by * {@link #computeHorizontalScrollRange()} and {@link #computeHorizontalScrollExtent()}.

* *

Default implementation returns 0.

* *

If you want to support scroll bars, override * {@link RecyclerView.LayoutManager#computeHorizontalScrollOffset(RecyclerView.State)} in your * LayoutManager.

* * @return The horizontal offset of the scrollbar's thumb * @see com.android.internal.widget.RecyclerView.LayoutManager#computeHorizontalScrollOffset * (RecyclerView.State) */ @Override public int computeHorizontalScrollOffset() { if (mLayout == null) { return 0; } return mLayout.canScrollHorizontally() ? mLayout.computeHorizontalScrollOffset(mState) : 0; } /** *

Compute the horizontal extent of the horizontal scrollbar's thumb within the * horizontal range. This value is used to compute the length of the thumb within the * scrollbar's track.

* *

The range is expressed in arbitrary units that must be the same as the units used by * {@link #computeHorizontalScrollRange()} and {@link #computeHorizontalScrollOffset()}.

* *

Default implementation returns 0.

* *

If you want to support scroll bars, override * {@link RecyclerView.LayoutManager#computeHorizontalScrollExtent(RecyclerView.State)} in your * LayoutManager.

* * @return The horizontal extent of the scrollbar's thumb * @see RecyclerView.LayoutManager#computeHorizontalScrollExtent(RecyclerView.State) */ @Override public int computeHorizontalScrollExtent() { if (mLayout == null) { return 0; } return mLayout.canScrollHorizontally() ? mLayout.computeHorizontalScrollExtent(mState) : 0; } /** *

Compute the horizontal range that the horizontal scrollbar represents.

* *

The range is expressed in arbitrary units that must be the same as the units used by * {@link #computeHorizontalScrollExtent()} and {@link #computeHorizontalScrollOffset()}.

* *

Default implementation returns 0.

* *

If you want to support scroll bars, override * {@link RecyclerView.LayoutManager#computeHorizontalScrollRange(RecyclerView.State)} in your * LayoutManager.

* * @return The total horizontal range represented by the vertical scrollbar * @see RecyclerView.LayoutManager#computeHorizontalScrollRange(RecyclerView.State) */ @Override public int computeHorizontalScrollRange() { if (mLayout == null) { return 0; } return mLayout.canScrollHorizontally() ? mLayout.computeHorizontalScrollRange(mState) : 0; } /** *

Compute the vertical offset of the vertical scrollbar's thumb within the vertical range. * This value is used to compute the length of the thumb within the scrollbar's track.

* *

The range is expressed in arbitrary units that must be the same as the units used by * {@link #computeVerticalScrollRange()} and {@link #computeVerticalScrollExtent()}.

* *

Default implementation returns 0.

* *

If you want to support scroll bars, override * {@link RecyclerView.LayoutManager#computeVerticalScrollOffset(RecyclerView.State)} in your * LayoutManager.

* * @return The vertical offset of the scrollbar's thumb * @see com.android.internal.widget.RecyclerView.LayoutManager#computeVerticalScrollOffset * (RecyclerView.State) */ @Override public int computeVerticalScrollOffset() { if (mLayout == null) { return 0; } return mLayout.canScrollVertically() ? mLayout.computeVerticalScrollOffset(mState) : 0; } /** *

Compute the vertical extent of the vertical scrollbar's thumb within the vertical range. * This value is used to compute the length of the thumb within the scrollbar's track.

* *

The range is expressed in arbitrary units that must be the same as the units used by * {@link #computeVerticalScrollRange()} and {@link #computeVerticalScrollOffset()}.

* *

Default implementation returns 0.

* *

If you want to support scroll bars, override * {@link RecyclerView.LayoutManager#computeVerticalScrollExtent(RecyclerView.State)} in your * LayoutManager.

* * @return The vertical extent of the scrollbar's thumb * @see RecyclerView.LayoutManager#computeVerticalScrollExtent(RecyclerView.State) */ @Override public int computeVerticalScrollExtent() { if (mLayout == null) { return 0; } return mLayout.canScrollVertically() ? mLayout.computeVerticalScrollExtent(mState) : 0; } /** *

Compute the vertical range that the vertical scrollbar represents.

* *

The range is expressed in arbitrary units that must be the same as the units used by * {@link #computeVerticalScrollExtent()} and {@link #computeVerticalScrollOffset()}.

* *

Default implementation returns 0.

* *

If you want to support scroll bars, override * {@link RecyclerView.LayoutManager#computeVerticalScrollRange(RecyclerView.State)} in your * LayoutManager.

* * @return The total vertical range represented by the vertical scrollbar * @see RecyclerView.LayoutManager#computeVerticalScrollRange(RecyclerView.State) */ @Override public int computeVerticalScrollRange() { if (mLayout == null) { return 0; } return mLayout.canScrollVertically() ? mLayout.computeVerticalScrollRange(mState) : 0; } void eatRequestLayout() { mEatRequestLayout++; if (mEatRequestLayout == 1 && !mLayoutFrozen) { mLayoutRequestEaten = false; } } void resumeRequestLayout(boolean performLayoutChildren) { if (mEatRequestLayout < 1) { //noinspection PointlessBooleanExpression if (DEBUG) { throw new IllegalStateException("invalid eat request layout count"); } mEatRequestLayout = 1; } if (!performLayoutChildren) { // Reset the layout request eaten counter. // This is necessary since eatRequest calls can be nested in which case the other // call will override the inner one. // for instance: // eat layout for process adapter updates // eat layout for dispatchLayout // a bunch of req layout calls arrive mLayoutRequestEaten = false; } if (mEatRequestLayout == 1) { // when layout is frozen we should delay dispatchLayout() if (performLayoutChildren && mLayoutRequestEaten && !mLayoutFrozen && mLayout != null && mAdapter != null) { dispatchLayout(); } if (!mLayoutFrozen) { mLayoutRequestEaten = false; } } mEatRequestLayout--; } /** * Enable or disable layout and scroll. After setLayoutFrozen(true) is called, * Layout requests will be postponed until setLayoutFrozen(false) is called; * child views are not updated when RecyclerView is frozen, {@link #smoothScrollBy(int, int)}, * {@link #scrollBy(int, int)}, {@link #scrollToPosition(int)} and * {@link #smoothScrollToPosition(int)} are dropped; TouchEvents and GenericMotionEvents are * dropped; {@link LayoutManager#onFocusSearchFailed(View, int, Recycler, State)} will not be * called. * *

* setLayoutFrozen(true) does not prevent app from directly calling {@link * LayoutManager#scrollToPosition(int)}, {@link LayoutManager#smoothScrollToPosition( * RecyclerView, State, int)}. *

* {@link #setAdapter(Adapter)} and {@link #swapAdapter(Adapter, boolean)} will automatically * stop frozen. *

* Note: Running ItemAnimator is not stopped automatically, it's caller's * responsibility to call ItemAnimator.end(). * * @param frozen true to freeze layout and scroll, false to re-enable. */ public void setLayoutFrozen(boolean frozen) { if (frozen != mLayoutFrozen) { assertNotInLayoutOrScroll("Do not setLayoutFrozen in layout or scroll"); if (!frozen) { mLayoutFrozen = false; if (mLayoutRequestEaten && mLayout != null && mAdapter != null) { requestLayout(); } mLayoutRequestEaten = false; } else { final long now = SystemClock.uptimeMillis(); MotionEvent cancelEvent = MotionEvent.obtain(now, now, MotionEvent.ACTION_CANCEL, 0.0f, 0.0f, 0); onTouchEvent(cancelEvent); mLayoutFrozen = true; mIgnoreMotionEventTillDown = true; stopScroll(); } } } /** * Returns true if layout and scroll are frozen. * * @return true if layout and scroll are frozen * @see #setLayoutFrozen(boolean) */ public boolean isLayoutFrozen() { return mLayoutFrozen; } /** * Animate a scroll by the given amount of pixels along either axis. * * @param dx Pixels to scroll horizontally * @param dy Pixels to scroll vertically */ public void smoothScrollBy(int dx, int dy) { smoothScrollBy(dx, dy, null); } /** * Animate a scroll by the given amount of pixels along either axis. * * @param dx Pixels to scroll horizontally * @param dy Pixels to scroll vertically * @param interpolator {@link Interpolator} to be used for scrolling. If it is * {@code null}, RecyclerView is going to use the default interpolator. */ public void smoothScrollBy(int dx, int dy, Interpolator interpolator) { if (mLayout == null) { Log.e(TAG, "Cannot smooth scroll without a LayoutManager set. " + "Call setLayoutManager with a non-null argument."); return; } if (mLayoutFrozen) { return; } if (!mLayout.canScrollHorizontally()) { dx = 0; } if (!mLayout.canScrollVertically()) { dy = 0; } if (dx != 0 || dy != 0) { mViewFlinger.smoothScrollBy(dx, dy, interpolator); } } /** * Begin a standard fling with an initial velocity along each axis in pixels per second. * If the velocity given is below the system-defined minimum this method will return false * and no fling will occur. * * @param velocityX Initial horizontal velocity in pixels per second * @param velocityY Initial vertical velocity in pixels per second * @return true if the fling was started, false if the velocity was too low to fling or * LayoutManager does not support scrolling in the axis fling is issued. * * @see LayoutManager#canScrollVertically() * @see LayoutManager#canScrollHorizontally() */ public boolean fling(int velocityX, int velocityY) { if (mLayout == null) { Log.e(TAG, "Cannot fling without a LayoutManager set. " + "Call setLayoutManager with a non-null argument."); return false; } if (mLayoutFrozen) { return false; } final boolean canScrollHorizontal = mLayout.canScrollHorizontally(); final boolean canScrollVertical = mLayout.canScrollVertically(); if (!canScrollHorizontal || Math.abs(velocityX) < mMinFlingVelocity) { velocityX = 0; } if (!canScrollVertical || Math.abs(velocityY) < mMinFlingVelocity) { velocityY = 0; } if (velocityX == 0 && velocityY == 0) { // If we don't have any velocity, return false return false; } if (!dispatchNestedPreFling(velocityX, velocityY)) { final boolean canScroll = canScrollHorizontal || canScrollVertical; dispatchNestedFling(velocityX, velocityY, canScroll); if (mOnFlingListener != null && mOnFlingListener.onFling(velocityX, velocityY)) { return true; } if (canScroll) { velocityX = Math.max(-mMaxFlingVelocity, Math.min(velocityX, mMaxFlingVelocity)); velocityY = Math.max(-mMaxFlingVelocity, Math.min(velocityY, mMaxFlingVelocity)); mViewFlinger.fling(velocityX, velocityY); return true; } } return false; } /** * Stop any current scroll in progress, such as one started by * {@link #smoothScrollBy(int, int)}, {@link #fling(int, int)} or a touch-initiated fling. */ public void stopScroll() { setScrollState(SCROLL_STATE_IDLE); stopScrollersInternal(); } /** * Similar to {@link #stopScroll()} but does not set the state. */ private void stopScrollersInternal() { mViewFlinger.stop(); if (mLayout != null) { mLayout.stopSmoothScroller(); } } /** * Returns the minimum velocity to start a fling. * * @return The minimum velocity to start a fling */ public int getMinFlingVelocity() { return mMinFlingVelocity; } /** * Returns the maximum fling velocity used by this RecyclerView. * * @return The maximum fling velocity used by this RecyclerView. */ public int getMaxFlingVelocity() { return mMaxFlingVelocity; } /** * Apply a pull to relevant overscroll glow effects */ private void pullGlows(float x, float overscrollX, float y, float overscrollY) { boolean invalidate = false; if (overscrollX < 0) { ensureLeftGlow(); mLeftGlow.onPull(-overscrollX / getWidth(), 1f - y / getHeight()); invalidate = true; } else if (overscrollX > 0) { ensureRightGlow(); mRightGlow.onPull(overscrollX / getWidth(), y / getHeight()); invalidate = true; } if (overscrollY < 0) { ensureTopGlow(); mTopGlow.onPull(-overscrollY / getHeight(), x / getWidth()); invalidate = true; } else if (overscrollY > 0) { ensureBottomGlow(); mBottomGlow.onPull(overscrollY / getHeight(), 1f - x / getWidth()); invalidate = true; } if (invalidate || overscrollX != 0 || overscrollY != 0) { postInvalidateOnAnimation(); } } private void releaseGlows() { boolean needsInvalidate = false; if (mLeftGlow != null) { mLeftGlow.onRelease(); needsInvalidate = true; } if (mTopGlow != null) { mTopGlow.onRelease(); needsInvalidate = true; } if (mRightGlow != null) { mRightGlow.onRelease(); needsInvalidate = true; } if (mBottomGlow != null) { mBottomGlow.onRelease(); needsInvalidate = true; } if (needsInvalidate) { postInvalidateOnAnimation(); } } void considerReleasingGlowsOnScroll(int dx, int dy) { boolean needsInvalidate = false; if (mLeftGlow != null && !mLeftGlow.isFinished() && dx > 0) { mLeftGlow.onRelease(); needsInvalidate = true; } if (mRightGlow != null && !mRightGlow.isFinished() && dx < 0) { mRightGlow.onRelease(); needsInvalidate = true; } if (mTopGlow != null && !mTopGlow.isFinished() && dy > 0) { mTopGlow.onRelease(); needsInvalidate = true; } if (mBottomGlow != null && !mBottomGlow.isFinished() && dy < 0) { mBottomGlow.onRelease(); needsInvalidate = true; } if (needsInvalidate) { postInvalidateOnAnimation(); } } void absorbGlows(int velocityX, int velocityY) { if (velocityX < 0) { ensureLeftGlow(); mLeftGlow.onAbsorb(-velocityX); } else if (velocityX > 0) { ensureRightGlow(); mRightGlow.onAbsorb(velocityX); } if (velocityY < 0) { ensureTopGlow(); mTopGlow.onAbsorb(-velocityY); } else if (velocityY > 0) { ensureBottomGlow(); mBottomGlow.onAbsorb(velocityY); } if (velocityX != 0 || velocityY != 0) { postInvalidateOnAnimation(); } } void ensureLeftGlow() { if (mLeftGlow != null) { return; } mLeftGlow = new EdgeEffect(getContext()); if (mClipToPadding) { mLeftGlow.setSize(getMeasuredHeight() - getPaddingTop() - getPaddingBottom(), getMeasuredWidth() - getPaddingLeft() - getPaddingRight()); } else { mLeftGlow.setSize(getMeasuredHeight(), getMeasuredWidth()); } } void ensureRightGlow() { if (mRightGlow != null) { return; } mRightGlow = new EdgeEffect(getContext()); if (mClipToPadding) { mRightGlow.setSize(getMeasuredHeight() - getPaddingTop() - getPaddingBottom(), getMeasuredWidth() - getPaddingLeft() - getPaddingRight()); } else { mRightGlow.setSize(getMeasuredHeight(), getMeasuredWidth()); } } void ensureTopGlow() { if (mTopGlow != null) { return; } mTopGlow = new EdgeEffect(getContext()); if (mClipToPadding) { mTopGlow.setSize(getMeasuredWidth() - getPaddingLeft() - getPaddingRight(), getMeasuredHeight() - getPaddingTop() - getPaddingBottom()); } else { mTopGlow.setSize(getMeasuredWidth(), getMeasuredHeight()); } } void ensureBottomGlow() { if (mBottomGlow != null) { return; } mBottomGlow = new EdgeEffect(getContext()); if (mClipToPadding) { mBottomGlow.setSize(getMeasuredWidth() - getPaddingLeft() - getPaddingRight(), getMeasuredHeight() - getPaddingTop() - getPaddingBottom()); } else { mBottomGlow.setSize(getMeasuredWidth(), getMeasuredHeight()); } } void invalidateGlows() { mLeftGlow = mRightGlow = mTopGlow = mBottomGlow = null; } /** * Since RecyclerView is a collection ViewGroup that includes virtual children (items that are * in the Adapter but not visible in the UI), it employs a more involved focus search strategy * that differs from other ViewGroups. *

* It first does a focus search within the RecyclerView. If this search finds a View that is in * the focus direction with respect to the currently focused View, RecyclerView returns that * child as the next focus target. When it cannot find such child, it calls * {@link LayoutManager#onFocusSearchFailed(View, int, Recycler, State)} to layout more Views * in the focus search direction. If LayoutManager adds a View that matches the * focus search criteria, it will be returned as the focus search result. Otherwise, * RecyclerView will call parent to handle the focus search like a regular ViewGroup. *

* When the direction is {@link View#FOCUS_FORWARD} or {@link View#FOCUS_BACKWARD}, a View that * is not in the focus direction is still valid focus target which may not be the desired * behavior if the Adapter has more children in the focus direction. To handle this case, * RecyclerView converts the focus direction to an absolute direction and makes a preliminary * focus search in that direction. If there are no Views to gain focus, it will call * {@link LayoutManager#onFocusSearchFailed(View, int, Recycler, State)} before running a * focus search with the original (relative) direction. This allows RecyclerView to provide * better candidates to the focus search while still allowing the view system to take focus from * the RecyclerView and give it to a more suitable child if such child exists. * * @param focused The view that currently has focus * @param direction One of {@link View#FOCUS_UP}, {@link View#FOCUS_DOWN}, * {@link View#FOCUS_LEFT}, {@link View#FOCUS_RIGHT}, {@link View#FOCUS_FORWARD}, * {@link View#FOCUS_BACKWARD} or 0 for not applicable. * * @return A new View that can be the next focus after the focused View */ @Override public View focusSearch(View focused, int direction) { View result = mLayout.onInterceptFocusSearch(focused, direction); if (result != null) { return result; } final boolean canRunFocusFailure = mAdapter != null && mLayout != null && !isComputingLayout() && !mLayoutFrozen; final FocusFinder ff = FocusFinder.getInstance(); if (canRunFocusFailure && (direction == View.FOCUS_FORWARD || direction == View.FOCUS_BACKWARD)) { // convert direction to absolute direction and see if we have a view there and if not // tell LayoutManager to add if it can. boolean needsFocusFailureLayout = false; if (mLayout.canScrollVertically()) { final int absDir = direction == View.FOCUS_FORWARD ? View.FOCUS_DOWN : View.FOCUS_UP; final View found = ff.findNextFocus(this, focused, absDir); needsFocusFailureLayout = found == null; if (FORCE_ABS_FOCUS_SEARCH_DIRECTION) { // Workaround for broken FOCUS_BACKWARD in API 15 and older devices. direction = absDir; } } if (!needsFocusFailureLayout && mLayout.canScrollHorizontally()) { boolean rtl = mLayout.getLayoutDirection() == View.LAYOUT_DIRECTION_RTL; final int absDir = (direction == View.FOCUS_FORWARD) ^ rtl ? View.FOCUS_RIGHT : View.FOCUS_LEFT; final View found = ff.findNextFocus(this, focused, absDir); needsFocusFailureLayout = found == null; if (FORCE_ABS_FOCUS_SEARCH_DIRECTION) { // Workaround for broken FOCUS_BACKWARD in API 15 and older devices. direction = absDir; } } if (needsFocusFailureLayout) { consumePendingUpdateOperations(); final View focusedItemView = findContainingItemView(focused); if (focusedItemView == null) { // panic, focused view is not a child anymore, cannot call super. return null; } eatRequestLayout(); mLayout.onFocusSearchFailed(focused, direction, mRecycler, mState); resumeRequestLayout(false); } result = ff.findNextFocus(this, focused, direction); } else { result = ff.findNextFocus(this, focused, direction); if (result == null && canRunFocusFailure) { consumePendingUpdateOperations(); final View focusedItemView = findContainingItemView(focused); if (focusedItemView == null) { // panic, focused view is not a child anymore, cannot call super. return null; } eatRequestLayout(); result = mLayout.onFocusSearchFailed(focused, direction, mRecycler, mState); resumeRequestLayout(false); } } return isPreferredNextFocus(focused, result, direction) ? result : super.focusSearch(focused, direction); } /** * Checks if the new focus candidate is a good enough candidate such that RecyclerView will * assign it as the next focus View instead of letting view hierarchy decide. * A good candidate means a View that is aligned in the focus direction wrt the focused View * and is not the RecyclerView itself. * When this method returns false, RecyclerView will let the parent make the decision so the * same View may still get the focus as a result of that search. */ private boolean isPreferredNextFocus(View focused, View next, int direction) { if (next == null || next == this) { return false; } if (focused == null) { return true; } if (direction == View.FOCUS_FORWARD || direction == View.FOCUS_BACKWARD) { final boolean rtl = mLayout.getLayoutDirection() == View.LAYOUT_DIRECTION_RTL; final int absHorizontal = (direction == View.FOCUS_FORWARD) ^ rtl ? View.FOCUS_RIGHT : View.FOCUS_LEFT; if (isPreferredNextFocusAbsolute(focused, next, absHorizontal)) { return true; } if (direction == View.FOCUS_FORWARD) { return isPreferredNextFocusAbsolute(focused, next, View.FOCUS_DOWN); } else { return isPreferredNextFocusAbsolute(focused, next, View.FOCUS_UP); } } else { return isPreferredNextFocusAbsolute(focused, next, direction); } } /** * Logic taken from FocusSearch#isCandidate */ private boolean isPreferredNextFocusAbsolute(View focused, View next, int direction) { mTempRect.set(0, 0, focused.getWidth(), focused.getHeight()); mTempRect2.set(0, 0, next.getWidth(), next.getHeight()); offsetDescendantRectToMyCoords(focused, mTempRect); offsetDescendantRectToMyCoords(next, mTempRect2); switch (direction) { case View.FOCUS_LEFT: return (mTempRect.right > mTempRect2.right || mTempRect.left >= mTempRect2.right) && mTempRect.left > mTempRect2.left; case View.FOCUS_RIGHT: return (mTempRect.left < mTempRect2.left || mTempRect.right <= mTempRect2.left) && mTempRect.right < mTempRect2.right; case View.FOCUS_UP: return (mTempRect.bottom > mTempRect2.bottom || mTempRect.top >= mTempRect2.bottom) && mTempRect.top > mTempRect2.top; case View.FOCUS_DOWN: return (mTempRect.top < mTempRect2.top || mTempRect.bottom <= mTempRect2.top) && mTempRect.bottom < mTempRect2.bottom; } throw new IllegalArgumentException("direction must be absolute. received:" + direction); } @Override public void requestChildFocus(View child, View focused) { if (!mLayout.onRequestChildFocus(this, mState, child, focused) && focused != null) { mTempRect.set(0, 0, focused.getWidth(), focused.getHeight()); // get item decor offsets w/o refreshing. If they are invalid, there will be another // layout pass to fix them, then it is LayoutManager's responsibility to keep focused // View in viewport. final ViewGroup.LayoutParams focusedLayoutParams = focused.getLayoutParams(); if (focusedLayoutParams instanceof LayoutParams) { // if focused child has item decors, use them. Otherwise, ignore. final LayoutParams lp = (LayoutParams) focusedLayoutParams; if (!lp.mInsetsDirty) { final Rect insets = lp.mDecorInsets; mTempRect.left -= insets.left; mTempRect.right += insets.right; mTempRect.top -= insets.top; mTempRect.bottom += insets.bottom; } } offsetDescendantRectToMyCoords(focused, mTempRect); offsetRectIntoDescendantCoords(child, mTempRect); requestChildRectangleOnScreen(child, mTempRect, !mFirstLayoutComplete); } super.requestChildFocus(child, focused); } @Override public boolean requestChildRectangleOnScreen(View child, Rect rect, boolean immediate) { return mLayout.requestChildRectangleOnScreen(this, child, rect, immediate); } @Override public void addFocusables(ArrayList views, int direction, int focusableMode) { if (mLayout == null || !mLayout.onAddFocusables(this, views, direction, focusableMode)) { super.addFocusables(views, direction, focusableMode); } } @Override protected boolean onRequestFocusInDescendants(int direction, Rect previouslyFocusedRect) { if (isComputingLayout()) { // if we are in the middle of a layout calculation, don't let any child take focus. // RV will handle it after layout calculation is finished. return false; } return super.onRequestFocusInDescendants(direction, previouslyFocusedRect); } @Override protected void onAttachedToWindow() { super.onAttachedToWindow(); mLayoutOrScrollCounter = 0; mIsAttached = true; mFirstLayoutComplete = mFirstLayoutComplete && !isLayoutRequested(); if (mLayout != null) { mLayout.dispatchAttachedToWindow(this); } mPostedAnimatorRunner = false; if (ALLOW_THREAD_GAP_WORK) { // Register with gap worker mGapWorker = GapWorker.sGapWorker.get(); if (mGapWorker == null) { mGapWorker = new GapWorker(); // break 60 fps assumption if data from display appears valid // NOTE: we only do this query once, statically, because it's very expensive (> 1ms) Display display = getDisplay(); float refreshRate = 60.0f; if (!isInEditMode() && display != null) { float displayRefreshRate = display.getRefreshRate(); if (displayRefreshRate >= 30.0f) { refreshRate = displayRefreshRate; } } mGapWorker.mFrameIntervalNs = (long) (1000000000 / refreshRate); GapWorker.sGapWorker.set(mGapWorker); } mGapWorker.add(this); } } @Override protected void onDetachedFromWindow() { super.onDetachedFromWindow(); if (mItemAnimator != null) { mItemAnimator.endAnimations(); } stopScroll(); mIsAttached = false; if (mLayout != null) { mLayout.dispatchDetachedFromWindow(this, mRecycler); } mPendingAccessibilityImportanceChange.clear(); removeCallbacks(mItemAnimatorRunner); mViewInfoStore.onDetach(); if (ALLOW_THREAD_GAP_WORK) { // Unregister with gap worker mGapWorker.remove(this); mGapWorker = null; } } /** * Returns true if RecyclerView is attached to window. */ // @override public boolean isAttachedToWindow() { return mIsAttached; } /** * Checks if RecyclerView is in the middle of a layout or scroll and throws an * {@link IllegalStateException} if it is not. * * @param message The message for the exception. Can be null. * @see #assertNotInLayoutOrScroll(String) */ void assertInLayoutOrScroll(String message) { if (!isComputingLayout()) { if (message == null) { throw new IllegalStateException("Cannot call this method unless RecyclerView is " + "computing a layout or scrolling"); } throw new IllegalStateException(message); } } /** * Checks if RecyclerView is in the middle of a layout or scroll and throws an * {@link IllegalStateException} if it is. * * @param message The message for the exception. Can be null. * @see #assertInLayoutOrScroll(String) */ void assertNotInLayoutOrScroll(String message) { if (isComputingLayout()) { if (message == null) { throw new IllegalStateException("Cannot call this method while RecyclerView is " + "computing a layout or scrolling"); } throw new IllegalStateException(message); } if (mDispatchScrollCounter > 0) { Log.w(TAG, "Cannot call this method in a scroll callback. Scroll callbacks might be run" + " during a measure & layout pass where you cannot change the RecyclerView" + " data. Any method call that might change the structure of the RecyclerView" + " or the adapter contents should be postponed to the next frame.", new IllegalStateException("")); } } /** * Add an {@link OnItemTouchListener} to intercept touch events before they are dispatched * to child views or this view's standard scrolling behavior. * *

Client code may use listeners to implement item manipulation behavior. Once a listener * returns true from * {@link OnItemTouchListener#onInterceptTouchEvent(RecyclerView, MotionEvent)} its * {@link OnItemTouchListener#onTouchEvent(RecyclerView, MotionEvent)} method will be called * for each incoming MotionEvent until the end of the gesture.

* * @param listener Listener to add * @see SimpleOnItemTouchListener */ public void addOnItemTouchListener(OnItemTouchListener listener) { mOnItemTouchListeners.add(listener); } /** * Remove an {@link OnItemTouchListener}. It will no longer be able to intercept touch events. * * @param listener Listener to remove */ public void removeOnItemTouchListener(OnItemTouchListener listener) { mOnItemTouchListeners.remove(listener); if (mActiveOnItemTouchListener == listener) { mActiveOnItemTouchListener = null; } } private boolean dispatchOnItemTouchIntercept(MotionEvent e) { final int action = e.getAction(); if (action == MotionEvent.ACTION_CANCEL || action == MotionEvent.ACTION_DOWN) { mActiveOnItemTouchListener = null; } final int listenerCount = mOnItemTouchListeners.size(); for (int i = 0; i < listenerCount; i++) { final OnItemTouchListener listener = mOnItemTouchListeners.get(i); if (listener.onInterceptTouchEvent(this, e) && action != MotionEvent.ACTION_CANCEL) { mActiveOnItemTouchListener = listener; return true; } } return false; } private boolean dispatchOnItemTouch(MotionEvent e) { final int action = e.getAction(); if (mActiveOnItemTouchListener != null) { if (action == MotionEvent.ACTION_DOWN) { // Stale state from a previous gesture, we're starting a new one. Clear it. mActiveOnItemTouchListener = null; } else { mActiveOnItemTouchListener.onTouchEvent(this, e); if (action == MotionEvent.ACTION_CANCEL || action == MotionEvent.ACTION_UP) { // Clean up for the next gesture. mActiveOnItemTouchListener = null; } return true; } } // Listeners will have already received the ACTION_DOWN via dispatchOnItemTouchIntercept // as called from onInterceptTouchEvent; skip it. if (action != MotionEvent.ACTION_DOWN) { final int listenerCount = mOnItemTouchListeners.size(); for (int i = 0; i < listenerCount; i++) { final OnItemTouchListener listener = mOnItemTouchListeners.get(i); if (listener.onInterceptTouchEvent(this, e)) { mActiveOnItemTouchListener = listener; return true; } } } return false; } @Override public boolean onInterceptTouchEvent(MotionEvent e) { if (mLayoutFrozen) { // When layout is frozen, RV does not intercept the motion event. // A child view e.g. a button may still get the click. return false; } if (dispatchOnItemTouchIntercept(e)) { cancelTouch(); return true; } if (mLayout == null) { return false; } final boolean canScrollHorizontally = mLayout.canScrollHorizontally(); final boolean canScrollVertically = mLayout.canScrollVertically(); if (mVelocityTracker == null) { mVelocityTracker = VelocityTracker.obtain(); } mVelocityTracker.addMovement(e); final int action = e.getActionMasked(); final int actionIndex = e.getActionIndex(); switch (action) { case MotionEvent.ACTION_DOWN: if (mIgnoreMotionEventTillDown) { mIgnoreMotionEventTillDown = false; } mScrollPointerId = e.getPointerId(0); mInitialTouchX = mLastTouchX = (int) (e.getX() + 0.5f); mInitialTouchY = mLastTouchY = (int) (e.getY() + 0.5f); if (mScrollState == SCROLL_STATE_SETTLING) { getParent().requestDisallowInterceptTouchEvent(true); setScrollState(SCROLL_STATE_DRAGGING); } // Clear the nested offsets mNestedOffsets[0] = mNestedOffsets[1] = 0; int nestedScrollAxis = View.SCROLL_AXIS_NONE; if (canScrollHorizontally) { nestedScrollAxis |= View.SCROLL_AXIS_HORIZONTAL; } if (canScrollVertically) { nestedScrollAxis |= View.SCROLL_AXIS_VERTICAL; } startNestedScroll(nestedScrollAxis); break; case MotionEvent.ACTION_POINTER_DOWN: mScrollPointerId = e.getPointerId(actionIndex); mInitialTouchX = mLastTouchX = (int) (e.getX(actionIndex) + 0.5f); mInitialTouchY = mLastTouchY = (int) (e.getY(actionIndex) + 0.5f); break; case MotionEvent.ACTION_MOVE: { final int index = e.findPointerIndex(mScrollPointerId); if (index < 0) { Log.e(TAG, "Error processing scroll; pointer index for id " + mScrollPointerId + " not found. Did any MotionEvents get skipped?"); return false; } final int x = (int) (e.getX(index) + 0.5f); final int y = (int) (e.getY(index) + 0.5f); if (mScrollState != SCROLL_STATE_DRAGGING) { final int dx = x - mInitialTouchX; final int dy = y - mInitialTouchY; boolean startScroll = false; if (canScrollHorizontally && Math.abs(dx) > mTouchSlop) { mLastTouchX = mInitialTouchX + mTouchSlop * (dx < 0 ? -1 : 1); startScroll = true; } if (canScrollVertically && Math.abs(dy) > mTouchSlop) { mLastTouchY = mInitialTouchY + mTouchSlop * (dy < 0 ? -1 : 1); startScroll = true; } if (startScroll) { setScrollState(SCROLL_STATE_DRAGGING); } } } break; case MotionEvent.ACTION_POINTER_UP: { onPointerUp(e); } break; case MotionEvent.ACTION_UP: { mVelocityTracker.clear(); stopNestedScroll(); } break; case MotionEvent.ACTION_CANCEL: { cancelTouch(); } } return mScrollState == SCROLL_STATE_DRAGGING; } @Override public void requestDisallowInterceptTouchEvent(boolean disallowIntercept) { final int listenerCount = mOnItemTouchListeners.size(); for (int i = 0; i < listenerCount; i++) { final OnItemTouchListener listener = mOnItemTouchListeners.get(i); listener.onRequestDisallowInterceptTouchEvent(disallowIntercept); } super.requestDisallowInterceptTouchEvent(disallowIntercept); } @Override public boolean onTouchEvent(MotionEvent e) { if (mLayoutFrozen || mIgnoreMotionEventTillDown) { return false; } if (dispatchOnItemTouch(e)) { cancelTouch(); return true; } if (mLayout == null) { return false; } final boolean canScrollHorizontally = mLayout.canScrollHorizontally(); final boolean canScrollVertically = mLayout.canScrollVertically(); if (mVelocityTracker == null) { mVelocityTracker = VelocityTracker.obtain(); } boolean eventAddedToVelocityTracker = false; final MotionEvent vtev = MotionEvent.obtain(e); final int action = e.getActionMasked(); final int actionIndex = e.getActionIndex(); if (action == MotionEvent.ACTION_DOWN) { mNestedOffsets[0] = mNestedOffsets[1] = 0; } vtev.offsetLocation(mNestedOffsets[0], mNestedOffsets[1]); switch (action) { case MotionEvent.ACTION_DOWN: { mScrollPointerId = e.getPointerId(0); mInitialTouchX = mLastTouchX = (int) (e.getX() + 0.5f); mInitialTouchY = mLastTouchY = (int) (e.getY() + 0.5f); int nestedScrollAxis = View.SCROLL_AXIS_NONE; if (canScrollHorizontally) { nestedScrollAxis |= View.SCROLL_AXIS_HORIZONTAL; } if (canScrollVertically) { nestedScrollAxis |= View.SCROLL_AXIS_VERTICAL; } startNestedScroll(nestedScrollAxis); } break; case MotionEvent.ACTION_POINTER_DOWN: { mScrollPointerId = e.getPointerId(actionIndex); mInitialTouchX = mLastTouchX = (int) (e.getX(actionIndex) + 0.5f); mInitialTouchY = mLastTouchY = (int) (e.getY(actionIndex) + 0.5f); } break; case MotionEvent.ACTION_MOVE: { final int index = e.findPointerIndex(mScrollPointerId); if (index < 0) { Log.e(TAG, "Error processing scroll; pointer index for id " + mScrollPointerId + " not found. Did any MotionEvents get skipped?"); return false; } final int x = (int) (e.getX(index) + 0.5f); final int y = (int) (e.getY(index) + 0.5f); int dx = mLastTouchX - x; int dy = mLastTouchY - y; if (dispatchNestedPreScroll(dx, dy, mScrollConsumed, mScrollOffset)) { dx -= mScrollConsumed[0]; dy -= mScrollConsumed[1]; vtev.offsetLocation(mScrollOffset[0], mScrollOffset[1]); // Updated the nested offsets mNestedOffsets[0] += mScrollOffset[0]; mNestedOffsets[1] += mScrollOffset[1]; } if (mScrollState != SCROLL_STATE_DRAGGING) { boolean startScroll = false; if (canScrollHorizontally && Math.abs(dx) > mTouchSlop) { if (dx > 0) { dx -= mTouchSlop; } else { dx += mTouchSlop; } startScroll = true; } if (canScrollVertically && Math.abs(dy) > mTouchSlop) { if (dy > 0) { dy -= mTouchSlop; } else { dy += mTouchSlop; } startScroll = true; } if (startScroll) { setScrollState(SCROLL_STATE_DRAGGING); } } if (mScrollState == SCROLL_STATE_DRAGGING) { mLastTouchX = x - mScrollOffset[0]; mLastTouchY = y - mScrollOffset[1]; if (scrollByInternal( canScrollHorizontally ? dx : 0, canScrollVertically ? dy : 0, vtev)) { getParent().requestDisallowInterceptTouchEvent(true); } if (mGapWorker != null && (dx != 0 || dy != 0)) { mGapWorker.postFromTraversal(this, dx, dy); } } } break; case MotionEvent.ACTION_POINTER_UP: { onPointerUp(e); } break; case MotionEvent.ACTION_UP: { mVelocityTracker.addMovement(vtev); eventAddedToVelocityTracker = true; mVelocityTracker.computeCurrentVelocity(1000, mMaxFlingVelocity); final float xvel = canScrollHorizontally ? -mVelocityTracker.getXVelocity(mScrollPointerId) : 0; final float yvel = canScrollVertically ? -mVelocityTracker.getYVelocity(mScrollPointerId) : 0; if (!((xvel != 0 || yvel != 0) && fling((int) xvel, (int) yvel))) { setScrollState(SCROLL_STATE_IDLE); } resetTouch(); } break; case MotionEvent.ACTION_CANCEL: { cancelTouch(); } break; } if (!eventAddedToVelocityTracker) { mVelocityTracker.addMovement(vtev); } vtev.recycle(); return true; } private void resetTouch() { if (mVelocityTracker != null) { mVelocityTracker.clear(); } stopNestedScroll(); releaseGlows(); } private void cancelTouch() { resetTouch(); setScrollState(SCROLL_STATE_IDLE); } private void onPointerUp(MotionEvent e) { final int actionIndex = e.getActionIndex(); if (e.getPointerId(actionIndex) == mScrollPointerId) { // Pick a new pointer to pick up the slack. final int newIndex = actionIndex == 0 ? 1 : 0; mScrollPointerId = e.getPointerId(newIndex); mInitialTouchX = mLastTouchX = (int) (e.getX(newIndex) + 0.5f); mInitialTouchY = mLastTouchY = (int) (e.getY(newIndex) + 0.5f); } } // @Override public boolean onGenericMotionEvent(MotionEvent event) { if (mLayout == null) { return false; } if (mLayoutFrozen) { return false; } if ((event.getSource() & InputDevice.SOURCE_CLASS_POINTER) != 0) { if (event.getAction() == MotionEvent.ACTION_SCROLL) { final float vScroll, hScroll; if (mLayout.canScrollVertically()) { // Inverse the sign of the vertical scroll to align the scroll orientation // with AbsListView. vScroll = -event.getAxisValue(MotionEvent.AXIS_VSCROLL); } else { vScroll = 0f; } if (mLayout.canScrollHorizontally()) { hScroll = event.getAxisValue(MotionEvent.AXIS_HSCROLL); } else { hScroll = 0f; } if (vScroll != 0 || hScroll != 0) { final float scrollFactor = getScrollFactor(); scrollByInternal((int) (hScroll * scrollFactor), (int) (vScroll * scrollFactor), event); } } } return false; } /** * Ported from View.getVerticalScrollFactor. */ private float getScrollFactor() { if (mScrollFactor == Float.MIN_VALUE) { TypedValue outValue = new TypedValue(); if (getContext().getTheme().resolveAttribute( android.R.attr.listPreferredItemHeight, outValue, true)) { mScrollFactor = outValue.getDimension( getContext().getResources().getDisplayMetrics()); } else { return 0; //listPreferredItemHeight is not defined, no generic scrolling } } return mScrollFactor; } @Override protected void onMeasure(int widthSpec, int heightSpec) { if (mLayout == null) { defaultOnMeasure(widthSpec, heightSpec); return; } if (mLayout.mAutoMeasure) { final int widthMode = MeasureSpec.getMode(widthSpec); final int heightMode = MeasureSpec.getMode(heightSpec); final boolean skipMeasure = widthMode == MeasureSpec.EXACTLY && heightMode == MeasureSpec.EXACTLY; mLayout.onMeasure(mRecycler, mState, widthSpec, heightSpec); if (skipMeasure || mAdapter == null) { return; } if (mState.mLayoutStep == State.STEP_START) { dispatchLayoutStep1(); } // set dimensions in 2nd step. Pre-layout should happen with old dimensions for // consistency mLayout.setMeasureSpecs(widthSpec, heightSpec); mState.mIsMeasuring = true; dispatchLayoutStep2(); // now we can get the width and height from the children. mLayout.setMeasuredDimensionFromChildren(widthSpec, heightSpec); // if RecyclerView has non-exact width and height and if there is at least one child // which also has non-exact width & height, we have to re-measure. if (mLayout.shouldMeasureTwice()) { mLayout.setMeasureSpecs( MeasureSpec.makeMeasureSpec(getMeasuredWidth(), MeasureSpec.EXACTLY), MeasureSpec.makeMeasureSpec(getMeasuredHeight(), MeasureSpec.EXACTLY)); mState.mIsMeasuring = true; dispatchLayoutStep2(); // now we can get the width and height from the children. mLayout.setMeasuredDimensionFromChildren(widthSpec, heightSpec); } } else { if (mHasFixedSize) { mLayout.onMeasure(mRecycler, mState, widthSpec, heightSpec); return; } // custom onMeasure if (mAdapterUpdateDuringMeasure) { eatRequestLayout(); onEnterLayoutOrScroll(); processAdapterUpdatesAndSetAnimationFlags(); onExitLayoutOrScroll(); if (mState.mRunPredictiveAnimations) { mState.mInPreLayout = true; } else { // consume remaining updates to provide a consistent state with the layout pass. mAdapterHelper.consumeUpdatesInOnePass(); mState.mInPreLayout = false; } mAdapterUpdateDuringMeasure = false; resumeRequestLayout(false); } if (mAdapter != null) { mState.mItemCount = mAdapter.getItemCount(); } else { mState.mItemCount = 0; } eatRequestLayout(); mLayout.onMeasure(mRecycler, mState, widthSpec, heightSpec); resumeRequestLayout(false); mState.mInPreLayout = false; // clear } } /** * Used when onMeasure is called before layout manager is set */ void defaultOnMeasure(int widthSpec, int heightSpec) { // calling LayoutManager here is not pretty but that API is already public and it is better // than creating another method since this is internal. final int width = LayoutManager.chooseSize(widthSpec, getPaddingLeft() + getPaddingRight(), getMinimumWidth()); final int height = LayoutManager.chooseSize(heightSpec, getPaddingTop() + getPaddingBottom(), getMinimumHeight()); setMeasuredDimension(width, height); } @Override protected void onSizeChanged(int w, int h, int oldw, int oldh) { super.onSizeChanged(w, h, oldw, oldh); if (w != oldw || h != oldh) { invalidateGlows(); // layout's w/h are updated during measure/layout steps. } } /** * Sets the {@link ItemAnimator} that will handle animations involving changes * to the items in this RecyclerView. By default, RecyclerView instantiates and * uses an instance of {@link DefaultItemAnimator}. Whether item animations are * enabled for the RecyclerView depends on the ItemAnimator and whether * the LayoutManager {@link LayoutManager#supportsPredictiveItemAnimations() * supports item animations}. * * @param animator The ItemAnimator being set. If null, no animations will occur * when changes occur to the items in this RecyclerView. */ public void setItemAnimator(ItemAnimator animator) { if (mItemAnimator != null) { mItemAnimator.endAnimations(); mItemAnimator.setListener(null); } mItemAnimator = animator; if (mItemAnimator != null) { mItemAnimator.setListener(mItemAnimatorListener); } } void onEnterLayoutOrScroll() { mLayoutOrScrollCounter++; } void onExitLayoutOrScroll() { mLayoutOrScrollCounter--; if (mLayoutOrScrollCounter < 1) { if (DEBUG && mLayoutOrScrollCounter < 0) { throw new IllegalStateException("layout or scroll counter cannot go below zero." + "Some calls are not matching"); } mLayoutOrScrollCounter = 0; dispatchContentChangedIfNecessary(); dispatchPendingImportantForAccessibilityChanges(); } } boolean isAccessibilityEnabled() { return mAccessibilityManager != null && mAccessibilityManager.isEnabled(); } private void dispatchContentChangedIfNecessary() { final int flags = mEatenAccessibilityChangeFlags; mEatenAccessibilityChangeFlags = 0; if (flags != 0 && isAccessibilityEnabled()) { final AccessibilityEvent event = AccessibilityEvent.obtain(); event.setEventType(AccessibilityEvent.TYPE_WINDOW_CONTENT_CHANGED); event.setContentChangeTypes(flags); sendAccessibilityEventUnchecked(event); } } /** * Returns whether RecyclerView is currently computing a layout. *

* If this method returns true, it means that RecyclerView is in a lockdown state and any * attempt to update adapter contents will result in an exception because adapter contents * cannot be changed while RecyclerView is trying to compute the layout. *

* It is very unlikely that your code will be running during this state as it is * called by the framework when a layout traversal happens or RecyclerView starts to scroll * in response to system events (touch, accessibility etc). *

* This case may happen if you have some custom logic to change adapter contents in * response to a View callback (e.g. focus change callback) which might be triggered during a * layout calculation. In these cases, you should just postpone the change using a Handler or a * similar mechanism. * * @return true if RecyclerView is currently computing a layout, false * otherwise */ public boolean isComputingLayout() { return mLayoutOrScrollCounter > 0; } /** * Returns true if an accessibility event should not be dispatched now. This happens when an * accessibility request arrives while RecyclerView does not have a stable state which is very * hard to handle for a LayoutManager. Instead, this method records necessary information about * the event and dispatches a window change event after the critical section is finished. * * @return True if the accessibility event should be postponed. */ boolean shouldDeferAccessibilityEvent(AccessibilityEvent event) { if (isComputingLayout()) { int type = 0; if (event != null) { type = event.getContentChangeTypes(); } if (type == 0) { type = AccessibilityEvent.CONTENT_CHANGE_TYPE_UNDEFINED; } mEatenAccessibilityChangeFlags |= type; return true; } return false; } @Override public void sendAccessibilityEventUnchecked(AccessibilityEvent event) { if (shouldDeferAccessibilityEvent(event)) { return; } super.sendAccessibilityEventUnchecked(event); } /** * Gets the current ItemAnimator for this RecyclerView. A null return value * indicates that there is no animator and that item changes will happen without * any animations. By default, RecyclerView instantiates and * uses an instance of {@link DefaultItemAnimator}. * * @return ItemAnimator The current ItemAnimator. If null, no animations will occur * when changes occur to the items in this RecyclerView. */ public ItemAnimator getItemAnimator() { return mItemAnimator; } /** * Post a runnable to the next frame to run pending item animations. Only the first such * request will be posted, governed by the mPostedAnimatorRunner flag. */ void postAnimationRunner() { if (!mPostedAnimatorRunner && mIsAttached) { postOnAnimation(mItemAnimatorRunner); mPostedAnimatorRunner = true; } } private boolean predictiveItemAnimationsEnabled() { return (mItemAnimator != null && mLayout.supportsPredictiveItemAnimations()); } /** * Consumes adapter updates and calculates which type of animations we want to run. * Called in onMeasure and dispatchLayout. *

* This method may process only the pre-layout state of updates or all of them. */ private void processAdapterUpdatesAndSetAnimationFlags() { if (mDataSetHasChangedAfterLayout) { // Processing these items have no value since data set changed unexpectedly. // Instead, we just reset it. mAdapterHelper.reset(); mLayout.onItemsChanged(this); } // simple animations are a subset of advanced animations (which will cause a // pre-layout step) // If layout supports predictive animations, pre-process to decide if we want to run them if (predictiveItemAnimationsEnabled()) { mAdapterHelper.preProcess(); } else { mAdapterHelper.consumeUpdatesInOnePass(); } boolean animationTypeSupported = mItemsAddedOrRemoved || mItemsChanged; mState.mRunSimpleAnimations = mFirstLayoutComplete && mItemAnimator != null && (mDataSetHasChangedAfterLayout || animationTypeSupported || mLayout.mRequestedSimpleAnimations) && (!mDataSetHasChangedAfterLayout || mAdapter.hasStableIds()); mState.mRunPredictiveAnimations = mState.mRunSimpleAnimations && animationTypeSupported && !mDataSetHasChangedAfterLayout && predictiveItemAnimationsEnabled(); } /** * Wrapper around layoutChildren() that handles animating changes caused by layout. * Animations work on the assumption that there are five different kinds of items * in play: * PERSISTENT: items are visible before and after layout * REMOVED: items were visible before layout and were removed by the app * ADDED: items did not exist before layout and were added by the app * DISAPPEARING: items exist in the data set before/after, but changed from * visible to non-visible in the process of layout (they were moved off * screen as a side-effect of other changes) * APPEARING: items exist in the data set before/after, but changed from * non-visible to visible in the process of layout (they were moved on * screen as a side-effect of other changes) * The overall approach figures out what items exist before/after layout and * infers one of the five above states for each of the items. Then the animations * are set up accordingly: * PERSISTENT views are animated via * {@link ItemAnimator#animatePersistence(ViewHolder, ItemHolderInfo, ItemHolderInfo)} * DISAPPEARING views are animated via * {@link ItemAnimator#animateDisappearance(ViewHolder, ItemHolderInfo, ItemHolderInfo)} * APPEARING views are animated via * {@link ItemAnimator#animateAppearance(ViewHolder, ItemHolderInfo, ItemHolderInfo)} * and changed views are animated via * {@link ItemAnimator#animateChange(ViewHolder, ViewHolder, ItemHolderInfo, ItemHolderInfo)}. */ void dispatchLayout() { if (mAdapter == null) { Log.e(TAG, "No adapter attached; skipping layout"); // leave the state in START return; } if (mLayout == null) { Log.e(TAG, "No layout manager attached; skipping layout"); // leave the state in START return; } mState.mIsMeasuring = false; if (mState.mLayoutStep == State.STEP_START) { dispatchLayoutStep1(); mLayout.setExactMeasureSpecsFrom(this); dispatchLayoutStep2(); } else if (mAdapterHelper.hasUpdates() || mLayout.getWidth() != getWidth() || mLayout.getHeight() != getHeight()) { // First 2 steps are done in onMeasure but looks like we have to run again due to // changed size. mLayout.setExactMeasureSpecsFrom(this); dispatchLayoutStep2(); } else { // always make sure we sync them (to ensure mode is exact) mLayout.setExactMeasureSpecsFrom(this); } dispatchLayoutStep3(); } private void saveFocusInfo() { View child = null; if (mPreserveFocusAfterLayout && hasFocus() && mAdapter != null) { child = getFocusedChild(); } final ViewHolder focusedVh = child == null ? null : findContainingViewHolder(child); if (focusedVh == null) { resetFocusInfo(); } else { mState.mFocusedItemId = mAdapter.hasStableIds() ? focusedVh.getItemId() : NO_ID; // mFocusedItemPosition should hold the current adapter position of the previously // focused item. If the item is removed, we store the previous adapter position of the // removed item. mState.mFocusedItemPosition = mDataSetHasChangedAfterLayout ? NO_POSITION : (focusedVh.isRemoved() ? focusedVh.mOldPosition : focusedVh.getAdapterPosition()); mState.mFocusedSubChildId = getDeepestFocusedViewWithId(focusedVh.itemView); } } private void resetFocusInfo() { mState.mFocusedItemId = NO_ID; mState.mFocusedItemPosition = NO_POSITION; mState.mFocusedSubChildId = View.NO_ID; } /** * Finds the best view candidate to request focus on using mFocusedItemPosition index of the * previously focused item. It first traverses the adapter forward to find a focusable candidate * and if no such candidate is found, it reverses the focus search direction for the items * before the mFocusedItemPosition'th index; * @return The best candidate to request focus on, or null if no such candidate exists. Null * indicates all the existing adapter items are unfocusable. */ @Nullable private View findNextViewToFocus() { int startFocusSearchIndex = mState.mFocusedItemPosition != -1 ? mState.mFocusedItemPosition : 0; ViewHolder nextFocus; final int itemCount = mState.getItemCount(); for (int i = startFocusSearchIndex; i < itemCount; i++) { nextFocus = findViewHolderForAdapterPosition(i); if (nextFocus == null) { break; } if (nextFocus.itemView.hasFocusable()) { return nextFocus.itemView; } } final int limit = Math.min(itemCount, startFocusSearchIndex); for (int i = limit - 1; i >= 0; i--) { nextFocus = findViewHolderForAdapterPosition(i); if (nextFocus == null) { return null; } if (nextFocus.itemView.hasFocusable()) { return nextFocus.itemView; } } return null; } private void recoverFocusFromState() { if (!mPreserveFocusAfterLayout || mAdapter == null || !hasFocus() || getDescendantFocusability() == FOCUS_BLOCK_DESCENDANTS || (getDescendantFocusability() == FOCUS_BEFORE_DESCENDANTS && isFocused())) { // No-op if either of these cases happens: // 1. RV has no focus, or 2. RV blocks focus to its children, or 3. RV takes focus // before its children and is focused (i.e. it already stole the focus away from its // descendants). return; } // only recover focus if RV itself has the focus or the focused view is hidden if (!isFocused()) { final View focusedChild = getFocusedChild(); if (IGNORE_DETACHED_FOCUSED_CHILD && (focusedChild.getParent() == null || !focusedChild.hasFocus())) { // Special handling of API 15-. A focused child can be invalid because mFocus is not // cleared when the child is detached (mParent = null), // This happens because clearFocus on API 15- does not invalidate mFocus of its // parent when this child is detached. // For API 16+, this is not an issue because requestFocus takes care of clearing the // prior detached focused child. For API 15- the problem happens in 2 cases because // clearChild does not call clearChildFocus on RV: 1. setFocusable(false) is called // for the current focused item which calls clearChild or 2. when the prior focused // child is removed, removeDetachedView called in layout step 3 which calls // clearChild. We should ignore this invalid focused child in all our calculations // for the next view to receive focus, and apply the focus recovery logic instead. if (mChildHelper.getChildCount() == 0) { // No children left. Request focus on the RV itself since one of its children // was holding focus previously. requestFocus(); return; } } else if (!mChildHelper.isHidden(focusedChild)) { // If the currently focused child is hidden, apply the focus recovery logic. // Otherwise return, i.e. the currently (unhidden) focused child is good enough :/. return; } } ViewHolder focusTarget = null; // RV first attempts to locate the previously focused item to request focus on using // mFocusedItemId. If such an item no longer exists, it then makes a best-effort attempt to // find the next best candidate to request focus on based on mFocusedItemPosition. if (mState.mFocusedItemId != NO_ID && mAdapter.hasStableIds()) { focusTarget = findViewHolderForItemId(mState.mFocusedItemId); } View viewToFocus = null; if (focusTarget == null || mChildHelper.isHidden(focusTarget.itemView) || !focusTarget.itemView.hasFocusable()) { if (mChildHelper.getChildCount() > 0) { // At this point, RV has focus and either of these conditions are true: // 1. There's no previously focused item either because RV received focused before // layout, or the previously focused item was removed, or RV doesn't have stable IDs // 2. Previous focus child is hidden, or 3. Previous focused child is no longer // focusable. In either of these cases, we make sure that RV still passes down the // focus to one of its focusable children using a best-effort algorithm. viewToFocus = findNextViewToFocus(); } } else { // looks like the focused item has been replaced with another view that represents the // same item in the adapter. Request focus on that. viewToFocus = focusTarget.itemView; } if (viewToFocus != null) { if (mState.mFocusedSubChildId != NO_ID) { View child = viewToFocus.findViewById(mState.mFocusedSubChildId); if (child != null && child.isFocusable()) { viewToFocus = child; } } viewToFocus.requestFocus(); } } private int getDeepestFocusedViewWithId(View view) { int lastKnownId = view.getId(); while (!view.isFocused() && view instanceof ViewGroup && view.hasFocus()) { view = ((ViewGroup) view).getFocusedChild(); final int id = view.getId(); if (id != View.NO_ID) { lastKnownId = view.getId(); } } return lastKnownId; } /** * The first step of a layout where we; * - process adapter updates * - decide which animation should run * - save information about current views * - If necessary, run predictive layout and save its information */ private void dispatchLayoutStep1() { mState.assertLayoutStep(State.STEP_START); mState.mIsMeasuring = false; eatRequestLayout(); mViewInfoStore.clear(); onEnterLayoutOrScroll(); processAdapterUpdatesAndSetAnimationFlags(); saveFocusInfo(); mState.mTrackOldChangeHolders = mState.mRunSimpleAnimations && mItemsChanged; mItemsAddedOrRemoved = mItemsChanged = false; mState.mInPreLayout = mState.mRunPredictiveAnimations; mState.mItemCount = mAdapter.getItemCount(); findMinMaxChildLayoutPositions(mMinMaxLayoutPositions); if (mState.mRunSimpleAnimations) { // Step 0: Find out where all non-removed items are, pre-layout int count = mChildHelper.getChildCount(); for (int i = 0; i < count; ++i) { final ViewHolder holder = getChildViewHolderInt(mChildHelper.getChildAt(i)); if (holder.shouldIgnore() || (holder.isInvalid() && !mAdapter.hasStableIds())) { continue; } final ItemHolderInfo animationInfo = mItemAnimator .recordPreLayoutInformation(mState, holder, ItemAnimator.buildAdapterChangeFlagsForAnimations(holder), holder.getUnmodifiedPayloads()); mViewInfoStore.addToPreLayout(holder, animationInfo); if (mState.mTrackOldChangeHolders && holder.isUpdated() && !holder.isRemoved() && !holder.shouldIgnore() && !holder.isInvalid()) { long key = getChangedHolderKey(holder); // This is NOT the only place where a ViewHolder is added to old change holders // list. There is another case where: // * A VH is currently hidden but not deleted // * The hidden item is changed in the adapter // * Layout manager decides to layout the item in the pre-Layout pass (step1) // When this case is detected, RV will un-hide that view and add to the old // change holders list. mViewInfoStore.addToOldChangeHolders(key, holder); } } } if (mState.mRunPredictiveAnimations) { // Step 1: run prelayout: This will use the old positions of items. The layout manager // is expected to layout everything, even removed items (though not to add removed // items back to the container). This gives the pre-layout position of APPEARING views // which come into existence as part of the real layout. // Save old positions so that LayoutManager can run its mapping logic. saveOldPositions(); final boolean didStructureChange = mState.mStructureChanged; mState.mStructureChanged = false; // temporarily disable flag because we are asking for previous layout mLayout.onLayoutChildren(mRecycler, mState); mState.mStructureChanged = didStructureChange; for (int i = 0; i < mChildHelper.getChildCount(); ++i) { final View child = mChildHelper.getChildAt(i); final ViewHolder viewHolder = getChildViewHolderInt(child); if (viewHolder.shouldIgnore()) { continue; } if (!mViewInfoStore.isInPreLayout(viewHolder)) { int flags = ItemAnimator.buildAdapterChangeFlagsForAnimations(viewHolder); boolean wasHidden = viewHolder .hasAnyOfTheFlags(ViewHolder.FLAG_BOUNCED_FROM_HIDDEN_LIST); if (!wasHidden) { flags |= ItemAnimator.FLAG_APPEARED_IN_PRE_LAYOUT; } final ItemHolderInfo animationInfo = mItemAnimator.recordPreLayoutInformation( mState, viewHolder, flags, viewHolder.getUnmodifiedPayloads()); if (wasHidden) { recordAnimationInfoIfBouncedHiddenView(viewHolder, animationInfo); } else { mViewInfoStore.addToAppearedInPreLayoutHolders(viewHolder, animationInfo); } } } // we don't process disappearing list because they may re-appear in post layout pass. clearOldPositions(); } else { clearOldPositions(); } onExitLayoutOrScroll(); resumeRequestLayout(false); mState.mLayoutStep = State.STEP_LAYOUT; } /** * The second layout step where we do the actual layout of the views for the final state. * This step might be run multiple times if necessary (e.g. measure). */ private void dispatchLayoutStep2() { eatRequestLayout(); onEnterLayoutOrScroll(); mState.assertLayoutStep(State.STEP_LAYOUT | State.STEP_ANIMATIONS); mAdapterHelper.consumeUpdatesInOnePass(); mState.mItemCount = mAdapter.getItemCount(); mState.mDeletedInvisibleItemCountSincePreviousLayout = 0; // Step 2: Run layout mState.mInPreLayout = false; mLayout.onLayoutChildren(mRecycler, mState); mState.mStructureChanged = false; mPendingSavedState = null; // onLayoutChildren may have caused client code to disable item animations; re-check mState.mRunSimpleAnimations = mState.mRunSimpleAnimations && mItemAnimator != null; mState.mLayoutStep = State.STEP_ANIMATIONS; onExitLayoutOrScroll(); resumeRequestLayout(false); } /** * The final step of the layout where we save the information about views for animations, * trigger animations and do any necessary cleanup. */ private void dispatchLayoutStep3() { mState.assertLayoutStep(State.STEP_ANIMATIONS); eatRequestLayout(); onEnterLayoutOrScroll(); mState.mLayoutStep = State.STEP_START; if (mState.mRunSimpleAnimations) { // Step 3: Find out where things are now, and process change animations. // traverse list in reverse because we may call animateChange in the loop which may // remove the target view holder. for (int i = mChildHelper.getChildCount() - 1; i >= 0; i--) { ViewHolder holder = getChildViewHolderInt(mChildHelper.getChildAt(i)); if (holder.shouldIgnore()) { continue; } long key = getChangedHolderKey(holder); final ItemHolderInfo animationInfo = mItemAnimator .recordPostLayoutInformation(mState, holder); ViewHolder oldChangeViewHolder = mViewInfoStore.getFromOldChangeHolders(key); if (oldChangeViewHolder != null && !oldChangeViewHolder.shouldIgnore()) { // run a change animation // If an Item is CHANGED but the updated version is disappearing, it creates // a conflicting case. // Since a view that is marked as disappearing is likely to be going out of // bounds, we run a change animation. Both views will be cleaned automatically // once their animations finish. // On the other hand, if it is the same view holder instance, we run a // disappearing animation instead because we are not going to rebind the updated // VH unless it is enforced by the layout manager. final boolean oldDisappearing = mViewInfoStore.isDisappearing( oldChangeViewHolder); final boolean newDisappearing = mViewInfoStore.isDisappearing(holder); if (oldDisappearing && oldChangeViewHolder == holder) { // run disappear animation instead of change mViewInfoStore.addToPostLayout(holder, animationInfo); } else { final ItemHolderInfo preInfo = mViewInfoStore.popFromPreLayout( oldChangeViewHolder); // we add and remove so that any post info is merged. mViewInfoStore.addToPostLayout(holder, animationInfo); ItemHolderInfo postInfo = mViewInfoStore.popFromPostLayout(holder); if (preInfo == null) { handleMissingPreInfoForChangeError(key, holder, oldChangeViewHolder); } else { animateChange(oldChangeViewHolder, holder, preInfo, postInfo, oldDisappearing, newDisappearing); } } } else { mViewInfoStore.addToPostLayout(holder, animationInfo); } } // Step 4: Process view info lists and trigger animations mViewInfoStore.process(mViewInfoProcessCallback); } mLayout.removeAndRecycleScrapInt(mRecycler); mState.mPreviousLayoutItemCount = mState.mItemCount; mDataSetHasChangedAfterLayout = false; mState.mRunSimpleAnimations = false; mState.mRunPredictiveAnimations = false; mLayout.mRequestedSimpleAnimations = false; if (mRecycler.mChangedScrap != null) { mRecycler.mChangedScrap.clear(); } if (mLayout.mPrefetchMaxObservedInInitialPrefetch) { // Initial prefetch has expanded cache, so reset until next prefetch. // This prevents initial prefetches from expanding the cache permanently. mLayout.mPrefetchMaxCountObserved = 0; mLayout.mPrefetchMaxObservedInInitialPrefetch = false; mRecycler.updateViewCacheSize(); } mLayout.onLayoutCompleted(mState); onExitLayoutOrScroll(); resumeRequestLayout(false); mViewInfoStore.clear(); if (didChildRangeChange(mMinMaxLayoutPositions[0], mMinMaxLayoutPositions[1])) { dispatchOnScrolled(0, 0); } recoverFocusFromState(); resetFocusInfo(); } /** * This handles the case where there is an unexpected VH missing in the pre-layout map. *

* We might be able to detect the error in the application which will help the developer to * resolve the issue. *

* If it is not an expected error, we at least print an error to notify the developer and ignore * the animation. * * https://code.google.com/p/android/issues/detail?id=193958 * * @param key The change key * @param holder Current ViewHolder * @param oldChangeViewHolder Changed ViewHolder */ private void handleMissingPreInfoForChangeError(long key, ViewHolder holder, ViewHolder oldChangeViewHolder) { // check if two VH have the same key, if so, print that as an error final int childCount = mChildHelper.getChildCount(); for (int i = 0; i < childCount; i++) { View view = mChildHelper.getChildAt(i); ViewHolder other = getChildViewHolderInt(view); if (other == holder) { continue; } final long otherKey = getChangedHolderKey(other); if (otherKey == key) { if (mAdapter != null && mAdapter.hasStableIds()) { throw new IllegalStateException("Two different ViewHolders have the same stable" + " ID. Stable IDs in your adapter MUST BE unique and SHOULD NOT" + " change.\n ViewHolder 1:" + other + " \n View Holder 2:" + holder); } else { throw new IllegalStateException("Two different ViewHolders have the same change" + " ID. This might happen due to inconsistent Adapter update events or" + " if the LayoutManager lays out the same View multiple times." + "\n ViewHolder 1:" + other + " \n View Holder 2:" + holder); } } } // Very unlikely to happen but if it does, notify the developer. Log.e(TAG, "Problem while matching changed view holders with the new" + "ones. The pre-layout information for the change holder " + oldChangeViewHolder + " cannot be found but it is necessary for " + holder); } /** * Records the animation information for a view holder that was bounced from hidden list. It * also clears the bounce back flag. */ void recordAnimationInfoIfBouncedHiddenView(ViewHolder viewHolder, ItemHolderInfo animationInfo) { // looks like this view bounced back from hidden list! viewHolder.setFlags(0, ViewHolder.FLAG_BOUNCED_FROM_HIDDEN_LIST); if (mState.mTrackOldChangeHolders && viewHolder.isUpdated() && !viewHolder.isRemoved() && !viewHolder.shouldIgnore()) { long key = getChangedHolderKey(viewHolder); mViewInfoStore.addToOldChangeHolders(key, viewHolder); } mViewInfoStore.addToPreLayout(viewHolder, animationInfo); } private void findMinMaxChildLayoutPositions(int[] into) { final int count = mChildHelper.getChildCount(); if (count == 0) { into[0] = NO_POSITION; into[1] = NO_POSITION; return; } int minPositionPreLayout = Integer.MAX_VALUE; int maxPositionPreLayout = Integer.MIN_VALUE; for (int i = 0; i < count; ++i) { final ViewHolder holder = getChildViewHolderInt(mChildHelper.getChildAt(i)); if (holder.shouldIgnore()) { continue; } final int pos = holder.getLayoutPosition(); if (pos < minPositionPreLayout) { minPositionPreLayout = pos; } if (pos > maxPositionPreLayout) { maxPositionPreLayout = pos; } } into[0] = minPositionPreLayout; into[1] = maxPositionPreLayout; } private boolean didChildRangeChange(int minPositionPreLayout, int maxPositionPreLayout) { findMinMaxChildLayoutPositions(mMinMaxLayoutPositions); return mMinMaxLayoutPositions[0] != minPositionPreLayout || mMinMaxLayoutPositions[1] != maxPositionPreLayout; } @Override protected void removeDetachedView(View child, boolean animate) { ViewHolder vh = getChildViewHolderInt(child); if (vh != null) { if (vh.isTmpDetached()) { vh.clearTmpDetachFlag(); } else if (!vh.shouldIgnore()) { throw new IllegalArgumentException("Called removeDetachedView with a view which" + " is not flagged as tmp detached." + vh); } } dispatchChildDetached(child); super.removeDetachedView(child, animate); } /** * Returns a unique key to be used while handling change animations. * It might be child's position or stable id depending on the adapter type. */ long getChangedHolderKey(ViewHolder holder) { return mAdapter.hasStableIds() ? holder.getItemId() : holder.mPosition; } void animateAppearance(@NonNull ViewHolder itemHolder, @Nullable ItemHolderInfo preLayoutInfo, @NonNull ItemHolderInfo postLayoutInfo) { itemHolder.setIsRecyclable(false); if (mItemAnimator.animateAppearance(itemHolder, preLayoutInfo, postLayoutInfo)) { postAnimationRunner(); } } void animateDisappearance(@NonNull ViewHolder holder, @NonNull ItemHolderInfo preLayoutInfo, @Nullable ItemHolderInfo postLayoutInfo) { addAnimatingView(holder); holder.setIsRecyclable(false); if (mItemAnimator.animateDisappearance(holder, preLayoutInfo, postLayoutInfo)) { postAnimationRunner(); } } private void animateChange(@NonNull ViewHolder oldHolder, @NonNull ViewHolder newHolder, @NonNull ItemHolderInfo preInfo, @NonNull ItemHolderInfo postInfo, boolean oldHolderDisappearing, boolean newHolderDisappearing) { oldHolder.setIsRecyclable(false); if (oldHolderDisappearing) { addAnimatingView(oldHolder); } if (oldHolder != newHolder) { if (newHolderDisappearing) { addAnimatingView(newHolder); } oldHolder.mShadowedHolder = newHolder; // old holder should disappear after animation ends addAnimatingView(oldHolder); mRecycler.unscrapView(oldHolder); newHolder.setIsRecyclable(false); newHolder.mShadowingHolder = oldHolder; } if (mItemAnimator.animateChange(oldHolder, newHolder, preInfo, postInfo)) { postAnimationRunner(); } } @Override protected void onLayout(boolean changed, int l, int t, int r, int b) { Trace.beginSection(TRACE_ON_LAYOUT_TAG); dispatchLayout(); Trace.endSection(); mFirstLayoutComplete = true; } @Override public void requestLayout() { if (mEatRequestLayout == 0 && !mLayoutFrozen) { super.requestLayout(); } else { mLayoutRequestEaten = true; } } void markItemDecorInsetsDirty() { final int childCount = mChildHelper.getUnfilteredChildCount(); for (int i = 0; i < childCount; i++) { final View child = mChildHelper.getUnfilteredChildAt(i); ((LayoutParams) child.getLayoutParams()).mInsetsDirty = true; } mRecycler.markItemDecorInsetsDirty(); } @Override public void draw(Canvas c) { super.draw(c); final int count = mItemDecorations.size(); for (int i = 0; i < count; i++) { mItemDecorations.get(i).onDrawOver(c, this, mState); } // TODO If padding is not 0 and clipChildrenToPadding is false, to draw glows properly, we // need find children closest to edges. Not sure if it is worth the effort. boolean needsInvalidate = false; if (mLeftGlow != null && !mLeftGlow.isFinished()) { final int restore = c.save(); final int padding = mClipToPadding ? getPaddingBottom() : 0; c.rotate(270); c.translate(-getHeight() + padding, 0); needsInvalidate = mLeftGlow != null && mLeftGlow.draw(c); c.restoreToCount(restore); } if (mTopGlow != null && !mTopGlow.isFinished()) { final int restore = c.save(); if (mClipToPadding) { c.translate(getPaddingLeft(), getPaddingTop()); } needsInvalidate |= mTopGlow != null && mTopGlow.draw(c); c.restoreToCount(restore); } if (mRightGlow != null && !mRightGlow.isFinished()) { final int restore = c.save(); final int width = getWidth(); final int padding = mClipToPadding ? getPaddingTop() : 0; c.rotate(90); c.translate(-padding, -width); needsInvalidate |= mRightGlow != null && mRightGlow.draw(c); c.restoreToCount(restore); } if (mBottomGlow != null && !mBottomGlow.isFinished()) { final int restore = c.save(); c.rotate(180); if (mClipToPadding) { c.translate(-getWidth() + getPaddingRight(), -getHeight() + getPaddingBottom()); } else { c.translate(-getWidth(), -getHeight()); } needsInvalidate |= mBottomGlow != null && mBottomGlow.draw(c); c.restoreToCount(restore); } // If some views are animating, ItemDecorators are likely to move/change with them. // Invalidate RecyclerView to re-draw decorators. This is still efficient because children's // display lists are not invalidated. if (!needsInvalidate && mItemAnimator != null && mItemDecorations.size() > 0 && mItemAnimator.isRunning()) { needsInvalidate = true; } if (needsInvalidate) { postInvalidateOnAnimation(); } } @Override public void onDraw(Canvas c) { super.onDraw(c); final int count = mItemDecorations.size(); for (int i = 0; i < count; i++) { mItemDecorations.get(i).onDraw(c, this, mState); } } @Override protected boolean checkLayoutParams(ViewGroup.LayoutParams p) { return p instanceof LayoutParams && mLayout.checkLayoutParams((LayoutParams) p); } @Override protected ViewGroup.LayoutParams generateDefaultLayoutParams() { if (mLayout == null) { throw new IllegalStateException("RecyclerView has no LayoutManager"); } return mLayout.generateDefaultLayoutParams(); } @Override public ViewGroup.LayoutParams generateLayoutParams(AttributeSet attrs) { if (mLayout == null) { throw new IllegalStateException("RecyclerView has no LayoutManager"); } return mLayout.generateLayoutParams(getContext(), attrs); } @Override protected ViewGroup.LayoutParams generateLayoutParams(ViewGroup.LayoutParams p) { if (mLayout == null) { throw new IllegalStateException("RecyclerView has no LayoutManager"); } return mLayout.generateLayoutParams(p); } /** * Returns true if RecyclerView is currently running some animations. *

* If you want to be notified when animations are finished, use * {@link ItemAnimator#isRunning(ItemAnimator.ItemAnimatorFinishedListener)}. * * @return True if there are some item animations currently running or waiting to be started. */ public boolean isAnimating() { return mItemAnimator != null && mItemAnimator.isRunning(); } void saveOldPositions() { final int childCount = mChildHelper.getUnfilteredChildCount(); for (int i = 0; i < childCount; i++) { final ViewHolder holder = getChildViewHolderInt(mChildHelper.getUnfilteredChildAt(i)); if (DEBUG && holder.mPosition == -1 && !holder.isRemoved()) { throw new IllegalStateException("view holder cannot have position -1 unless it" + " is removed"); } if (!holder.shouldIgnore()) { holder.saveOldPosition(); } } } void clearOldPositions() { final int childCount = mChildHelper.getUnfilteredChildCount(); for (int i = 0; i < childCount; i++) { final ViewHolder holder = getChildViewHolderInt(mChildHelper.getUnfilteredChildAt(i)); if (!holder.shouldIgnore()) { holder.clearOldPosition(); } } mRecycler.clearOldPositions(); } void offsetPositionRecordsForMove(int from, int to) { final int childCount = mChildHelper.getUnfilteredChildCount(); final int start, end, inBetweenOffset; if (from < to) { start = from; end = to; inBetweenOffset = -1; } else { start = to; end = from; inBetweenOffset = 1; } for (int i = 0; i < childCount; i++) { final ViewHolder holder = getChildViewHolderInt(mChildHelper.getUnfilteredChildAt(i)); if (holder == null || holder.mPosition < start || holder.mPosition > end) { continue; } if (DEBUG) { Log.d(TAG, "offsetPositionRecordsForMove attached child " + i + " holder " + holder); } if (holder.mPosition == from) { holder.offsetPosition(to - from, false); } else { holder.offsetPosition(inBetweenOffset, false); } mState.mStructureChanged = true; } mRecycler.offsetPositionRecordsForMove(from, to); requestLayout(); } void offsetPositionRecordsForInsert(int positionStart, int itemCount) { final int childCount = mChildHelper.getUnfilteredChildCount(); for (int i = 0; i < childCount; i++) { final ViewHolder holder = getChildViewHolderInt(mChildHelper.getUnfilteredChildAt(i)); if (holder != null && !holder.shouldIgnore() && holder.mPosition >= positionStart) { if (DEBUG) { Log.d(TAG, "offsetPositionRecordsForInsert attached child " + i + " holder " + holder + " now at position " + (holder.mPosition + itemCount)); } holder.offsetPosition(itemCount, false); mState.mStructureChanged = true; } } mRecycler.offsetPositionRecordsForInsert(positionStart, itemCount); requestLayout(); } void offsetPositionRecordsForRemove(int positionStart, int itemCount, boolean applyToPreLayout) { final int positionEnd = positionStart + itemCount; final int childCount = mChildHelper.getUnfilteredChildCount(); for (int i = 0; i < childCount; i++) { final ViewHolder holder = getChildViewHolderInt(mChildHelper.getUnfilteredChildAt(i)); if (holder != null && !holder.shouldIgnore()) { if (holder.mPosition >= positionEnd) { if (DEBUG) { Log.d(TAG, "offsetPositionRecordsForRemove attached child " + i + " holder " + holder + " now at position " + (holder.mPosition - itemCount)); } holder.offsetPosition(-itemCount, applyToPreLayout); mState.mStructureChanged = true; } else if (holder.mPosition >= positionStart) { if (DEBUG) { Log.d(TAG, "offsetPositionRecordsForRemove attached child " + i + " holder " + holder + " now REMOVED"); } holder.flagRemovedAndOffsetPosition(positionStart - 1, -itemCount, applyToPreLayout); mState.mStructureChanged = true; } } } mRecycler.offsetPositionRecordsForRemove(positionStart, itemCount, applyToPreLayout); requestLayout(); } /** * Rebind existing views for the given range, or create as needed. * * @param positionStart Adapter position to start at * @param itemCount Number of views that must explicitly be rebound */ void viewRangeUpdate(int positionStart, int itemCount, Object payload) { final int childCount = mChildHelper.getUnfilteredChildCount(); final int positionEnd = positionStart + itemCount; for (int i = 0; i < childCount; i++) { final View child = mChildHelper.getUnfilteredChildAt(i); final ViewHolder holder = getChildViewHolderInt(child); if (holder == null || holder.shouldIgnore()) { continue; } if (holder.mPosition >= positionStart && holder.mPosition < positionEnd) { // We re-bind these view holders after pre-processing is complete so that // ViewHolders have their final positions assigned. holder.addFlags(ViewHolder.FLAG_UPDATE); holder.addChangePayload(payload); // lp cannot be null since we get ViewHolder from it. ((LayoutParams) child.getLayoutParams()).mInsetsDirty = true; } } mRecycler.viewRangeUpdate(positionStart, itemCount); } boolean canReuseUpdatedViewHolder(ViewHolder viewHolder) { return mItemAnimator == null || mItemAnimator.canReuseUpdatedViewHolder(viewHolder, viewHolder.getUnmodifiedPayloads()); } /** * Call this method to signal that *all* adapter content has changed (generally, because of * swapAdapter, or notifyDataSetChanged), and that once layout occurs, all attached items should * be discarded or animated. Note that this work is deferred because RecyclerView requires a * layout to resolve non-incremental changes to the data set. * * Attached items are labeled as position unknown, and may no longer be cached. * * It is still possible for items to be prefetched while mDataSetHasChangedAfterLayout == true, * so calling this method *must* be associated with marking the cache invalid, so that the * only valid items that remain in the cache, once layout occurs, are prefetched items. */ void setDataSetChangedAfterLayout() { if (mDataSetHasChangedAfterLayout) { return; } mDataSetHasChangedAfterLayout = true; final int childCount = mChildHelper.getUnfilteredChildCount(); for (int i = 0; i < childCount; i++) { final ViewHolder holder = getChildViewHolderInt(mChildHelper.getUnfilteredChildAt(i)); if (holder != null && !holder.shouldIgnore()) { holder.addFlags(ViewHolder.FLAG_ADAPTER_POSITION_UNKNOWN); } } mRecycler.setAdapterPositionsAsUnknown(); // immediately mark all views as invalid, so prefetched views can be // differentiated from views bound to previous data set - both in children, and cache markKnownViewsInvalid(); } /** * Mark all known views as invalid. Used in response to a, "the whole world might have changed" * data change event. */ void markKnownViewsInvalid() { final int childCount = mChildHelper.getUnfilteredChildCount(); for (int i = 0; i < childCount; i++) { final ViewHolder holder = getChildViewHolderInt(mChildHelper.getUnfilteredChildAt(i)); if (holder != null && !holder.shouldIgnore()) { holder.addFlags(ViewHolder.FLAG_UPDATE | ViewHolder.FLAG_INVALID); } } markItemDecorInsetsDirty(); mRecycler.markKnownViewsInvalid(); } /** * Invalidates all ItemDecorations. If RecyclerView has item decorations, calling this method * will trigger a {@link #requestLayout()} call. */ public void invalidateItemDecorations() { if (mItemDecorations.size() == 0) { return; } if (mLayout != null) { mLayout.assertNotInLayoutOrScroll("Cannot invalidate item decorations during a scroll" + " or layout"); } markItemDecorInsetsDirty(); requestLayout(); } /** * Returns true if the RecyclerView should attempt to preserve currently focused Adapter Item's * focus even if the View representing the Item is replaced during a layout calculation. *

* By default, this value is {@code true}. * * @return True if the RecyclerView will try to preserve focused Item after a layout if it loses * focus. * * @see #setPreserveFocusAfterLayout(boolean) */ public boolean getPreserveFocusAfterLayout() { return mPreserveFocusAfterLayout; } /** * Set whether the RecyclerView should try to keep the same Item focused after a layout * calculation or not. *

* Usually, LayoutManagers keep focused views visible before and after layout but sometimes, * views may lose focus during a layout calculation as their state changes or they are replaced * with another view due to type change or animation. In these cases, RecyclerView can request * focus on the new view automatically. * * @param preserveFocusAfterLayout Whether RecyclerView should preserve focused Item during a * layout calculations. Defaults to true. * * @see #getPreserveFocusAfterLayout() */ public void setPreserveFocusAfterLayout(boolean preserveFocusAfterLayout) { mPreserveFocusAfterLayout = preserveFocusAfterLayout; } /** * Retrieve the {@link ViewHolder} for the given child view. * * @param child Child of this RecyclerView to query for its ViewHolder * @return The child view's ViewHolder */ public ViewHolder getChildViewHolder(View child) { final ViewParent parent = child.getParent(); if (parent != null && parent != this) { throw new IllegalArgumentException("View " + child + " is not a direct child of " + this); } return getChildViewHolderInt(child); } /** * Traverses the ancestors of the given view and returns the item view that contains it and * also a direct child of the RecyclerView. This returned view can be used to get the * ViewHolder by calling {@link #getChildViewHolder(View)}. * * @param view The view that is a descendant of the RecyclerView. * * @return The direct child of the RecyclerView which contains the given view or null if the * provided view is not a descendant of this RecyclerView. * * @see #getChildViewHolder(View) * @see #findContainingViewHolder(View) */ @Nullable public View findContainingItemView(View view) { ViewParent parent = view.getParent(); while (parent != null && parent != this && parent instanceof View) { view = (View) parent; parent = view.getParent(); } return parent == this ? view : null; } /** * Returns the ViewHolder that contains the given view. * * @param view The view that is a descendant of the RecyclerView. * * @return The ViewHolder that contains the given view or null if the provided view is not a * descendant of this RecyclerView. */ @Nullable public ViewHolder findContainingViewHolder(View view) { View itemView = findContainingItemView(view); return itemView == null ? null : getChildViewHolder(itemView); } static ViewHolder getChildViewHolderInt(View child) { if (child == null) { return null; } return ((LayoutParams) child.getLayoutParams()).mViewHolder; } /** * @deprecated use {@link #getChildAdapterPosition(View)} or * {@link #getChildLayoutPosition(View)}. */ @Deprecated public int getChildPosition(View child) { return getChildAdapterPosition(child); } /** * Return the adapter position that the given child view corresponds to. * * @param child Child View to query * @return Adapter position corresponding to the given view or {@link #NO_POSITION} */ public int getChildAdapterPosition(View child) { final ViewHolder holder = getChildViewHolderInt(child); return holder != null ? holder.getAdapterPosition() : NO_POSITION; } /** * Return the adapter position of the given child view as of the latest completed layout pass. *

* This position may not be equal to Item's adapter position if there are pending changes * in the adapter which have not been reflected to the layout yet. * * @param child Child View to query * @return Adapter position of the given View as of last layout pass or {@link #NO_POSITION} if * the View is representing a removed item. */ public int getChildLayoutPosition(View child) { final ViewHolder holder = getChildViewHolderInt(child); return holder != null ? holder.getLayoutPosition() : NO_POSITION; } /** * Return the stable item id that the given child view corresponds to. * * @param child Child View to query * @return Item id corresponding to the given view or {@link #NO_ID} */ public long getChildItemId(View child) { if (mAdapter == null || !mAdapter.hasStableIds()) { return NO_ID; } final ViewHolder holder = getChildViewHolderInt(child); return holder != null ? holder.getItemId() : NO_ID; } /** * @deprecated use {@link #findViewHolderForLayoutPosition(int)} or * {@link #findViewHolderForAdapterPosition(int)} */ @Deprecated public ViewHolder findViewHolderForPosition(int position) { return findViewHolderForPosition(position, false); } /** * Return the ViewHolder for the item in the given position of the data set as of the latest * layout pass. *

* This method checks only the children of RecyclerView. If the item at the given * position is not laid out, it will not create a new one. *

* Note that when Adapter contents change, ViewHolder positions are not updated until the * next layout calculation. If there are pending adapter updates, the return value of this * method may not match your adapter contents. You can use * #{@link ViewHolder#getAdapterPosition()} to get the current adapter position of a ViewHolder. *

* When the ItemAnimator is running a change animation, there might be 2 ViewHolders * with the same layout position representing the same Item. In this case, the updated * ViewHolder will be returned. * * @param position The position of the item in the data set of the adapter * @return The ViewHolder at position or null if there is no such item */ public ViewHolder findViewHolderForLayoutPosition(int position) { return findViewHolderForPosition(position, false); } /** * Return the ViewHolder for the item in the given position of the data set. Unlike * {@link #findViewHolderForLayoutPosition(int)} this method takes into account any pending * adapter changes that may not be reflected to the layout yet. On the other hand, if * {@link Adapter#notifyDataSetChanged()} has been called but the new layout has not been * calculated yet, this method will return null since the new positions of views * are unknown until the layout is calculated. *

* This method checks only the children of RecyclerView. If the item at the given * position is not laid out, it will not create a new one. *

* When the ItemAnimator is running a change animation, there might be 2 ViewHolders * representing the same Item. In this case, the updated ViewHolder will be returned. * * @param position The position of the item in the data set of the adapter * @return The ViewHolder at position or null if there is no such item */ public ViewHolder findViewHolderForAdapterPosition(int position) { if (mDataSetHasChangedAfterLayout) { return null; } final int childCount = mChildHelper.getUnfilteredChildCount(); // hidden VHs are not preferred but if that is the only one we find, we rather return it ViewHolder hidden = null; for (int i = 0; i < childCount; i++) { final ViewHolder holder = getChildViewHolderInt(mChildHelper.getUnfilteredChildAt(i)); if (holder != null && !holder.isRemoved() && getAdapterPositionFor(holder) == position) { if (mChildHelper.isHidden(holder.itemView)) { hidden = holder; } else { return holder; } } } return hidden; } ViewHolder findViewHolderForPosition(int position, boolean checkNewPosition) { final int childCount = mChildHelper.getUnfilteredChildCount(); ViewHolder hidden = null; for (int i = 0; i < childCount; i++) { final ViewHolder holder = getChildViewHolderInt(mChildHelper.getUnfilteredChildAt(i)); if (holder != null && !holder.isRemoved()) { if (checkNewPosition) { if (holder.mPosition != position) { continue; } } else if (holder.getLayoutPosition() != position) { continue; } if (mChildHelper.isHidden(holder.itemView)) { hidden = holder; } else { return holder; } } } // This method should not query cached views. It creates a problem during adapter updates // when we are dealing with already laid out views. Also, for the public method, it is more // reasonable to return null if position is not laid out. return hidden; } /** * Return the ViewHolder for the item with the given id. The RecyclerView must * use an Adapter with {@link Adapter#setHasStableIds(boolean) stableIds} to * return a non-null value. *

* This method checks only the children of RecyclerView. If the item with the given * id is not laid out, it will not create a new one. * * When the ItemAnimator is running a change animation, there might be 2 ViewHolders with the * same id. In this case, the updated ViewHolder will be returned. * * @param id The id for the requested item * @return The ViewHolder with the given id or null if there is no such item */ public ViewHolder findViewHolderForItemId(long id) { if (mAdapter == null || !mAdapter.hasStableIds()) { return null; } final int childCount = mChildHelper.getUnfilteredChildCount(); ViewHolder hidden = null; for (int i = 0; i < childCount; i++) { final ViewHolder holder = getChildViewHolderInt(mChildHelper.getUnfilteredChildAt(i)); if (holder != null && !holder.isRemoved() && holder.getItemId() == id) { if (mChildHelper.isHidden(holder.itemView)) { hidden = holder; } else { return holder; } } } return hidden; } /** * Find the topmost view under the given point. * * @param x Horizontal position in pixels to search * @param y Vertical position in pixels to search * @return The child view under (x, y) or null if no matching child is found */ public View findChildViewUnder(float x, float y) { final int count = mChildHelper.getChildCount(); for (int i = count - 1; i >= 0; i--) { final View child = mChildHelper.getChildAt(i); final float translationX = child.getTranslationX(); final float translationY = child.getTranslationY(); if (x >= child.getLeft() + translationX && x <= child.getRight() + translationX && y >= child.getTop() + translationY && y <= child.getBottom() + translationY) { return child; } } return null; } @Override public boolean drawChild(Canvas canvas, View child, long drawingTime) { return super.drawChild(canvas, child, drawingTime); } /** * Offset the bounds of all child views by dy pixels. * Useful for implementing simple scrolling in {@link LayoutManager LayoutManagers}. * * @param dy Vertical pixel offset to apply to the bounds of all child views */ public void offsetChildrenVertical(int dy) { final int childCount = mChildHelper.getChildCount(); for (int i = 0; i < childCount; i++) { mChildHelper.getChildAt(i).offsetTopAndBottom(dy); } } /** * Called when an item view is attached to this RecyclerView. * *

Subclasses of RecyclerView may want to perform extra bookkeeping or modifications * of child views as they become attached. This will be called before a * {@link LayoutManager} measures or lays out the view and is a good time to perform these * changes.

* * @param child Child view that is now attached to this RecyclerView and its associated window */ public void onChildAttachedToWindow(View child) { } /** * Called when an item view is detached from this RecyclerView. * *

Subclasses of RecyclerView may want to perform extra bookkeeping or modifications * of child views as they become detached. This will be called as a * {@link LayoutManager} fully detaches the child view from the parent and its window.

* * @param child Child view that is now detached from this RecyclerView and its associated window */ public void onChildDetachedFromWindow(View child) { } /** * Offset the bounds of all child views by dx pixels. * Useful for implementing simple scrolling in {@link LayoutManager LayoutManagers}. * * @param dx Horizontal pixel offset to apply to the bounds of all child views */ public void offsetChildrenHorizontal(int dx) { final int childCount = mChildHelper.getChildCount(); for (int i = 0; i < childCount; i++) { mChildHelper.getChildAt(i).offsetLeftAndRight(dx); } } /** * Returns the bounds of the view including its decoration and margins. * * @param view The view element to check * @param outBounds A rect that will receive the bounds of the element including its * decoration and margins. */ public void getDecoratedBoundsWithMargins(View view, Rect outBounds) { getDecoratedBoundsWithMarginsInt(view, outBounds); } static void getDecoratedBoundsWithMarginsInt(View view, Rect outBounds) { final LayoutParams lp = (LayoutParams) view.getLayoutParams(); final Rect insets = lp.mDecorInsets; outBounds.set(view.getLeft() - insets.left - lp.leftMargin, view.getTop() - insets.top - lp.topMargin, view.getRight() + insets.right + lp.rightMargin, view.getBottom() + insets.bottom + lp.bottomMargin); } Rect getItemDecorInsetsForChild(View child) { final LayoutParams lp = (LayoutParams) child.getLayoutParams(); if (!lp.mInsetsDirty) { return lp.mDecorInsets; } if (mState.isPreLayout() && (lp.isItemChanged() || lp.isViewInvalid())) { // changed/invalid items should not be updated until they are rebound. return lp.mDecorInsets; } final Rect insets = lp.mDecorInsets; insets.set(0, 0, 0, 0); final int decorCount = mItemDecorations.size(); for (int i = 0; i < decorCount; i++) { mTempRect.set(0, 0, 0, 0); mItemDecorations.get(i).getItemOffsets(mTempRect, child, this, mState); insets.left += mTempRect.left; insets.top += mTempRect.top; insets.right += mTempRect.right; insets.bottom += mTempRect.bottom; } lp.mInsetsDirty = false; return insets; } /** * Called when the scroll position of this RecyclerView changes. Subclasses should use * this method to respond to scrolling within the adapter's data set instead of an explicit * listener. * *

This method will always be invoked before listeners. If a subclass needs to perform * any additional upkeep or bookkeeping after scrolling but before listeners run, * this is a good place to do so.

* *

This differs from {@link View#onScrollChanged(int, int, int, int)} in that it receives * the distance scrolled in either direction within the adapter's data set instead of absolute * scroll coordinates. Since RecyclerView cannot compute the absolute scroll position from * any arbitrary point in the data set, onScrollChanged will always receive * the current {@link View#getScrollX()} and {@link View#getScrollY()} values which * do not correspond to the data set scroll position. However, some subclasses may choose * to use these fields as special offsets.

* * @param dx horizontal distance scrolled in pixels * @param dy vertical distance scrolled in pixels */ public void onScrolled(int dx, int dy) { // Do nothing } void dispatchOnScrolled(int hresult, int vresult) { mDispatchScrollCounter++; // Pass the current scrollX/scrollY values; no actual change in these properties occurred // but some general-purpose code may choose to respond to changes this way. final int scrollX = getScrollX(); final int scrollY = getScrollY(); onScrollChanged(scrollX, scrollY, scrollX, scrollY); // Pass the real deltas to onScrolled, the RecyclerView-specific method. onScrolled(hresult, vresult); // Invoke listeners last. Subclassed view methods always handle the event first. // All internal state is consistent by the time listeners are invoked. if (mScrollListener != null) { mScrollListener.onScrolled(this, hresult, vresult); } if (mScrollListeners != null) { for (int i = mScrollListeners.size() - 1; i >= 0; i--) { mScrollListeners.get(i).onScrolled(this, hresult, vresult); } } mDispatchScrollCounter--; } /** * Called when the scroll state of this RecyclerView changes. Subclasses should use this * method to respond to state changes instead of an explicit listener. * *

This method will always be invoked before listeners, but after the LayoutManager * responds to the scroll state change.

* * @param state the new scroll state, one of {@link #SCROLL_STATE_IDLE}, * {@link #SCROLL_STATE_DRAGGING} or {@link #SCROLL_STATE_SETTLING} */ public void onScrollStateChanged(int state) { // Do nothing } void dispatchOnScrollStateChanged(int state) { // Let the LayoutManager go first; this allows it to bring any properties into // a consistent state before the RecyclerView subclass responds. if (mLayout != null) { mLayout.onScrollStateChanged(state); } // Let the RecyclerView subclass handle this event next; any LayoutManager property // changes will be reflected by this time. onScrollStateChanged(state); // Listeners go last. All other internal state is consistent by this point. if (mScrollListener != null) { mScrollListener.onScrollStateChanged(this, state); } if (mScrollListeners != null) { for (int i = mScrollListeners.size() - 1; i >= 0; i--) { mScrollListeners.get(i).onScrollStateChanged(this, state); } } } /** * Returns whether there are pending adapter updates which are not yet applied to the layout. *

* If this method returns true, it means that what user is currently seeing may not * reflect them adapter contents (depending on what has changed). * You may use this information to defer or cancel some operations. *

* This method returns true if RecyclerView has not yet calculated the first layout after it is * attached to the Window or the Adapter has been replaced. * * @return True if there are some adapter updates which are not yet reflected to layout or false * if layout is up to date. */ public boolean hasPendingAdapterUpdates() { return !mFirstLayoutComplete || mDataSetHasChangedAfterLayout || mAdapterHelper.hasPendingUpdates(); } class ViewFlinger implements Runnable { private int mLastFlingX; private int mLastFlingY; private OverScroller mScroller; Interpolator mInterpolator = sQuinticInterpolator; // When set to true, postOnAnimation callbacks are delayed until the run method completes private boolean mEatRunOnAnimationRequest = false; // Tracks if postAnimationCallback should be re-attached when it is done private boolean mReSchedulePostAnimationCallback = false; ViewFlinger() { mScroller = new OverScroller(getContext(), sQuinticInterpolator); } @Override public void run() { if (mLayout == null) { stop(); return; // no layout, cannot scroll. } disableRunOnAnimationRequests(); consumePendingUpdateOperations(); // keep a local reference so that if it is changed during onAnimation method, it won't // cause unexpected behaviors final OverScroller scroller = mScroller; final SmoothScroller smoothScroller = mLayout.mSmoothScroller; if (scroller.computeScrollOffset()) { final int x = scroller.getCurrX(); final int y = scroller.getCurrY(); final int dx = x - mLastFlingX; final int dy = y - mLastFlingY; int hresult = 0; int vresult = 0; mLastFlingX = x; mLastFlingY = y; int overscrollX = 0, overscrollY = 0; if (mAdapter != null) { eatRequestLayout(); onEnterLayoutOrScroll(); Trace.beginSection(TRACE_SCROLL_TAG); if (dx != 0) { hresult = mLayout.scrollHorizontallyBy(dx, mRecycler, mState); overscrollX = dx - hresult; } if (dy != 0) { vresult = mLayout.scrollVerticallyBy(dy, mRecycler, mState); overscrollY = dy - vresult; } Trace.endSection(); repositionShadowingViews(); onExitLayoutOrScroll(); resumeRequestLayout(false); if (smoothScroller != null && !smoothScroller.isPendingInitialRun() && smoothScroller.isRunning()) { final int adapterSize = mState.getItemCount(); if (adapterSize == 0) { smoothScroller.stop(); } else if (smoothScroller.getTargetPosition() >= adapterSize) { smoothScroller.setTargetPosition(adapterSize - 1); smoothScroller.onAnimation(dx - overscrollX, dy - overscrollY); } else { smoothScroller.onAnimation(dx - overscrollX, dy - overscrollY); } } } if (!mItemDecorations.isEmpty()) { invalidate(); } if (getOverScrollMode() != View.OVER_SCROLL_NEVER) { considerReleasingGlowsOnScroll(dx, dy); } if (overscrollX != 0 || overscrollY != 0) { final int vel = (int) scroller.getCurrVelocity(); int velX = 0; if (overscrollX != x) { velX = overscrollX < 0 ? -vel : overscrollX > 0 ? vel : 0; } int velY = 0; if (overscrollY != y) { velY = overscrollY < 0 ? -vel : overscrollY > 0 ? vel : 0; } if (getOverScrollMode() != View.OVER_SCROLL_NEVER) { absorbGlows(velX, velY); } if ((velX != 0 || overscrollX == x || scroller.getFinalX() == 0) && (velY != 0 || overscrollY == y || scroller.getFinalY() == 0)) { scroller.abortAnimation(); } } if (hresult != 0 || vresult != 0) { dispatchOnScrolled(hresult, vresult); } if (!awakenScrollBars()) { invalidate(); } final boolean fullyConsumedVertical = dy != 0 && mLayout.canScrollVertically() && vresult == dy; final boolean fullyConsumedHorizontal = dx != 0 && mLayout.canScrollHorizontally() && hresult == dx; final boolean fullyConsumedAny = (dx == 0 && dy == 0) || fullyConsumedHorizontal || fullyConsumedVertical; if (scroller.isFinished() || !fullyConsumedAny) { setScrollState(SCROLL_STATE_IDLE); // setting state to idle will stop this. if (ALLOW_THREAD_GAP_WORK) { mPrefetchRegistry.clearPrefetchPositions(); } } else { postOnAnimation(); if (mGapWorker != null) { mGapWorker.postFromTraversal(RecyclerView.this, dx, dy); } } } // call this after the onAnimation is complete not to have inconsistent callbacks etc. if (smoothScroller != null) { if (smoothScroller.isPendingInitialRun()) { smoothScroller.onAnimation(0, 0); } if (!mReSchedulePostAnimationCallback) { smoothScroller.stop(); //stop if it does not trigger any scroll } } enableRunOnAnimationRequests(); } private void disableRunOnAnimationRequests() { mReSchedulePostAnimationCallback = false; mEatRunOnAnimationRequest = true; } private void enableRunOnAnimationRequests() { mEatRunOnAnimationRequest = false; if (mReSchedulePostAnimationCallback) { postOnAnimation(); } } void postOnAnimation() { if (mEatRunOnAnimationRequest) { mReSchedulePostAnimationCallback = true; } else { removeCallbacks(this); RecyclerView.this.postOnAnimation(this); } } public void fling(int velocityX, int velocityY) { setScrollState(SCROLL_STATE_SETTLING); mLastFlingX = mLastFlingY = 0; mScroller.fling(0, 0, velocityX, velocityY, Integer.MIN_VALUE, Integer.MAX_VALUE, Integer.MIN_VALUE, Integer.MAX_VALUE); postOnAnimation(); } public void smoothScrollBy(int dx, int dy) { smoothScrollBy(dx, dy, 0, 0); } public void smoothScrollBy(int dx, int dy, int vx, int vy) { smoothScrollBy(dx, dy, computeScrollDuration(dx, dy, vx, vy)); } private float distanceInfluenceForSnapDuration(float f) { f -= 0.5f; // center the values about 0. f *= 0.3f * Math.PI / 2.0f; return (float) Math.sin(f); } private int computeScrollDuration(int dx, int dy, int vx, int vy) { final int absDx = Math.abs(dx); final int absDy = Math.abs(dy); final boolean horizontal = absDx > absDy; final int velocity = (int) Math.sqrt(vx * vx + vy * vy); final int delta = (int) Math.sqrt(dx * dx + dy * dy); final int containerSize = horizontal ? getWidth() : getHeight(); final int halfContainerSize = containerSize / 2; final float distanceRatio = Math.min(1.f, 1.f * delta / containerSize); final float distance = halfContainerSize + halfContainerSize * distanceInfluenceForSnapDuration(distanceRatio); final int duration; if (velocity > 0) { duration = 4 * Math.round(1000 * Math.abs(distance / velocity)); } else { float absDelta = (float) (horizontal ? absDx : absDy); duration = (int) (((absDelta / containerSize) + 1) * 300); } return Math.min(duration, MAX_SCROLL_DURATION); } public void smoothScrollBy(int dx, int dy, int duration) { smoothScrollBy(dx, dy, duration, sQuinticInterpolator); } public void smoothScrollBy(int dx, int dy, Interpolator interpolator) { smoothScrollBy(dx, dy, computeScrollDuration(dx, dy, 0, 0), interpolator == null ? sQuinticInterpolator : interpolator); } public void smoothScrollBy(int dx, int dy, int duration, Interpolator interpolator) { if (mInterpolator != interpolator) { mInterpolator = interpolator; mScroller = new OverScroller(getContext(), interpolator); } setScrollState(SCROLL_STATE_SETTLING); mLastFlingX = mLastFlingY = 0; mScroller.startScroll(0, 0, dx, dy, duration); postOnAnimation(); } public void stop() { removeCallbacks(this); mScroller.abortAnimation(); } } void repositionShadowingViews() { // Fix up shadow views used by change animations int count = mChildHelper.getChildCount(); for (int i = 0; i < count; i++) { View view = mChildHelper.getChildAt(i); ViewHolder holder = getChildViewHolder(view); if (holder != null && holder.mShadowingHolder != null) { View shadowingView = holder.mShadowingHolder.itemView; int left = view.getLeft(); int top = view.getTop(); if (left != shadowingView.getLeft() || top != shadowingView.getTop()) { shadowingView.layout(left, top, left + shadowingView.getWidth(), top + shadowingView.getHeight()); } } } } private class RecyclerViewDataObserver extends AdapterDataObserver { RecyclerViewDataObserver() { } @Override public void onChanged() { assertNotInLayoutOrScroll(null); mState.mStructureChanged = true; setDataSetChangedAfterLayout(); if (!mAdapterHelper.hasPendingUpdates()) { requestLayout(); } } @Override public void onItemRangeChanged(int positionStart, int itemCount, Object payload) { assertNotInLayoutOrScroll(null); if (mAdapterHelper.onItemRangeChanged(positionStart, itemCount, payload)) { triggerUpdateProcessor(); } } @Override public void onItemRangeInserted(int positionStart, int itemCount) { assertNotInLayoutOrScroll(null); if (mAdapterHelper.onItemRangeInserted(positionStart, itemCount)) { triggerUpdateProcessor(); } } @Override public void onItemRangeRemoved(int positionStart, int itemCount) { assertNotInLayoutOrScroll(null); if (mAdapterHelper.onItemRangeRemoved(positionStart, itemCount)) { triggerUpdateProcessor(); } } @Override public void onItemRangeMoved(int fromPosition, int toPosition, int itemCount) { assertNotInLayoutOrScroll(null); if (mAdapterHelper.onItemRangeMoved(fromPosition, toPosition, itemCount)) { triggerUpdateProcessor(); } } void triggerUpdateProcessor() { if (POST_UPDATES_ON_ANIMATION && mHasFixedSize && mIsAttached) { RecyclerView.this.postOnAnimation(mUpdateChildViewsRunnable); } else { mAdapterUpdateDuringMeasure = true; requestLayout(); } } } /** * RecycledViewPool lets you share Views between multiple RecyclerViews. *

* If you want to recycle views across RecyclerViews, create an instance of RecycledViewPool * and use {@link RecyclerView#setRecycledViewPool(RecycledViewPool)}. *

* RecyclerView automatically creates a pool for itself if you don't provide one. * */ public static class RecycledViewPool { private static final int DEFAULT_MAX_SCRAP = 5; /** * Tracks both pooled holders, as well as create/bind timing metadata for the given type. * * Note that this tracks running averages of create/bind time across all RecyclerViews * (and, indirectly, Adapters) that use this pool. * * 1) This enables us to track average create and bind times across multiple adapters. Even * though create (and especially bind) may behave differently for different Adapter * subclasses, sharing the pool is a strong signal that they'll perform similarly, per type. * * 2) If {@link #willBindInTime(int, long, long)} returns false for one view, it will return * false for all other views of its type for the same deadline. This prevents items * constructed by {@link GapWorker} prefetch from being bound to a lower priority prefetch. */ static class ScrapData { ArrayList mScrapHeap = new ArrayList<>(); int mMaxScrap = DEFAULT_MAX_SCRAP; long mCreateRunningAverageNs = 0; long mBindRunningAverageNs = 0; } SparseArray mScrap = new SparseArray<>(); private int mAttachCount = 0; public void clear() { for (int i = 0; i < mScrap.size(); i++) { ScrapData data = mScrap.valueAt(i); data.mScrapHeap.clear(); } } public void setMaxRecycledViews(int viewType, int max) { ScrapData scrapData = getScrapDataForType(viewType); scrapData.mMaxScrap = max; final ArrayList scrapHeap = scrapData.mScrapHeap; if (scrapHeap != null) { while (scrapHeap.size() > max) { scrapHeap.remove(scrapHeap.size() - 1); } } } /** * Returns the current number of Views held by the RecycledViewPool of the given view type. */ public int getRecycledViewCount(int viewType) { return getScrapDataForType(viewType).mScrapHeap.size(); } public ViewHolder getRecycledView(int viewType) { final ScrapData scrapData = mScrap.get(viewType); if (scrapData != null && !scrapData.mScrapHeap.isEmpty()) { final ArrayList scrapHeap = scrapData.mScrapHeap; return scrapHeap.remove(scrapHeap.size() - 1); } return null; } int size() { int count = 0; for (int i = 0; i < mScrap.size(); i++) { ArrayList viewHolders = mScrap.valueAt(i).mScrapHeap; if (viewHolders != null) { count += viewHolders.size(); } } return count; } public void putRecycledView(ViewHolder scrap) { final int viewType = scrap.getItemViewType(); final ArrayList scrapHeap = getScrapDataForType(viewType).mScrapHeap; if (mScrap.get(viewType).mMaxScrap <= scrapHeap.size()) { return; } if (DEBUG && scrapHeap.contains(scrap)) { throw new IllegalArgumentException("this scrap item already exists"); } scrap.resetInternal(); scrapHeap.add(scrap); } long runningAverage(long oldAverage, long newValue) { if (oldAverage == 0) { return newValue; } return (oldAverage / 4 * 3) + (newValue / 4); } void factorInCreateTime(int viewType, long createTimeNs) { ScrapData scrapData = getScrapDataForType(viewType); scrapData.mCreateRunningAverageNs = runningAverage( scrapData.mCreateRunningAverageNs, createTimeNs); } void factorInBindTime(int viewType, long bindTimeNs) { ScrapData scrapData = getScrapDataForType(viewType); scrapData.mBindRunningAverageNs = runningAverage( scrapData.mBindRunningAverageNs, bindTimeNs); } boolean willCreateInTime(int viewType, long approxCurrentNs, long deadlineNs) { long expectedDurationNs = getScrapDataForType(viewType).mCreateRunningAverageNs; return expectedDurationNs == 0 || (approxCurrentNs + expectedDurationNs < deadlineNs); } boolean willBindInTime(int viewType, long approxCurrentNs, long deadlineNs) { long expectedDurationNs = getScrapDataForType(viewType).mBindRunningAverageNs; return expectedDurationNs == 0 || (approxCurrentNs + expectedDurationNs < deadlineNs); } void attach(Adapter adapter) { mAttachCount++; } void detach() { mAttachCount--; } /** * Detaches the old adapter and attaches the new one. *

* RecycledViewPool will clear its cache if it has only one adapter attached and the new * adapter uses a different ViewHolder than the oldAdapter. * * @param oldAdapter The previous adapter instance. Will be detached. * @param newAdapter The new adapter instance. Will be attached. * @param compatibleWithPrevious True if both oldAdapter and newAdapter are using the same * ViewHolder and view types. */ void onAdapterChanged(Adapter oldAdapter, Adapter newAdapter, boolean compatibleWithPrevious) { if (oldAdapter != null) { detach(); } if (!compatibleWithPrevious && mAttachCount == 0) { clear(); } if (newAdapter != null) { attach(newAdapter); } } private ScrapData getScrapDataForType(int viewType) { ScrapData scrapData = mScrap.get(viewType); if (scrapData == null) { scrapData = new ScrapData(); mScrap.put(viewType, scrapData); } return scrapData; } } /** * Utility method for finding an internal RecyclerView, if present */ @Nullable static RecyclerView findNestedRecyclerView(@NonNull View view) { if (!(view instanceof ViewGroup)) { return null; } if (view instanceof RecyclerView) { return (RecyclerView) view; } final ViewGroup parent = (ViewGroup) view; final int count = parent.getChildCount(); for (int i = 0; i < count; i++) { final View child = parent.getChildAt(i); final RecyclerView descendant = findNestedRecyclerView(child); if (descendant != null) { return descendant; } } return null; } /** * Utility method for clearing holder's internal RecyclerView, if present */ static void clearNestedRecyclerViewIfNotNested(@NonNull ViewHolder holder) { if (holder.mNestedRecyclerView != null) { View item = holder.mNestedRecyclerView.get(); while (item != null) { if (item == holder.itemView) { return; // match found, don't need to clear } ViewParent parent = item.getParent(); if (parent instanceof View) { item = (View) parent; } else { item = null; } } holder.mNestedRecyclerView = null; // not nested } } /** * Time base for deadline-aware work scheduling. Overridable for testing. * * Will return 0 to avoid cost of System.nanoTime where deadline-aware work scheduling * isn't relevant. */ long getNanoTime() { if (ALLOW_THREAD_GAP_WORK) { return System.nanoTime(); } else { return 0; } } /** * A Recycler is responsible for managing scrapped or detached item views for reuse. * *

A "scrapped" view is a view that is still attached to its parent RecyclerView but * that has been marked for removal or reuse.

* *

Typical use of a Recycler by a {@link LayoutManager} will be to obtain views for * an adapter's data set representing the data at a given position or item ID. * If the view to be reused is considered "dirty" the adapter will be asked to rebind it. * If not, the view can be quickly reused by the LayoutManager with no further work. * Clean views that have not {@link android.view.View#isLayoutRequested() requested layout} * may be repositioned by a LayoutManager without remeasurement.

*/ public final class Recycler { final ArrayList mAttachedScrap = new ArrayList<>(); ArrayList mChangedScrap = null; final ArrayList mCachedViews = new ArrayList(); private final List mUnmodifiableAttachedScrap = Collections.unmodifiableList(mAttachedScrap); private int mRequestedCacheMax = DEFAULT_CACHE_SIZE; int mViewCacheMax = DEFAULT_CACHE_SIZE; RecycledViewPool mRecyclerPool; private ViewCacheExtension mViewCacheExtension; static final int DEFAULT_CACHE_SIZE = 2; /** * Clear scrap views out of this recycler. Detached views contained within a * recycled view pool will remain. */ public void clear() { mAttachedScrap.clear(); recycleAndClearCachedViews(); } /** * Set the maximum number of detached, valid views we should retain for later use. * * @param viewCount Number of views to keep before sending views to the shared pool */ public void setViewCacheSize(int viewCount) { mRequestedCacheMax = viewCount; updateViewCacheSize(); } void updateViewCacheSize() { int extraCache = mLayout != null ? mLayout.mPrefetchMaxCountObserved : 0; mViewCacheMax = mRequestedCacheMax + extraCache; // first, try the views that can be recycled for (int i = mCachedViews.size() - 1; i >= 0 && mCachedViews.size() > mViewCacheMax; i--) { recycleCachedViewAt(i); } } /** * Returns an unmodifiable list of ViewHolders that are currently in the scrap list. * * @return List of ViewHolders in the scrap list. */ public List getScrapList() { return mUnmodifiableAttachedScrap; } /** * Helper method for getViewForPosition. *

* Checks whether a given view holder can be used for the provided position. * * @param holder ViewHolder * @return true if ViewHolder matches the provided position, false otherwise */ boolean validateViewHolderForOffsetPosition(ViewHolder holder) { // if it is a removed holder, nothing to verify since we cannot ask adapter anymore // if it is not removed, verify the type and id. if (holder.isRemoved()) { if (DEBUG && !mState.isPreLayout()) { throw new IllegalStateException("should not receive a removed view unless it" + " is pre layout"); } return mState.isPreLayout(); } if (holder.mPosition < 0 || holder.mPosition >= mAdapter.getItemCount()) { throw new IndexOutOfBoundsException("Inconsistency detected. Invalid view holder " + "adapter position" + holder); } if (!mState.isPreLayout()) { // don't check type if it is pre-layout. final int type = mAdapter.getItemViewType(holder.mPosition); if (type != holder.getItemViewType()) { return false; } } if (mAdapter.hasStableIds()) { return holder.getItemId() == mAdapter.getItemId(holder.mPosition); } return true; } /** * Attempts to bind view, and account for relevant timing information. If * deadlineNs != FOREVER_NS, this method may fail to bind, and return false. * * @param holder Holder to be bound. * @param offsetPosition Position of item to be bound. * @param position Pre-layout position of item to be bound. * @param deadlineNs Time, relative to getNanoTime(), by which bind/create work should * complete. If FOREVER_NS is passed, this method will not fail to * bind the holder. * @return */ private boolean tryBindViewHolderByDeadline(ViewHolder holder, int offsetPosition, int position, long deadlineNs) { holder.mOwnerRecyclerView = RecyclerView.this; final int viewType = holder.getItemViewType(); long startBindNs = getNanoTime(); if (deadlineNs != FOREVER_NS && !mRecyclerPool.willBindInTime(viewType, startBindNs, deadlineNs)) { // abort - we have a deadline we can't meet return false; } mAdapter.bindViewHolder(holder, offsetPosition); long endBindNs = getNanoTime(); mRecyclerPool.factorInBindTime(holder.getItemViewType(), endBindNs - startBindNs); attachAccessibilityDelegate(holder.itemView); if (mState.isPreLayout()) { holder.mPreLayoutPosition = position; } return true; } /** * Binds the given View to the position. The View can be a View previously retrieved via * {@link #getViewForPosition(int)} or created by * {@link Adapter#onCreateViewHolder(ViewGroup, int)}. *

* Generally, a LayoutManager should acquire its views via {@link #getViewForPosition(int)} * and let the RecyclerView handle caching. This is a helper method for LayoutManager who * wants to handle its own recycling logic. *

* Note that, {@link #getViewForPosition(int)} already binds the View to the position so * you don't need to call this method unless you want to bind this View to another position. * * @param view The view to update. * @param position The position of the item to bind to this View. */ public void bindViewToPosition(View view, int position) { ViewHolder holder = getChildViewHolderInt(view); if (holder == null) { throw new IllegalArgumentException("The view does not have a ViewHolder. You cannot" + " pass arbitrary views to this method, they should be created by the " + "Adapter"); } final int offsetPosition = mAdapterHelper.findPositionOffset(position); if (offsetPosition < 0 || offsetPosition >= mAdapter.getItemCount()) { throw new IndexOutOfBoundsException("Inconsistency detected. Invalid item " + "position " + position + "(offset:" + offsetPosition + ")." + "state:" + mState.getItemCount()); } tryBindViewHolderByDeadline(holder, offsetPosition, position, FOREVER_NS); final ViewGroup.LayoutParams lp = holder.itemView.getLayoutParams(); final LayoutParams rvLayoutParams; if (lp == null) { rvLayoutParams = (LayoutParams) generateDefaultLayoutParams(); holder.itemView.setLayoutParams(rvLayoutParams); } else if (!checkLayoutParams(lp)) { rvLayoutParams = (LayoutParams) generateLayoutParams(lp); holder.itemView.setLayoutParams(rvLayoutParams); } else { rvLayoutParams = (LayoutParams) lp; } rvLayoutParams.mInsetsDirty = true; rvLayoutParams.mViewHolder = holder; rvLayoutParams.mPendingInvalidate = holder.itemView.getParent() == null; } /** * RecyclerView provides artificial position range (item count) in pre-layout state and * automatically maps these positions to {@link Adapter} positions when * {@link #getViewForPosition(int)} or {@link #bindViewToPosition(View, int)} is called. *

* Usually, LayoutManager does not need to worry about this. However, in some cases, your * LayoutManager may need to call some custom component with item positions in which * case you need the actual adapter position instead of the pre layout position. You * can use this method to convert a pre-layout position to adapter (post layout) position. *

* Note that if the provided position belongs to a deleted ViewHolder, this method will * return -1. *

* Calling this method in post-layout state returns the same value back. * * @param position The pre-layout position to convert. Must be greater or equal to 0 and * less than {@link State#getItemCount()}. */ public int convertPreLayoutPositionToPostLayout(int position) { if (position < 0 || position >= mState.getItemCount()) { throw new IndexOutOfBoundsException("invalid position " + position + ". State " + "item count is " + mState.getItemCount()); } if (!mState.isPreLayout()) { return position; } return mAdapterHelper.findPositionOffset(position); } /** * Obtain a view initialized for the given position. * * This method should be used by {@link LayoutManager} implementations to obtain * views to represent data from an {@link Adapter}. *

* The Recycler may reuse a scrap or detached view from a shared pool if one is * available for the correct view type. If the adapter has not indicated that the * data at the given position has changed, the Recycler will attempt to hand back * a scrap view that was previously initialized for that data without rebinding. * * @param position Position to obtain a view for * @return A view representing the data at position from adapter */ public View getViewForPosition(int position) { return getViewForPosition(position, false); } View getViewForPosition(int position, boolean dryRun) { return tryGetViewHolderForPositionByDeadline(position, dryRun, FOREVER_NS).itemView; } /** * Attempts to get the ViewHolder for the given position, either from the Recycler scrap, * cache, the RecycledViewPool, or creating it directly. *

* If a deadlineNs other than {@link #FOREVER_NS} is passed, this method early return * rather than constructing or binding a ViewHolder if it doesn't think it has time. * If a ViewHolder must be constructed and not enough time remains, null is returned. If a * ViewHolder is aquired and must be bound but not enough time remains, an unbound holder is * returned. Use {@link ViewHolder#isBound()} on the returned object to check for this. * * @param position Position of ViewHolder to be returned. * @param dryRun True if the ViewHolder should not be removed from scrap/cache/ * @param deadlineNs Time, relative to getNanoTime(), by which bind/create work should * complete. If FOREVER_NS is passed, this method will not fail to * create/bind the holder if needed. * * @return ViewHolder for requested position */ @Nullable ViewHolder tryGetViewHolderForPositionByDeadline(int position, boolean dryRun, long deadlineNs) { if (position < 0 || position >= mState.getItemCount()) { throw new IndexOutOfBoundsException("Invalid item position " + position + "(" + position + "). Item count:" + mState.getItemCount()); } boolean fromScrapOrHiddenOrCache = false; ViewHolder holder = null; // 0) If there is a changed scrap, try to find from there if (mState.isPreLayout()) { holder = getChangedScrapViewForPosition(position); fromScrapOrHiddenOrCache = holder != null; } // 1) Find by position from scrap/hidden list/cache if (holder == null) { holder = getScrapOrHiddenOrCachedHolderForPosition(position, dryRun); if (holder != null) { if (!validateViewHolderForOffsetPosition(holder)) { // recycle holder (and unscrap if relevant) since it can't be used if (!dryRun) { // we would like to recycle this but need to make sure it is not used by // animation logic etc. holder.addFlags(ViewHolder.FLAG_INVALID); if (holder.isScrap()) { removeDetachedView(holder.itemView, false); holder.unScrap(); } else if (holder.wasReturnedFromScrap()) { holder.clearReturnedFromScrapFlag(); } recycleViewHolderInternal(holder); } holder = null; } else { fromScrapOrHiddenOrCache = true; } } } if (holder == null) { final int offsetPosition = mAdapterHelper.findPositionOffset(position); if (offsetPosition < 0 || offsetPosition >= mAdapter.getItemCount()) { throw new IndexOutOfBoundsException("Inconsistency detected. Invalid item " + "position " + position + "(offset:" + offsetPosition + ")." + "state:" + mState.getItemCount()); } final int type = mAdapter.getItemViewType(offsetPosition); // 2) Find from scrap/cache via stable ids, if exists if (mAdapter.hasStableIds()) { holder = getScrapOrCachedViewForId(mAdapter.getItemId(offsetPosition), type, dryRun); if (holder != null) { // update position holder.mPosition = offsetPosition; fromScrapOrHiddenOrCache = true; } } if (holder == null && mViewCacheExtension != null) { // We are NOT sending the offsetPosition because LayoutManager does not // know it. final View view = mViewCacheExtension .getViewForPositionAndType(this, position, type); if (view != null) { holder = getChildViewHolder(view); if (holder == null) { throw new IllegalArgumentException("getViewForPositionAndType returned" + " a view which does not have a ViewHolder"); } else if (holder.shouldIgnore()) { throw new IllegalArgumentException("getViewForPositionAndType returned" + " a view that is ignored. You must call stopIgnoring before" + " returning this view."); } } } if (holder == null) { // fallback to pool if (DEBUG) { Log.d(TAG, "tryGetViewHolderForPositionByDeadline(" + position + ") fetching from shared pool"); } holder = getRecycledViewPool().getRecycledView(type); if (holder != null) { holder.resetInternal(); if (FORCE_INVALIDATE_DISPLAY_LIST) { invalidateDisplayListInt(holder); } } } if (holder == null) { long start = getNanoTime(); if (deadlineNs != FOREVER_NS && !mRecyclerPool.willCreateInTime(type, start, deadlineNs)) { // abort - we have a deadline we can't meet return null; } holder = mAdapter.createViewHolder(RecyclerView.this, type); if (ALLOW_THREAD_GAP_WORK) { // only bother finding nested RV if prefetching RecyclerView innerView = findNestedRecyclerView(holder.itemView); if (innerView != null) { holder.mNestedRecyclerView = new WeakReference<>(innerView); } } long end = getNanoTime(); mRecyclerPool.factorInCreateTime(type, end - start); if (DEBUG) { Log.d(TAG, "tryGetViewHolderForPositionByDeadline created new ViewHolder"); } } } // This is very ugly but the only place we can grab this information // before the View is rebound and returned to the LayoutManager for post layout ops. // We don't need this in pre-layout since the VH is not updated by the LM. if (fromScrapOrHiddenOrCache && !mState.isPreLayout() && holder .hasAnyOfTheFlags(ViewHolder.FLAG_BOUNCED_FROM_HIDDEN_LIST)) { holder.setFlags(0, ViewHolder.FLAG_BOUNCED_FROM_HIDDEN_LIST); if (mState.mRunSimpleAnimations) { int changeFlags = ItemAnimator .buildAdapterChangeFlagsForAnimations(holder); changeFlags |= ItemAnimator.FLAG_APPEARED_IN_PRE_LAYOUT; final ItemHolderInfo info = mItemAnimator.recordPreLayoutInformation(mState, holder, changeFlags, holder.getUnmodifiedPayloads()); recordAnimationInfoIfBouncedHiddenView(holder, info); } } boolean bound = false; if (mState.isPreLayout() && holder.isBound()) { // do not update unless we absolutely have to. holder.mPreLayoutPosition = position; } else if (!holder.isBound() || holder.needsUpdate() || holder.isInvalid()) { if (DEBUG && holder.isRemoved()) { throw new IllegalStateException("Removed holder should be bound and it should" + " come here only in pre-layout. Holder: " + holder); } final int offsetPosition = mAdapterHelper.findPositionOffset(position); bound = tryBindViewHolderByDeadline(holder, offsetPosition, position, deadlineNs); } final ViewGroup.LayoutParams lp = holder.itemView.getLayoutParams(); final LayoutParams rvLayoutParams; if (lp == null) { rvLayoutParams = (LayoutParams) generateDefaultLayoutParams(); holder.itemView.setLayoutParams(rvLayoutParams); } else if (!checkLayoutParams(lp)) { rvLayoutParams = (LayoutParams) generateLayoutParams(lp); holder.itemView.setLayoutParams(rvLayoutParams); } else { rvLayoutParams = (LayoutParams) lp; } rvLayoutParams.mViewHolder = holder; rvLayoutParams.mPendingInvalidate = fromScrapOrHiddenOrCache && bound; return holder; } private void attachAccessibilityDelegate(View itemView) { if (isAccessibilityEnabled()) { if (itemView.getImportantForAccessibility() == View.IMPORTANT_FOR_ACCESSIBILITY_AUTO) { itemView.setImportantForAccessibility(View.IMPORTANT_FOR_ACCESSIBILITY_YES); } if (itemView.getAccessibilityDelegate() == null) { itemView.setAccessibilityDelegate(mAccessibilityDelegate.getItemDelegate()); } } } private void invalidateDisplayListInt(ViewHolder holder) { if (holder.itemView instanceof ViewGroup) { invalidateDisplayListInt((ViewGroup) holder.itemView, false); } } private void invalidateDisplayListInt(ViewGroup viewGroup, boolean invalidateThis) { for (int i = viewGroup.getChildCount() - 1; i >= 0; i--) { final View view = viewGroup.getChildAt(i); if (view instanceof ViewGroup) { invalidateDisplayListInt((ViewGroup) view, true); } } if (!invalidateThis) { return; } // we need to force it to become invisible if (viewGroup.getVisibility() == View.INVISIBLE) { viewGroup.setVisibility(View.VISIBLE); viewGroup.setVisibility(View.INVISIBLE); } else { final int visibility = viewGroup.getVisibility(); viewGroup.setVisibility(View.INVISIBLE); viewGroup.setVisibility(visibility); } } /** * Recycle a detached view. The specified view will be added to a pool of views * for later rebinding and reuse. * *

A view must be fully detached (removed from parent) before it may be recycled. If the * View is scrapped, it will be removed from scrap list.

* * @param view Removed view for recycling * @see LayoutManager#removeAndRecycleView(View, Recycler) */ public void recycleView(View view) { // This public recycle method tries to make view recycle-able since layout manager // intended to recycle this view (e.g. even if it is in scrap or change cache) ViewHolder holder = getChildViewHolderInt(view); if (holder.isTmpDetached()) { removeDetachedView(view, false); } if (holder.isScrap()) { holder.unScrap(); } else if (holder.wasReturnedFromScrap()) { holder.clearReturnedFromScrapFlag(); } recycleViewHolderInternal(holder); } /** * Internally, use this method instead of {@link #recycleView(android.view.View)} to * catch potential bugs. * @param view */ void recycleViewInternal(View view) { recycleViewHolderInternal(getChildViewHolderInt(view)); } void recycleAndClearCachedViews() { final int count = mCachedViews.size(); for (int i = count - 1; i >= 0; i--) { recycleCachedViewAt(i); } mCachedViews.clear(); if (ALLOW_THREAD_GAP_WORK) { mPrefetchRegistry.clearPrefetchPositions(); } } /** * Recycles a cached view and removes the view from the list. Views are added to cache * if and only if they are recyclable, so this method does not check it again. *

* A small exception to this rule is when the view does not have an animator reference * but transient state is true (due to animations created outside ItemAnimator). In that * case, adapter may choose to recycle it. From RecyclerView's perspective, the view is * still recyclable since Adapter wants to do so. * * @param cachedViewIndex The index of the view in cached views list */ void recycleCachedViewAt(int cachedViewIndex) { if (DEBUG) { Log.d(TAG, "Recycling cached view at index " + cachedViewIndex); } ViewHolder viewHolder = mCachedViews.get(cachedViewIndex); if (DEBUG) { Log.d(TAG, "CachedViewHolder to be recycled: " + viewHolder); } addViewHolderToRecycledViewPool(viewHolder, true); mCachedViews.remove(cachedViewIndex); } /** * internal implementation checks if view is scrapped or attached and throws an exception * if so. * Public version un-scraps before calling recycle. */ void recycleViewHolderInternal(ViewHolder holder) { if (holder.isScrap() || holder.itemView.getParent() != null) { throw new IllegalArgumentException( "Scrapped or attached views may not be recycled. isScrap:" + holder.isScrap() + " isAttached:" + (holder.itemView.getParent() != null)); } if (holder.isTmpDetached()) { throw new IllegalArgumentException("Tmp detached view should be removed " + "from RecyclerView before it can be recycled: " + holder); } if (holder.shouldIgnore()) { throw new IllegalArgumentException("Trying to recycle an ignored view holder. You" + " should first call stopIgnoringView(view) before calling recycle."); } //noinspection unchecked final boolean transientStatePreventsRecycling = holder .doesTransientStatePreventRecycling(); final boolean forceRecycle = mAdapter != null && transientStatePreventsRecycling && mAdapter.onFailedToRecycleView(holder); boolean cached = false; boolean recycled = false; if (DEBUG && mCachedViews.contains(holder)) { throw new IllegalArgumentException("cached view received recycle internal? " + holder); } if (forceRecycle || holder.isRecyclable()) { if (mViewCacheMax > 0 && !holder.hasAnyOfTheFlags(ViewHolder.FLAG_INVALID | ViewHolder.FLAG_REMOVED | ViewHolder.FLAG_UPDATE | ViewHolder.FLAG_ADAPTER_POSITION_UNKNOWN)) { // Retire oldest cached view int cachedViewSize = mCachedViews.size(); if (cachedViewSize >= mViewCacheMax && cachedViewSize > 0) { recycleCachedViewAt(0); cachedViewSize--; } int targetCacheIndex = cachedViewSize; if (ALLOW_THREAD_GAP_WORK && cachedViewSize > 0 && !mPrefetchRegistry.lastPrefetchIncludedPosition(holder.mPosition)) { // when adding the view, skip past most recently prefetched views int cacheIndex = cachedViewSize - 1; while (cacheIndex >= 0) { int cachedPos = mCachedViews.get(cacheIndex).mPosition; if (!mPrefetchRegistry.lastPrefetchIncludedPosition(cachedPos)) { break; } cacheIndex--; } targetCacheIndex = cacheIndex + 1; } mCachedViews.add(targetCacheIndex, holder); cached = true; } if (!cached) { addViewHolderToRecycledViewPool(holder, true); recycled = true; } } else { // NOTE: A view can fail to be recycled when it is scrolled off while an animation // runs. In this case, the item is eventually recycled by // ItemAnimatorRestoreListener#onAnimationFinished. // TODO: consider cancelling an animation when an item is removed scrollBy, // to return it to the pool faster if (DEBUG) { Log.d(TAG, "trying to recycle a non-recycleable holder. Hopefully, it will " + "re-visit here. We are still removing it from animation lists"); } } // even if the holder is not removed, we still call this method so that it is removed // from view holder lists. mViewInfoStore.removeViewHolder(holder); if (!cached && !recycled && transientStatePreventsRecycling) { holder.mOwnerRecyclerView = null; } } /** * Prepares the ViewHolder to be removed/recycled, and inserts it into the RecycledViewPool. * * Pass false to dispatchRecycled for views that have not been bound. * * @param holder Holder to be added to the pool. * @param dispatchRecycled True to dispatch View recycled callbacks. */ void addViewHolderToRecycledViewPool(ViewHolder holder, boolean dispatchRecycled) { clearNestedRecyclerViewIfNotNested(holder); holder.itemView.setAccessibilityDelegate(null); if (dispatchRecycled) { dispatchViewRecycled(holder); } holder.mOwnerRecyclerView = null; getRecycledViewPool().putRecycledView(holder); } /** * Used as a fast path for unscrapping and recycling a view during a bulk operation. * The caller must call {@link #clearScrap()} when it's done to update the recycler's * internal bookkeeping. */ void quickRecycleScrapView(View view) { final ViewHolder holder = getChildViewHolderInt(view); holder.mScrapContainer = null; holder.mInChangeScrap = false; holder.clearReturnedFromScrapFlag(); recycleViewHolderInternal(holder); } /** * Mark an attached view as scrap. * *

"Scrap" views are still attached to their parent RecyclerView but are eligible * for rebinding and reuse. Requests for a view for a given position may return a * reused or rebound scrap view instance.

* * @param view View to scrap */ void scrapView(View view) { final ViewHolder holder = getChildViewHolderInt(view); if (holder.hasAnyOfTheFlags(ViewHolder.FLAG_REMOVED | ViewHolder.FLAG_INVALID) || !holder.isUpdated() || canReuseUpdatedViewHolder(holder)) { if (holder.isInvalid() && !holder.isRemoved() && !mAdapter.hasStableIds()) { throw new IllegalArgumentException("Called scrap view with an invalid view." + " Invalid views cannot be reused from scrap, they should rebound from" + " recycler pool."); } holder.setScrapContainer(this, false); mAttachedScrap.add(holder); } else { if (mChangedScrap == null) { mChangedScrap = new ArrayList(); } holder.setScrapContainer(this, true); mChangedScrap.add(holder); } } /** * Remove a previously scrapped view from the pool of eligible scrap. * *

This view will no longer be eligible for reuse until re-scrapped or * until it is explicitly removed and recycled.

*/ void unscrapView(ViewHolder holder) { if (holder.mInChangeScrap) { mChangedScrap.remove(holder); } else { mAttachedScrap.remove(holder); } holder.mScrapContainer = null; holder.mInChangeScrap = false; holder.clearReturnedFromScrapFlag(); } int getScrapCount() { return mAttachedScrap.size(); } View getScrapViewAt(int index) { return mAttachedScrap.get(index).itemView; } void clearScrap() { mAttachedScrap.clear(); if (mChangedScrap != null) { mChangedScrap.clear(); } } ViewHolder getChangedScrapViewForPosition(int position) { // If pre-layout, check the changed scrap for an exact match. final int changedScrapSize; if (mChangedScrap == null || (changedScrapSize = mChangedScrap.size()) == 0) { return null; } // find by position for (int i = 0; i < changedScrapSize; i++) { final ViewHolder holder = mChangedScrap.get(i); if (!holder.wasReturnedFromScrap() && holder.getLayoutPosition() == position) { holder.addFlags(ViewHolder.FLAG_RETURNED_FROM_SCRAP); return holder; } } // find by id if (mAdapter.hasStableIds()) { final int offsetPosition = mAdapterHelper.findPositionOffset(position); if (offsetPosition > 0 && offsetPosition < mAdapter.getItemCount()) { final long id = mAdapter.getItemId(offsetPosition); for (int i = 0; i < changedScrapSize; i++) { final ViewHolder holder = mChangedScrap.get(i); if (!holder.wasReturnedFromScrap() && holder.getItemId() == id) { holder.addFlags(ViewHolder.FLAG_RETURNED_FROM_SCRAP); return holder; } } } } return null; } /** * Returns a view for the position either from attach scrap, hidden children, or cache. * * @param position Item position * @param dryRun Does a dry run, finds the ViewHolder but does not remove * @return a ViewHolder that can be re-used for this position. */ ViewHolder getScrapOrHiddenOrCachedHolderForPosition(int position, boolean dryRun) { final int scrapCount = mAttachedScrap.size(); // Try first for an exact, non-invalid match from scrap. for (int i = 0; i < scrapCount; i++) { final ViewHolder holder = mAttachedScrap.get(i); if (!holder.wasReturnedFromScrap() && holder.getLayoutPosition() == position && !holder.isInvalid() && (mState.mInPreLayout || !holder.isRemoved())) { holder.addFlags(ViewHolder.FLAG_RETURNED_FROM_SCRAP); return holder; } } if (!dryRun) { View view = mChildHelper.findHiddenNonRemovedView(position); if (view != null) { // This View is good to be used. We just need to unhide, detach and move to the // scrap list. final ViewHolder vh = getChildViewHolderInt(view); mChildHelper.unhide(view); int layoutIndex = mChildHelper.indexOfChild(view); if (layoutIndex == RecyclerView.NO_POSITION) { throw new IllegalStateException("layout index should not be -1 after " + "unhiding a view:" + vh); } mChildHelper.detachViewFromParent(layoutIndex); scrapView(view); vh.addFlags(ViewHolder.FLAG_RETURNED_FROM_SCRAP | ViewHolder.FLAG_BOUNCED_FROM_HIDDEN_LIST); return vh; } } // Search in our first-level recycled view cache. final int cacheSize = mCachedViews.size(); for (int i = 0; i < cacheSize; i++) { final ViewHolder holder = mCachedViews.get(i); // invalid view holders may be in cache if adapter has stable ids as they can be // retrieved via getScrapOrCachedViewForId if (!holder.isInvalid() && holder.getLayoutPosition() == position) { if (!dryRun) { mCachedViews.remove(i); } if (DEBUG) { Log.d(TAG, "getScrapOrHiddenOrCachedHolderForPosition(" + position + ") found match in cache: " + holder); } return holder; } } return null; } ViewHolder getScrapOrCachedViewForId(long id, int type, boolean dryRun) { // Look in our attached views first final int count = mAttachedScrap.size(); for (int i = count - 1; i >= 0; i--) { final ViewHolder holder = mAttachedScrap.get(i); if (holder.getItemId() == id && !holder.wasReturnedFromScrap()) { if (type == holder.getItemViewType()) { holder.addFlags(ViewHolder.FLAG_RETURNED_FROM_SCRAP); if (holder.isRemoved()) { // this might be valid in two cases: // > item is removed but we are in pre-layout pass // >> do nothing. return as is. make sure we don't rebind // > item is removed then added to another position and we are in // post layout. // >> remove removed and invalid flags, add update flag to rebind // because item was invisible to us and we don't know what happened in // between. if (!mState.isPreLayout()) { holder.setFlags(ViewHolder.FLAG_UPDATE, ViewHolder.FLAG_UPDATE | ViewHolder.FLAG_INVALID | ViewHolder.FLAG_REMOVED); } } return holder; } else if (!dryRun) { // if we are running animations, it is actually better to keep it in scrap // but this would force layout manager to lay it out which would be bad. // Recycle this scrap. Type mismatch. mAttachedScrap.remove(i); removeDetachedView(holder.itemView, false); quickRecycleScrapView(holder.itemView); } } } // Search the first-level cache final int cacheSize = mCachedViews.size(); for (int i = cacheSize - 1; i >= 0; i--) { final ViewHolder holder = mCachedViews.get(i); if (holder.getItemId() == id) { if (type == holder.getItemViewType()) { if (!dryRun) { mCachedViews.remove(i); } return holder; } else if (!dryRun) { recycleCachedViewAt(i); return null; } } } return null; } void dispatchViewRecycled(ViewHolder holder) { if (mRecyclerListener != null) { mRecyclerListener.onViewRecycled(holder); } if (mAdapter != null) { mAdapter.onViewRecycled(holder); } if (mState != null) { mViewInfoStore.removeViewHolder(holder); } if (DEBUG) Log.d(TAG, "dispatchViewRecycled: " + holder); } void onAdapterChanged(Adapter oldAdapter, Adapter newAdapter, boolean compatibleWithPrevious) { clear(); getRecycledViewPool().onAdapterChanged(oldAdapter, newAdapter, compatibleWithPrevious); } void offsetPositionRecordsForMove(int from, int to) { final int start, end, inBetweenOffset; if (from < to) { start = from; end = to; inBetweenOffset = -1; } else { start = to; end = from; inBetweenOffset = 1; } final int cachedCount = mCachedViews.size(); for (int i = 0; i < cachedCount; i++) { final ViewHolder holder = mCachedViews.get(i); if (holder == null || holder.mPosition < start || holder.mPosition > end) { continue; } if (holder.mPosition == from) { holder.offsetPosition(to - from, false); } else { holder.offsetPosition(inBetweenOffset, false); } if (DEBUG) { Log.d(TAG, "offsetPositionRecordsForMove cached child " + i + " holder " + holder); } } } void offsetPositionRecordsForInsert(int insertedAt, int count) { final int cachedCount = mCachedViews.size(); for (int i = 0; i < cachedCount; i++) { final ViewHolder holder = mCachedViews.get(i); if (holder != null && holder.mPosition >= insertedAt) { if (DEBUG) { Log.d(TAG, "offsetPositionRecordsForInsert cached " + i + " holder " + holder + " now at position " + (holder.mPosition + count)); } holder.offsetPosition(count, true); } } } /** * @param removedFrom Remove start index * @param count Remove count * @param applyToPreLayout If true, changes will affect ViewHolder's pre-layout position, if * false, they'll be applied before the second layout pass */ void offsetPositionRecordsForRemove(int removedFrom, int count, boolean applyToPreLayout) { final int removedEnd = removedFrom + count; final int cachedCount = mCachedViews.size(); for (int i = cachedCount - 1; i >= 0; i--) { final ViewHolder holder = mCachedViews.get(i); if (holder != null) { if (holder.mPosition >= removedEnd) { if (DEBUG) { Log.d(TAG, "offsetPositionRecordsForRemove cached " + i + " holder " + holder + " now at position " + (holder.mPosition - count)); } holder.offsetPosition(-count, applyToPreLayout); } else if (holder.mPosition >= removedFrom) { // Item for this view was removed. Dump it from the cache. holder.addFlags(ViewHolder.FLAG_REMOVED); recycleCachedViewAt(i); } } } } void setViewCacheExtension(ViewCacheExtension extension) { mViewCacheExtension = extension; } void setRecycledViewPool(RecycledViewPool pool) { if (mRecyclerPool != null) { mRecyclerPool.detach(); } mRecyclerPool = pool; if (pool != null) { mRecyclerPool.attach(getAdapter()); } } RecycledViewPool getRecycledViewPool() { if (mRecyclerPool == null) { mRecyclerPool = new RecycledViewPool(); } return mRecyclerPool; } void viewRangeUpdate(int positionStart, int itemCount) { final int positionEnd = positionStart + itemCount; final int cachedCount = mCachedViews.size(); for (int i = cachedCount - 1; i >= 0; i--) { final ViewHolder holder = mCachedViews.get(i); if (holder == null) { continue; } final int pos = holder.getLayoutPosition(); if (pos >= positionStart && pos < positionEnd) { holder.addFlags(ViewHolder.FLAG_UPDATE); recycleCachedViewAt(i); // cached views should not be flagged as changed because this will cause them // to animate when they are returned from cache. } } } void setAdapterPositionsAsUnknown() { final int cachedCount = mCachedViews.size(); for (int i = 0; i < cachedCount; i++) { final ViewHolder holder = mCachedViews.get(i); if (holder != null) { holder.addFlags(ViewHolder.FLAG_ADAPTER_POSITION_UNKNOWN); } } } void markKnownViewsInvalid() { if (mAdapter != null && mAdapter.hasStableIds()) { final int cachedCount = mCachedViews.size(); for (int i = 0; i < cachedCount; i++) { final ViewHolder holder = mCachedViews.get(i); if (holder != null) { holder.addFlags(ViewHolder.FLAG_UPDATE | ViewHolder.FLAG_INVALID); holder.addChangePayload(null); } } } else { // we cannot re-use cached views in this case. Recycle them all recycleAndClearCachedViews(); } } void clearOldPositions() { final int cachedCount = mCachedViews.size(); for (int i = 0; i < cachedCount; i++) { final ViewHolder holder = mCachedViews.get(i); holder.clearOldPosition(); } final int scrapCount = mAttachedScrap.size(); for (int i = 0; i < scrapCount; i++) { mAttachedScrap.get(i).clearOldPosition(); } if (mChangedScrap != null) { final int changedScrapCount = mChangedScrap.size(); for (int i = 0; i < changedScrapCount; i++) { mChangedScrap.get(i).clearOldPosition(); } } } void markItemDecorInsetsDirty() { final int cachedCount = mCachedViews.size(); for (int i = 0; i < cachedCount; i++) { final ViewHolder holder = mCachedViews.get(i); LayoutParams layoutParams = (LayoutParams) holder.itemView.getLayoutParams(); if (layoutParams != null) { layoutParams.mInsetsDirty = true; } } } } /** * ViewCacheExtension is a helper class to provide an additional layer of view caching that can * be controlled by the developer. *

* When {@link Recycler#getViewForPosition(int)} is called, Recycler checks attached scrap and * first level cache to find a matching View. If it cannot find a suitable View, Recycler will * call the {@link #getViewForPositionAndType(Recycler, int, int)} before checking * {@link RecycledViewPool}. *

* Note that, Recycler never sends Views to this method to be cached. It is developers * responsibility to decide whether they want to keep their Views in this custom cache or let * the default recycling policy handle it. */ public abstract static class ViewCacheExtension { /** * Returns a View that can be binded to the given Adapter position. *

* This method should not create a new View. Instead, it is expected to return * an already created View that can be re-used for the given type and position. * If the View is marked as ignored, it should first call * {@link LayoutManager#stopIgnoringView(View)} before returning the View. *

* RecyclerView will re-bind the returned View to the position if necessary. * * @param recycler The Recycler that can be used to bind the View * @param position The adapter position * @param type The type of the View, defined by adapter * @return A View that is bound to the given position or NULL if there is no View to re-use * @see LayoutManager#ignoreView(View) */ public abstract View getViewForPositionAndType(Recycler recycler, int position, int type); } /** * Base class for an Adapter * *

Adapters provide a binding from an app-specific data set to views that are displayed * within a {@link RecyclerView}.

* * @param A class that extends ViewHolder that will be used by the adapter. */ public abstract static class Adapter { private final AdapterDataObservable mObservable = new AdapterDataObservable(); private boolean mHasStableIds = false; /** * Called when RecyclerView needs a new {@link ViewHolder} of the given type to represent * an item. *

* This new ViewHolder should be constructed with a new View that can represent the items * of the given type. You can either create a new View manually or inflate it from an XML * layout file. *

* The new ViewHolder will be used to display items of the adapter using * {@link #onBindViewHolder(ViewHolder, int, List)}. Since it will be re-used to display * different items in the data set, it is a good idea to cache references to sub views of * the View to avoid unnecessary {@link View#findViewById(int)} calls. * * @param parent The ViewGroup into which the new View will be added after it is bound to * an adapter position. * @param viewType The view type of the new View. * * @return A new ViewHolder that holds a View of the given view type. * @see #getItemViewType(int) * @see #onBindViewHolder(ViewHolder, int) */ public abstract VH onCreateViewHolder(ViewGroup parent, int viewType); /** * Called by RecyclerView to display the data at the specified position. This method should * update the contents of the {@link ViewHolder#itemView} to reflect the item at the given * position. *

* Note that unlike {@link android.widget.ListView}, RecyclerView will not call this method * again if the position of the item changes in the data set unless the item itself is * invalidated or the new position cannot be determined. For this reason, you should only * use the position parameter while acquiring the related data item inside * this method and should not keep a copy of it. If you need the position of an item later * on (e.g. in a click listener), use {@link ViewHolder#getAdapterPosition()} which will * have the updated adapter position. * * Override {@link #onBindViewHolder(ViewHolder, int, List)} instead if Adapter can * handle efficient partial bind. * * @param holder The ViewHolder which should be updated to represent the contents of the * item at the given position in the data set. * @param position The position of the item within the adapter's data set. */ public abstract void onBindViewHolder(VH holder, int position); /** * Called by RecyclerView to display the data at the specified position. This method * should update the contents of the {@link ViewHolder#itemView} to reflect the item at * the given position. *

* Note that unlike {@link android.widget.ListView}, RecyclerView will not call this method * again if the position of the item changes in the data set unless the item itself is * invalidated or the new position cannot be determined. For this reason, you should only * use the position parameter while acquiring the related data item inside * this method and should not keep a copy of it. If you need the position of an item later * on (e.g. in a click listener), use {@link ViewHolder#getAdapterPosition()} which will * have the updated adapter position. *

* Partial bind vs full bind: *

* The payloads parameter is a merge list from {@link #notifyItemChanged(int, Object)} or * {@link #notifyItemRangeChanged(int, int, Object)}. If the payloads list is not empty, * the ViewHolder is currently bound to old data and Adapter may run an efficient partial * update using the payload info. If the payload is empty, Adapter must run a full bind. * Adapter should not assume that the payload passed in notify methods will be received by * onBindViewHolder(). For example when the view is not attached to the screen, the * payload in notifyItemChange() will be simply dropped. * * @param holder The ViewHolder which should be updated to represent the contents of the * item at the given position in the data set. * @param position The position of the item within the adapter's data set. * @param payloads A non-null list of merged payloads. Can be empty list if requires full * update. */ public void onBindViewHolder(VH holder, int position, List payloads) { onBindViewHolder(holder, position); } /** * This method calls {@link #onCreateViewHolder(ViewGroup, int)} to create a new * {@link ViewHolder} and initializes some private fields to be used by RecyclerView. * * @see #onCreateViewHolder(ViewGroup, int) */ public final VH createViewHolder(ViewGroup parent, int viewType) { Trace.beginSection(TRACE_CREATE_VIEW_TAG); final VH holder = onCreateViewHolder(parent, viewType); holder.mItemViewType = viewType; Trace.endSection(); return holder; } /** * This method internally calls {@link #onBindViewHolder(ViewHolder, int)} to update the * {@link ViewHolder} contents with the item at the given position and also sets up some * private fields to be used by RecyclerView. * * @see #onBindViewHolder(ViewHolder, int) */ public final void bindViewHolder(VH holder, int position) { holder.mPosition = position; if (hasStableIds()) { holder.mItemId = getItemId(position); } holder.setFlags(ViewHolder.FLAG_BOUND, ViewHolder.FLAG_BOUND | ViewHolder.FLAG_UPDATE | ViewHolder.FLAG_INVALID | ViewHolder.FLAG_ADAPTER_POSITION_UNKNOWN); Trace.beginSection(TRACE_BIND_VIEW_TAG); onBindViewHolder(holder, position, holder.getUnmodifiedPayloads()); holder.clearPayload(); final ViewGroup.LayoutParams layoutParams = holder.itemView.getLayoutParams(); if (layoutParams instanceof RecyclerView.LayoutParams) { ((LayoutParams) layoutParams).mInsetsDirty = true; } Trace.endSection(); } /** * Return the view type of the item at position for the purposes * of view recycling. * *

The default implementation of this method returns 0, making the assumption of * a single view type for the adapter. Unlike ListView adapters, types need not * be contiguous. Consider using id resources to uniquely identify item view types. * * @param position position to query * @return integer value identifying the type of the view needed to represent the item at * position. Type codes need not be contiguous. */ public int getItemViewType(int position) { return 0; } /** * Indicates whether each item in the data set can be represented with a unique identifier * of type {@link java.lang.Long}. * * @param hasStableIds Whether items in data set have unique identifiers or not. * @see #hasStableIds() * @see #getItemId(int) */ public void setHasStableIds(boolean hasStableIds) { if (hasObservers()) { throw new IllegalStateException("Cannot change whether this adapter has " + "stable IDs while the adapter has registered observers."); } mHasStableIds = hasStableIds; } /** * Return the stable ID for the item at position. If {@link #hasStableIds()} * would return false this method should return {@link #NO_ID}. The default implementation * of this method returns {@link #NO_ID}. * * @param position Adapter position to query * @return the stable ID of the item at position */ public long getItemId(int position) { return NO_ID; } /** * Returns the total number of items in the data set held by the adapter. * * @return The total number of items in this adapter. */ public abstract int getItemCount(); /** * Returns true if this adapter publishes a unique long value that can * act as a key for the item at a given position in the data set. If that item is relocated * in the data set, the ID returned for that item should be the same. * * @return true if this adapter's items have stable IDs */ public final boolean hasStableIds() { return mHasStableIds; } /** * Called when a view created by this adapter has been recycled. * *

A view is recycled when a {@link LayoutManager} decides that it no longer * needs to be attached to its parent {@link RecyclerView}. This can be because it has * fallen out of visibility or a set of cached views represented by views still * attached to the parent RecyclerView. If an item view has large or expensive data * bound to it such as large bitmaps, this may be a good place to release those * resources.

*

* RecyclerView calls this method right before clearing ViewHolder's internal data and * sending it to RecycledViewPool. This way, if ViewHolder was holding valid information * before being recycled, you can call {@link ViewHolder#getAdapterPosition()} to get * its adapter position. * * @param holder The ViewHolder for the view being recycled */ public void onViewRecycled(VH holder) { } /** * Called by the RecyclerView if a ViewHolder created by this Adapter cannot be recycled * due to its transient state. Upon receiving this callback, Adapter can clear the * animation(s) that effect the View's transient state and return true so that * the View can be recycled. Keep in mind that the View in question is already removed from * the RecyclerView. *

* In some cases, it is acceptable to recycle a View although it has transient state. Most * of the time, this is a case where the transient state will be cleared in * {@link #onBindViewHolder(ViewHolder, int)} call when View is rebound to a new position. * For this reason, RecyclerView leaves the decision to the Adapter and uses the return * value of this method to decide whether the View should be recycled or not. *

* Note that when all animations are created by {@link RecyclerView.ItemAnimator}, you * should never receive this callback because RecyclerView keeps those Views as children * until their animations are complete. This callback is useful when children of the item * views create animations which may not be easy to implement using an {@link ItemAnimator}. *

* You should never fix this issue by calling * holder.itemView.setHasTransientState(false); unless you've previously called * holder.itemView.setHasTransientState(true);. Each * View.setHasTransientState(true) call must be matched by a * View.setHasTransientState(false) call, otherwise, the state of the View * may become inconsistent. You should always prefer to end or cancel animations that are * triggering the transient state instead of handling it manually. * * @param holder The ViewHolder containing the View that could not be recycled due to its * transient state. * @return True if the View should be recycled, false otherwise. Note that if this method * returns true, RecyclerView will ignore the transient state of * the View and recycle it regardless. If this method returns false, * RecyclerView will check the View's transient state again before giving a final decision. * Default implementation returns false. */ public boolean onFailedToRecycleView(VH holder) { return false; } /** * Called when a view created by this adapter has been attached to a window. * *

This can be used as a reasonable signal that the view is about to be seen * by the user. If the adapter previously freed any resources in * {@link #onViewDetachedFromWindow(RecyclerView.ViewHolder) onViewDetachedFromWindow} * those resources should be restored here.

* * @param holder Holder of the view being attached */ public void onViewAttachedToWindow(VH holder) { } /** * Called when a view created by this adapter has been detached from its window. * *

Becoming detached from the window is not necessarily a permanent condition; * the consumer of an Adapter's views may choose to cache views offscreen while they * are not visible, attaching and detaching them as appropriate.

* * @param holder Holder of the view being detached */ public void onViewDetachedFromWindow(VH holder) { } /** * Returns true if one or more observers are attached to this adapter. * * @return true if this adapter has observers */ public final boolean hasObservers() { return mObservable.hasObservers(); } /** * Register a new observer to listen for data changes. * *

The adapter may publish a variety of events describing specific changes. * Not all adapters may support all change types and some may fall back to a generic * {@link com.android.internal.widget.RecyclerView.AdapterDataObserver#onChanged() * "something changed"} event if more specific data is not available.

* *

Components registering observers with an adapter are responsible for * {@link #unregisterAdapterDataObserver(RecyclerView.AdapterDataObserver) * unregistering} those observers when finished.

* * @param observer Observer to register * * @see #unregisterAdapterDataObserver(RecyclerView.AdapterDataObserver) */ public void registerAdapterDataObserver(AdapterDataObserver observer) { mObservable.registerObserver(observer); } /** * Unregister an observer currently listening for data changes. * *

The unregistered observer will no longer receive events about changes * to the adapter.

* * @param observer Observer to unregister * * @see #registerAdapterDataObserver(RecyclerView.AdapterDataObserver) */ public void unregisterAdapterDataObserver(AdapterDataObserver observer) { mObservable.unregisterObserver(observer); } /** * Called by RecyclerView when it starts observing this Adapter. *

* Keep in mind that same adapter may be observed by multiple RecyclerViews. * * @param recyclerView The RecyclerView instance which started observing this adapter. * @see #onDetachedFromRecyclerView(RecyclerView) */ public void onAttachedToRecyclerView(RecyclerView recyclerView) { } /** * Called by RecyclerView when it stops observing this Adapter. * * @param recyclerView The RecyclerView instance which stopped observing this adapter. * @see #onAttachedToRecyclerView(RecyclerView) */ public void onDetachedFromRecyclerView(RecyclerView recyclerView) { } /** * Notify any registered observers that the data set has changed. * *

There are two different classes of data change events, item changes and structural * changes. Item changes are when a single item has its data updated but no positional * changes have occurred. Structural changes are when items are inserted, removed or moved * within the data set.

* *

This event does not specify what about the data set has changed, forcing * any observers to assume that all existing items and structure may no longer be valid. * LayoutManagers will be forced to fully rebind and relayout all visible views.

* *

RecyclerView will attempt to synthesize visible structural change events * for adapters that report that they have {@link #hasStableIds() stable IDs} when * this method is used. This can help for the purposes of animation and visual * object persistence but individual item views will still need to be rebound * and relaid out.

* *

If you are writing an adapter it will always be more efficient to use the more * specific change events if you can. Rely on notifyDataSetChanged() * as a last resort.

* * @see #notifyItemChanged(int) * @see #notifyItemInserted(int) * @see #notifyItemRemoved(int) * @see #notifyItemRangeChanged(int, int) * @see #notifyItemRangeInserted(int, int) * @see #notifyItemRangeRemoved(int, int) */ public final void notifyDataSetChanged() { mObservable.notifyChanged(); } /** * Notify any registered observers that the item at position has changed. * Equivalent to calling notifyItemChanged(position, null);. * *

This is an item change event, not a structural change event. It indicates that any * reflection of the data at position is out of date and should be updated. * The item at position retains the same identity.

* * @param position Position of the item that has changed * * @see #notifyItemRangeChanged(int, int) */ public final void notifyItemChanged(int position) { mObservable.notifyItemRangeChanged(position, 1); } /** * Notify any registered observers that the item at position has changed with * an optional payload object. * *

This is an item change event, not a structural change event. It indicates that any * reflection of the data at position is out of date and should be updated. * The item at position retains the same identity. *

* *

* Client can optionally pass a payload for partial change. These payloads will be merged * and may be passed to adapter's {@link #onBindViewHolder(ViewHolder, int, List)} if the * item is already represented by a ViewHolder and it will be rebound to the same * ViewHolder. A notifyItemRangeChanged() with null payload will clear all existing * payloads on that item and prevent future payload until * {@link #onBindViewHolder(ViewHolder, int, List)} is called. Adapter should not assume * that the payload will always be passed to onBindViewHolder(), e.g. when the view is not * attached, the payload will be simply dropped. * * @param position Position of the item that has changed * @param payload Optional parameter, use null to identify a "full" update * * @see #notifyItemRangeChanged(int, int) */ public final void notifyItemChanged(int position, Object payload) { mObservable.notifyItemRangeChanged(position, 1, payload); } /** * Notify any registered observers that the itemCount items starting at * position positionStart have changed. * Equivalent to calling notifyItemRangeChanged(position, itemCount, null);. * *

This is an item change event, not a structural change event. It indicates that * any reflection of the data in the given position range is out of date and should * be updated. The items in the given range retain the same identity.

* * @param positionStart Position of the first item that has changed * @param itemCount Number of items that have changed * * @see #notifyItemChanged(int) */ public final void notifyItemRangeChanged(int positionStart, int itemCount) { mObservable.notifyItemRangeChanged(positionStart, itemCount); } /** * Notify any registered observers that the itemCount items starting at * position positionStart have changed. An optional payload can be * passed to each changed item. * *

This is an item change event, not a structural change event. It indicates that any * reflection of the data in the given position range is out of date and should be updated. * The items in the given range retain the same identity. *

* *

* Client can optionally pass a payload for partial change. These payloads will be merged * and may be passed to adapter's {@link #onBindViewHolder(ViewHolder, int, List)} if the * item is already represented by a ViewHolder and it will be rebound to the same * ViewHolder. A notifyItemRangeChanged() with null payload will clear all existing * payloads on that item and prevent future payload until * {@link #onBindViewHolder(ViewHolder, int, List)} is called. Adapter should not assume * that the payload will always be passed to onBindViewHolder(), e.g. when the view is not * attached, the payload will be simply dropped. * * @param positionStart Position of the first item that has changed * @param itemCount Number of items that have changed * @param payload Optional parameter, use null to identify a "full" update * * @see #notifyItemChanged(int) */ public final void notifyItemRangeChanged(int positionStart, int itemCount, Object payload) { mObservable.notifyItemRangeChanged(positionStart, itemCount, payload); } /** * Notify any registered observers that the item reflected at position * has been newly inserted. The item previously at position is now at * position position + 1. * *

This is a structural change event. Representations of other existing items in the * data set are still considered up to date and will not be rebound, though their * positions may be altered.

* * @param position Position of the newly inserted item in the data set * * @see #notifyItemRangeInserted(int, int) */ public final void notifyItemInserted(int position) { mObservable.notifyItemRangeInserted(position, 1); } /** * Notify any registered observers that the item reflected at fromPosition * has been moved to toPosition. * *

This is a structural change event. Representations of other existing items in the * data set are still considered up to date and will not be rebound, though their * positions may be altered.

* * @param fromPosition Previous position of the item. * @param toPosition New position of the item. */ public final void notifyItemMoved(int fromPosition, int toPosition) { mObservable.notifyItemMoved(fromPosition, toPosition); } /** * Notify any registered observers that the currently reflected itemCount * items starting at positionStart have been newly inserted. The items * previously located at positionStart and beyond can now be found starting * at position positionStart + itemCount. * *

This is a structural change event. Representations of other existing items in the * data set are still considered up to date and will not be rebound, though their positions * may be altered.

* * @param positionStart Position of the first item that was inserted * @param itemCount Number of items inserted * * @see #notifyItemInserted(int) */ public final void notifyItemRangeInserted(int positionStart, int itemCount) { mObservable.notifyItemRangeInserted(positionStart, itemCount); } /** * Notify any registered observers that the item previously located at position * has been removed from the data set. The items previously located at and after * position may now be found at oldPosition - 1. * *

This is a structural change event. Representations of other existing items in the * data set are still considered up to date and will not be rebound, though their positions * may be altered.

* * @param position Position of the item that has now been removed * * @see #notifyItemRangeRemoved(int, int) */ public final void notifyItemRemoved(int position) { mObservable.notifyItemRangeRemoved(position, 1); } /** * Notify any registered observers that the itemCount items previously * located at positionStart have been removed from the data set. The items * previously located at and after positionStart + itemCount may now be found * at oldPosition - itemCount. * *

This is a structural change event. Representations of other existing items in the data * set are still considered up to date and will not be rebound, though their positions * may be altered.

* * @param positionStart Previous position of the first item that was removed * @param itemCount Number of items removed from the data set */ public final void notifyItemRangeRemoved(int positionStart, int itemCount) { mObservable.notifyItemRangeRemoved(positionStart, itemCount); } } void dispatchChildDetached(View child) { final ViewHolder viewHolder = getChildViewHolderInt(child); onChildDetachedFromWindow(child); if (mAdapter != null && viewHolder != null) { mAdapter.onViewDetachedFromWindow(viewHolder); } if (mOnChildAttachStateListeners != null) { final int cnt = mOnChildAttachStateListeners.size(); for (int i = cnt - 1; i >= 0; i--) { mOnChildAttachStateListeners.get(i).onChildViewDetachedFromWindow(child); } } } void dispatchChildAttached(View child) { final ViewHolder viewHolder = getChildViewHolderInt(child); onChildAttachedToWindow(child); if (mAdapter != null && viewHolder != null) { mAdapter.onViewAttachedToWindow(viewHolder); } if (mOnChildAttachStateListeners != null) { final int cnt = mOnChildAttachStateListeners.size(); for (int i = cnt - 1; i >= 0; i--) { mOnChildAttachStateListeners.get(i).onChildViewAttachedToWindow(child); } } } /** * A LayoutManager is responsible for measuring and positioning item views * within a RecyclerView as well as determining the policy for when to recycle * item views that are no longer visible to the user. By changing the LayoutManager * a RecyclerView can be used to implement a standard vertically scrolling list, * a uniform grid, staggered grids, horizontally scrolling collections and more. Several stock * layout managers are provided for general use. *

* If the LayoutManager specifies a default constructor or one with the signature * ({@link Context}, {@link AttributeSet}, {@code int}, {@code int}), RecyclerView will * instantiate and set the LayoutManager when being inflated. Most used properties can * be then obtained from {@link #getProperties(Context, AttributeSet, int, int)}. In case * a LayoutManager specifies both constructors, the non-default constructor will take * precedence. * */ public abstract static class LayoutManager { ChildHelper mChildHelper; RecyclerView mRecyclerView; @Nullable SmoothScroller mSmoothScroller; boolean mRequestedSimpleAnimations = false; boolean mIsAttachedToWindow = false; boolean mAutoMeasure = false; /** * LayoutManager has its own more strict measurement cache to avoid re-measuring a child * if the space that will be given to it is already larger than what it has measured before. */ private boolean mMeasurementCacheEnabled = true; private boolean mItemPrefetchEnabled = true; /** * Written by {@link GapWorker} when prefetches occur to track largest number of view ever * requested by a {@link #collectInitialPrefetchPositions(int, LayoutPrefetchRegistry)} or * {@link #collectAdjacentPrefetchPositions(int, int, State, LayoutPrefetchRegistry)} call. * * If expanded by a {@link #collectInitialPrefetchPositions(int, LayoutPrefetchRegistry)}, * will be reset upon layout to prevent initial prefetches (often large, since they're * proportional to expected child count) from expanding cache permanently. */ int mPrefetchMaxCountObserved; /** * If true, mPrefetchMaxCountObserved is only valid until next layout, and should be reset. */ boolean mPrefetchMaxObservedInInitialPrefetch; /** * These measure specs might be the measure specs that were passed into RecyclerView's * onMeasure method OR fake measure specs created by the RecyclerView. * For example, when a layout is run, RecyclerView always sets these specs to be * EXACTLY because a LayoutManager cannot resize RecyclerView during a layout pass. *

* Also, to be able to use the hint in unspecified measure specs, RecyclerView checks the * API level and sets the size to 0 pre-M to avoid any issue that might be caused by * corrupt values. Older platforms have no responsibility to provide a size if they set * mode to unspecified. */ private int mWidthMode, mHeightMode; private int mWidth, mHeight; /** * Interface for LayoutManagers to request items to be prefetched, based on position, with * specified distance from viewport, which indicates priority. * * @see LayoutManager#collectAdjacentPrefetchPositions(int, int, State, LayoutPrefetchRegistry) * @see LayoutManager#collectInitialPrefetchPositions(int, LayoutPrefetchRegistry) */ public interface LayoutPrefetchRegistry { /** * Requests an an item to be prefetched, based on position, with a specified distance, * indicating priority. * * @param layoutPosition Position of the item to prefetch. * @param pixelDistance Distance from the current viewport to the bounds of the item, * must be non-negative. */ void addPosition(int layoutPosition, int pixelDistance); } void setRecyclerView(RecyclerView recyclerView) { if (recyclerView == null) { mRecyclerView = null; mChildHelper = null; mWidth = 0; mHeight = 0; } else { mRecyclerView = recyclerView; mChildHelper = recyclerView.mChildHelper; mWidth = recyclerView.getWidth(); mHeight = recyclerView.getHeight(); } mWidthMode = MeasureSpec.EXACTLY; mHeightMode = MeasureSpec.EXACTLY; } void setMeasureSpecs(int wSpec, int hSpec) { mWidth = MeasureSpec.getSize(wSpec); mWidthMode = MeasureSpec.getMode(wSpec); if (mWidthMode == MeasureSpec.UNSPECIFIED && !ALLOW_SIZE_IN_UNSPECIFIED_SPEC) { mWidth = 0; } mHeight = MeasureSpec.getSize(hSpec); mHeightMode = MeasureSpec.getMode(hSpec); if (mHeightMode == MeasureSpec.UNSPECIFIED && !ALLOW_SIZE_IN_UNSPECIFIED_SPEC) { mHeight = 0; } } /** * Called after a layout is calculated during a measure pass when using auto-measure. *

* It simply traverses all children to calculate a bounding box then calls * {@link #setMeasuredDimension(Rect, int, int)}. LayoutManagers can override that method * if they need to handle the bounding box differently. *

* For example, GridLayoutManager override that method to ensure that even if a column is * empty, the GridLayoutManager still measures wide enough to include it. * * @param widthSpec The widthSpec that was passing into RecyclerView's onMeasure * @param heightSpec The heightSpec that was passing into RecyclerView's onMeasure */ void setMeasuredDimensionFromChildren(int widthSpec, int heightSpec) { final int count = getChildCount(); if (count == 0) { mRecyclerView.defaultOnMeasure(widthSpec, heightSpec); return; } int minX = Integer.MAX_VALUE; int minY = Integer.MAX_VALUE; int maxX = Integer.MIN_VALUE; int maxY = Integer.MIN_VALUE; for (int i = 0; i < count; i++) { View child = getChildAt(i); final Rect bounds = mRecyclerView.mTempRect; getDecoratedBoundsWithMargins(child, bounds); if (bounds.left < minX) { minX = bounds.left; } if (bounds.right > maxX) { maxX = bounds.right; } if (bounds.top < minY) { minY = bounds.top; } if (bounds.bottom > maxY) { maxY = bounds.bottom; } } mRecyclerView.mTempRect.set(minX, minY, maxX, maxY); setMeasuredDimension(mRecyclerView.mTempRect, widthSpec, heightSpec); } /** * Sets the measured dimensions from the given bounding box of the children and the * measurement specs that were passed into {@link RecyclerView#onMeasure(int, int)}. It is * called after the RecyclerView calls * {@link LayoutManager#onLayoutChildren(Recycler, State)} during a measurement pass. *

* This method should call {@link #setMeasuredDimension(int, int)}. *

* The default implementation adds the RecyclerView's padding to the given bounding box * then caps the value to be within the given measurement specs. *

* This method is only called if the LayoutManager opted into the auto measurement API. * * @param childrenBounds The bounding box of all children * @param wSpec The widthMeasureSpec that was passed into the RecyclerView. * @param hSpec The heightMeasureSpec that was passed into the RecyclerView. * * @see #setAutoMeasureEnabled(boolean) */ public void setMeasuredDimension(Rect childrenBounds, int wSpec, int hSpec) { int usedWidth = childrenBounds.width() + getPaddingLeft() + getPaddingRight(); int usedHeight = childrenBounds.height() + getPaddingTop() + getPaddingBottom(); int width = chooseSize(wSpec, usedWidth, getMinimumWidth()); int height = chooseSize(hSpec, usedHeight, getMinimumHeight()); setMeasuredDimension(width, height); } /** * Calls {@code RecyclerView#requestLayout} on the underlying RecyclerView */ public void requestLayout() { if (mRecyclerView != null) { mRecyclerView.requestLayout(); } } /** * Checks if RecyclerView is in the middle of a layout or scroll and throws an * {@link IllegalStateException} if it is not. * * @param message The message for the exception. Can be null. * @see #assertNotInLayoutOrScroll(String) */ public void assertInLayoutOrScroll(String message) { if (mRecyclerView != null) { mRecyclerView.assertInLayoutOrScroll(message); } } /** * Chooses a size from the given specs and parameters that is closest to the desired size * and also complies with the spec. * * @param spec The measureSpec * @param desired The preferred measurement * @param min The minimum value * * @return A size that fits to the given specs */ public static int chooseSize(int spec, int desired, int min) { final int mode = View.MeasureSpec.getMode(spec); final int size = View.MeasureSpec.getSize(spec); switch (mode) { case View.MeasureSpec.EXACTLY: return size; case View.MeasureSpec.AT_MOST: return Math.min(size, Math.max(desired, min)); case View.MeasureSpec.UNSPECIFIED: default: return Math.max(desired, min); } } /** * Checks if RecyclerView is in the middle of a layout or scroll and throws an * {@link IllegalStateException} if it is. * * @param message The message for the exception. Can be null. * @see #assertInLayoutOrScroll(String) */ public void assertNotInLayoutOrScroll(String message) { if (mRecyclerView != null) { mRecyclerView.assertNotInLayoutOrScroll(message); } } /** * Defines whether the layout should be measured by the RecyclerView or the LayoutManager * wants to handle the layout measurements itself. *

* This method is usually called by the LayoutManager with value {@code true} if it wants * to support WRAP_CONTENT. If you are using a public LayoutManager but want to customize * the measurement logic, you can call this method with {@code false} and override * {@link LayoutManager#onMeasure(int, int)} to implement your custom measurement logic. *

* AutoMeasure is a convenience mechanism for LayoutManagers to easily wrap their content or * handle various specs provided by the RecyclerView's parent. * It works by calling {@link LayoutManager#onLayoutChildren(Recycler, State)} during an * {@link RecyclerView#onMeasure(int, int)} call, then calculating desired dimensions based * on children's positions. It does this while supporting all existing animation * capabilities of the RecyclerView. *

* AutoMeasure works as follows: *

    *
  1. LayoutManager should call {@code setAutoMeasureEnabled(true)} to enable it. All of * the framework LayoutManagers use {@code auto-measure}.
  2. *
  3. When {@link RecyclerView#onMeasure(int, int)} is called, if the provided specs are * exact, RecyclerView will only call LayoutManager's {@code onMeasure} and return without * doing any layout calculation.
  4. *
  5. If one of the layout specs is not {@code EXACT}, the RecyclerView will start the * layout process in {@code onMeasure} call. It will process all pending Adapter updates and * decide whether to run a predictive layout or not. If it decides to do so, it will first * call {@link #onLayoutChildren(Recycler, State)} with {@link State#isPreLayout()} set to * {@code true}. At this stage, {@link #getWidth()} and {@link #getHeight()} will still * return the width and height of the RecyclerView as of the last layout calculation. *

    * After handling the predictive case, RecyclerView will call * {@link #onLayoutChildren(Recycler, State)} with {@link State#isMeasuring()} set to * {@code true} and {@link State#isPreLayout()} set to {@code false}. The LayoutManager can * access the measurement specs via {@link #getHeight()}, {@link #getHeightMode()}, * {@link #getWidth()} and {@link #getWidthMode()}.

  6. *
  7. After the layout calculation, RecyclerView sets the measured width & height by * calculating the bounding box for the children (+ RecyclerView's padding). The * LayoutManagers can override {@link #setMeasuredDimension(Rect, int, int)} to choose * different values. For instance, GridLayoutManager overrides this value to handle the case * where if it is vertical and has 3 columns but only 2 items, it should still measure its * width to fit 3 items, not 2.
  8. *
  9. Any following on measure call to the RecyclerView will run * {@link #onLayoutChildren(Recycler, State)} with {@link State#isMeasuring()} set to * {@code true} and {@link State#isPreLayout()} set to {@code false}. RecyclerView will * take care of which views are actually added / removed / moved / changed for animations so * that the LayoutManager should not worry about them and handle each * {@link #onLayoutChildren(Recycler, State)} call as if it is the last one. *
  10. *
  11. When measure is complete and RecyclerView's * {@link #onLayout(boolean, int, int, int, int)} method is called, RecyclerView checks * whether it already did layout calculations during the measure pass and if so, it re-uses * that information. It may still decide to call {@link #onLayoutChildren(Recycler, State)} * if the last measure spec was different from the final dimensions or adapter contents * have changed between the measure call and the layout call.
  12. *
  13. Finally, animations are calculated and run as usual.
  14. *
* * @param enabled True if the Layout should be measured by the * RecyclerView, false if the LayoutManager wants * to measure itself. * * @see #setMeasuredDimension(Rect, int, int) * @see #isAutoMeasureEnabled() */ public void setAutoMeasureEnabled(boolean enabled) { mAutoMeasure = enabled; } /** * Returns whether the LayoutManager uses the automatic measurement API or not. * * @return True if the LayoutManager is measured by the RecyclerView or * false if it measures itself. * * @see #setAutoMeasureEnabled(boolean) */ public boolean isAutoMeasureEnabled() { return mAutoMeasure; } /** * Returns whether this LayoutManager supports automatic item animations. * A LayoutManager wishing to support item animations should obey certain * rules as outlined in {@link #onLayoutChildren(Recycler, State)}. * The default return value is false, so subclasses of LayoutManager * will not get predictive item animations by default. * *

Whether item animations are enabled in a RecyclerView is determined both * by the return value from this method and the * {@link RecyclerView#setItemAnimator(ItemAnimator) ItemAnimator} set on the * RecyclerView itself. If the RecyclerView has a non-null ItemAnimator but this * method returns false, then simple item animations will be enabled, in which * views that are moving onto or off of the screen are simply faded in/out. If * the RecyclerView has a non-null ItemAnimator and this method returns true, * then there will be two calls to {@link #onLayoutChildren(Recycler, State)} to * setup up the information needed to more intelligently predict where appearing * and disappearing views should be animated from/to.

* * @return true if predictive item animations should be enabled, false otherwise */ public boolean supportsPredictiveItemAnimations() { return false; } /** * Sets whether the LayoutManager should be queried for views outside of * its viewport while the UI thread is idle between frames. * *

If enabled, the LayoutManager will be queried for items to inflate/bind in between * view system traversals on devices running API 21 or greater. Default value is true.

* *

On platforms API level 21 and higher, the UI thread is idle between passing a frame * to RenderThread and the starting up its next frame at the next VSync pulse. By * prefetching out of window views in this time period, delays from inflation and view * binding are much less likely to cause jank and stuttering during scrolls and flings.

* *

While prefetch is enabled, it will have the side effect of expanding the effective * size of the View cache to hold prefetched views.

* * @param enabled True if items should be prefetched in between traversals. * * @see #isItemPrefetchEnabled() */ public final void setItemPrefetchEnabled(boolean enabled) { if (enabled != mItemPrefetchEnabled) { mItemPrefetchEnabled = enabled; mPrefetchMaxCountObserved = 0; if (mRecyclerView != null) { mRecyclerView.mRecycler.updateViewCacheSize(); } } } /** * Sets whether the LayoutManager should be queried for views outside of * its viewport while the UI thread is idle between frames. * * @see #setItemPrefetchEnabled(boolean) * * @return true if item prefetch is enabled, false otherwise */ public final boolean isItemPrefetchEnabled() { return mItemPrefetchEnabled; } /** * Gather all positions from the LayoutManager to be prefetched, given specified momentum. * *

If item prefetch is enabled, this method is called in between traversals to gather * which positions the LayoutManager will soon need, given upcoming movement in subsequent * traversals.

* *

The LayoutManager should call {@link LayoutPrefetchRegistry#addPosition(int, int)} for * each item to be prepared, and these positions will have their ViewHolders created and * bound, if there is sufficient time available, in advance of being needed by a * scroll or layout.

* * @param dx X movement component. * @param dy Y movement component. * @param state State of RecyclerView * @param layoutPrefetchRegistry PrefetchRegistry to add prefetch entries into. * * @see #isItemPrefetchEnabled() * @see #collectInitialPrefetchPositions(int, LayoutPrefetchRegistry) */ public void collectAdjacentPrefetchPositions(int dx, int dy, State state, LayoutPrefetchRegistry layoutPrefetchRegistry) {} /** * Gather all positions from the LayoutManager to be prefetched in preperation for its * RecyclerView to come on screen, due to the movement of another, containing RecyclerView. * *

This method is only called when a RecyclerView is nested in another RecyclerView.

* *

If item prefetch is enabled for this LayoutManager, as well in another containing * LayoutManager, this method is called in between draw traversals to gather * which positions this LayoutManager will first need, once it appears on the screen.

* *

For example, if this LayoutManager represents a horizontally scrolling list within a * vertically scrolling LayoutManager, this method would be called when the horizontal list * is about to come onscreen.

* *

The LayoutManager should call {@link LayoutPrefetchRegistry#addPosition(int, int)} for * each item to be prepared, and these positions will have their ViewHolders created and * bound, if there is sufficient time available, in advance of being needed by a * scroll or layout.

* * @param adapterItemCount number of items in the associated adapter. * @param layoutPrefetchRegistry PrefetchRegistry to add prefetch entries into. * * @see #isItemPrefetchEnabled() * @see #collectAdjacentPrefetchPositions(int, int, State, LayoutPrefetchRegistry) */ public void collectInitialPrefetchPositions(int adapterItemCount, LayoutPrefetchRegistry layoutPrefetchRegistry) {} void dispatchAttachedToWindow(RecyclerView view) { mIsAttachedToWindow = true; onAttachedToWindow(view); } void dispatchDetachedFromWindow(RecyclerView view, Recycler recycler) { mIsAttachedToWindow = false; onDetachedFromWindow(view, recycler); } /** * Returns whether LayoutManager is currently attached to a RecyclerView which is attached * to a window. * * @return True if this LayoutManager is controlling a RecyclerView and the RecyclerView * is attached to window. */ public boolean isAttachedToWindow() { return mIsAttachedToWindow; } /** * Causes the Runnable to execute on the next animation time step. * The runnable will be run on the user interface thread. *

* Calling this method when LayoutManager is not attached to a RecyclerView has no effect. * * @param action The Runnable that will be executed. * * @see #removeCallbacks */ public void postOnAnimation(Runnable action) { if (mRecyclerView != null) { mRecyclerView.postOnAnimation(action); } } /** * Removes the specified Runnable from the message queue. *

* Calling this method when LayoutManager is not attached to a RecyclerView has no effect. * * @param action The Runnable to remove from the message handling queue * * @return true if RecyclerView could ask the Handler to remove the Runnable, * false otherwise. When the returned value is true, the Runnable * may or may not have been actually removed from the message queue * (for instance, if the Runnable was not in the queue already.) * * @see #postOnAnimation */ public boolean removeCallbacks(Runnable action) { if (mRecyclerView != null) { return mRecyclerView.removeCallbacks(action); } return false; } /** * Called when this LayoutManager is both attached to a RecyclerView and that RecyclerView * is attached to a window. *

* If the RecyclerView is re-attached with the same LayoutManager and Adapter, it may not * call {@link #onLayoutChildren(Recycler, State)} if nothing has changed and a layout was * not requested on the RecyclerView while it was detached. *

* Subclass implementations should always call through to the superclass implementation. * * @param view The RecyclerView this LayoutManager is bound to * * @see #onDetachedFromWindow(RecyclerView, Recycler) */ @CallSuper public void onAttachedToWindow(RecyclerView view) { } /** * @deprecated * override {@link #onDetachedFromWindow(RecyclerView, Recycler)} */ @Deprecated public void onDetachedFromWindow(RecyclerView view) { } /** * Called when this LayoutManager is detached from its parent RecyclerView or when * its parent RecyclerView is detached from its window. *

* LayoutManager should clear all of its View references as another LayoutManager might be * assigned to the RecyclerView. *

* If the RecyclerView is re-attached with the same LayoutManager and Adapter, it may not * call {@link #onLayoutChildren(Recycler, State)} if nothing has changed and a layout was * not requested on the RecyclerView while it was detached. *

* If your LayoutManager has View references that it cleans in on-detach, it should also * call {@link RecyclerView#requestLayout()} to ensure that it is re-laid out when * RecyclerView is re-attached. *

* Subclass implementations should always call through to the superclass implementation. * * @param view The RecyclerView this LayoutManager is bound to * @param recycler The recycler to use if you prefer to recycle your children instead of * keeping them around. * * @see #onAttachedToWindow(RecyclerView) */ @CallSuper public void onDetachedFromWindow(RecyclerView view, Recycler recycler) { onDetachedFromWindow(view); } /** * Check if the RecyclerView is configured to clip child views to its padding. * * @return true if this RecyclerView clips children to its padding, false otherwise */ public boolean getClipToPadding() { return mRecyclerView != null && mRecyclerView.mClipToPadding; } /** * Lay out all relevant child views from the given adapter. * * The LayoutManager is in charge of the behavior of item animations. By default, * RecyclerView has a non-null {@link #getItemAnimator() ItemAnimator}, and simple * item animations are enabled. This means that add/remove operations on the * adapter will result in animations to add new or appearing items, removed or * disappearing items, and moved items. If a LayoutManager returns false from * {@link #supportsPredictiveItemAnimations()}, which is the default, and runs a * normal layout operation during {@link #onLayoutChildren(Recycler, State)}, the * RecyclerView will have enough information to run those animations in a simple * way. For example, the default ItemAnimator, {@link DefaultItemAnimator}, will * simply fade views in and out, whether they are actually added/removed or whether * they are moved on or off the screen due to other add/remove operations. * *

A LayoutManager wanting a better item animation experience, where items can be * animated onto and off of the screen according to where the items exist when they * are not on screen, then the LayoutManager should return true from * {@link #supportsPredictiveItemAnimations()} and add additional logic to * {@link #onLayoutChildren(Recycler, State)}. Supporting predictive animations * means that {@link #onLayoutChildren(Recycler, State)} will be called twice; * once as a "pre" layout step to determine where items would have been prior to * a real layout, and again to do the "real" layout. In the pre-layout phase, * items will remember their pre-layout positions to allow them to be laid out * appropriately. Also, {@link LayoutParams#isItemRemoved() removed} items will * be returned from the scrap to help determine correct placement of other items. * These removed items should not be added to the child list, but should be used * to help calculate correct positioning of other views, including views that * were not previously onscreen (referred to as APPEARING views), but whose * pre-layout offscreen position can be determined given the extra * information about the pre-layout removed views.

* *

The second layout pass is the real layout in which only non-removed views * will be used. The only additional requirement during this pass is, if * {@link #supportsPredictiveItemAnimations()} returns true, to note which * views exist in the child list prior to layout and which are not there after * layout (referred to as DISAPPEARING views), and to position/layout those views * appropriately, without regard to the actual bounds of the RecyclerView. This allows * the animation system to know the location to which to animate these disappearing * views.

* *

The default LayoutManager implementations for RecyclerView handle all of these * requirements for animations already. Clients of RecyclerView can either use one * of these layout managers directly or look at their implementations of * onLayoutChildren() to see how they account for the APPEARING and * DISAPPEARING views.

* * @param recycler Recycler to use for fetching potentially cached views for a * position * @param state Transient state of RecyclerView */ public void onLayoutChildren(Recycler recycler, State state) { Log.e(TAG, "You must override onLayoutChildren(Recycler recycler, State state) "); } /** * Called after a full layout calculation is finished. The layout calculation may include * multiple {@link #onLayoutChildren(Recycler, State)} calls due to animations or * layout measurement but it will include only one {@link #onLayoutCompleted(State)} call. * This method will be called at the end of {@link View#layout(int, int, int, int)} call. *

* This is a good place for the LayoutManager to do some cleanup like pending scroll * position, saved state etc. * * @param state Transient state of RecyclerView */ public void onLayoutCompleted(State state) { } /** * Create a default LayoutParams object for a child of the RecyclerView. * *

LayoutManagers will often want to use a custom LayoutParams type * to store extra information specific to the layout. Client code should subclass * {@link RecyclerView.LayoutParams} for this purpose.

* *

Important: if you use your own custom LayoutParams type * you must also override * {@link #checkLayoutParams(LayoutParams)}, * {@link #generateLayoutParams(android.view.ViewGroup.LayoutParams)} and * {@link #generateLayoutParams(android.content.Context, android.util.AttributeSet)}.

* * @return A new LayoutParams for a child view */ public abstract LayoutParams generateDefaultLayoutParams(); /** * Determines the validity of the supplied LayoutParams object. * *

This should check to make sure that the object is of the correct type * and all values are within acceptable ranges. The default implementation * returns true for non-null params.

* * @param lp LayoutParams object to check * @return true if this LayoutParams object is valid, false otherwise */ public boolean checkLayoutParams(LayoutParams lp) { return lp != null; } /** * Create a LayoutParams object suitable for this LayoutManager, copying relevant * values from the supplied LayoutParams object if possible. * *

Important: if you use your own custom LayoutParams type * you must also override * {@link #checkLayoutParams(LayoutParams)}, * {@link #generateLayoutParams(android.view.ViewGroup.LayoutParams)} and * {@link #generateLayoutParams(android.content.Context, android.util.AttributeSet)}.

* * @param lp Source LayoutParams object to copy values from * @return a new LayoutParams object */ public LayoutParams generateLayoutParams(ViewGroup.LayoutParams lp) { if (lp instanceof LayoutParams) { return new LayoutParams((LayoutParams) lp); } else if (lp instanceof MarginLayoutParams) { return new LayoutParams((MarginLayoutParams) lp); } else { return new LayoutParams(lp); } } /** * Create a LayoutParams object suitable for this LayoutManager from * an inflated layout resource. * *

Important: if you use your own custom LayoutParams type * you must also override * {@link #checkLayoutParams(LayoutParams)}, * {@link #generateLayoutParams(android.view.ViewGroup.LayoutParams)} and * {@link #generateLayoutParams(android.content.Context, android.util.AttributeSet)}.

* * @param c Context for obtaining styled attributes * @param attrs AttributeSet describing the supplied arguments * @return a new LayoutParams object */ public LayoutParams generateLayoutParams(Context c, AttributeSet attrs) { return new LayoutParams(c, attrs); } /** * Scroll horizontally by dx pixels in screen coordinates and return the distance traveled. * The default implementation does nothing and returns 0. * * @param dx distance to scroll by in pixels. X increases as scroll position * approaches the right. * @param recycler Recycler to use for fetching potentially cached views for a * position * @param state Transient state of RecyclerView * @return The actual distance scrolled. The return value will be negative if dx was * negative and scrolling proceeeded in that direction. * Math.abs(result) may be less than dx if a boundary was reached. */ public int scrollHorizontallyBy(int dx, Recycler recycler, State state) { return 0; } /** * Scroll vertically by dy pixels in screen coordinates and return the distance traveled. * The default implementation does nothing and returns 0. * * @param dy distance to scroll in pixels. Y increases as scroll position * approaches the bottom. * @param recycler Recycler to use for fetching potentially cached views for a * position * @param state Transient state of RecyclerView * @return The actual distance scrolled. The return value will be negative if dy was * negative and scrolling proceeeded in that direction. * Math.abs(result) may be less than dy if a boundary was reached. */ public int scrollVerticallyBy(int dy, Recycler recycler, State state) { return 0; } /** * Query if horizontal scrolling is currently supported. The default implementation * returns false. * * @return True if this LayoutManager can scroll the current contents horizontally */ public boolean canScrollHorizontally() { return false; } /** * Query if vertical scrolling is currently supported. The default implementation * returns false. * * @return True if this LayoutManager can scroll the current contents vertically */ public boolean canScrollVertically() { return false; } /** * Scroll to the specified adapter position. * * Actual position of the item on the screen depends on the LayoutManager implementation. * @param position Scroll to this adapter position. */ public void scrollToPosition(int position) { if (DEBUG) { Log.e(TAG, "You MUST implement scrollToPosition. It will soon become abstract"); } } /** *

Smooth scroll to the specified adapter position.

*

To support smooth scrolling, override this method, create your {@link SmoothScroller} * instance and call {@link #startSmoothScroll(SmoothScroller)}. *

* @param recyclerView The RecyclerView to which this layout manager is attached * @param state Current State of RecyclerView * @param position Scroll to this adapter position. */ public void smoothScrollToPosition(RecyclerView recyclerView, State state, int position) { Log.e(TAG, "You must override smoothScrollToPosition to support smooth scrolling"); } /** *

Starts a smooth scroll using the provided SmoothScroller.

*

Calling this method will cancel any previous smooth scroll request.

* @param smoothScroller Instance which defines how smooth scroll should be animated */ public void startSmoothScroll(SmoothScroller smoothScroller) { if (mSmoothScroller != null && smoothScroller != mSmoothScroller && mSmoothScroller.isRunning()) { mSmoothScroller.stop(); } mSmoothScroller = smoothScroller; mSmoothScroller.start(mRecyclerView, this); } /** * @return true if RecycylerView is currently in the state of smooth scrolling. */ public boolean isSmoothScrolling() { return mSmoothScroller != null && mSmoothScroller.isRunning(); } /** * Returns the resolved layout direction for this RecyclerView. * * @return {@link android.view.View#LAYOUT_DIRECTION_RTL} if the layout * direction is RTL or returns * {@link android.view.View#LAYOUT_DIRECTION_LTR} if the layout direction * is not RTL. */ public int getLayoutDirection() { return mRecyclerView.getLayoutDirection(); } /** * Ends all animations on the view created by the {@link ItemAnimator}. * * @param view The View for which the animations should be ended. * @see RecyclerView.ItemAnimator#endAnimations() */ public void endAnimation(View view) { if (mRecyclerView.mItemAnimator != null) { mRecyclerView.mItemAnimator.endAnimation(getChildViewHolderInt(view)); } } /** * To be called only during {@link #onLayoutChildren(Recycler, State)} to add a view * to the layout that is known to be going away, either because it has been * {@link Adapter#notifyItemRemoved(int) removed} or because it is actually not in the * visible portion of the container but is being laid out in order to inform RecyclerView * in how to animate the item out of view. *

* Views added via this method are going to be invisible to LayoutManager after the * dispatchLayout pass is complete. They cannot be retrieved via {@link #getChildAt(int)} * or won't be included in {@link #getChildCount()} method. * * @param child View to add and then remove with animation. */ public void addDisappearingView(View child) { addDisappearingView(child, -1); } /** * To be called only during {@link #onLayoutChildren(Recycler, State)} to add a view * to the layout that is known to be going away, either because it has been * {@link Adapter#notifyItemRemoved(int) removed} or because it is actually not in the * visible portion of the container but is being laid out in order to inform RecyclerView * in how to animate the item out of view. *

* Views added via this method are going to be invisible to LayoutManager after the * dispatchLayout pass is complete. They cannot be retrieved via {@link #getChildAt(int)} * or won't be included in {@link #getChildCount()} method. * * @param child View to add and then remove with animation. * @param index Index of the view. */ public void addDisappearingView(View child, int index) { addViewInt(child, index, true); } /** * Add a view to the currently attached RecyclerView if needed. LayoutManagers should * use this method to add views obtained from a {@link Recycler} using * {@link Recycler#getViewForPosition(int)}. * * @param child View to add */ public void addView(View child) { addView(child, -1); } /** * Add a view to the currently attached RecyclerView if needed. LayoutManagers should * use this method to add views obtained from a {@link Recycler} using * {@link Recycler#getViewForPosition(int)}. * * @param child View to add * @param index Index to add child at */ public void addView(View child, int index) { addViewInt(child, index, false); } private void addViewInt(View child, int index, boolean disappearing) { final ViewHolder holder = getChildViewHolderInt(child); if (disappearing || holder.isRemoved()) { // these views will be hidden at the end of the layout pass. mRecyclerView.mViewInfoStore.addToDisappearedInLayout(holder); } else { // This may look like unnecessary but may happen if layout manager supports // predictive layouts and adapter removed then re-added the same item. // In this case, added version will be visible in the post layout (because add is // deferred) but RV will still bind it to the same View. // So if a View re-appears in post layout pass, remove it from disappearing list. mRecyclerView.mViewInfoStore.removeFromDisappearedInLayout(holder); } final LayoutParams lp = (LayoutParams) child.getLayoutParams(); if (holder.wasReturnedFromScrap() || holder.isScrap()) { if (holder.isScrap()) { holder.unScrap(); } else { holder.clearReturnedFromScrapFlag(); } mChildHelper.attachViewToParent(child, index, child.getLayoutParams(), false); if (DISPATCH_TEMP_DETACH) { child.dispatchFinishTemporaryDetach(); } } else if (child.getParent() == mRecyclerView) { // it was not a scrap but a valid child // ensure in correct position int currentIndex = mChildHelper.indexOfChild(child); if (index == -1) { index = mChildHelper.getChildCount(); } if (currentIndex == -1) { throw new IllegalStateException("Added View has RecyclerView as parent but" + " view is not a real child. Unfiltered index:" + mRecyclerView.indexOfChild(child)); } if (currentIndex != index) { mRecyclerView.mLayout.moveView(currentIndex, index); } } else { mChildHelper.addView(child, index, false); lp.mInsetsDirty = true; if (mSmoothScroller != null && mSmoothScroller.isRunning()) { mSmoothScroller.onChildAttachedToWindow(child); } } if (lp.mPendingInvalidate) { if (DEBUG) { Log.d(TAG, "consuming pending invalidate on child " + lp.mViewHolder); } holder.itemView.invalidate(); lp.mPendingInvalidate = false; } } /** * Remove a view from the currently attached RecyclerView if needed. LayoutManagers should * use this method to completely remove a child view that is no longer needed. * LayoutManagers should strongly consider recycling removed views using * {@link Recycler#recycleView(android.view.View)}. * * @param child View to remove */ public void removeView(View child) { mChildHelper.removeView(child); } /** * Remove a view from the currently attached RecyclerView if needed. LayoutManagers should * use this method to completely remove a child view that is no longer needed. * LayoutManagers should strongly consider recycling removed views using * {@link Recycler#recycleView(android.view.View)}. * * @param index Index of the child view to remove */ public void removeViewAt(int index) { final View child = getChildAt(index); if (child != null) { mChildHelper.removeViewAt(index); } } /** * Remove all views from the currently attached RecyclerView. This will not recycle * any of the affected views; the LayoutManager is responsible for doing so if desired. */ public void removeAllViews() { // Only remove non-animating views final int childCount = getChildCount(); for (int i = childCount - 1; i >= 0; i--) { mChildHelper.removeViewAt(i); } } /** * Returns offset of the RecyclerView's text baseline from the its top boundary. * * @return The offset of the RecyclerView's text baseline from the its top boundary; -1 if * there is no baseline. */ public int getBaseline() { return -1; } /** * Returns the adapter position of the item represented by the given View. This does not * contain any adapter changes that might have happened after the last layout. * * @param view The view to query * @return The adapter position of the item which is rendered by this View. */ public int getPosition(View view) { return ((RecyclerView.LayoutParams) view.getLayoutParams()).getViewLayoutPosition(); } /** * Returns the View type defined by the adapter. * * @param view The view to query * @return The type of the view assigned by the adapter. */ public int getItemViewType(View view) { return getChildViewHolderInt(view).getItemViewType(); } /** * Traverses the ancestors of the given view and returns the item view that contains it * and also a direct child of the LayoutManager. *

* Note that this method may return null if the view is a child of the RecyclerView but * not a child of the LayoutManager (e.g. running a disappear animation). * * @param view The view that is a descendant of the LayoutManager. * * @return The direct child of the LayoutManager which contains the given view or null if * the provided view is not a descendant of this LayoutManager. * * @see RecyclerView#getChildViewHolder(View) * @see RecyclerView#findContainingViewHolder(View) */ @Nullable public View findContainingItemView(View view) { if (mRecyclerView == null) { return null; } View found = mRecyclerView.findContainingItemView(view); if (found == null) { return null; } if (mChildHelper.isHidden(found)) { return null; } return found; } /** * Finds the view which represents the given adapter position. *

* This method traverses each child since it has no information about child order. * Override this method to improve performance if your LayoutManager keeps data about * child views. *

* If a view is ignored via {@link #ignoreView(View)}, it is also ignored by this method. * * @param position Position of the item in adapter * @return The child view that represents the given position or null if the position is not * laid out */ public View findViewByPosition(int position) { final int childCount = getChildCount(); for (int i = 0; i < childCount; i++) { View child = getChildAt(i); ViewHolder vh = getChildViewHolderInt(child); if (vh == null) { continue; } if (vh.getLayoutPosition() == position && !vh.shouldIgnore() && (mRecyclerView.mState.isPreLayout() || !vh.isRemoved())) { return child; } } return null; } /** * Temporarily detach a child view. * *

LayoutManagers may want to perform a lightweight detach operation to rearrange * views currently attached to the RecyclerView. Generally LayoutManager implementations * will want to use {@link #detachAndScrapView(android.view.View, RecyclerView.Recycler)} * so that the detached view may be rebound and reused.

* *

If a LayoutManager uses this method to detach a view, it must * {@link #attachView(android.view.View, int, RecyclerView.LayoutParams) reattach} * or {@link #removeDetachedView(android.view.View) fully remove} the detached view * before the LayoutManager entry point method called by RecyclerView returns.

* * @param child Child to detach */ public void detachView(View child) { final int ind = mChildHelper.indexOfChild(child); if (ind >= 0) { detachViewInternal(ind, child); } } /** * Temporarily detach a child view. * *

LayoutManagers may want to perform a lightweight detach operation to rearrange * views currently attached to the RecyclerView. Generally LayoutManager implementations * will want to use {@link #detachAndScrapView(android.view.View, RecyclerView.Recycler)} * so that the detached view may be rebound and reused.

* *

If a LayoutManager uses this method to detach a view, it must * {@link #attachView(android.view.View, int, RecyclerView.LayoutParams) reattach} * or {@link #removeDetachedView(android.view.View) fully remove} the detached view * before the LayoutManager entry point method called by RecyclerView returns.

* * @param index Index of the child to detach */ public void detachViewAt(int index) { detachViewInternal(index, getChildAt(index)); } private void detachViewInternal(int index, View view) { if (DISPATCH_TEMP_DETACH) { view.dispatchStartTemporaryDetach(); } mChildHelper.detachViewFromParent(index); } /** * Reattach a previously {@link #detachView(android.view.View) detached} view. * This method should not be used to reattach views that were previously * {@link #detachAndScrapView(android.view.View, RecyclerView.Recycler)} scrapped}. * * @param child Child to reattach * @param index Intended child index for child * @param lp LayoutParams for child */ public void attachView(View child, int index, LayoutParams lp) { ViewHolder vh = getChildViewHolderInt(child); if (vh.isRemoved()) { mRecyclerView.mViewInfoStore.addToDisappearedInLayout(vh); } else { mRecyclerView.mViewInfoStore.removeFromDisappearedInLayout(vh); } mChildHelper.attachViewToParent(child, index, lp, vh.isRemoved()); if (DISPATCH_TEMP_DETACH) { child.dispatchFinishTemporaryDetach(); } } /** * Reattach a previously {@link #detachView(android.view.View) detached} view. * This method should not be used to reattach views that were previously * {@link #detachAndScrapView(android.view.View, RecyclerView.Recycler)} scrapped}. * * @param child Child to reattach * @param index Intended child index for child */ public void attachView(View child, int index) { attachView(child, index, (LayoutParams) child.getLayoutParams()); } /** * Reattach a previously {@link #detachView(android.view.View) detached} view. * This method should not be used to reattach views that were previously * {@link #detachAndScrapView(android.view.View, RecyclerView.Recycler)} scrapped}. * * @param child Child to reattach */ public void attachView(View child) { attachView(child, -1); } /** * Finish removing a view that was previously temporarily * {@link #detachView(android.view.View) detached}. * * @param child Detached child to remove */ public void removeDetachedView(View child) { mRecyclerView.removeDetachedView(child, false); } /** * Moves a View from one position to another. * * @param fromIndex The View's initial index * @param toIndex The View's target index */ public void moveView(int fromIndex, int toIndex) { View view = getChildAt(fromIndex); if (view == null) { throw new IllegalArgumentException("Cannot move a child from non-existing index:" + fromIndex); } detachViewAt(fromIndex); attachView(view, toIndex); } /** * Detach a child view and add it to a {@link Recycler Recycler's} scrap heap. * *

Scrapping a view allows it to be rebound and reused to show updated or * different data.

* * @param child Child to detach and scrap * @param recycler Recycler to deposit the new scrap view into */ public void detachAndScrapView(View child, Recycler recycler) { int index = mChildHelper.indexOfChild(child); scrapOrRecycleView(recycler, index, child); } /** * Detach a child view and add it to a {@link Recycler Recycler's} scrap heap. * *

Scrapping a view allows it to be rebound and reused to show updated or * different data.

* * @param index Index of child to detach and scrap * @param recycler Recycler to deposit the new scrap view into */ public void detachAndScrapViewAt(int index, Recycler recycler) { final View child = getChildAt(index); scrapOrRecycleView(recycler, index, child); } /** * Remove a child view and recycle it using the given Recycler. * * @param child Child to remove and recycle * @param recycler Recycler to use to recycle child */ public void removeAndRecycleView(View child, Recycler recycler) { removeView(child); recycler.recycleView(child); } /** * Remove a child view and recycle it using the given Recycler. * * @param index Index of child to remove and recycle * @param recycler Recycler to use to recycle child */ public void removeAndRecycleViewAt(int index, Recycler recycler) { final View view = getChildAt(index); removeViewAt(index); recycler.recycleView(view); } /** * Return the current number of child views attached to the parent RecyclerView. * This does not include child views that were temporarily detached and/or scrapped. * * @return Number of attached children */ public int getChildCount() { return mChildHelper != null ? mChildHelper.getChildCount() : 0; } /** * Return the child view at the given index * @param index Index of child to return * @return Child view at index */ public View getChildAt(int index) { return mChildHelper != null ? mChildHelper.getChildAt(index) : null; } /** * Return the width measurement spec mode of the RecyclerView. *

* This value is set only if the LayoutManager opts into the auto measure api via * {@link #setAutoMeasureEnabled(boolean)}. *

* When RecyclerView is running a layout, this value is always set to * {@link View.MeasureSpec#EXACTLY} even if it was measured with a different spec mode. * * @return Width measure spec mode. * * @see View.MeasureSpec#getMode(int) * @see View#onMeasure(int, int) */ public int getWidthMode() { return mWidthMode; } /** * Return the height measurement spec mode of the RecyclerView. *

* This value is set only if the LayoutManager opts into the auto measure api via * {@link #setAutoMeasureEnabled(boolean)}. *

* When RecyclerView is running a layout, this value is always set to * {@link View.MeasureSpec#EXACTLY} even if it was measured with a different spec mode. * * @return Height measure spec mode. * * @see View.MeasureSpec#getMode(int) * @see View#onMeasure(int, int) */ public int getHeightMode() { return mHeightMode; } /** * Return the width of the parent RecyclerView * * @return Width in pixels */ public int getWidth() { return mWidth; } /** * Return the height of the parent RecyclerView * * @return Height in pixels */ public int getHeight() { return mHeight; } /** * Return the left padding of the parent RecyclerView * * @return Padding in pixels */ public int getPaddingLeft() { return mRecyclerView != null ? mRecyclerView.getPaddingLeft() : 0; } /** * Return the top padding of the parent RecyclerView * * @return Padding in pixels */ public int getPaddingTop() { return mRecyclerView != null ? mRecyclerView.getPaddingTop() : 0; } /** * Return the right padding of the parent RecyclerView * * @return Padding in pixels */ public int getPaddingRight() { return mRecyclerView != null ? mRecyclerView.getPaddingRight() : 0; } /** * Return the bottom padding of the parent RecyclerView * * @return Padding in pixels */ public int getPaddingBottom() { return mRecyclerView != null ? mRecyclerView.getPaddingBottom() : 0; } /** * Return the start padding of the parent RecyclerView * * @return Padding in pixels */ public int getPaddingStart() { return mRecyclerView != null ? mRecyclerView.getPaddingStart() : 0; } /** * Return the end padding of the parent RecyclerView * * @return Padding in pixels */ public int getPaddingEnd() { return mRecyclerView != null ? mRecyclerView.getPaddingEnd() : 0; } /** * Returns true if the RecyclerView this LayoutManager is bound to has focus. * * @return True if the RecyclerView has focus, false otherwise. * @see View#isFocused() */ public boolean isFocused() { return mRecyclerView != null && mRecyclerView.isFocused(); } /** * Returns true if the RecyclerView this LayoutManager is bound to has or contains focus. * * @return true if the RecyclerView has or contains focus * @see View#hasFocus() */ public boolean hasFocus() { return mRecyclerView != null && mRecyclerView.hasFocus(); } /** * Returns the item View which has or contains focus. * * @return A direct child of RecyclerView which has focus or contains the focused child. */ public View getFocusedChild() { if (mRecyclerView == null) { return null; } final View focused = mRecyclerView.getFocusedChild(); if (focused == null || mChildHelper.isHidden(focused)) { return null; } return focused; } /** * Returns the number of items in the adapter bound to the parent RecyclerView. *

* Note that this number is not necessarily equal to * {@link State#getItemCount() State#getItemCount()}. In methods where {@link State} is * available, you should use {@link State#getItemCount() State#getItemCount()} instead. * For more details, check the documentation for * {@link State#getItemCount() State#getItemCount()}. * * @return The number of items in the bound adapter * @see State#getItemCount() */ public int getItemCount() { final Adapter a = mRecyclerView != null ? mRecyclerView.getAdapter() : null; return a != null ? a.getItemCount() : 0; } /** * Offset all child views attached to the parent RecyclerView by dx pixels along * the horizontal axis. * * @param dx Pixels to offset by */ public void offsetChildrenHorizontal(int dx) { if (mRecyclerView != null) { mRecyclerView.offsetChildrenHorizontal(dx); } } /** * Offset all child views attached to the parent RecyclerView by dy pixels along * the vertical axis. * * @param dy Pixels to offset by */ public void offsetChildrenVertical(int dy) { if (mRecyclerView != null) { mRecyclerView.offsetChildrenVertical(dy); } } /** * Flags a view so that it will not be scrapped or recycled. *

* Scope of ignoring a child is strictly restricted to position tracking, scrapping and * recyling. Methods like {@link #removeAndRecycleAllViews(Recycler)} will ignore the child * whereas {@link #removeAllViews()} or {@link #offsetChildrenHorizontal(int)} will not * ignore the child. *

* Before this child can be recycled again, you have to call * {@link #stopIgnoringView(View)}. *

* You can call this method only if your LayoutManger is in onLayout or onScroll callback. * * @param view View to ignore. * @see #stopIgnoringView(View) */ public void ignoreView(View view) { if (view.getParent() != mRecyclerView || mRecyclerView.indexOfChild(view) == -1) { // checking this because calling this method on a recycled or detached view may // cause loss of state. throw new IllegalArgumentException("View should be fully attached to be ignored"); } final ViewHolder vh = getChildViewHolderInt(view); vh.addFlags(ViewHolder.FLAG_IGNORE); mRecyclerView.mViewInfoStore.removeViewHolder(vh); } /** * View can be scrapped and recycled again. *

* Note that calling this method removes all information in the view holder. *

* You can call this method only if your LayoutManger is in onLayout or onScroll callback. * * @param view View to ignore. */ public void stopIgnoringView(View view) { final ViewHolder vh = getChildViewHolderInt(view); vh.stopIgnoring(); vh.resetInternal(); vh.addFlags(ViewHolder.FLAG_INVALID); } /** * Temporarily detach and scrap all currently attached child views. Views will be scrapped * into the given Recycler. The Recycler may prefer to reuse scrap views before * other views that were previously recycled. * * @param recycler Recycler to scrap views into */ public void detachAndScrapAttachedViews(Recycler recycler) { final int childCount = getChildCount(); for (int i = childCount - 1; i >= 0; i--) { final View v = getChildAt(i); scrapOrRecycleView(recycler, i, v); } } private void scrapOrRecycleView(Recycler recycler, int index, View view) { final ViewHolder viewHolder = getChildViewHolderInt(view); if (viewHolder.shouldIgnore()) { if (DEBUG) { Log.d(TAG, "ignoring view " + viewHolder); } return; } if (viewHolder.isInvalid() && !viewHolder.isRemoved() && !mRecyclerView.mAdapter.hasStableIds()) { removeViewAt(index); recycler.recycleViewHolderInternal(viewHolder); } else { detachViewAt(index); recycler.scrapView(view); mRecyclerView.mViewInfoStore.onViewDetached(viewHolder); } } /** * Recycles the scrapped views. *

* When a view is detached and removed, it does not trigger a ViewGroup invalidate. This is * the expected behavior if scrapped views are used for animations. Otherwise, we need to * call remove and invalidate RecyclerView to ensure UI update. * * @param recycler Recycler */ void removeAndRecycleScrapInt(Recycler recycler) { final int scrapCount = recycler.getScrapCount(); // Loop backward, recycler might be changed by removeDetachedView() for (int i = scrapCount - 1; i >= 0; i--) { final View scrap = recycler.getScrapViewAt(i); final ViewHolder vh = getChildViewHolderInt(scrap); if (vh.shouldIgnore()) { continue; } // If the scrap view is animating, we need to cancel them first. If we cancel it // here, ItemAnimator callback may recycle it which will cause double recycling. // To avoid this, we mark it as not recycleable before calling the item animator. // Since removeDetachedView calls a user API, a common mistake (ending animations on // the view) may recycle it too, so we guard it before we call user APIs. vh.setIsRecyclable(false); if (vh.isTmpDetached()) { mRecyclerView.removeDetachedView(scrap, false); } if (mRecyclerView.mItemAnimator != null) { mRecyclerView.mItemAnimator.endAnimation(vh); } vh.setIsRecyclable(true); recycler.quickRecycleScrapView(scrap); } recycler.clearScrap(); if (scrapCount > 0) { mRecyclerView.invalidate(); } } /** * Measure a child view using standard measurement policy, taking the padding * of the parent RecyclerView and any added item decorations into account. * *

If the RecyclerView can be scrolled in either dimension the caller may * pass 0 as the widthUsed or heightUsed parameters as they will be irrelevant.

* * @param child Child view to measure * @param widthUsed Width in pixels currently consumed by other views, if relevant * @param heightUsed Height in pixels currently consumed by other views, if relevant */ public void measureChild(View child, int widthUsed, int heightUsed) { final LayoutParams lp = (LayoutParams) child.getLayoutParams(); final Rect insets = mRecyclerView.getItemDecorInsetsForChild(child); widthUsed += insets.left + insets.right; heightUsed += insets.top + insets.bottom; final int widthSpec = getChildMeasureSpec(getWidth(), getWidthMode(), getPaddingLeft() + getPaddingRight() + widthUsed, lp.width, canScrollHorizontally()); final int heightSpec = getChildMeasureSpec(getHeight(), getHeightMode(), getPaddingTop() + getPaddingBottom() + heightUsed, lp.height, canScrollVertically()); if (shouldMeasureChild(child, widthSpec, heightSpec, lp)) { child.measure(widthSpec, heightSpec); } } /** * RecyclerView internally does its own View measurement caching which should help with * WRAP_CONTENT. *

* Use this method if the View is already measured once in this layout pass. */ boolean shouldReMeasureChild(View child, int widthSpec, int heightSpec, LayoutParams lp) { return !mMeasurementCacheEnabled || !isMeasurementUpToDate(child.getMeasuredWidth(), widthSpec, lp.width) || !isMeasurementUpToDate(child.getMeasuredHeight(), heightSpec, lp.height); } // we may consider making this public /** * RecyclerView internally does its own View measurement caching which should help with * WRAP_CONTENT. *

* Use this method if the View is not yet measured and you need to decide whether to * measure this View or not. */ boolean shouldMeasureChild(View child, int widthSpec, int heightSpec, LayoutParams lp) { return child.isLayoutRequested() || !mMeasurementCacheEnabled || !isMeasurementUpToDate(child.getWidth(), widthSpec, lp.width) || !isMeasurementUpToDate(child.getHeight(), heightSpec, lp.height); } /** * In addition to the View Framework's measurement cache, RecyclerView uses its own * additional measurement cache for its children to avoid re-measuring them when not * necessary. It is on by default but it can be turned off via * {@link #setMeasurementCacheEnabled(boolean)}. * * @return True if measurement cache is enabled, false otherwise. * * @see #setMeasurementCacheEnabled(boolean) */ public boolean isMeasurementCacheEnabled() { return mMeasurementCacheEnabled; } /** * Sets whether RecyclerView should use its own measurement cache for the children. This is * a more aggressive cache than the framework uses. * * @param measurementCacheEnabled True to enable the measurement cache, false otherwise. * * @see #isMeasurementCacheEnabled() */ public void setMeasurementCacheEnabled(boolean measurementCacheEnabled) { mMeasurementCacheEnabled = measurementCacheEnabled; } private static boolean isMeasurementUpToDate(int childSize, int spec, int dimension) { final int specMode = MeasureSpec.getMode(spec); final int specSize = MeasureSpec.getSize(spec); if (dimension > 0 && childSize != dimension) { return false; } switch (specMode) { case MeasureSpec.UNSPECIFIED: return true; case MeasureSpec.AT_MOST: return specSize >= childSize; case MeasureSpec.EXACTLY: return specSize == childSize; } return false; } /** * Measure a child view using standard measurement policy, taking the padding * of the parent RecyclerView, any added item decorations and the child margins * into account. * *

If the RecyclerView can be scrolled in either dimension the caller may * pass 0 as the widthUsed or heightUsed parameters as they will be irrelevant.

* * @param child Child view to measure * @param widthUsed Width in pixels currently consumed by other views, if relevant * @param heightUsed Height in pixels currently consumed by other views, if relevant */ public void measureChildWithMargins(View child, int widthUsed, int heightUsed) { final LayoutParams lp = (LayoutParams) child.getLayoutParams(); final Rect insets = mRecyclerView.getItemDecorInsetsForChild(child); widthUsed += insets.left + insets.right; heightUsed += insets.top + insets.bottom; final int widthSpec = getChildMeasureSpec(getWidth(), getWidthMode(), getPaddingLeft() + getPaddingRight() + lp.leftMargin + lp.rightMargin + widthUsed, lp.width, canScrollHorizontally()); final int heightSpec = getChildMeasureSpec(getHeight(), getHeightMode(), getPaddingTop() + getPaddingBottom() + lp.topMargin + lp.bottomMargin + heightUsed, lp.height, canScrollVertically()); if (shouldMeasureChild(child, widthSpec, heightSpec, lp)) { child.measure(widthSpec, heightSpec); } } /** * Calculate a MeasureSpec value for measuring a child view in one dimension. * * @param parentSize Size of the parent view where the child will be placed * @param padding Total space currently consumed by other elements of the parent * @param childDimension Desired size of the child view, or MATCH_PARENT/WRAP_CONTENT. * Generally obtained from the child view's LayoutParams * @param canScroll true if the parent RecyclerView can scroll in this dimension * * @return a MeasureSpec value for the child view * @deprecated use {@link #getChildMeasureSpec(int, int, int, int, boolean)} */ @Deprecated public static int getChildMeasureSpec(int parentSize, int padding, int childDimension, boolean canScroll) { int size = Math.max(0, parentSize - padding); int resultSize = 0; int resultMode = 0; if (canScroll) { if (childDimension >= 0) { resultSize = childDimension; resultMode = MeasureSpec.EXACTLY; } else { // MATCH_PARENT can't be applied since we can scroll in this dimension, wrap // instead using UNSPECIFIED. resultSize = 0; resultMode = MeasureSpec.UNSPECIFIED; } } else { if (childDimension >= 0) { resultSize = childDimension; resultMode = MeasureSpec.EXACTLY; } else if (childDimension == LayoutParams.MATCH_PARENT) { resultSize = size; // TODO this should be my spec. resultMode = MeasureSpec.EXACTLY; } else if (childDimension == LayoutParams.WRAP_CONTENT) { resultSize = size; resultMode = MeasureSpec.AT_MOST; } } return MeasureSpec.makeMeasureSpec(resultSize, resultMode); } /** * Calculate a MeasureSpec value for measuring a child view in one dimension. * * @param parentSize Size of the parent view where the child will be placed * @param parentMode The measurement spec mode of the parent * @param padding Total space currently consumed by other elements of parent * @param childDimension Desired size of the child view, or MATCH_PARENT/WRAP_CONTENT. * Generally obtained from the child view's LayoutParams * @param canScroll true if the parent RecyclerView can scroll in this dimension * * @return a MeasureSpec value for the child view */ public static int getChildMeasureSpec(int parentSize, int parentMode, int padding, int childDimension, boolean canScroll) { int size = Math.max(0, parentSize - padding); int resultSize = 0; int resultMode = 0; if (canScroll) { if (childDimension >= 0) { resultSize = childDimension; resultMode = MeasureSpec.EXACTLY; } else if (childDimension == LayoutParams.MATCH_PARENT) { switch (parentMode) { case MeasureSpec.AT_MOST: case MeasureSpec.EXACTLY: resultSize = size; resultMode = parentMode; break; case MeasureSpec.UNSPECIFIED: resultSize = 0; resultMode = MeasureSpec.UNSPECIFIED; break; } } else if (childDimension == LayoutParams.WRAP_CONTENT) { resultSize = 0; resultMode = MeasureSpec.UNSPECIFIED; } } else { if (childDimension >= 0) { resultSize = childDimension; resultMode = MeasureSpec.EXACTLY; } else if (childDimension == LayoutParams.MATCH_PARENT) { resultSize = size; resultMode = parentMode; } else if (childDimension == LayoutParams.WRAP_CONTENT) { resultSize = size; if (parentMode == MeasureSpec.AT_MOST || parentMode == MeasureSpec.EXACTLY) { resultMode = MeasureSpec.AT_MOST; } else { resultMode = MeasureSpec.UNSPECIFIED; } } } //noinspection WrongConstant return MeasureSpec.makeMeasureSpec(resultSize, resultMode); } /** * Returns the measured width of the given child, plus the additional size of * any insets applied by {@link ItemDecoration ItemDecorations}. * * @param child Child view to query * @return child's measured width plus ItemDecoration insets * * @see View#getMeasuredWidth() */ public int getDecoratedMeasuredWidth(View child) { final Rect insets = ((LayoutParams) child.getLayoutParams()).mDecorInsets; return child.getMeasuredWidth() + insets.left + insets.right; } /** * Returns the measured height of the given child, plus the additional size of * any insets applied by {@link ItemDecoration ItemDecorations}. * * @param child Child view to query * @return child's measured height plus ItemDecoration insets * * @see View#getMeasuredHeight() */ public int getDecoratedMeasuredHeight(View child) { final Rect insets = ((LayoutParams) child.getLayoutParams()).mDecorInsets; return child.getMeasuredHeight() + insets.top + insets.bottom; } /** * Lay out the given child view within the RecyclerView using coordinates that * include any current {@link ItemDecoration ItemDecorations}. * *

LayoutManagers should prefer working in sizes and coordinates that include * item decoration insets whenever possible. This allows the LayoutManager to effectively * ignore decoration insets within measurement and layout code. See the following * methods:

*
    *
  • {@link #layoutDecoratedWithMargins(View, int, int, int, int)}
  • *
  • {@link #getDecoratedBoundsWithMargins(View, Rect)}
  • *
  • {@link #measureChild(View, int, int)}
  • *
  • {@link #measureChildWithMargins(View, int, int)}
  • *
  • {@link #getDecoratedLeft(View)}
  • *
  • {@link #getDecoratedTop(View)}
  • *
  • {@link #getDecoratedRight(View)}
  • *
  • {@link #getDecoratedBottom(View)}
  • *
  • {@link #getDecoratedMeasuredWidth(View)}
  • *
  • {@link #getDecoratedMeasuredHeight(View)}
  • *
* * @param child Child to lay out * @param left Left edge, with item decoration insets included * @param top Top edge, with item decoration insets included * @param right Right edge, with item decoration insets included * @param bottom Bottom edge, with item decoration insets included * * @see View#layout(int, int, int, int) * @see #layoutDecoratedWithMargins(View, int, int, int, int) */ public void layoutDecorated(View child, int left, int top, int right, int bottom) { final Rect insets = ((LayoutParams) child.getLayoutParams()).mDecorInsets; child.layout(left + insets.left, top + insets.top, right - insets.right, bottom - insets.bottom); } /** * Lay out the given child view within the RecyclerView using coordinates that * include any current {@link ItemDecoration ItemDecorations} and margins. * *

LayoutManagers should prefer working in sizes and coordinates that include * item decoration insets whenever possible. This allows the LayoutManager to effectively * ignore decoration insets within measurement and layout code. See the following * methods:

*
    *
  • {@link #layoutDecorated(View, int, int, int, int)}
  • *
  • {@link #measureChild(View, int, int)}
  • *
  • {@link #measureChildWithMargins(View, int, int)}
  • *
  • {@link #getDecoratedLeft(View)}
  • *
  • {@link #getDecoratedTop(View)}
  • *
  • {@link #getDecoratedRight(View)}
  • *
  • {@link #getDecoratedBottom(View)}
  • *
  • {@link #getDecoratedMeasuredWidth(View)}
  • *
  • {@link #getDecoratedMeasuredHeight(View)}
  • *
* * @param child Child to lay out * @param left Left edge, with item decoration insets and left margin included * @param top Top edge, with item decoration insets and top margin included * @param right Right edge, with item decoration insets and right margin included * @param bottom Bottom edge, with item decoration insets and bottom margin included * * @see View#layout(int, int, int, int) * @see #layoutDecorated(View, int, int, int, int) */ public void layoutDecoratedWithMargins(View child, int left, int top, int right, int bottom) { final LayoutParams lp = (LayoutParams) child.getLayoutParams(); final Rect insets = lp.mDecorInsets; child.layout(left + insets.left + lp.leftMargin, top + insets.top + lp.topMargin, right - insets.right - lp.rightMargin, bottom - insets.bottom - lp.bottomMargin); } /** * Calculates the bounding box of the View while taking into account its matrix changes * (translation, scale etc) with respect to the RecyclerView. *

* If {@code includeDecorInsets} is {@code true}, they are applied first before applying * the View's matrix so that the decor offsets also go through the same transformation. * * @param child The ItemView whose bounding box should be calculated. * @param includeDecorInsets True if the decor insets should be included in the bounding box * @param out The rectangle into which the output will be written. */ public void getTransformedBoundingBox(View child, boolean includeDecorInsets, Rect out) { if (includeDecorInsets) { Rect insets = ((LayoutParams) child.getLayoutParams()).mDecorInsets; out.set(-insets.left, -insets.top, child.getWidth() + insets.right, child.getHeight() + insets.bottom); } else { out.set(0, 0, child.getWidth(), child.getHeight()); } if (mRecyclerView != null) { final Matrix childMatrix = child.getMatrix(); if (childMatrix != null && !childMatrix.isIdentity()) { final RectF tempRectF = mRecyclerView.mTempRectF; tempRectF.set(out); childMatrix.mapRect(tempRectF); out.set( (int) Math.floor(tempRectF.left), (int) Math.floor(tempRectF.top), (int) Math.ceil(tempRectF.right), (int) Math.ceil(tempRectF.bottom) ); } } out.offset(child.getLeft(), child.getTop()); } /** * Returns the bounds of the view including its decoration and margins. * * @param view The view element to check * @param outBounds A rect that will receive the bounds of the element including its * decoration and margins. */ public void getDecoratedBoundsWithMargins(View view, Rect outBounds) { RecyclerView.getDecoratedBoundsWithMarginsInt(view, outBounds); } /** * Returns the left edge of the given child view within its parent, offset by any applied * {@link ItemDecoration ItemDecorations}. * * @param child Child to query * @return Child left edge with offsets applied * @see #getLeftDecorationWidth(View) */ public int getDecoratedLeft(View child) { return child.getLeft() - getLeftDecorationWidth(child); } /** * Returns the top edge of the given child view within its parent, offset by any applied * {@link ItemDecoration ItemDecorations}. * * @param child Child to query * @return Child top edge with offsets applied * @see #getTopDecorationHeight(View) */ public int getDecoratedTop(View child) { return child.getTop() - getTopDecorationHeight(child); } /** * Returns the right edge of the given child view within its parent, offset by any applied * {@link ItemDecoration ItemDecorations}. * * @param child Child to query * @return Child right edge with offsets applied * @see #getRightDecorationWidth(View) */ public int getDecoratedRight(View child) { return child.getRight() + getRightDecorationWidth(child); } /** * Returns the bottom edge of the given child view within its parent, offset by any applied * {@link ItemDecoration ItemDecorations}. * * @param child Child to query * @return Child bottom edge with offsets applied * @see #getBottomDecorationHeight(View) */ public int getDecoratedBottom(View child) { return child.getBottom() + getBottomDecorationHeight(child); } /** * Calculates the item decor insets applied to the given child and updates the provided * Rect instance with the inset values. *

    *
  • The Rect's left is set to the total width of left decorations.
  • *
  • The Rect's top is set to the total height of top decorations.
  • *
  • The Rect's right is set to the total width of right decorations.
  • *
  • The Rect's bottom is set to total height of bottom decorations.
  • *
*

* Note that item decorations are automatically calculated when one of the LayoutManager's * measure child methods is called. If you need to measure the child with custom specs via * {@link View#measure(int, int)}, you can use this method to get decorations. * * @param child The child view whose decorations should be calculated * @param outRect The Rect to hold result values */ public void calculateItemDecorationsForChild(View child, Rect outRect) { if (mRecyclerView == null) { outRect.set(0, 0, 0, 0); return; } Rect insets = mRecyclerView.getItemDecorInsetsForChild(child); outRect.set(insets); } /** * Returns the total height of item decorations applied to child's top. *

* Note that this value is not updated until the View is measured or * {@link #calculateItemDecorationsForChild(View, Rect)} is called. * * @param child Child to query * @return The total height of item decorations applied to the child's top. * @see #getDecoratedTop(View) * @see #calculateItemDecorationsForChild(View, Rect) */ public int getTopDecorationHeight(View child) { return ((LayoutParams) child.getLayoutParams()).mDecorInsets.top; } /** * Returns the total height of item decorations applied to child's bottom. *

* Note that this value is not updated until the View is measured or * {@link #calculateItemDecorationsForChild(View, Rect)} is called. * * @param child Child to query * @return The total height of item decorations applied to the child's bottom. * @see #getDecoratedBottom(View) * @see #calculateItemDecorationsForChild(View, Rect) */ public int getBottomDecorationHeight(View child) { return ((LayoutParams) child.getLayoutParams()).mDecorInsets.bottom; } /** * Returns the total width of item decorations applied to child's left. *

* Note that this value is not updated until the View is measured or * {@link #calculateItemDecorationsForChild(View, Rect)} is called. * * @param child Child to query * @return The total width of item decorations applied to the child's left. * @see #getDecoratedLeft(View) * @see #calculateItemDecorationsForChild(View, Rect) */ public int getLeftDecorationWidth(View child) { return ((LayoutParams) child.getLayoutParams()).mDecorInsets.left; } /** * Returns the total width of item decorations applied to child's right. *

* Note that this value is not updated until the View is measured or * {@link #calculateItemDecorationsForChild(View, Rect)} is called. * * @param child Child to query * @return The total width of item decorations applied to the child's right. * @see #getDecoratedRight(View) * @see #calculateItemDecorationsForChild(View, Rect) */ public int getRightDecorationWidth(View child) { return ((LayoutParams) child.getLayoutParams()).mDecorInsets.right; } /** * Called when searching for a focusable view in the given direction has failed * for the current content of the RecyclerView. * *

This is the LayoutManager's opportunity to populate views in the given direction * to fulfill the request if it can. The LayoutManager should attach and return * the view to be focused. The default implementation returns null.

* * @param focused The currently focused view * @param direction 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 * @param recycler The recycler to use for obtaining views for currently offscreen items * @param state Transient state of RecyclerView * @return The chosen view to be focused */ @Nullable public View onFocusSearchFailed(View focused, int direction, Recycler recycler, State state) { return null; } /** * This method gives a LayoutManager an opportunity to intercept the initial focus search * before the default behavior of {@link FocusFinder} is used. If this method returns * null FocusFinder will attempt to find a focusable child view. If it fails * then {@link #onFocusSearchFailed(View, int, RecyclerView.Recycler, RecyclerView.State)} * will be called to give the LayoutManager an opportunity to add new views for items * that did not have attached views representing them. The LayoutManager should not add * or remove views from this method. * * @param focused The currently focused view * @param direction 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} * @return A descendant view to focus or null to fall back to default behavior. * The default implementation returns null. */ public View onInterceptFocusSearch(View focused, int direction) { return null; } /** * Called when a child of the RecyclerView wants a particular rectangle to be positioned * onto the screen. See {@link ViewParent#requestChildRectangleOnScreen(android.view.View, * android.graphics.Rect, boolean)} for more details. * *

The base implementation will attempt to perform a standard programmatic scroll * to bring the given rect into view, within the padded area of the RecyclerView.

* * @param child The direct child making the request. * @param rect The rectangle in the child's coordinates the child * wishes to be on the screen. * @param immediate True to forbid animated or delayed scrolling, * false otherwise * @return Whether the group scrolled to handle the operation */ public boolean requestChildRectangleOnScreen(RecyclerView parent, View child, Rect rect, boolean immediate) { final int parentLeft = getPaddingLeft(); final int parentTop = getPaddingTop(); final int parentRight = getWidth() - getPaddingRight(); final int parentBottom = getHeight() - getPaddingBottom(); final int childLeft = child.getLeft() + rect.left - child.getScrollX(); final int childTop = child.getTop() + rect.top - child.getScrollY(); final int childRight = childLeft + rect.width(); final int childBottom = childTop + rect.height(); final int offScreenLeft = Math.min(0, childLeft - parentLeft); final int offScreenTop = Math.min(0, childTop - parentTop); final int offScreenRight = Math.max(0, childRight - parentRight); final int offScreenBottom = Math.max(0, childBottom - parentBottom); // Favor the "start" layout direction over the end when bringing one side or the other // of a large rect into view. If we decide to bring in end because start is already // visible, limit the scroll such that start won't go out of bounds. final int dx; if (getLayoutDirection() == View.LAYOUT_DIRECTION_RTL) { dx = offScreenRight != 0 ? offScreenRight : Math.max(offScreenLeft, childRight - parentRight); } else { dx = offScreenLeft != 0 ? offScreenLeft : Math.min(childLeft - parentLeft, offScreenRight); } // Favor bringing the top into view over the bottom. If top is already visible and // we should scroll to make bottom visible, make sure top does not go out of bounds. final int dy = offScreenTop != 0 ? offScreenTop : Math.min(childTop - parentTop, offScreenBottom); if (dx != 0 || dy != 0) { if (immediate) { parent.scrollBy(dx, dy); } else { parent.smoothScrollBy(dx, dy); } return true; } return false; } /** * @deprecated Use {@link #onRequestChildFocus(RecyclerView, State, View, View)} */ @Deprecated public boolean onRequestChildFocus(RecyclerView parent, View child, View focused) { // eat the request if we are in the middle of a scroll or layout return isSmoothScrolling() || parent.isComputingLayout(); } /** * Called when a descendant view of the RecyclerView requests focus. * *

A LayoutManager wishing to keep focused views aligned in a specific * portion of the view may implement that behavior in an override of this method.

* *

If the LayoutManager executes different behavior that should override the default * behavior of scrolling the focused child on screen instead of running alongside it, * this method should return true.

* * @param parent The RecyclerView hosting this LayoutManager * @param state Current state of RecyclerView * @param child Direct child of the RecyclerView containing the newly focused view * @param focused The newly focused view. This may be the same view as child or it may be * null * @return true if the default scroll behavior should be suppressed */ public boolean onRequestChildFocus(RecyclerView parent, State state, View child, View focused) { return onRequestChildFocus(parent, child, focused); } /** * Called if the RecyclerView this LayoutManager is bound to has a different adapter set. * The LayoutManager may use this opportunity to clear caches and configure state such * that it can relayout appropriately with the new data and potentially new view types. * *

The default implementation removes all currently attached views.

* * @param oldAdapter The previous adapter instance. Will be null if there was previously no * adapter. * @param newAdapter The new adapter instance. Might be null if * {@link #setAdapter(RecyclerView.Adapter)} is called with {@code null}. */ public void onAdapterChanged(Adapter oldAdapter, Adapter newAdapter) { } /** * Called to populate focusable views within the RecyclerView. * *

The LayoutManager implementation should return true if the default * behavior of {@link ViewGroup#addFocusables(java.util.ArrayList, int)} should be * suppressed.

* *

The default implementation returns false to trigger RecyclerView * to fall back to the default ViewGroup behavior.

* * @param recyclerView The RecyclerView hosting this LayoutManager * @param views List of output views. This method should add valid focusable views * to this list. * @param direction 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} * @param focusableMode The type of focusables to be added. * * @return true to suppress the default behavior, false to add default focusables after * this method returns. * * @see #FOCUSABLES_ALL * @see #FOCUSABLES_TOUCH_MODE */ public boolean onAddFocusables(RecyclerView recyclerView, ArrayList views, int direction, int focusableMode) { return false; } /** * Called when {@link Adapter#notifyDataSetChanged()} is triggered instead of giving * detailed information on what has actually changed. * * @param recyclerView */ public void onItemsChanged(RecyclerView recyclerView) { } /** * Called when items have been added to the adapter. The LayoutManager may choose to * requestLayout if the inserted items would require refreshing the currently visible set * of child views. (e.g. currently empty space would be filled by appended items, etc.) * * @param recyclerView * @param positionStart * @param itemCount */ public void onItemsAdded(RecyclerView recyclerView, int positionStart, int itemCount) { } /** * Called when items have been removed from the adapter. * * @param recyclerView * @param positionStart * @param itemCount */ public void onItemsRemoved(RecyclerView recyclerView, int positionStart, int itemCount) { } /** * Called when items have been changed in the adapter. * To receive payload, override {@link #onItemsUpdated(RecyclerView, int, int, Object)} * instead, then this callback will not be invoked. * * @param recyclerView * @param positionStart * @param itemCount */ public void onItemsUpdated(RecyclerView recyclerView, int positionStart, int itemCount) { } /** * Called when items have been changed in the adapter and with optional payload. * Default implementation calls {@link #onItemsUpdated(RecyclerView, int, int)}. * * @param recyclerView * @param positionStart * @param itemCount * @param payload */ public void onItemsUpdated(RecyclerView recyclerView, int positionStart, int itemCount, Object payload) { onItemsUpdated(recyclerView, positionStart, itemCount); } /** * Called when an item is moved withing the adapter. *

* Note that, an item may also change position in response to another ADD/REMOVE/MOVE * operation. This callback is only called if and only if {@link Adapter#notifyItemMoved} * is called. * * @param recyclerView * @param from * @param to * @param itemCount */ public void onItemsMoved(RecyclerView recyclerView, int from, int to, int itemCount) { } /** *

Override this method if you want to support scroll bars.

* *

Read {@link RecyclerView#computeHorizontalScrollExtent()} for details.

* *

Default implementation returns 0.

* * @param state Current state of RecyclerView * @return The horizontal extent of the scrollbar's thumb * @see RecyclerView#computeHorizontalScrollExtent() */ public int computeHorizontalScrollExtent(State state) { return 0; } /** *

Override this method if you want to support scroll bars.

* *

Read {@link RecyclerView#computeHorizontalScrollOffset()} for details.

* *

Default implementation returns 0.

* * @param state Current State of RecyclerView where you can find total item count * @return The horizontal offset of the scrollbar's thumb * @see RecyclerView#computeHorizontalScrollOffset() */ public int computeHorizontalScrollOffset(State state) { return 0; } /** *

Override this method if you want to support scroll bars.

* *

Read {@link RecyclerView#computeHorizontalScrollRange()} for details.

* *

Default implementation returns 0.

* * @param state Current State of RecyclerView where you can find total item count * @return The total horizontal range represented by the vertical scrollbar * @see RecyclerView#computeHorizontalScrollRange() */ public int computeHorizontalScrollRange(State state) { return 0; } /** *

Override this method if you want to support scroll bars.

* *

Read {@link RecyclerView#computeVerticalScrollExtent()} for details.

* *

Default implementation returns 0.

* * @param state Current state of RecyclerView * @return The vertical extent of the scrollbar's thumb * @see RecyclerView#computeVerticalScrollExtent() */ public int computeVerticalScrollExtent(State state) { return 0; } /** *

Override this method if you want to support scroll bars.

* *

Read {@link RecyclerView#computeVerticalScrollOffset()} for details.

* *

Default implementation returns 0.

* * @param state Current State of RecyclerView where you can find total item count * @return The vertical offset of the scrollbar's thumb * @see RecyclerView#computeVerticalScrollOffset() */ public int computeVerticalScrollOffset(State state) { return 0; } /** *

Override this method if you want to support scroll bars.

* *

Read {@link RecyclerView#computeVerticalScrollRange()} for details.

* *

Default implementation returns 0.

* * @param state Current State of RecyclerView where you can find total item count * @return The total vertical range represented by the vertical scrollbar * @see RecyclerView#computeVerticalScrollRange() */ public int computeVerticalScrollRange(State state) { return 0; } /** * Measure the attached RecyclerView. Implementations must call * {@link #setMeasuredDimension(int, int)} before returning. * *

The default implementation will handle EXACTLY measurements and respect * the minimum width and height properties of the host RecyclerView if measured * as UNSPECIFIED. AT_MOST measurements will be treated as EXACTLY and the RecyclerView * will consume all available space.

* * @param recycler Recycler * @param state Transient state of RecyclerView * @param widthSpec Width {@link android.view.View.MeasureSpec} * @param heightSpec Height {@link android.view.View.MeasureSpec} */ public void onMeasure(Recycler recycler, State state, int widthSpec, int heightSpec) { mRecyclerView.defaultOnMeasure(widthSpec, heightSpec); } /** * {@link View#setMeasuredDimension(int, int) Set the measured dimensions} of the * host RecyclerView. * * @param widthSize Measured width * @param heightSize Measured height */ public void setMeasuredDimension(int widthSize, int heightSize) { mRecyclerView.setMeasuredDimension(widthSize, heightSize); } /** * @return The host RecyclerView's {@link View#getMinimumWidth()} */ public int getMinimumWidth() { return mRecyclerView.getMinimumWidth(); } /** * @return The host RecyclerView's {@link View#getMinimumHeight()} */ public int getMinimumHeight() { return mRecyclerView.getMinimumHeight(); } /** *

Called when the LayoutManager should save its state. This is a good time to save your * scroll position, configuration and anything else that may be required to restore the same * layout state if the LayoutManager is recreated.

*

RecyclerView does NOT verify if the LayoutManager has changed between state save and * restore. This will let you share information between your LayoutManagers but it is also * your responsibility to make sure they use the same parcelable class.

* * @return Necessary information for LayoutManager to be able to restore its state */ public Parcelable onSaveInstanceState() { return null; } public void onRestoreInstanceState(Parcelable state) { } void stopSmoothScroller() { if (mSmoothScroller != null) { mSmoothScroller.stop(); } } private void onSmoothScrollerStopped(SmoothScroller smoothScroller) { if (mSmoothScroller == smoothScroller) { mSmoothScroller = null; } } /** * RecyclerView calls this method to notify LayoutManager that scroll state has changed. * * @param state The new scroll state for RecyclerView */ public void onScrollStateChanged(int state) { } /** * Removes all views and recycles them using the given recycler. *

* If you want to clean cached views as well, you should call {@link Recycler#clear()} too. *

* If a View is marked as "ignored", it is not removed nor recycled. * * @param recycler Recycler to use to recycle children * @see #removeAndRecycleView(View, Recycler) * @see #removeAndRecycleViewAt(int, Recycler) * @see #ignoreView(View) */ public void removeAndRecycleAllViews(Recycler recycler) { for (int i = getChildCount() - 1; i >= 0; i--) { final View view = getChildAt(i); if (!getChildViewHolderInt(view).shouldIgnore()) { removeAndRecycleViewAt(i, recycler); } } } // called by accessibility delegate void onInitializeAccessibilityNodeInfo(AccessibilityNodeInfo info) { onInitializeAccessibilityNodeInfo(mRecyclerView.mRecycler, mRecyclerView.mState, info); } /** * Called by the AccessibilityDelegate when the information about the current layout should * be populated. *

* Default implementation adds a {@link * android.view.accessibility.AccessibilityNodeInfo.CollectionInfo}. *

* You should override * {@link #getRowCountForAccessibility(RecyclerView.Recycler, RecyclerView.State)}, * {@link #getColumnCountForAccessibility(RecyclerView.Recycler, RecyclerView.State)}, * {@link #isLayoutHierarchical(RecyclerView.Recycler, RecyclerView.State)} and * {@link #getSelectionModeForAccessibility(RecyclerView.Recycler, RecyclerView.State)} for * more accurate accessibility information. * * @param recycler The Recycler that can be used to convert view positions into adapter * positions * @param state The current state of RecyclerView * @param info The info that should be filled by the LayoutManager * @see View#onInitializeAccessibilityNodeInfo( *android.view.accessibility.AccessibilityNodeInfo) * @see #getRowCountForAccessibility(RecyclerView.Recycler, RecyclerView.State) * @see #getColumnCountForAccessibility(RecyclerView.Recycler, RecyclerView.State) * @see #isLayoutHierarchical(RecyclerView.Recycler, RecyclerView.State) * @see #getSelectionModeForAccessibility(RecyclerView.Recycler, RecyclerView.State) */ public void onInitializeAccessibilityNodeInfo(Recycler recycler, State state, AccessibilityNodeInfo info) { if (mRecyclerView.canScrollVertically(-1) || mRecyclerView.canScrollHorizontally(-1)) { info.addAction(AccessibilityNodeInfo.ACTION_SCROLL_BACKWARD); info.setScrollable(true); } if (mRecyclerView.canScrollVertically(1) || mRecyclerView.canScrollHorizontally(1)) { info.addAction(AccessibilityNodeInfo.ACTION_SCROLL_FORWARD); info.setScrollable(true); } final AccessibilityNodeInfo.CollectionInfo collectionInfo = AccessibilityNodeInfo.CollectionInfo .obtain(getRowCountForAccessibility(recycler, state), getColumnCountForAccessibility(recycler, state), isLayoutHierarchical(recycler, state), getSelectionModeForAccessibility(recycler, state)); info.setCollectionInfo(collectionInfo); } // called by accessibility delegate public void onInitializeAccessibilityEvent(AccessibilityEvent event) { onInitializeAccessibilityEvent(mRecyclerView.mRecycler, mRecyclerView.mState, event); } /** * Called by the accessibility delegate to initialize an accessibility event. *

* Default implementation adds item count and scroll information to the event. * * @param recycler The Recycler that can be used to convert view positions into adapter * positions * @param state The current state of RecyclerView * @param event The event instance to initialize * @see View#onInitializeAccessibilityEvent(android.view.accessibility.AccessibilityEvent) */ public void onInitializeAccessibilityEvent(Recycler recycler, State state, AccessibilityEvent event) { if (mRecyclerView == null || event == null) { return; } event.setScrollable(mRecyclerView.canScrollVertically(1) || mRecyclerView.canScrollVertically(-1) || mRecyclerView.canScrollHorizontally(-1) || mRecyclerView.canScrollHorizontally(1)); if (mRecyclerView.mAdapter != null) { event.setItemCount(mRecyclerView.mAdapter.getItemCount()); } } // called by accessibility delegate void onInitializeAccessibilityNodeInfoForItem(View host, AccessibilityNodeInfo info) { final ViewHolder vh = getChildViewHolderInt(host); // avoid trying to create accessibility node info for removed children if (vh != null && !vh.isRemoved() && !mChildHelper.isHidden(vh.itemView)) { onInitializeAccessibilityNodeInfoForItem(mRecyclerView.mRecycler, mRecyclerView.mState, host, info); } } /** * Called by the AccessibilityDelegate when the accessibility information for a specific * item should be populated. *

* Default implementation adds basic positioning information about the item. * * @param recycler The Recycler that can be used to convert view positions into adapter * positions * @param state The current state of RecyclerView * @param host The child for which accessibility node info should be populated * @param info The info to fill out about the item * @see android.widget.AbsListView#onInitializeAccessibilityNodeInfoForItem(View, int, * android.view.accessibility.AccessibilityNodeInfo) */ public void onInitializeAccessibilityNodeInfoForItem(Recycler recycler, State state, View host, AccessibilityNodeInfo info) { int rowIndexGuess = canScrollVertically() ? getPosition(host) : 0; int columnIndexGuess = canScrollHorizontally() ? getPosition(host) : 0; final AccessibilityNodeInfo.CollectionItemInfo itemInfo = AccessibilityNodeInfo.CollectionItemInfo.obtain(rowIndexGuess, 1, columnIndexGuess, 1, false, false); info.setCollectionItemInfo(itemInfo); } /** * A LayoutManager can call this method to force RecyclerView to run simple animations in * the next layout pass, even if there is not any trigger to do so. (e.g. adapter data * change). *

* Note that, calling this method will not guarantee that RecyclerView will run animations * at all. For example, if there is not any {@link ItemAnimator} set, RecyclerView will * not run any animations but will still clear this flag after the layout is complete. * */ public void requestSimpleAnimationsInNextLayout() { mRequestedSimpleAnimations = true; } /** * Returns the selection mode for accessibility. Should be * {@link AccessibilityNodeInfo.CollectionInfo#SELECTION_MODE_NONE}, * {@link AccessibilityNodeInfo.CollectionInfo#SELECTION_MODE_SINGLE} or * {@link AccessibilityNodeInfo.CollectionInfo#SELECTION_MODE_MULTIPLE}. *

* Default implementation returns * {@link AccessibilityNodeInfo.CollectionInfo#SELECTION_MODE_NONE}. * * @param recycler The Recycler that can be used to convert view positions into adapter * positions * @param state The current state of RecyclerView * @return Selection mode for accessibility. Default implementation returns * {@link AccessibilityNodeInfo.CollectionInfo#SELECTION_MODE_NONE}. */ public int getSelectionModeForAccessibility(Recycler recycler, State state) { return AccessibilityNodeInfo.CollectionInfo.SELECTION_MODE_NONE; } /** * Returns the number of rows for accessibility. *

* Default implementation returns the number of items in the adapter if LayoutManager * supports vertical scrolling or 1 if LayoutManager does not support vertical * scrolling. * * @param recycler The Recycler that can be used to convert view positions into adapter * positions * @param state The current state of RecyclerView * @return The number of rows in LayoutManager for accessibility. */ public int getRowCountForAccessibility(Recycler recycler, State state) { if (mRecyclerView == null || mRecyclerView.mAdapter == null) { return 1; } return canScrollVertically() ? mRecyclerView.mAdapter.getItemCount() : 1; } /** * Returns the number of columns for accessibility. *

* Default implementation returns the number of items in the adapter if LayoutManager * supports horizontal scrolling or 1 if LayoutManager does not support horizontal * scrolling. * * @param recycler The Recycler that can be used to convert view positions into adapter * positions * @param state The current state of RecyclerView * @return The number of rows in LayoutManager for accessibility. */ public int getColumnCountForAccessibility(Recycler recycler, State state) { if (mRecyclerView == null || mRecyclerView.mAdapter == null) { return 1; } return canScrollHorizontally() ? mRecyclerView.mAdapter.getItemCount() : 1; } /** * Returns whether layout is hierarchical or not to be used for accessibility. *

* Default implementation returns false. * * @param recycler The Recycler that can be used to convert view positions into adapter * positions * @param state The current state of RecyclerView * @return True if layout is hierarchical. */ public boolean isLayoutHierarchical(Recycler recycler, State state) { return false; } // called by accessibility delegate boolean performAccessibilityAction(int action, Bundle args) { return performAccessibilityAction(mRecyclerView.mRecycler, mRecyclerView.mState, action, args); } /** * Called by AccessibilityDelegate when an action is requested from the RecyclerView. * * @param recycler The Recycler that can be used to convert view positions into adapter * positions * @param state The current state of RecyclerView * @param action The action to perform * @param args Optional action arguments * @see View#performAccessibilityAction(int, android.os.Bundle) */ public boolean performAccessibilityAction(Recycler recycler, State state, int action, Bundle args) { if (mRecyclerView == null) { return false; } int vScroll = 0, hScroll = 0; switch (action) { case AccessibilityNodeInfo.ACTION_SCROLL_BACKWARD: if (mRecyclerView.canScrollVertically(-1)) { vScroll = -(getHeight() - getPaddingTop() - getPaddingBottom()); } if (mRecyclerView.canScrollHorizontally(-1)) { hScroll = -(getWidth() - getPaddingLeft() - getPaddingRight()); } break; case AccessibilityNodeInfo.ACTION_SCROLL_FORWARD: if (mRecyclerView.canScrollVertically(1)) { vScroll = getHeight() - getPaddingTop() - getPaddingBottom(); } if (mRecyclerView.canScrollHorizontally(1)) { hScroll = getWidth() - getPaddingLeft() - getPaddingRight(); } break; } if (vScroll == 0 && hScroll == 0) { return false; } mRecyclerView.scrollBy(hScroll, vScroll); return true; } // called by accessibility delegate boolean performAccessibilityActionForItem(View view, int action, Bundle args) { return performAccessibilityActionForItem(mRecyclerView.mRecycler, mRecyclerView.mState, view, action, args); } /** * Called by AccessibilityDelegate when an accessibility action is requested on one of the * children of LayoutManager. *

* Default implementation does not do anything. * * @param recycler The Recycler that can be used to convert view positions into adapter * positions * @param state The current state of RecyclerView * @param view The child view on which the action is performed * @param action The action to perform * @param args Optional action arguments * @return true if action is handled * @see View#performAccessibilityAction(int, android.os.Bundle) */ public boolean performAccessibilityActionForItem(Recycler recycler, State state, View view, int action, Bundle args) { return false; } /** * Parse the xml attributes to get the most common properties used by layout managers. * * @return an object containing the properties as specified in the attrs. */ public static Properties getProperties(Context context, AttributeSet attrs, int defStyleAttr, int defStyleRes) { Properties properties = new Properties(); TypedArray a = context.obtainStyledAttributes(attrs, R.styleable.RecyclerView, defStyleAttr, defStyleRes); properties.orientation = a.getInt(R.styleable.RecyclerView_orientation, VERTICAL); properties.spanCount = a.getInt(R.styleable.RecyclerView_spanCount, 1); properties.reverseLayout = a.getBoolean(R.styleable.RecyclerView_reverseLayout, false); properties.stackFromEnd = a.getBoolean(R.styleable.RecyclerView_stackFromEnd, false); a.recycle(); return properties; } void setExactMeasureSpecsFrom(RecyclerView recyclerView) { setMeasureSpecs( MeasureSpec.makeMeasureSpec(recyclerView.getWidth(), MeasureSpec.EXACTLY), MeasureSpec.makeMeasureSpec(recyclerView.getHeight(), MeasureSpec.EXACTLY) ); } /** * Internal API to allow LayoutManagers to be measured twice. *

* This is not public because LayoutManagers should be able to handle their layouts in one * pass but it is very convenient to make existing LayoutManagers support wrapping content * when both orientations are undefined. *

* This API will be removed after default LayoutManagers properly implement wrap content in * non-scroll orientation. */ boolean shouldMeasureTwice() { return false; } boolean hasFlexibleChildInBothOrientations() { final int childCount = getChildCount(); for (int i = 0; i < childCount; i++) { final View child = getChildAt(i); final ViewGroup.LayoutParams lp = child.getLayoutParams(); if (lp.width < 0 && lp.height < 0) { return true; } } return false; } /** * Some general properties that a LayoutManager may want to use. */ public static class Properties { /** @attr ref android.support.v7.recyclerview.R.styleable#RecyclerView_android_orientation */ public int orientation; /** @attr ref android.support.v7.recyclerview.R.styleable#RecyclerView_spanCount */ public int spanCount; /** @attr ref android.support.v7.recyclerview.R.styleable#RecyclerView_reverseLayout */ public boolean reverseLayout; /** @attr ref android.support.v7.recyclerview.R.styleable#RecyclerView_stackFromEnd */ public boolean stackFromEnd; } } /** * An ItemDecoration allows the application to add a special drawing and layout offset * to specific item views from the adapter's data set. This can be useful for drawing dividers * between items, highlights, visual grouping boundaries and more. * *

All ItemDecorations are drawn in the order they were added, before the item * views (in {@link ItemDecoration#onDraw(Canvas, RecyclerView, RecyclerView.State) onDraw()} * and after the items (in {@link ItemDecoration#onDrawOver(Canvas, RecyclerView, * RecyclerView.State)}.

*/ public abstract static class ItemDecoration { /** * Draw any appropriate decorations into the Canvas supplied to the RecyclerView. * Any content drawn by this method will be drawn before the item views are drawn, * and will thus appear underneath the views. * * @param c Canvas to draw into * @param parent RecyclerView this ItemDecoration is drawing into * @param state The current state of RecyclerView */ public void onDraw(Canvas c, RecyclerView parent, State state) { onDraw(c, parent); } /** * @deprecated * Override {@link #onDraw(Canvas, RecyclerView, RecyclerView.State)} */ @Deprecated public void onDraw(Canvas c, RecyclerView parent) { } /** * Draw any appropriate decorations into the Canvas supplied to the RecyclerView. * Any content drawn by this method will be drawn after the item views are drawn * and will thus appear over the views. * * @param c Canvas to draw into * @param parent RecyclerView this ItemDecoration is drawing into * @param state The current state of RecyclerView. */ public void onDrawOver(Canvas c, RecyclerView parent, State state) { onDrawOver(c, parent); } /** * @deprecated * Override {@link #onDrawOver(Canvas, RecyclerView, RecyclerView.State)} */ @Deprecated public void onDrawOver(Canvas c, RecyclerView parent) { } /** * @deprecated * Use {@link #getItemOffsets(Rect, View, RecyclerView, State)} */ @Deprecated public void getItemOffsets(Rect outRect, int itemPosition, RecyclerView parent) { outRect.set(0, 0, 0, 0); } /** * Retrieve any offsets for the given item. Each field of outRect specifies * the number of pixels that the item view should be inset by, similar to padding or margin. * The default implementation sets the bounds of outRect to 0 and returns. * *

* If this ItemDecoration does not affect the positioning of item views, it should set * all four fields of outRect (left, top, right, bottom) to zero * before returning. * *

* If you need to access Adapter for additional data, you can call * {@link RecyclerView#getChildAdapterPosition(View)} to get the adapter position of the * View. * * @param outRect Rect to receive the output. * @param view The child view to decorate * @param parent RecyclerView this ItemDecoration is decorating * @param state The current state of RecyclerView. */ public void getItemOffsets(Rect outRect, View view, RecyclerView parent, State state) { getItemOffsets(outRect, ((LayoutParams) view.getLayoutParams()).getViewLayoutPosition(), parent); } } /** * An OnItemTouchListener allows the application to intercept touch events in progress at the * view hierarchy level of the RecyclerView before those touch events are considered for * RecyclerView's own scrolling behavior. * *

This can be useful for applications that wish to implement various forms of gestural * manipulation of item views within the RecyclerView. OnItemTouchListeners may intercept * a touch interaction already in progress even if the RecyclerView is already handling that * gesture stream itself for the purposes of scrolling.

* * @see SimpleOnItemTouchListener */ public interface OnItemTouchListener { /** * Silently observe and/or take over touch events sent to the RecyclerView * before they are handled by either the RecyclerView itself or its child views. * *

The onInterceptTouchEvent methods of each attached OnItemTouchListener will be run * in the order in which each listener was added, before any other touch processing * by the RecyclerView itself or child views occurs.

* * @param e MotionEvent describing the touch event. All coordinates are in * the RecyclerView's coordinate system. * @return true if this OnItemTouchListener wishes to begin intercepting touch events, false * to continue with the current behavior and continue observing future events in * the gesture. */ boolean onInterceptTouchEvent(RecyclerView rv, MotionEvent e); /** * Process a touch event as part of a gesture that was claimed by returning true from * a previous call to {@link #onInterceptTouchEvent}. * * @param e MotionEvent describing the touch event. All coordinates are in * the RecyclerView's coordinate system. */ void onTouchEvent(RecyclerView rv, MotionEvent e); /** * Called when a child of RecyclerView does not want RecyclerView and its ancestors to * intercept touch events with * {@link ViewGroup#onInterceptTouchEvent(MotionEvent)}. * * @param disallowIntercept True if the child does not want the parent to * intercept touch events. * @see ViewParent#requestDisallowInterceptTouchEvent(boolean) */ void onRequestDisallowInterceptTouchEvent(boolean disallowIntercept); } /** * An implementation of {@link RecyclerView.OnItemTouchListener} that has empty method bodies * and default return values. *

* You may prefer to extend this class if you don't need to override all methods. Another * benefit of using this class is future compatibility. As the interface may change, we'll * always provide a default implementation on this class so that your code won't break when * you update to a new version of the support library. */ public static class SimpleOnItemTouchListener implements RecyclerView.OnItemTouchListener { @Override public boolean onInterceptTouchEvent(RecyclerView rv, MotionEvent e) { return false; } @Override public void onTouchEvent(RecyclerView rv, MotionEvent e) { } @Override public void onRequestDisallowInterceptTouchEvent(boolean disallowIntercept) { } } /** * An OnScrollListener can be added to a RecyclerView to receive messages when a scrolling event * has occurred on that RecyclerView. *

* @see RecyclerView#addOnScrollListener(OnScrollListener) * @see RecyclerView#clearOnChildAttachStateChangeListeners() * */ public abstract static class OnScrollListener { /** * Callback method to be invoked when RecyclerView's scroll state changes. * * @param recyclerView The RecyclerView whose scroll state has changed. * @param newState The updated scroll state. One of {@link #SCROLL_STATE_IDLE}, * {@link #SCROLL_STATE_DRAGGING} or {@link #SCROLL_STATE_SETTLING}. */ public void onScrollStateChanged(RecyclerView recyclerView, int newState){} /** * Callback method to be invoked when the RecyclerView has been scrolled. This will be * called after the scroll has completed. *

* This callback will also be called if visible item range changes after a layout * calculation. In that case, dx and dy will be 0. * * @param recyclerView The RecyclerView which scrolled. * @param dx The amount of horizontal scroll. * @param dy The amount of vertical scroll. */ public void onScrolled(RecyclerView recyclerView, int dx, int dy){} } /** * A RecyclerListener can be set on a RecyclerView to receive messages whenever * a view is recycled. * * @see RecyclerView#setRecyclerListener(RecyclerListener) */ public interface RecyclerListener { /** * This method is called whenever the view in the ViewHolder is recycled. * * RecyclerView calls this method right before clearing ViewHolder's internal data and * sending it to RecycledViewPool. This way, if ViewHolder was holding valid information * before being recycled, you can call {@link ViewHolder#getAdapterPosition()} to get * its adapter position. * * @param holder The ViewHolder containing the view that was recycled */ void onViewRecycled(ViewHolder holder); } /** * A Listener interface that can be attached to a RecylcerView to get notified * whenever a ViewHolder is attached to or detached from RecyclerView. */ public interface OnChildAttachStateChangeListener { /** * Called when a view is attached to the RecyclerView. * * @param view The View which is attached to the RecyclerView */ void onChildViewAttachedToWindow(View view); /** * Called when a view is detached from RecyclerView. * * @param view The View which is being detached from the RecyclerView */ void onChildViewDetachedFromWindow(View view); } /** * A ViewHolder describes an item view and metadata about its place within the RecyclerView. * *

{@link Adapter} implementations should subclass ViewHolder and add fields for caching * potentially expensive {@link View#findViewById(int)} results.

* *

While {@link LayoutParams} belong to the {@link LayoutManager}, * {@link ViewHolder ViewHolders} belong to the adapter. Adapters should feel free to use * their own custom ViewHolder implementations to store data that makes binding view contents * easier. Implementations should assume that individual item views will hold strong references * to ViewHolder objects and that RecyclerView instances may hold * strong references to extra off-screen item views for caching purposes

*/ public abstract static class ViewHolder { public final View itemView; WeakReference mNestedRecyclerView; int mPosition = NO_POSITION; int mOldPosition = NO_POSITION; long mItemId = NO_ID; int mItemViewType = INVALID_TYPE; int mPreLayoutPosition = NO_POSITION; // The item that this holder is shadowing during an item change event/animation ViewHolder mShadowedHolder = null; // The item that is shadowing this holder during an item change event/animation ViewHolder mShadowingHolder = null; /** * This ViewHolder has been bound to a position; mPosition, mItemId and mItemViewType * are all valid. */ static final int FLAG_BOUND = 1 << 0; /** * The data this ViewHolder's view reflects is stale and needs to be rebound * by the adapter. mPosition and mItemId are consistent. */ static final int FLAG_UPDATE = 1 << 1; /** * This ViewHolder's data is invalid. The identity implied by mPosition and mItemId * are not to be trusted and may no longer match the item view type. * This ViewHolder must be fully rebound to different data. */ static final int FLAG_INVALID = 1 << 2; /** * This ViewHolder points at data that represents an item previously removed from the * data set. Its view may still be used for things like outgoing animations. */ static final int FLAG_REMOVED = 1 << 3; /** * This ViewHolder should not be recycled. This flag is set via setIsRecyclable() * and is intended to keep views around during animations. */ static final int FLAG_NOT_RECYCLABLE = 1 << 4; /** * This ViewHolder is returned from scrap which means we are expecting an addView call * for this itemView. When returned from scrap, ViewHolder stays in the scrap list until * the end of the layout pass and then recycled by RecyclerView if it is not added back to * the RecyclerView. */ static final int FLAG_RETURNED_FROM_SCRAP = 1 << 5; /** * This ViewHolder is fully managed by the LayoutManager. We do not scrap, recycle or remove * it unless LayoutManager is replaced. * It is still fully visible to the LayoutManager. */ static final int FLAG_IGNORE = 1 << 7; /** * When the View is detached form the parent, we set this flag so that we can take correct * action when we need to remove it or add it back. */ static final int FLAG_TMP_DETACHED = 1 << 8; /** * Set when we can no longer determine the adapter position of this ViewHolder until it is * rebound to a new position. It is different than FLAG_INVALID because FLAG_INVALID is * set even when the type does not match. Also, FLAG_ADAPTER_POSITION_UNKNOWN is set as soon * as adapter notification arrives vs FLAG_INVALID is set lazily before layout is * re-calculated. */ static final int FLAG_ADAPTER_POSITION_UNKNOWN = 1 << 9; /** * Set when a addChangePayload(null) is called */ static final int FLAG_ADAPTER_FULLUPDATE = 1 << 10; /** * Used by ItemAnimator when a ViewHolder's position changes */ static final int FLAG_MOVED = 1 << 11; /** * Used by ItemAnimator when a ViewHolder appears in pre-layout */ static final int FLAG_APPEARED_IN_PRE_LAYOUT = 1 << 12; static final int PENDING_ACCESSIBILITY_STATE_NOT_SET = -1; /** * Used when a ViewHolder starts the layout pass as a hidden ViewHolder but is re-used from * hidden list (as if it was scrap) without being recycled in between. * * When a ViewHolder is hidden, there are 2 paths it can be re-used: * a) Animation ends, view is recycled and used from the recycle pool. * b) LayoutManager asks for the View for that position while the ViewHolder is hidden. * * This flag is used to represent "case b" where the ViewHolder is reused without being * recycled (thus "bounced" from the hidden list). This state requires special handling * because the ViewHolder must be added to pre layout maps for animations as if it was * already there. */ static final int FLAG_BOUNCED_FROM_HIDDEN_LIST = 1 << 13; private int mFlags; private static final List FULLUPDATE_PAYLOADS = Collections.EMPTY_LIST; List mPayloads = null; List mUnmodifiedPayloads = null; private int mIsRecyclableCount = 0; // If non-null, view is currently considered scrap and may be reused for other data by the // scrap container. private Recycler mScrapContainer = null; // Keeps whether this ViewHolder lives in Change scrap or Attached scrap private boolean mInChangeScrap = false; // Saves isImportantForAccessibility value for the view item while it's in hidden state and // marked as unimportant for accessibility. private int mWasImportantForAccessibilityBeforeHidden = View.IMPORTANT_FOR_ACCESSIBILITY_AUTO; // set if we defer the accessibility state change of the view holder @VisibleForTesting int mPendingAccessibilityState = PENDING_ACCESSIBILITY_STATE_NOT_SET; /** * Is set when VH is bound from the adapter and cleaned right before it is sent to * {@link RecycledViewPool}. */ RecyclerView mOwnerRecyclerView; public ViewHolder(View itemView) { if (itemView == null) { throw new IllegalArgumentException("itemView may not be null"); } this.itemView = itemView; } void flagRemovedAndOffsetPosition(int mNewPosition, int offset, boolean applyToPreLayout) { addFlags(ViewHolder.FLAG_REMOVED); offsetPosition(offset, applyToPreLayout); mPosition = mNewPosition; } void offsetPosition(int offset, boolean applyToPreLayout) { if (mOldPosition == NO_POSITION) { mOldPosition = mPosition; } if (mPreLayoutPosition == NO_POSITION) { mPreLayoutPosition = mPosition; } if (applyToPreLayout) { mPreLayoutPosition += offset; } mPosition += offset; if (itemView.getLayoutParams() != null) { ((LayoutParams) itemView.getLayoutParams()).mInsetsDirty = true; } } void clearOldPosition() { mOldPosition = NO_POSITION; mPreLayoutPosition = NO_POSITION; } void saveOldPosition() { if (mOldPosition == NO_POSITION) { mOldPosition = mPosition; } } boolean shouldIgnore() { return (mFlags & FLAG_IGNORE) != 0; } /** * @deprecated This method is deprecated because its meaning is ambiguous due to the async * handling of adapter updates. Please use {@link #getLayoutPosition()} or * {@link #getAdapterPosition()} depending on your use case. * * @see #getLayoutPosition() * @see #getAdapterPosition() */ @Deprecated public final int getPosition() { return mPreLayoutPosition == NO_POSITION ? mPosition : mPreLayoutPosition; } /** * Returns the position of the ViewHolder in terms of the latest layout pass. *

* This position is mostly used by RecyclerView components to be consistent while * RecyclerView lazily processes adapter updates. *

* For performance and animation reasons, RecyclerView batches all adapter updates until the * next layout pass. This may cause mismatches between the Adapter position of the item and * the position it had in the latest layout calculations. *

* LayoutManagers should always call this method while doing calculations based on item * positions. All methods in {@link RecyclerView.LayoutManager}, {@link RecyclerView.State}, * {@link RecyclerView.Recycler} that receive a position expect it to be the layout position * of the item. *

* If LayoutManager needs to call an external method that requires the adapter position of * the item, it can use {@link #getAdapterPosition()} or * {@link RecyclerView.Recycler#convertPreLayoutPositionToPostLayout(int)}. * * @return Returns the adapter position of the ViewHolder in the latest layout pass. * @see #getAdapterPosition() */ public final int getLayoutPosition() { return mPreLayoutPosition == NO_POSITION ? mPosition : mPreLayoutPosition; } /** * Returns the Adapter position of the item represented by this ViewHolder. *

* Note that this might be different than the {@link #getLayoutPosition()} if there are * pending adapter updates but a new layout pass has not happened yet. *

* RecyclerView does not handle any adapter updates until the next layout traversal. This * may create temporary inconsistencies between what user sees on the screen and what * adapter contents have. This inconsistency is not important since it will be less than * 16ms but it might be a problem if you want to use ViewHolder position to access the * adapter. Sometimes, you may need to get the exact adapter position to do * some actions in response to user events. In that case, you should use this method which * will calculate the Adapter position of the ViewHolder. *

* Note that if you've called {@link RecyclerView.Adapter#notifyDataSetChanged()}, until the * next layout pass, the return value of this method will be {@link #NO_POSITION}. * * @return The adapter position of the item if it still exists in the adapter. * {@link RecyclerView#NO_POSITION} if item has been removed from the adapter, * {@link RecyclerView.Adapter#notifyDataSetChanged()} has been called after the last * layout pass or the ViewHolder has already been recycled. */ public final int getAdapterPosition() { if (mOwnerRecyclerView == null) { return NO_POSITION; } return mOwnerRecyclerView.getAdapterPositionFor(this); } /** * When LayoutManager supports animations, RecyclerView tracks 3 positions for ViewHolders * to perform animations. *

* If a ViewHolder was laid out in the previous onLayout call, old position will keep its * adapter index in the previous layout. * * @return The previous adapter index of the Item represented by this ViewHolder or * {@link #NO_POSITION} if old position does not exists or cleared (pre-layout is * complete). */ public final int getOldPosition() { return mOldPosition; } /** * Returns The itemId represented by this ViewHolder. * * @return The item's id if adapter has stable ids, {@link RecyclerView#NO_ID} * otherwise */ public final long getItemId() { return mItemId; } /** * @return The view type of this ViewHolder. */ public final int getItemViewType() { return mItemViewType; } boolean isScrap() { return mScrapContainer != null; } void unScrap() { mScrapContainer.unscrapView(this); } boolean wasReturnedFromScrap() { return (mFlags & FLAG_RETURNED_FROM_SCRAP) != 0; } void clearReturnedFromScrapFlag() { mFlags = mFlags & ~FLAG_RETURNED_FROM_SCRAP; } void clearTmpDetachFlag() { mFlags = mFlags & ~FLAG_TMP_DETACHED; } void stopIgnoring() { mFlags = mFlags & ~FLAG_IGNORE; } void setScrapContainer(Recycler recycler, boolean isChangeScrap) { mScrapContainer = recycler; mInChangeScrap = isChangeScrap; } boolean isInvalid() { return (mFlags & FLAG_INVALID) != 0; } boolean needsUpdate() { return (mFlags & FLAG_UPDATE) != 0; } boolean isBound() { return (mFlags & FLAG_BOUND) != 0; } boolean isRemoved() { return (mFlags & FLAG_REMOVED) != 0; } boolean hasAnyOfTheFlags(int flags) { return (mFlags & flags) != 0; } boolean isTmpDetached() { return (mFlags & FLAG_TMP_DETACHED) != 0; } boolean isAdapterPositionUnknown() { return (mFlags & FLAG_ADAPTER_POSITION_UNKNOWN) != 0 || isInvalid(); } void setFlags(int flags, int mask) { mFlags = (mFlags & ~mask) | (flags & mask); } void addFlags(int flags) { mFlags |= flags; } void addChangePayload(Object payload) { if (payload == null) { addFlags(FLAG_ADAPTER_FULLUPDATE); } else if ((mFlags & FLAG_ADAPTER_FULLUPDATE) == 0) { createPayloadsIfNeeded(); mPayloads.add(payload); } } private void createPayloadsIfNeeded() { if (mPayloads == null) { mPayloads = new ArrayList(); mUnmodifiedPayloads = Collections.unmodifiableList(mPayloads); } } void clearPayload() { if (mPayloads != null) { mPayloads.clear(); } mFlags = mFlags & ~FLAG_ADAPTER_FULLUPDATE; } List getUnmodifiedPayloads() { if ((mFlags & FLAG_ADAPTER_FULLUPDATE) == 0) { if (mPayloads == null || mPayloads.size() == 0) { // Initial state, no update being called. return FULLUPDATE_PAYLOADS; } // there are none-null payloads return mUnmodifiedPayloads; } else { // a full update has been called. return FULLUPDATE_PAYLOADS; } } void resetInternal() { mFlags = 0; mPosition = NO_POSITION; mOldPosition = NO_POSITION; mItemId = NO_ID; mPreLayoutPosition = NO_POSITION; mIsRecyclableCount = 0; mShadowedHolder = null; mShadowingHolder = null; clearPayload(); mWasImportantForAccessibilityBeforeHidden = View.IMPORTANT_FOR_ACCESSIBILITY_AUTO; mPendingAccessibilityState = PENDING_ACCESSIBILITY_STATE_NOT_SET; clearNestedRecyclerViewIfNotNested(this); } /** * Called when the child view enters the hidden state */ private void onEnteredHiddenState(RecyclerView parent) { // While the view item is in hidden state, make it invisible for the accessibility. mWasImportantForAccessibilityBeforeHidden = itemView.getImportantForAccessibility(); parent.setChildImportantForAccessibilityInternal(this, View.IMPORTANT_FOR_ACCESSIBILITY_NO_HIDE_DESCENDANTS); } /** * Called when the child view leaves the hidden state */ private void onLeftHiddenState(RecyclerView parent) { parent.setChildImportantForAccessibilityInternal(this, mWasImportantForAccessibilityBeforeHidden); mWasImportantForAccessibilityBeforeHidden = View.IMPORTANT_FOR_ACCESSIBILITY_AUTO; } @Override public String toString() { final StringBuilder sb = new StringBuilder("ViewHolder{" + Integer.toHexString(hashCode()) + " position=" + mPosition + " id=" + mItemId + ", oldPos=" + mOldPosition + ", pLpos:" + mPreLayoutPosition); if (isScrap()) { sb.append(" scrap ") .append(mInChangeScrap ? "[changeScrap]" : "[attachedScrap]"); } if (isInvalid()) sb.append(" invalid"); if (!isBound()) sb.append(" unbound"); if (needsUpdate()) sb.append(" update"); if (isRemoved()) sb.append(" removed"); if (shouldIgnore()) sb.append(" ignored"); if (isTmpDetached()) sb.append(" tmpDetached"); if (!isRecyclable()) sb.append(" not recyclable(" + mIsRecyclableCount + ")"); if (isAdapterPositionUnknown()) sb.append(" undefined adapter position"); if (itemView.getParent() == null) sb.append(" no parent"); sb.append("}"); return sb.toString(); } /** * Informs the recycler whether this item can be recycled. Views which are not * recyclable will not be reused for other items until setIsRecyclable() is * later set to true. Calls to setIsRecyclable() should always be paired (one * call to setIsRecyclabe(false) should always be matched with a later call to * setIsRecyclable(true)). Pairs of calls may be nested, as the state is internally * reference-counted. * * @param recyclable Whether this item is available to be recycled. Default value * is true. * * @see #isRecyclable() */ public final void setIsRecyclable(boolean recyclable) { mIsRecyclableCount = recyclable ? mIsRecyclableCount - 1 : mIsRecyclableCount + 1; if (mIsRecyclableCount < 0) { mIsRecyclableCount = 0; if (DEBUG) { throw new RuntimeException("isRecyclable decremented below 0: " + "unmatched pair of setIsRecyable() calls for " + this); } Log.e(VIEW_LOG_TAG, "isRecyclable decremented below 0: " + "unmatched pair of setIsRecyable() calls for " + this); } else if (!recyclable && mIsRecyclableCount == 1) { mFlags |= FLAG_NOT_RECYCLABLE; } else if (recyclable && mIsRecyclableCount == 0) { mFlags &= ~FLAG_NOT_RECYCLABLE; } if (DEBUG) { Log.d(TAG, "setIsRecyclable val:" + recyclable + ":" + this); } } /** * @return true if this item is available to be recycled, false otherwise. * * @see #setIsRecyclable(boolean) */ public final boolean isRecyclable() { return (mFlags & FLAG_NOT_RECYCLABLE) == 0 && !itemView.hasTransientState(); } /** * Returns whether we have animations referring to this view holder or not. * This is similar to isRecyclable flag but does not check transient state. */ private boolean shouldBeKeptAsChild() { return (mFlags & FLAG_NOT_RECYCLABLE) != 0; } /** * @return True if ViewHolder is not referenced by RecyclerView animations but has * transient state which will prevent it from being recycled. */ private boolean doesTransientStatePreventRecycling() { return (mFlags & FLAG_NOT_RECYCLABLE) == 0 && itemView.hasTransientState(); } boolean isUpdated() { return (mFlags & FLAG_UPDATE) != 0; } } /** * This method is here so that we can control the important for a11y changes and test it. */ @VisibleForTesting boolean setChildImportantForAccessibilityInternal(ViewHolder viewHolder, int importantForAccessibility) { if (isComputingLayout()) { viewHolder.mPendingAccessibilityState = importantForAccessibility; mPendingAccessibilityImportanceChange.add(viewHolder); return false; } viewHolder.itemView.setImportantForAccessibility(importantForAccessibility); return true; } void dispatchPendingImportantForAccessibilityChanges() { for (int i = mPendingAccessibilityImportanceChange.size() - 1; i >= 0; i--) { ViewHolder viewHolder = mPendingAccessibilityImportanceChange.get(i); if (viewHolder.itemView.getParent() != this || viewHolder.shouldIgnore()) { continue; } int state = viewHolder.mPendingAccessibilityState; if (state != ViewHolder.PENDING_ACCESSIBILITY_STATE_NOT_SET) { //noinspection WrongConstant viewHolder.itemView.setImportantForAccessibility(state); viewHolder.mPendingAccessibilityState = ViewHolder.PENDING_ACCESSIBILITY_STATE_NOT_SET; } } mPendingAccessibilityImportanceChange.clear(); } int getAdapterPositionFor(ViewHolder viewHolder) { if (viewHolder.hasAnyOfTheFlags(ViewHolder.FLAG_INVALID | ViewHolder.FLAG_REMOVED | ViewHolder.FLAG_ADAPTER_POSITION_UNKNOWN) || !viewHolder.isBound()) { return RecyclerView.NO_POSITION; } return mAdapterHelper.applyPendingUpdatesToPosition(viewHolder.mPosition); } /** * {@link android.view.ViewGroup.MarginLayoutParams LayoutParams} subclass for children of * {@link RecyclerView}. Custom {@link LayoutManager layout managers} are encouraged * to create their own subclass of this LayoutParams class * to store any additional required per-child view metadata about the layout. */ public static class LayoutParams extends android.view.ViewGroup.MarginLayoutParams { ViewHolder mViewHolder; final Rect mDecorInsets = new Rect(); boolean mInsetsDirty = true; // Flag is set to true if the view is bound while it is detached from RV. // In this case, we need to manually call invalidate after view is added to guarantee that // invalidation is populated through the View hierarchy boolean mPendingInvalidate = false; public LayoutParams(Context c, AttributeSet attrs) { super(c, attrs); } public LayoutParams(int width, int height) { super(width, height); } public LayoutParams(MarginLayoutParams source) { super(source); } public LayoutParams(ViewGroup.LayoutParams source) { super(source); } public LayoutParams(LayoutParams source) { super((ViewGroup.LayoutParams) source); } /** * Returns true if the view this LayoutParams is attached to needs to have its content * updated from the corresponding adapter. * * @return true if the view should have its content updated */ public boolean viewNeedsUpdate() { return mViewHolder.needsUpdate(); } /** * Returns true if the view this LayoutParams is attached to is now representing * potentially invalid data. A LayoutManager should scrap/recycle it. * * @return true if the view is invalid */ public boolean isViewInvalid() { return mViewHolder.isInvalid(); } /** * Returns true if the adapter data item corresponding to the view this LayoutParams * is attached to has been removed from the data set. A LayoutManager may choose to * treat it differently in order to animate its outgoing or disappearing state. * * @return true if the item the view corresponds to was removed from the data set */ public boolean isItemRemoved() { return mViewHolder.isRemoved(); } /** * Returns true if the adapter data item corresponding to the view this LayoutParams * is attached to has been changed in the data set. A LayoutManager may choose to * treat it differently in order to animate its changing state. * * @return true if the item the view corresponds to was changed in the data set */ public boolean isItemChanged() { return mViewHolder.isUpdated(); } /** * @deprecated use {@link #getViewLayoutPosition()} or {@link #getViewAdapterPosition()} */ @Deprecated public int getViewPosition() { return mViewHolder.getPosition(); } /** * Returns the adapter position that the view this LayoutParams is attached to corresponds * to as of latest layout calculation. * * @return the adapter position this view as of latest layout pass */ public int getViewLayoutPosition() { return mViewHolder.getLayoutPosition(); } /** * Returns the up-to-date adapter position that the view this LayoutParams is attached to * corresponds to. * * @return the up-to-date adapter position this view. It may return * {@link RecyclerView#NO_POSITION} if item represented by this View has been removed or * its up-to-date position cannot be calculated. */ public int getViewAdapterPosition() { return mViewHolder.getAdapterPosition(); } } /** * Observer base class for watching changes to an {@link Adapter}. * See {@link Adapter#registerAdapterDataObserver(AdapterDataObserver)}. */ public abstract static class AdapterDataObserver { public void onChanged() { // Do nothing } public void onItemRangeChanged(int positionStart, int itemCount) { // do nothing } public void onItemRangeChanged(int positionStart, int itemCount, Object payload) { // fallback to onItemRangeChanged(positionStart, itemCount) if app // does not override this method. onItemRangeChanged(positionStart, itemCount); } public void onItemRangeInserted(int positionStart, int itemCount) { // do nothing } public void onItemRangeRemoved(int positionStart, int itemCount) { // do nothing } public void onItemRangeMoved(int fromPosition, int toPosition, int itemCount) { // do nothing } } /** *

Base class for smooth scrolling. Handles basic tracking of the target view position and * provides methods to trigger a programmatic scroll.

* * @see LinearSmoothScroller */ public abstract static class SmoothScroller { private int mTargetPosition = RecyclerView.NO_POSITION; private RecyclerView mRecyclerView; private LayoutManager mLayoutManager; private boolean mPendingInitialRun; private boolean mRunning; private View mTargetView; private final Action mRecyclingAction; public SmoothScroller() { mRecyclingAction = new Action(0, 0); } /** * Starts a smooth scroll for the given target position. *

In each animation step, {@link RecyclerView} will check * for the target view and call either * {@link #onTargetFound(android.view.View, RecyclerView.State, SmoothScroller.Action)} or * {@link #onSeekTargetStep(int, int, RecyclerView.State, SmoothScroller.Action)} until * SmoothScroller is stopped.

* *

Note that if RecyclerView finds the target view, it will automatically stop the * SmoothScroller. This does not mean that scroll will stop, it only means it will * stop calling SmoothScroller in each animation step.

*/ void start(RecyclerView recyclerView, LayoutManager layoutManager) { mRecyclerView = recyclerView; mLayoutManager = layoutManager; if (mTargetPosition == RecyclerView.NO_POSITION) { throw new IllegalArgumentException("Invalid target position"); } mRecyclerView.mState.mTargetPosition = mTargetPosition; mRunning = true; mPendingInitialRun = true; mTargetView = findViewByPosition(getTargetPosition()); onStart(); mRecyclerView.mViewFlinger.postOnAnimation(); } public void setTargetPosition(int targetPosition) { mTargetPosition = targetPosition; } /** * @return The LayoutManager to which this SmoothScroller is attached. Will return * null after the SmoothScroller is stopped. */ @Nullable public LayoutManager getLayoutManager() { return mLayoutManager; } /** * Stops running the SmoothScroller in each animation callback. Note that this does not * cancel any existing {@link Action} updated by * {@link #onTargetFound(android.view.View, RecyclerView.State, SmoothScroller.Action)} or * {@link #onSeekTargetStep(int, int, RecyclerView.State, SmoothScroller.Action)}. */ protected final void stop() { if (!mRunning) { return; } onStop(); mRecyclerView.mState.mTargetPosition = RecyclerView.NO_POSITION; mTargetView = null; mTargetPosition = RecyclerView.NO_POSITION; mPendingInitialRun = false; mRunning = false; // trigger a cleanup mLayoutManager.onSmoothScrollerStopped(this); // clear references to avoid any potential leak by a custom smooth scroller mLayoutManager = null; mRecyclerView = null; } /** * Returns true if SmoothScroller has been started but has not received the first * animation * callback yet. * * @return True if this SmoothScroller is waiting to start */ public boolean isPendingInitialRun() { return mPendingInitialRun; } /** * @return True if SmoothScroller is currently active */ public boolean isRunning() { return mRunning; } /** * Returns the adapter position of the target item * * @return Adapter position of the target item or * {@link RecyclerView#NO_POSITION} if no target view is set. */ public int getTargetPosition() { return mTargetPosition; } private void onAnimation(int dx, int dy) { final RecyclerView recyclerView = mRecyclerView; if (!mRunning || mTargetPosition == RecyclerView.NO_POSITION || recyclerView == null) { stop(); } mPendingInitialRun = false; if (mTargetView != null) { // verify target position if (getChildPosition(mTargetView) == mTargetPosition) { onTargetFound(mTargetView, recyclerView.mState, mRecyclingAction); mRecyclingAction.runIfNecessary(recyclerView); stop(); } else { Log.e(TAG, "Passed over target position while smooth scrolling."); mTargetView = null; } } if (mRunning) { onSeekTargetStep(dx, dy, recyclerView.mState, mRecyclingAction); boolean hadJumpTarget = mRecyclingAction.hasJumpTarget(); mRecyclingAction.runIfNecessary(recyclerView); if (hadJumpTarget) { // It is not stopped so needs to be restarted if (mRunning) { mPendingInitialRun = true; recyclerView.mViewFlinger.postOnAnimation(); } else { stop(); // done } } } } /** * @see RecyclerView#getChildLayoutPosition(android.view.View) */ public int getChildPosition(View view) { return mRecyclerView.getChildLayoutPosition(view); } /** * @see RecyclerView.LayoutManager#getChildCount() */ public int getChildCount() { return mRecyclerView.mLayout.getChildCount(); } /** * @see RecyclerView.LayoutManager#findViewByPosition(int) */ public View findViewByPosition(int position) { return mRecyclerView.mLayout.findViewByPosition(position); } /** * @see RecyclerView#scrollToPosition(int) * @deprecated Use {@link Action#jumpTo(int)}. */ @Deprecated public void instantScrollToPosition(int position) { mRecyclerView.scrollToPosition(position); } protected void onChildAttachedToWindow(View child) { if (getChildPosition(child) == getTargetPosition()) { mTargetView = child; if (DEBUG) { Log.d(TAG, "smooth scroll target view has been attached"); } } } /** * Normalizes the vector. * @param scrollVector The vector that points to the target scroll position */ protected void normalize(PointF scrollVector) { final double magnitude = Math.sqrt(scrollVector.x * scrollVector.x + scrollVector.y * scrollVector.y); scrollVector.x /= magnitude; scrollVector.y /= magnitude; } /** * Called when smooth scroll is started. This might be a good time to do setup. */ protected abstract void onStart(); /** * Called when smooth scroller is stopped. This is a good place to cleanup your state etc. * @see #stop() */ protected abstract void onStop(); /** *

RecyclerView will call this method each time it scrolls until it can find the target * position in the layout.

*

SmoothScroller should check dx, dy and if scroll should be changed, update the * provided {@link Action} to define the next scroll.

* * @param dx Last scroll amount horizontally * @param dy Last scroll amount vertically * @param state Transient state of RecyclerView * @param action If you want to trigger a new smooth scroll and cancel the previous one, * update this object. */ protected abstract void onSeekTargetStep(int dx, int dy, State state, Action action); /** * Called when the target position is laid out. This is the last callback SmoothScroller * will receive and it should update the provided {@link Action} to define the scroll * details towards the target view. * @param targetView The view element which render the target position. * @param state Transient state of RecyclerView * @param action Action instance that you should update to define final scroll action * towards the targetView */ protected abstract void onTargetFound(View targetView, State state, Action action); /** * Holds information about a smooth scroll request by a {@link SmoothScroller}. */ public static class Action { public static final int UNDEFINED_DURATION = Integer.MIN_VALUE; private int mDx; private int mDy; private int mDuration; private int mJumpToPosition = NO_POSITION; private Interpolator mInterpolator; private boolean mChanged = false; // we track this variable to inform custom implementer if they are updating the action // in every animation callback private int mConsecutiveUpdates = 0; /** * @param dx Pixels to scroll horizontally * @param dy Pixels to scroll vertically */ public Action(int dx, int dy) { this(dx, dy, UNDEFINED_DURATION, null); } /** * @param dx Pixels to scroll horizontally * @param dy Pixels to scroll vertically * @param duration Duration of the animation in milliseconds */ public Action(int dx, int dy, int duration) { this(dx, dy, duration, null); } /** * @param dx Pixels to scroll horizontally * @param dy Pixels to scroll vertically * @param duration Duration of the animation in milliseconds * @param interpolator Interpolator to be used when calculating scroll position in each * animation step */ public Action(int dx, int dy, int duration, Interpolator interpolator) { mDx = dx; mDy = dy; mDuration = duration; mInterpolator = interpolator; } /** * Instead of specifying pixels to scroll, use the target position to jump using * {@link RecyclerView#scrollToPosition(int)}. *

* You may prefer using this method if scroll target is really far away and you prefer * to jump to a location and smooth scroll afterwards. *

* Note that calling this method takes priority over other update methods such as * {@link #update(int, int, int, Interpolator)}, {@link #setX(float)}, * {@link #setY(float)} and #{@link #setInterpolator(Interpolator)}. If you call * {@link #jumpTo(int)}, the other changes will not be considered for this animation * frame. * * @param targetPosition The target item position to scroll to using instant scrolling. */ public void jumpTo(int targetPosition) { mJumpToPosition = targetPosition; } boolean hasJumpTarget() { return mJumpToPosition >= 0; } void runIfNecessary(RecyclerView recyclerView) { if (mJumpToPosition >= 0) { final int position = mJumpToPosition; mJumpToPosition = NO_POSITION; recyclerView.jumpToPositionForSmoothScroller(position); mChanged = false; return; } if (mChanged) { validate(); if (mInterpolator == null) { if (mDuration == UNDEFINED_DURATION) { recyclerView.mViewFlinger.smoothScrollBy(mDx, mDy); } else { recyclerView.mViewFlinger.smoothScrollBy(mDx, mDy, mDuration); } } else { recyclerView.mViewFlinger.smoothScrollBy( mDx, mDy, mDuration, mInterpolator); } mConsecutiveUpdates++; if (mConsecutiveUpdates > 10) { // A new action is being set in every animation step. This looks like a bad // implementation. Inform developer. Log.e(TAG, "Smooth Scroll action is being updated too frequently. Make sure" + " you are not changing it unless necessary"); } mChanged = false; } else { mConsecutiveUpdates = 0; } } private void validate() { if (mInterpolator != null && mDuration < 1) { throw new IllegalStateException("If you provide an interpolator, you must" + " set a positive duration"); } else if (mDuration < 1) { throw new IllegalStateException("Scroll duration must be a positive number"); } } public int getDx() { return mDx; } public void setDx(int dx) { mChanged = true; mDx = dx; } public int getDy() { return mDy; } public void setDy(int dy) { mChanged = true; mDy = dy; } public int getDuration() { return mDuration; } public void setDuration(int duration) { mChanged = true; mDuration = duration; } public Interpolator getInterpolator() { return mInterpolator; } /** * Sets the interpolator to calculate scroll steps * @param interpolator The interpolator to use. If you specify an interpolator, you must * also set the duration. * @see #setDuration(int) */ public void setInterpolator(Interpolator interpolator) { mChanged = true; mInterpolator = interpolator; } /** * Updates the action with given parameters. * @param dx Pixels to scroll horizontally * @param dy Pixels to scroll vertically * @param duration Duration of the animation in milliseconds * @param interpolator Interpolator to be used when calculating scroll position in each * animation step */ public void update(int dx, int dy, int duration, Interpolator interpolator) { mDx = dx; mDy = dy; mDuration = duration; mInterpolator = interpolator; mChanged = true; } } /** * An interface which is optionally implemented by custom {@link RecyclerView.LayoutManager} * to provide a hint to a {@link SmoothScroller} about the location of the target position. */ public interface ScrollVectorProvider { /** * Should calculate the vector that points to the direction where the target position * can be found. *

* This method is used by the {@link LinearSmoothScroller} to initiate a scroll towards * the target position. *

* The magnitude of the vector is not important. It is always normalized before being * used by the {@link LinearSmoothScroller}. *

* LayoutManager should not check whether the position exists in the adapter or not. * * @param targetPosition the target position to which the returned vector should point * * @return the scroll vector for a given position. */ PointF computeScrollVectorForPosition(int targetPosition); } } static class AdapterDataObservable extends Observable { public boolean hasObservers() { return !mObservers.isEmpty(); } public void notifyChanged() { // since onChanged() is implemented by the app, it could do anything, including // removing itself from {@link mObservers} - and that could cause problems if // an iterator is used on the ArrayList {@link mObservers}. // to avoid such problems, just march thru the list in the reverse order. for (int i = mObservers.size() - 1; i >= 0; i--) { mObservers.get(i).onChanged(); } } public void notifyItemRangeChanged(int positionStart, int itemCount) { notifyItemRangeChanged(positionStart, itemCount, null); } public void notifyItemRangeChanged(int positionStart, int itemCount, Object payload) { // since onItemRangeChanged() is implemented by the app, it could do anything, including // removing itself from {@link mObservers} - and that could cause problems if // an iterator is used on the ArrayList {@link mObservers}. // to avoid such problems, just march thru the list in the reverse order. for (int i = mObservers.size() - 1; i >= 0; i--) { mObservers.get(i).onItemRangeChanged(positionStart, itemCount, payload); } } public void notifyItemRangeInserted(int positionStart, int itemCount) { // since onItemRangeInserted() is implemented by the app, it could do anything, // including removing itself from {@link mObservers} - and that could cause problems if // an iterator is used on the ArrayList {@link mObservers}. // to avoid such problems, just march thru the list in the reverse order. for (int i = mObservers.size() - 1; i >= 0; i--) { mObservers.get(i).onItemRangeInserted(positionStart, itemCount); } } public void notifyItemRangeRemoved(int positionStart, int itemCount) { // since onItemRangeRemoved() is implemented by the app, it could do anything, including // removing itself from {@link mObservers} - and that could cause problems if // an iterator is used on the ArrayList {@link mObservers}. // to avoid such problems, just march thru the list in the reverse order. for (int i = mObservers.size() - 1; i >= 0; i--) { mObservers.get(i).onItemRangeRemoved(positionStart, itemCount); } } public void notifyItemMoved(int fromPosition, int toPosition) { for (int i = mObservers.size() - 1; i >= 0; i--) { mObservers.get(i).onItemRangeMoved(fromPosition, toPosition, 1); } } } /** * This is public so that the CREATOR can be access on cold launch. * @hide */ public static class SavedState extends AbsSavedState { Parcelable mLayoutState; /** * called by CREATOR */ SavedState(Parcel in) { super(in); mLayoutState = in.readParcelable(LayoutManager.class.getClassLoader()); } /** * Called by onSaveInstanceState */ SavedState(Parcelable superState) { super(superState); } @Override public void writeToParcel(Parcel dest, int flags) { super.writeToParcel(dest, flags); dest.writeParcelable(mLayoutState, 0); } void copyFrom(SavedState other) { mLayoutState = other.mLayoutState; } public static final Parcelable.Creator CREATOR = new Parcelable.Creator() { @Override public SavedState createFromParcel(Parcel in) { return new SavedState(in); } @Override public SavedState[] newArray(int size) { return new SavedState[size]; } }; } /** *

Contains useful information about the current RecyclerView state like target scroll * position or view focus. State object can also keep arbitrary data, identified by resource * ids.

*

Often times, RecyclerView components will need to pass information between each other. * To provide a well defined data bus between components, RecyclerView passes the same State * object to component callbacks and these components can use it to exchange data.

*

If you implement custom components, you can use State's put/get/remove methods to pass * data between your components without needing to manage their lifecycles.

*/ public static class State { static final int STEP_START = 1; static final int STEP_LAYOUT = 1 << 1; static final int STEP_ANIMATIONS = 1 << 2; void assertLayoutStep(int accepted) { if ((accepted & mLayoutStep) == 0) { throw new IllegalStateException("Layout state should be one of " + Integer.toBinaryString(accepted) + " but it is " + Integer.toBinaryString(mLayoutStep)); } } /** Owned by SmoothScroller */ private int mTargetPosition = RecyclerView.NO_POSITION; private SparseArray mData; //////////////////////////////////////////////////////////////////////////////////////////// // Fields below are carried from one layout pass to the next //////////////////////////////////////////////////////////////////////////////////////////// /** * Number of items adapter had in the previous layout. */ int mPreviousLayoutItemCount = 0; /** * Number of items that were NOT laid out but has been deleted from the adapter after the * previous layout. */ int mDeletedInvisibleItemCountSincePreviousLayout = 0; //////////////////////////////////////////////////////////////////////////////////////////// // Fields below must be updated or cleared before they are used (generally before a pass) //////////////////////////////////////////////////////////////////////////////////////////// @IntDef(flag = true, value = { STEP_START, STEP_LAYOUT, STEP_ANIMATIONS }) @Retention(RetentionPolicy.SOURCE) @interface LayoutState {} @LayoutState int mLayoutStep = STEP_START; /** * Number of items adapter has. */ int mItemCount = 0; boolean mStructureChanged = false; boolean mInPreLayout = false; boolean mTrackOldChangeHolders = false; boolean mIsMeasuring = false; //////////////////////////////////////////////////////////////////////////////////////////// // Fields below are always reset outside of the pass (or passes) that use them //////////////////////////////////////////////////////////////////////////////////////////// boolean mRunSimpleAnimations = false; boolean mRunPredictiveAnimations = false; /** * This data is saved before a layout calculation happens. After the layout is finished, * if the previously focused view has been replaced with another view for the same item, we * move the focus to the new item automatically. */ int mFocusedItemPosition; long mFocusedItemId; // when a sub child has focus, record its id and see if we can directly request focus on // that one instead int mFocusedSubChildId; //////////////////////////////////////////////////////////////////////////////////////////// State reset() { mTargetPosition = RecyclerView.NO_POSITION; if (mData != null) { mData.clear(); } mItemCount = 0; mStructureChanged = false; mIsMeasuring = false; return this; } /** * Prepare for a prefetch occurring on the RecyclerView in between traversals, potentially * prior to any layout passes. * *

Don't touch any state stored between layout passes, only reset per-layout state, so * that Recycler#getViewForPosition() can function safely.

*/ void prepareForNestedPrefetch(Adapter adapter) { mLayoutStep = STEP_START; mItemCount = adapter.getItemCount(); mStructureChanged = false; mInPreLayout = false; mTrackOldChangeHolders = false; mIsMeasuring = false; } /** * Returns true if the RecyclerView is currently measuring the layout. This value is * {@code true} only if the LayoutManager opted into the auto measure API and RecyclerView * has non-exact measurement specs. *

* Note that if the LayoutManager supports predictive animations and it is calculating the * pre-layout step, this value will be {@code false} even if the RecyclerView is in * {@code onMeasure} call. This is because pre-layout means the previous state of the * RecyclerView and measurements made for that state cannot change the RecyclerView's size. * LayoutManager is always guaranteed to receive another call to * {@link LayoutManager#onLayoutChildren(Recycler, State)} when this happens. * * @return True if the RecyclerView is currently calculating its bounds, false otherwise. */ public boolean isMeasuring() { return mIsMeasuring; } /** * Returns true if * @return */ public boolean isPreLayout() { return mInPreLayout; } /** * Returns whether RecyclerView will run predictive animations in this layout pass * or not. * * @return true if RecyclerView is calculating predictive animations to be run at the end * of the layout pass. */ public boolean willRunPredictiveAnimations() { return mRunPredictiveAnimations; } /** * Returns whether RecyclerView will run simple animations in this layout pass * or not. * * @return true if RecyclerView is calculating simple animations to be run at the end of * the layout pass. */ public boolean willRunSimpleAnimations() { return mRunSimpleAnimations; } /** * Removes the mapping from the specified id, if there was any. * @param resourceId Id of the resource you want to remove. It is suggested to use R.id.* to * preserve cross functionality and avoid conflicts. */ public void remove(int resourceId) { if (mData == null) { return; } mData.remove(resourceId); } /** * Gets the Object mapped from the specified id, or null * if no such data exists. * * @param resourceId Id of the resource you want to remove. It is suggested to use R.id.* * to * preserve cross functionality and avoid conflicts. */ public T get(int resourceId) { if (mData == null) { return null; } return (T) mData.get(resourceId); } /** * Adds a mapping from the specified id to the specified value, replacing the previous * mapping from the specified key if there was one. * * @param resourceId Id of the resource you want to add. It is suggested to use R.id.* to * preserve cross functionality and avoid conflicts. * @param data The data you want to associate with the resourceId. */ public void put(int resourceId, Object data) { if (mData == null) { mData = new SparseArray(); } mData.put(resourceId, data); } /** * If scroll is triggered to make a certain item visible, this value will return the * adapter index of that item. * @return Adapter index of the target item or * {@link RecyclerView#NO_POSITION} if there is no target * position. */ public int getTargetScrollPosition() { return mTargetPosition; } /** * Returns if current scroll has a target position. * @return true if scroll is being triggered to make a certain position visible * @see #getTargetScrollPosition() */ public boolean hasTargetScrollPosition() { return mTargetPosition != RecyclerView.NO_POSITION; } /** * @return true if the structure of the data set has changed since the last call to * onLayoutChildren, false otherwise */ public boolean didStructureChange() { return mStructureChanged; } /** * Returns the total number of items that can be laid out. Note that this number is not * necessarily equal to the number of items in the adapter, so you should always use this * number for your position calculations and never access the adapter directly. *

* RecyclerView listens for Adapter's notify events and calculates the effects of adapter * data changes on existing Views. These calculations are used to decide which animations * should be run. *

* To support predictive animations, RecyclerView may rewrite or reorder Adapter changes to * present the correct state to LayoutManager in pre-layout pass. *

* For example, a newly added item is not included in pre-layout item count because * pre-layout reflects the contents of the adapter before the item is added. Behind the * scenes, RecyclerView offsets {@link Recycler#getViewForPosition(int)} calls such that * LayoutManager does not know about the new item's existence in pre-layout. The item will * be available in second layout pass and will be included in the item count. Similar * adjustments are made for moved and removed items as well. *

* You can get the adapter's item count via {@link LayoutManager#getItemCount()} method. * * @return The number of items currently available * @see LayoutManager#getItemCount() */ public int getItemCount() { return mInPreLayout ? (mPreviousLayoutItemCount - mDeletedInvisibleItemCountSincePreviousLayout) : mItemCount; } @Override public String toString() { return "State{" + "mTargetPosition=" + mTargetPosition + ", mData=" + mData + ", mItemCount=" + mItemCount + ", mPreviousLayoutItemCount=" + mPreviousLayoutItemCount + ", mDeletedInvisibleItemCountSincePreviousLayout=" + mDeletedInvisibleItemCountSincePreviousLayout + ", mStructureChanged=" + mStructureChanged + ", mInPreLayout=" + mInPreLayout + ", mRunSimpleAnimations=" + mRunSimpleAnimations + ", mRunPredictiveAnimations=" + mRunPredictiveAnimations + '}'; } } /** * This class defines the behavior of fling if the developer wishes to handle it. *

* Subclasses of {@link OnFlingListener} can be used to implement custom fling behavior. * * @see #setOnFlingListener(OnFlingListener) */ public abstract static class OnFlingListener { /** * Override this to handle a fling given the velocities in both x and y directions. * Note that this method will only be called if the associated {@link LayoutManager} * supports scrolling and the fling is not handled by nested scrolls first. * * @param velocityX the fling velocity on the X axis * @param velocityY the fling velocity on the Y axis * * @return true if the fling washandled, false otherwise. */ public abstract boolean onFling(int velocityX, int velocityY); } /** * Internal listener that manages items after animations finish. This is how items are * retained (not recycled) during animations, but allowed to be recycled afterwards. * It depends on the contract with the ItemAnimator to call the appropriate dispatch*Finished() * method on the animator's listener when it is done animating any item. */ private class ItemAnimatorRestoreListener implements ItemAnimator.ItemAnimatorListener { ItemAnimatorRestoreListener() { } @Override public void onAnimationFinished(ViewHolder item) { item.setIsRecyclable(true); if (item.mShadowedHolder != null && item.mShadowingHolder == null) { // old vh item.mShadowedHolder = null; } // always null this because an OldViewHolder can never become NewViewHolder w/o being // recycled. item.mShadowingHolder = null; if (!item.shouldBeKeptAsChild()) { if (!removeAnimatingView(item.itemView) && item.isTmpDetached()) { removeDetachedView(item.itemView, false); } } } } /** * This class defines the animations that take place on items as changes are made * to the adapter. * * Subclasses of ItemAnimator can be used to implement custom animations for actions on * ViewHolder items. The RecyclerView will manage retaining these items while they * are being animated, but implementors must call {@link #dispatchAnimationFinished(ViewHolder)} * when a ViewHolder's animation is finished. In other words, there must be a matching * {@link #dispatchAnimationFinished(ViewHolder)} call for each * {@link #animateAppearance(ViewHolder, ItemHolderInfo, ItemHolderInfo) animateAppearance()}, * {@link #animateChange(ViewHolder, ViewHolder, ItemHolderInfo, ItemHolderInfo) * animateChange()} * {@link #animatePersistence(ViewHolder, ItemHolderInfo, ItemHolderInfo) animatePersistence()}, * and * {@link #animateDisappearance(ViewHolder, ItemHolderInfo, ItemHolderInfo) * animateDisappearance()} call. * *

By default, RecyclerView uses {@link DefaultItemAnimator}.

* * @see #setItemAnimator(ItemAnimator) */ @SuppressWarnings("UnusedParameters") public abstract static class ItemAnimator { /** * The Item represented by this ViewHolder is updated. *

* @see #recordPreLayoutInformation(State, ViewHolder, int, List) */ public static final int FLAG_CHANGED = ViewHolder.FLAG_UPDATE; /** * The Item represented by this ViewHolder is removed from the adapter. *

* @see #recordPreLayoutInformation(State, ViewHolder, int, List) */ public static final int FLAG_REMOVED = ViewHolder.FLAG_REMOVED; /** * Adapter {@link Adapter#notifyDataSetChanged()} has been called and the content * represented by this ViewHolder is invalid. *

* @see #recordPreLayoutInformation(State, ViewHolder, int, List) */ public static final int FLAG_INVALIDATED = ViewHolder.FLAG_INVALID; /** * The position of the Item represented by this ViewHolder has been changed. This flag is * not bound to {@link Adapter#notifyItemMoved(int, int)}. It might be set in response to * any adapter change that may have a side effect on this item. (e.g. The item before this * one has been removed from the Adapter). *

* @see #recordPreLayoutInformation(State, ViewHolder, int, List) */ public static final int FLAG_MOVED = ViewHolder.FLAG_MOVED; /** * This ViewHolder was not laid out but has been added to the layout in pre-layout state * by the {@link LayoutManager}. This means that the item was already in the Adapter but * invisible and it may become visible in the post layout phase. LayoutManagers may prefer * to add new items in pre-layout to specify their virtual location when they are invisible * (e.g. to specify the item should animate in from below the visible area). *

* @see #recordPreLayoutInformation(State, ViewHolder, int, List) */ public static final int FLAG_APPEARED_IN_PRE_LAYOUT = ViewHolder.FLAG_APPEARED_IN_PRE_LAYOUT; /** * The set of flags that might be passed to * {@link #recordPreLayoutInformation(State, ViewHolder, int, List)}. */ @IntDef(flag = true, value = { FLAG_CHANGED, FLAG_REMOVED, FLAG_MOVED, FLAG_INVALIDATED, FLAG_APPEARED_IN_PRE_LAYOUT }) @Retention(RetentionPolicy.SOURCE) public @interface AdapterChanges {} private ItemAnimatorListener mListener = null; private ArrayList mFinishedListeners = new ArrayList(); private long mAddDuration = 120; private long mRemoveDuration = 120; private long mMoveDuration = 250; private long mChangeDuration = 250; /** * Gets the current duration for which all move animations will run. * * @return The current move duration */ public long getMoveDuration() { return mMoveDuration; } /** * Sets the duration for which all move animations will run. * * @param moveDuration The move duration */ public void setMoveDuration(long moveDuration) { mMoveDuration = moveDuration; } /** * Gets the current duration for which all add animations will run. * * @return The current add duration */ public long getAddDuration() { return mAddDuration; } /** * Sets the duration for which all add animations will run. * * @param addDuration The add duration */ public void setAddDuration(long addDuration) { mAddDuration = addDuration; } /** * Gets the current duration for which all remove animations will run. * * @return The current remove duration */ public long getRemoveDuration() { return mRemoveDuration; } /** * Sets the duration for which all remove animations will run. * * @param removeDuration The remove duration */ public void setRemoveDuration(long removeDuration) { mRemoveDuration = removeDuration; } /** * Gets the current duration for which all change animations will run. * * @return The current change duration */ public long getChangeDuration() { return mChangeDuration; } /** * Sets the duration for which all change animations will run. * * @param changeDuration The change duration */ public void setChangeDuration(long changeDuration) { mChangeDuration = changeDuration; } /** * Internal only: * Sets the listener that must be called when the animator is finished * animating the item (or immediately if no animation happens). This is set * internally and is not intended to be set by external code. * * @param listener The listener that must be called. */ void setListener(ItemAnimatorListener listener) { mListener = listener; } /** * Called by the RecyclerView before the layout begins. Item animator should record * necessary information about the View before it is potentially rebound, moved or removed. *

* The data returned from this method will be passed to the related animate** * methods. *

* Note that this method may be called after pre-layout phase if LayoutManager adds new * Views to the layout in pre-layout pass. *

* The default implementation returns an {@link ItemHolderInfo} which holds the bounds of * the View and the adapter change flags. * * @param state The current State of RecyclerView which includes some useful data * about the layout that will be calculated. * @param viewHolder The ViewHolder whose information should be recorded. * @param changeFlags Additional information about what changes happened in the Adapter * about the Item represented by this ViewHolder. For instance, if * item is deleted from the adapter, {@link #FLAG_REMOVED} will be set. * @param payloads The payload list that was previously passed to * {@link Adapter#notifyItemChanged(int, Object)} or * {@link Adapter#notifyItemRangeChanged(int, int, Object)}. * * @return An ItemHolderInfo instance that preserves necessary information about the * ViewHolder. This object will be passed back to related animate** methods * after layout is complete. * * @see #recordPostLayoutInformation(State, ViewHolder) * @see #animateAppearance(ViewHolder, ItemHolderInfo, ItemHolderInfo) * @see #animateDisappearance(ViewHolder, ItemHolderInfo, ItemHolderInfo) * @see #animateChange(ViewHolder, ViewHolder, ItemHolderInfo, ItemHolderInfo) * @see #animatePersistence(ViewHolder, ItemHolderInfo, ItemHolderInfo) */ public @NonNull ItemHolderInfo recordPreLayoutInformation(@NonNull State state, @NonNull ViewHolder viewHolder, @AdapterChanges int changeFlags, @NonNull List payloads) { return obtainHolderInfo().setFrom(viewHolder); } /** * Called by the RecyclerView after the layout is complete. Item animator should record * necessary information about the View's final state. *

* The data returned from this method will be passed to the related animate** * methods. *

* The default implementation returns an {@link ItemHolderInfo} which holds the bounds of * the View. * * @param state The current State of RecyclerView which includes some useful data about * the layout that will be calculated. * @param viewHolder The ViewHolder whose information should be recorded. * * @return An ItemHolderInfo that preserves necessary information about the ViewHolder. * This object will be passed back to related animate** methods when * RecyclerView decides how items should be animated. * * @see #recordPreLayoutInformation(State, ViewHolder, int, List) * @see #animateAppearance(ViewHolder, ItemHolderInfo, ItemHolderInfo) * @see #animateDisappearance(ViewHolder, ItemHolderInfo, ItemHolderInfo) * @see #animateChange(ViewHolder, ViewHolder, ItemHolderInfo, ItemHolderInfo) * @see #animatePersistence(ViewHolder, ItemHolderInfo, ItemHolderInfo) */ public @NonNull ItemHolderInfo recordPostLayoutInformation(@NonNull State state, @NonNull ViewHolder viewHolder) { return obtainHolderInfo().setFrom(viewHolder); } /** * Called by the RecyclerView when a ViewHolder has disappeared from the layout. *

* This means that the View was a child of the LayoutManager when layout started but has * been removed by the LayoutManager. It might have been removed from the adapter or simply * become invisible due to other factors. You can distinguish these two cases by checking * the change flags that were passed to * {@link #recordPreLayoutInformation(State, ViewHolder, int, List)}. *

* Note that when a ViewHolder both changes and disappears in the same layout pass, the * animation callback method which will be called by the RecyclerView depends on the * ItemAnimator's decision whether to re-use the same ViewHolder or not, and also the * LayoutManager's decision whether to layout the changed version of a disappearing * ViewHolder or not. RecyclerView will call * {@link #animateChange(ViewHolder, ViewHolder, ItemHolderInfo, ItemHolderInfo) * animateChange} instead of {@code animateDisappearance} if and only if the ItemAnimator * returns {@code false} from * {@link #canReuseUpdatedViewHolder(ViewHolder) canReuseUpdatedViewHolder} and the * LayoutManager lays out a new disappearing view that holds the updated information. * Built-in LayoutManagers try to avoid laying out updated versions of disappearing views. *

* If LayoutManager supports predictive animations, it might provide a target disappear * location for the View by laying it out in that location. When that happens, * RecyclerView will call {@link #recordPostLayoutInformation(State, ViewHolder)} and the * response of that call will be passed to this method as the postLayoutInfo. *

* ItemAnimator must call {@link #dispatchAnimationFinished(ViewHolder)} when the animation * is complete (or instantly call {@link #dispatchAnimationFinished(ViewHolder)} if it * decides not to animate the view). * * @param viewHolder The ViewHolder which should be animated * @param preLayoutInfo The information that was returned from * {@link #recordPreLayoutInformation(State, ViewHolder, int, List)}. * @param postLayoutInfo The information that was returned from * {@link #recordPostLayoutInformation(State, ViewHolder)}. Might be * null if the LayoutManager did not layout the item. * * @return true if a later call to {@link #runPendingAnimations()} is requested, * false otherwise. */ public abstract boolean animateDisappearance(@NonNull ViewHolder viewHolder, @NonNull ItemHolderInfo preLayoutInfo, @Nullable ItemHolderInfo postLayoutInfo); /** * Called by the RecyclerView when a ViewHolder is added to the layout. *

* In detail, this means that the ViewHolder was not a child when the layout started * but has been added by the LayoutManager. It might be newly added to the adapter or * simply become visible due to other factors. *

* ItemAnimator must call {@link #dispatchAnimationFinished(ViewHolder)} when the animation * is complete (or instantly call {@link #dispatchAnimationFinished(ViewHolder)} if it * decides not to animate the view). * * @param viewHolder The ViewHolder which should be animated * @param preLayoutInfo The information that was returned from * {@link #recordPreLayoutInformation(State, ViewHolder, int, List)}. * Might be null if Item was just added to the adapter or * LayoutManager does not support predictive animations or it could * not predict that this ViewHolder will become visible. * @param postLayoutInfo The information that was returned from {@link * #recordPreLayoutInformation(State, ViewHolder, int, List)}. * * @return true if a later call to {@link #runPendingAnimations()} is requested, * false otherwise. */ public abstract boolean animateAppearance(@NonNull ViewHolder viewHolder, @Nullable ItemHolderInfo preLayoutInfo, @NonNull ItemHolderInfo postLayoutInfo); /** * Called by the RecyclerView when a ViewHolder is present in both before and after the * layout and RecyclerView has not received a {@link Adapter#notifyItemChanged(int)} call * for it or a {@link Adapter#notifyDataSetChanged()} call. *

* This ViewHolder still represents the same data that it was representing when the layout * started but its position / size may be changed by the LayoutManager. *

* If the Item's layout position didn't change, RecyclerView still calls this method because * it does not track this information (or does not necessarily know that an animation is * not required). Your ItemAnimator should handle this case and if there is nothing to * animate, it should call {@link #dispatchAnimationFinished(ViewHolder)} and return * false. *

* ItemAnimator must call {@link #dispatchAnimationFinished(ViewHolder)} when the animation * is complete (or instantly call {@link #dispatchAnimationFinished(ViewHolder)} if it * decides not to animate the view). * * @param viewHolder The ViewHolder which should be animated * @param preLayoutInfo The information that was returned from * {@link #recordPreLayoutInformation(State, ViewHolder, int, List)}. * @param postLayoutInfo The information that was returned from {@link * #recordPreLayoutInformation(State, ViewHolder, int, List)}. * * @return true if a later call to {@link #runPendingAnimations()} is requested, * false otherwise. */ public abstract boolean animatePersistence(@NonNull ViewHolder viewHolder, @NonNull ItemHolderInfo preLayoutInfo, @NonNull ItemHolderInfo postLayoutInfo); /** * Called by the RecyclerView when an adapter item is present both before and after the * layout and RecyclerView has received a {@link Adapter#notifyItemChanged(int)} call * for it. This method may also be called when * {@link Adapter#notifyDataSetChanged()} is called and adapter has stable ids so that * RecyclerView could still rebind views to the same ViewHolders. If viewType changes when * {@link Adapter#notifyDataSetChanged()} is called, this method will not be called, * instead, {@link #animateAppearance(ViewHolder, ItemHolderInfo, ItemHolderInfo)} will be * called for the new ViewHolder and the old one will be recycled. *

* If this method is called due to a {@link Adapter#notifyDataSetChanged()} call, there is * a good possibility that item contents didn't really change but it is rebound from the * adapter. {@link DefaultItemAnimator} will skip animating the View if its location on the * screen didn't change and your animator should handle this case as well and avoid creating * unnecessary animations. *

* When an item is updated, ItemAnimator has a chance to ask RecyclerView to keep the * previous presentation of the item as-is and supply a new ViewHolder for the updated * presentation (see: {@link #canReuseUpdatedViewHolder(ViewHolder, List)}. * This is useful if you don't know the contents of the Item and would like * to cross-fade the old and the new one ({@link DefaultItemAnimator} uses this technique). *

* When you are writing a custom item animator for your layout, it might be more performant * and elegant to re-use the same ViewHolder and animate the content changes manually. *

* When {@link Adapter#notifyItemChanged(int)} is called, the Item's view type may change. * If the Item's view type has changed or ItemAnimator returned false for * this ViewHolder when {@link #canReuseUpdatedViewHolder(ViewHolder, List)} was called, the * oldHolder and newHolder will be different ViewHolder instances * which represent the same Item. In that case, only the new ViewHolder is visible * to the LayoutManager but RecyclerView keeps old ViewHolder attached for animations. *

* ItemAnimator must call {@link #dispatchAnimationFinished(ViewHolder)} for each distinct * ViewHolder when their animation is complete * (or instantly call {@link #dispatchAnimationFinished(ViewHolder)} if it decides not to * animate the view). *

* If oldHolder and newHolder are the same instance, you should call * {@link #dispatchAnimationFinished(ViewHolder)} only once. *

* Note that when a ViewHolder both changes and disappears in the same layout pass, the * animation callback method which will be called by the RecyclerView depends on the * ItemAnimator's decision whether to re-use the same ViewHolder or not, and also the * LayoutManager's decision whether to layout the changed version of a disappearing * ViewHolder or not. RecyclerView will call * {@code animateChange} instead of * {@link #animateDisappearance(ViewHolder, ItemHolderInfo, ItemHolderInfo) * animateDisappearance} if and only if the ItemAnimator returns {@code false} from * {@link #canReuseUpdatedViewHolder(ViewHolder) canReuseUpdatedViewHolder} and the * LayoutManager lays out a new disappearing view that holds the updated information. * Built-in LayoutManagers try to avoid laying out updated versions of disappearing views. * * @param oldHolder The ViewHolder before the layout is started, might be the same * instance with newHolder. * @param newHolder The ViewHolder after the layout is finished, might be the same * instance with oldHolder. * @param preLayoutInfo The information that was returned from * {@link #recordPreLayoutInformation(State, ViewHolder, int, List)}. * @param postLayoutInfo The information that was returned from {@link * #recordPreLayoutInformation(State, ViewHolder, int, List)}. * * @return true if a later call to {@link #runPendingAnimations()} is requested, * false otherwise. */ public abstract boolean animateChange(@NonNull ViewHolder oldHolder, @NonNull ViewHolder newHolder, @NonNull ItemHolderInfo preLayoutInfo, @NonNull ItemHolderInfo postLayoutInfo); @AdapterChanges static int buildAdapterChangeFlagsForAnimations(ViewHolder viewHolder) { int flags = viewHolder.mFlags & (FLAG_INVALIDATED | FLAG_REMOVED | FLAG_CHANGED); if (viewHolder.isInvalid()) { return FLAG_INVALIDATED; } if ((flags & FLAG_INVALIDATED) == 0) { final int oldPos = viewHolder.getOldPosition(); final int pos = viewHolder.getAdapterPosition(); if (oldPos != NO_POSITION && pos != NO_POSITION && oldPos != pos) { flags |= FLAG_MOVED; } } return flags; } /** * Called when there are pending animations waiting to be started. This state * is governed by the return values from * {@link #animateAppearance(ViewHolder, ItemHolderInfo, ItemHolderInfo) * animateAppearance()}, * {@link #animateChange(ViewHolder, ViewHolder, ItemHolderInfo, ItemHolderInfo) * animateChange()} * {@link #animatePersistence(ViewHolder, ItemHolderInfo, ItemHolderInfo) * animatePersistence()}, and * {@link #animateDisappearance(ViewHolder, ItemHolderInfo, ItemHolderInfo) * animateDisappearance()}, which inform the RecyclerView that the ItemAnimator wants to be * called later to start the associated animations. runPendingAnimations() will be scheduled * to be run on the next frame. */ public abstract void runPendingAnimations(); /** * Method called when an animation on a view should be ended immediately. * This could happen when other events, like scrolling, occur, so that * animating views can be quickly put into their proper end locations. * Implementations should ensure that any animations running on the item * are canceled and affected properties are set to their end values. * Also, {@link #dispatchAnimationFinished(ViewHolder)} should be called for each finished * animation since the animations are effectively done when this method is called. * * @param item The item for which an animation should be stopped. */ public abstract void endAnimation(ViewHolder item); /** * Method called when all item animations should be ended immediately. * This could happen when other events, like scrolling, occur, so that * animating views can be quickly put into their proper end locations. * Implementations should ensure that any animations running on any items * are canceled and affected properties are set to their end values. * Also, {@link #dispatchAnimationFinished(ViewHolder)} should be called for each finished * animation since the animations are effectively done when this method is called. */ public abstract void endAnimations(); /** * Method which returns whether there are any item animations currently running. * This method can be used to determine whether to delay other actions until * animations end. * * @return true if there are any item animations currently running, false otherwise. */ public abstract boolean isRunning(); /** * Method to be called by subclasses when an animation is finished. *

* For each call RecyclerView makes to * {@link #animateAppearance(ViewHolder, ItemHolderInfo, ItemHolderInfo) * animateAppearance()}, * {@link #animatePersistence(ViewHolder, ItemHolderInfo, ItemHolderInfo) * animatePersistence()}, or * {@link #animateDisappearance(ViewHolder, ItemHolderInfo, ItemHolderInfo) * animateDisappearance()}, there * should * be a matching {@link #dispatchAnimationFinished(ViewHolder)} call by the subclass. *

* For {@link #animateChange(ViewHolder, ViewHolder, ItemHolderInfo, ItemHolderInfo) * animateChange()}, subclass should call this method for both the oldHolder * and newHolder (if they are not the same instance). * * @param viewHolder The ViewHolder whose animation is finished. * @see #onAnimationFinished(ViewHolder) */ public final void dispatchAnimationFinished(ViewHolder viewHolder) { onAnimationFinished(viewHolder); if (mListener != null) { mListener.onAnimationFinished(viewHolder); } } /** * Called after {@link #dispatchAnimationFinished(ViewHolder)} is called by the * ItemAnimator. * * @param viewHolder The ViewHolder whose animation is finished. There might still be other * animations running on this ViewHolder. * @see #dispatchAnimationFinished(ViewHolder) */ public void onAnimationFinished(ViewHolder viewHolder) { } /** * Method to be called by subclasses when an animation is started. *

* For each call RecyclerView makes to * {@link #animateAppearance(ViewHolder, ItemHolderInfo, ItemHolderInfo) * animateAppearance()}, * {@link #animatePersistence(ViewHolder, ItemHolderInfo, ItemHolderInfo) * animatePersistence()}, or * {@link #animateDisappearance(ViewHolder, ItemHolderInfo, ItemHolderInfo) * animateDisappearance()}, there should be a matching * {@link #dispatchAnimationStarted(ViewHolder)} call by the subclass. *

* For {@link #animateChange(ViewHolder, ViewHolder, ItemHolderInfo, ItemHolderInfo) * animateChange()}, subclass should call this method for both the oldHolder * and newHolder (if they are not the same instance). *

* If your ItemAnimator decides not to animate a ViewHolder, it should call * {@link #dispatchAnimationFinished(ViewHolder)} without calling * {@link #dispatchAnimationStarted(ViewHolder)}. * * @param viewHolder The ViewHolder whose animation is starting. * @see #onAnimationStarted(ViewHolder) */ public final void dispatchAnimationStarted(ViewHolder viewHolder) { onAnimationStarted(viewHolder); } /** * Called when a new animation is started on the given ViewHolder. * * @param viewHolder The ViewHolder which started animating. Note that the ViewHolder * might already be animating and this might be another animation. * @see #dispatchAnimationStarted(ViewHolder) */ public void onAnimationStarted(ViewHolder viewHolder) { } /** * Like {@link #isRunning()}, this method returns whether there are any item * animations currently running. Additionally, the listener passed in will be called * when there are no item animations running, either immediately (before the method * returns) if no animations are currently running, or when the currently running * animations are {@link #dispatchAnimationsFinished() finished}. * *

Note that the listener is transient - it is either called immediately and not * stored at all, or stored only until it is called when running animations * are finished sometime later.

* * @param listener A listener to be called immediately if no animations are running * or later when currently-running animations have finished. A null listener is * equivalent to calling {@link #isRunning()}. * @return true if there are any item animations currently running, false otherwise. */ public final boolean isRunning(ItemAnimatorFinishedListener listener) { boolean running = isRunning(); if (listener != null) { if (!running) { listener.onAnimationsFinished(); } else { mFinishedListeners.add(listener); } } return running; } /** * When an item is changed, ItemAnimator can decide whether it wants to re-use * the same ViewHolder for animations or RecyclerView should create a copy of the * item and ItemAnimator will use both to run the animation (e.g. cross-fade). *

* Note that this method will only be called if the {@link ViewHolder} still has the same * type ({@link Adapter#getItemViewType(int)}). Otherwise, ItemAnimator will always receive * both {@link ViewHolder}s in the * {@link #animateChange(ViewHolder, ViewHolder, ItemHolderInfo, ItemHolderInfo)} method. *

* If your application is using change payloads, you can override * {@link #canReuseUpdatedViewHolder(ViewHolder, List)} to decide based on payloads. * * @param viewHolder The ViewHolder which represents the changed item's old content. * * @return True if RecyclerView should just rebind to the same ViewHolder or false if * RecyclerView should create a new ViewHolder and pass this ViewHolder to the * ItemAnimator to animate. Default implementation returns true. * * @see #canReuseUpdatedViewHolder(ViewHolder, List) */ public boolean canReuseUpdatedViewHolder(@NonNull ViewHolder viewHolder) { return true; } /** * When an item is changed, ItemAnimator can decide whether it wants to re-use * the same ViewHolder for animations or RecyclerView should create a copy of the * item and ItemAnimator will use both to run the animation (e.g. cross-fade). *

* Note that this method will only be called if the {@link ViewHolder} still has the same * type ({@link Adapter#getItemViewType(int)}). Otherwise, ItemAnimator will always receive * both {@link ViewHolder}s in the * {@link #animateChange(ViewHolder, ViewHolder, ItemHolderInfo, ItemHolderInfo)} method. * * @param viewHolder The ViewHolder which represents the changed item's old content. * @param payloads A non-null list of merged payloads that were sent with change * notifications. Can be empty if the adapter is invalidated via * {@link RecyclerView.Adapter#notifyDataSetChanged()}. The same list of * payloads will be passed into * {@link RecyclerView.Adapter#onBindViewHolder(ViewHolder, int, List)} * method if this method returns true. * * @return True if RecyclerView should just rebind to the same ViewHolder or false if * RecyclerView should create a new ViewHolder and pass this ViewHolder to the * ItemAnimator to animate. Default implementation calls * {@link #canReuseUpdatedViewHolder(ViewHolder)}. * * @see #canReuseUpdatedViewHolder(ViewHolder) */ public boolean canReuseUpdatedViewHolder(@NonNull ViewHolder viewHolder, @NonNull List payloads) { return canReuseUpdatedViewHolder(viewHolder); } /** * This method should be called by ItemAnimator implementations to notify * any listeners that all pending and active item animations are finished. */ public final void dispatchAnimationsFinished() { final int count = mFinishedListeners.size(); for (int i = 0; i < count; ++i) { mFinishedListeners.get(i).onAnimationsFinished(); } mFinishedListeners.clear(); } /** * Returns a new {@link ItemHolderInfo} which will be used to store information about the * ViewHolder. This information will later be passed into animate** methods. *

* You can override this method if you want to extend {@link ItemHolderInfo} and provide * your own instances. * * @return A new {@link ItemHolderInfo}. */ public ItemHolderInfo obtainHolderInfo() { return new ItemHolderInfo(); } /** * The interface to be implemented by listeners to animation events from this * ItemAnimator. This is used internally and is not intended for developers to * create directly. */ interface ItemAnimatorListener { void onAnimationFinished(ViewHolder item); } /** * This interface is used to inform listeners when all pending or running animations * in an ItemAnimator are finished. This can be used, for example, to delay an action * in a data set until currently-running animations are complete. * * @see #isRunning(ItemAnimatorFinishedListener) */ public interface ItemAnimatorFinishedListener { /** * Notifies when all pending or running animations in an ItemAnimator are finished. */ void onAnimationsFinished(); } /** * A simple data structure that holds information about an item's bounds. * This information is used in calculating item animations. Default implementation of * {@link #recordPreLayoutInformation(RecyclerView.State, ViewHolder, int, List)} and * {@link #recordPostLayoutInformation(RecyclerView.State, ViewHolder)} returns this data * structure. You can extend this class if you would like to keep more information about * the Views. *

* If you want to provide your own implementation but still use `super` methods to record * basic information, you can override {@link #obtainHolderInfo()} to provide your own * instances. */ public static class ItemHolderInfo { /** * The left edge of the View (excluding decorations) */ public int left; /** * The top edge of the View (excluding decorations) */ public int top; /** * The right edge of the View (excluding decorations) */ public int right; /** * The bottom edge of the View (excluding decorations) */ public int bottom; /** * The change flags that were passed to * {@link #recordPreLayoutInformation(RecyclerView.State, ViewHolder, int, List)}. */ @AdapterChanges public int changeFlags; public ItemHolderInfo() { } /** * Sets the {@link #left}, {@link #top}, {@link #right} and {@link #bottom} values from * the given ViewHolder. Clears all {@link #changeFlags}. * * @param holder The ViewHolder whose bounds should be copied. * @return This {@link ItemHolderInfo} */ public ItemHolderInfo setFrom(RecyclerView.ViewHolder holder) { return setFrom(holder, 0); } /** * Sets the {@link #left}, {@link #top}, {@link #right} and {@link #bottom} values from * the given ViewHolder and sets the {@link #changeFlags} to the given flags parameter. * * @param holder The ViewHolder whose bounds should be copied. * @param flags The adapter change flags that were passed into * {@link #recordPreLayoutInformation(RecyclerView.State, ViewHolder, int, * List)}. * @return This {@link ItemHolderInfo} */ public ItemHolderInfo setFrom(RecyclerView.ViewHolder holder, @AdapterChanges int flags) { final View view = holder.itemView; this.left = view.getLeft(); this.top = view.getTop(); this.right = view.getRight(); this.bottom = view.getBottom(); return this; } } } @Override protected int getChildDrawingOrder(int childCount, int i) { if (mChildDrawingOrderCallback == null) { return super.getChildDrawingOrder(childCount, i); } else { return mChildDrawingOrderCallback.onGetChildDrawingOrder(childCount, i); } } /** * A callback interface that can be used to alter the drawing order of RecyclerView children. *

* It works using the {@link ViewGroup#getChildDrawingOrder(int, int)} method, so any case * that applies to that method also applies to this callback. For example, changing the drawing * order of two views will not have any effect if their elevation values are different since * elevation overrides the result of this callback. */ public interface ChildDrawingOrderCallback { /** * Returns the index of the child to draw for this iteration. Override this * if you want to change the drawing order of children. By default, it * returns i. * * @param i The current iteration. * @return The index of the child to draw this iteration. * * @see RecyclerView#setChildDrawingOrderCallback(RecyclerView.ChildDrawingOrderCallback) */ int onGetChildDrawingOrder(int childCount, int i); } }