/* * Copyright (C) 2014 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except * in compliance with the License. You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software distributed under the License * is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express * or implied. See the License for the specific language governing permissions and limitations under * the License. */ package android.support.v17.leanback.widget; import android.support.v4.util.CircularIntArray; import android.util.Log; import java.io.PrintWriter; /** * A grid is representation of multiple row layout data structure and algorithm. * Grid is the base class for both staggered case or simple non-staggered case. *

* User calls Grid.createStaggeredMutipleRows() to create an staggered instance. * TODO add createNonStaggeredRows(). * To use the Grid, user must implement a Provider to create or remove visible item. * Grid maintains a list of visible items. Visible items are created when * user calls appendVisibleItems() or prependVisibleItems() with certain limitation * (e.g. a max edge that append up to). Visible items are deleted when user calls * removeInvisibleItemsAtEnd() or removeInvisibleItemsAtFront(). Grid's algorithm * uses size of visible item returned from Provider.createItem() to decide which row * to add a new visible item and may cache the algorithm results. User must call * invalidateItemsAfter() when it detects item size changed to ask Grid to remove cached * results. */ abstract class Grid { /** * A constant representing a default starting index, indicating that the * developer did not provide a start index. */ public static final int START_DEFAULT = -1; /** * When user uses Grid, he should provide count of items and * the method to create item and remove item. */ public static interface Provider { /** * Return how many items (are in the adapter). */ public abstract int getCount(); /** * Create visible item and where the provider should measure it. * The call is always followed by addItem(). * @param index 0-based index of the item in provider * @param append True if new item is after last visible item, false if new item is * before first visible item. * @param item item[0] returns created item that will be passed in addItem() call. * @return length of the item. */ public abstract int createItem(int index, boolean append, Object[] item); /** * add item to given row and given edge. The call is always after createItem(). * @param item The object returned by createItem() * @param index 0-based index of the item in provider * @param length The size of the object * @param rowIndex Row index to put the item * @param edge min_edge if not reversed or max_edge if reversed. */ public abstract void addItem(Object item, int index, int length, int rowIndex, int edge); /** * Remove visible item at index. * @param index 0-based index of the item in provider */ public abstract void removeItem(int index); /** * Get edge of an existing visible item. edge will be the min_edge * if not reversed or the max_edge if reversed. * @param index 0-based index of the item in provider */ public abstract int getEdge(int index); /** * Get size of an existing visible item. * @param index 0-based index of the item in provider */ public abstract int getSize(int index); } /** * Cached representation of an item in Grid. May be subclassed. */ public static class Location { /** * The index of the row for this Location. */ public int row; public Location(int row) { this.row = row; } } protected Provider mProvider; protected boolean mReversedFlow; protected int mMargin; protected int mNumRows; protected int mFirstVisibleIndex = -1; protected int mLastVisibleIndex = -1; protected CircularIntArray[] mTmpItemPositionsInRows; // the first index that grid will layout protected int mStartIndex = START_DEFAULT; /** * Creates a multiple rows staggered grid. */ public static Grid createStaggeredMultipleRows(int rows) { StaggeredGridDefault grid = new StaggeredGridDefault(); grid.setNumRows(rows); return grid; } /** * Sets the margin between items in a row */ public final void setMargin(int margin) { mMargin = margin; } /** * Sets if reversed flow (rtl) */ public final void setReversedFlow(boolean reversedFlow) { mReversedFlow = reversedFlow; } /** * Returns true if reversed flow (rtl) */ public boolean isReversedFlow() { return mReversedFlow; } /** * Sets the {@link Provider} for this grid. * * @param provider The provider for this grid. */ public void setProvider(Provider provider) { mProvider = provider; } /** * Sets the first item index to create when there are no items. * * @param startIndex the index of the first item */ public void setStart(int startIndex) { mStartIndex = startIndex; } /** * Returns the number of rows in the grid. */ public int getNumRows() { return mNumRows; } /** * Sets number of rows to fill into. For views that represent a * horizontal list, this will be the rows of the view. For views that * represent a vertical list, this will be the columns. * * @param numRows numberOfRows */ void setNumRows(int numRows) { if (numRows <= 0) { throw new IllegalArgumentException(); } if (mNumRows == numRows) { return; } mNumRows = numRows; mTmpItemPositionsInRows = new CircularIntArray[mNumRows]; for (int i = 0; i < mNumRows; i++) { mTmpItemPositionsInRows[i] = new CircularIntArray(); } } /** * Returns index of first visible item in the staggered grid. Returns negative value * if no visible item. */ public final int getFirstVisibleIndex() { return mFirstVisibleIndex; } /** * Returns index of last visible item in the staggered grid. Returns negative value * if no visible item. */ public final int getLastVisibleIndex() { return mLastVisibleIndex; } /** * Reset visible indices and keep cache (if exists) */ public void resetVisibleIndex() { mFirstVisibleIndex = mLastVisibleIndex = -1; } /** * Invalidate items after or equal to index. This will remove visible items * after that and invalidate cache of layout results after that. */ public void invalidateItemsAfter(int index) { if (index < 0) { return; } if (mLastVisibleIndex < 0) { return; } while (mLastVisibleIndex >= index) { mProvider.removeItem(mLastVisibleIndex); mLastVisibleIndex--; } resetVisbileIndexIfEmpty(); if (getFirstVisibleIndex() < 0) { setStart(index); } } /** * Gets the row index of item at given index. */ public final int getRowIndex(int index) { return getLocation(index).row; } /** * Gets {@link Location} of item. The return object is read only and temporarily. */ public abstract Location getLocation(int index); /** * Finds the largest or smallest row min edge of visible items, * the row index is returned in indices[0], the item index is returned in indices[1]. */ public final int findRowMin(boolean findLarge, int[] indices) { return findRowMin(findLarge, mReversedFlow ? mLastVisibleIndex : mFirstVisibleIndex, indices); } /** * Finds the largest or smallest row min edge of visible items, starts searching from * indexLimit, the row index is returned in indices[0], the item index is returned in indices[1]. */ protected abstract int findRowMin(boolean findLarge, int indexLimit, int[] rowIndex); /** * Finds the largest or smallest row max edge of visible items, the row index is returned in * indices[0], the item index is returned in indices[1]. */ public final int findRowMax(boolean findLarge, int[] indices) { return findRowMax(findLarge, mReversedFlow ? mFirstVisibleIndex : mLastVisibleIndex, indices); } /** * Find largest or smallest row max edge of visible items, starts searching from indexLimit, * the row index is returned in indices[0], the item index is returned in indices[1]. */ protected abstract int findRowMax(boolean findLarge, int indexLimit, int[] indices); /** * Returns true if appending item has reached "toLimit" */ protected final boolean checkAppendOverLimit(int toLimit) { if (mLastVisibleIndex < 0) { return false; } return mReversedFlow ? findRowMin(true, null) <= toLimit + mMargin : findRowMax(false, null) >= toLimit - mMargin; } /** * Returns true if prepending item has reached "toLimit" */ protected final boolean checkPrependOverLimit(int toLimit) { if (mLastVisibleIndex < 0) { return false; } return mReversedFlow ? findRowMax(false, null) >= toLimit + mMargin : findRowMin(true, null) <= toLimit - mMargin; } /** * Return array of int array for all rows, each int array contains visible item positions * in pair on that row between startPos(included) and endPositions(included). * Returned value is read only, do not change it. *

* E.g. First row has 3,7,8, second row has 4,5,6. * getItemPositionsInRows(3, 8) returns { {3,3,7,8}, {4,6} } */ public abstract CircularIntArray[] getItemPositionsInRows(int startPos, int endPos); /** * Return array of int array for all rows, each int array contains visible item positions * in pair on that row. * Returned value is read only, do not change it. *

* E.g. First row has 3,7,8, second row has 4,5,6 { {3,3,7,8}, {4,6} } */ public final CircularIntArray[] getItemPositionsInRows() { return getItemPositionsInRows(getFirstVisibleIndex(), getLastVisibleIndex()); } /** * Prepends items and stops after one column is filled. * (i.e. filled items from row 0 to row mNumRows - 1) * @return true if at least one item is filled. */ public final boolean prependOneColumnVisibleItems() { return prependVisibleItems(mReversedFlow ? Integer.MIN_VALUE : Integer.MAX_VALUE, true); } /** * Prepends items until first item or reaches toLimit (min edge when not reversed or * max edge when reversed) */ public final void prependVisibleItems(int toLimit) { prependVisibleItems(toLimit, false); } /** * Prepends items until first item or reaches toLimit (min edge when not reversed or * max edge when reversed). * @param oneColumnMode true when fills one column and stops, false * when checks if condition matches before filling first column. * @return true if at least one item is filled. */ protected abstract boolean prependVisibleItems(int toLimit, boolean oneColumnMode); /** * Appends items and stops after one column is filled. * (i.e. filled items from row 0 to row mNumRows - 1) * @return true if at least one item is filled. */ public boolean appendOneColumnVisibleItems() { return appendVisibleItems(mReversedFlow ? Integer.MAX_VALUE : Integer.MIN_VALUE, true); } /** * Append items until last item or reaches toLimit (max edge when not * reversed or min edge when reversed) */ public final void appendVisibleItems(int toLimit) { appendVisibleItems(toLimit, false); } /** * Appends items until last or reaches toLimit (high edge when not * reversed or low edge when reversed). * @param oneColumnMode True when fills one column and stops, false * when checks if condition matches before filling first column. * @return true if filled at least one item */ protected abstract boolean appendVisibleItems(int toLimit, boolean oneColumnMode); /** * Removes invisible items from end until reaches item at aboveIndex or toLimit. */ public void removeInvisibleItemsAtEnd(int aboveIndex, int toLimit) { while(mLastVisibleIndex >= mFirstVisibleIndex && mLastVisibleIndex > aboveIndex) { boolean offEnd = !mReversedFlow ? mProvider.getEdge(mLastVisibleIndex) >= toLimit : mProvider.getEdge(mLastVisibleIndex) <= toLimit; if (offEnd) { mProvider.removeItem(mLastVisibleIndex); mLastVisibleIndex--; } else { break; } } resetVisbileIndexIfEmpty(); } /** * Removes invisible items from front until reaches item at belowIndex or toLimit. */ public void removeInvisibleItemsAtFront(int belowIndex, int toLimit) { while(mLastVisibleIndex >= mFirstVisibleIndex && mFirstVisibleIndex < belowIndex) { boolean offFront = !mReversedFlow ? mProvider.getEdge(mFirstVisibleIndex) + mProvider.getSize(mFirstVisibleIndex) <= toLimit : mProvider.getEdge(mFirstVisibleIndex) - mProvider.getSize(mFirstVisibleIndex) >= toLimit; if (offFront) { mProvider.removeItem(mFirstVisibleIndex); mFirstVisibleIndex++; } else { break; } } resetVisbileIndexIfEmpty(); } private void resetVisbileIndexIfEmpty() { if (mLastVisibleIndex < mFirstVisibleIndex) { resetVisibleIndex(); } } public abstract void debugPrint(PrintWriter pw); }