1 /* 2 * Copyright (C) 2008 The Android Open Source Project 3 * 4 * Licensed under the Apache License, Version 2.0 (the "License"); 5 * you may not use this file except in compliance with the License. 6 * You may obtain a copy of the License at 7 * 8 * http://www.apache.org/licenses/LICENSE-2.0 9 * 10 * Unless required by applicable law or agreed to in writing, software 11 * distributed under the License is distributed on an "AS IS" BASIS, 12 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. 13 * See the License for the specific language governing permissions and 14 * limitations under the License. 15 */ 16 17 package com.android.launcher2; 18 19 import android.animation.Animator; 20 import android.animation.AnimatorListenerAdapter; 21 import android.animation.AnimatorSet; 22 import android.animation.ObjectAnimator; 23 import android.animation.PropertyValuesHolder; 24 import android.animation.TimeInterpolator; 25 import android.animation.ValueAnimator; 26 import android.animation.ValueAnimator.AnimatorUpdateListener; 27 import android.content.Context; 28 import android.content.res.Resources; 29 import android.content.res.TypedArray; 30 import android.graphics.Bitmap; 31 import android.graphics.Canvas; 32 import android.graphics.Paint; 33 import android.graphics.Point; 34 import android.graphics.PointF; 35 import android.graphics.PorterDuff; 36 import android.graphics.PorterDuffXfermode; 37 import android.graphics.Rect; 38 import android.graphics.RectF; 39 import android.graphics.Region; 40 import android.graphics.drawable.Drawable; 41 import android.graphics.drawable.NinePatchDrawable; 42 import android.util.AttributeSet; 43 import android.util.Log; 44 import android.view.MotionEvent; 45 import android.view.View; 46 import android.view.ViewDebug; 47 import android.view.ViewGroup; 48 import android.view.animation.Animation; 49 import android.view.animation.DecelerateInterpolator; 50 import android.view.animation.LayoutAnimationController; 51 52 import com.android.launcher.R; 53 import com.android.launcher2.FolderIcon.FolderRingAnimator; 54 55 import java.util.ArrayList; 56 import java.util.Arrays; 57 import java.util.HashMap; 58 59 public class CellLayout extends ViewGroup { 60 static final String TAG = "CellLayout"; 61 62 private int mOriginalCellWidth; 63 private int mOriginalCellHeight; 64 private int mCellWidth; 65 private int mCellHeight; 66 67 private int mCountX; 68 private int mCountY; 69 70 private int mOriginalWidthGap; 71 private int mOriginalHeightGap; 72 private int mWidthGap; 73 private int mHeightGap; 74 private int mMaxGap; 75 76 private final Rect mRect = new Rect(); 77 private final CellInfo mCellInfo = new CellInfo(); 78 79 // These are temporary variables to prevent having to allocate a new object just to 80 // return an (x, y) value from helper functions. Do NOT use them to maintain other state. 81 private final int[] mTmpXY = new int[2]; 82 private final int[] mTmpPoint = new int[2]; 83 private final PointF mTmpPointF = new PointF(); 84 int[] mTempLocation = new int[2]; 85 86 boolean[][] mOccupied; 87 private boolean mLastDownOnOccupiedCell = false; 88 89 private OnTouchListener mInterceptTouchListener; 90 91 private ArrayList<FolderRingAnimator> mFolderOuterRings = new ArrayList<FolderRingAnimator>(); 92 private int[] mFolderLeaveBehindCell = {-1, -1}; 93 94 private int mForegroundAlpha = 0; 95 private float mBackgroundAlpha; 96 private float mBackgroundAlphaMultiplier = 1.0f; 97 98 private Drawable mNormalBackground; 99 private Drawable mActiveBackground; 100 private Drawable mActiveGlowBackground; 101 private Drawable mNormalBackgroundMini; 102 private Drawable mNormalGlowBackgroundMini; 103 private Drawable mActiveBackgroundMini; 104 private Drawable mActiveGlowBackgroundMini; 105 private Drawable mOverScrollForegroundDrawable; 106 private Drawable mOverScrollLeft; 107 private Drawable mOverScrollRight; 108 private Rect mBackgroundRect; 109 private Rect mForegroundRect; 110 private Rect mGlowBackgroundRect; 111 private float mGlowBackgroundScale; 112 private float mGlowBackgroundAlpha; 113 private int mForegroundPadding; 114 115 private boolean mAcceptsDrops = true; 116 // If we're actively dragging something over this screen, mIsDragOverlapping is true 117 private boolean mIsDragOverlapping = false; 118 private boolean mIsDragOccuring = false; 119 private boolean mIsDefaultDropTarget = false; 120 private final Point mDragCenter = new Point(); 121 122 // These arrays are used to implement the drag visualization on x-large screens. 123 // They are used as circular arrays, indexed by mDragOutlineCurrent. 124 private Point[] mDragOutlines = new Point[4]; 125 private float[] mDragOutlineAlphas = new float[mDragOutlines.length]; 126 private InterruptibleInOutAnimator[] mDragOutlineAnims = 127 new InterruptibleInOutAnimator[mDragOutlines.length]; 128 129 // Used as an index into the above 3 arrays; indicates which is the most current value. 130 private int mDragOutlineCurrent = 0; 131 private final Paint mDragOutlinePaint = new Paint(); 132 133 private BubbleTextView mPressedOrFocusedIcon; 134 135 private Drawable mCrosshairsDrawable = null; 136 private InterruptibleInOutAnimator mCrosshairsAnimator = null; 137 private float mCrosshairsVisibility = 0.0f; 138 139 private HashMap<CellLayout.LayoutParams, ObjectAnimator> mReorderAnimators = new 140 HashMap<CellLayout.LayoutParams, ObjectAnimator>(); 141 142 // When a drag operation is in progress, holds the nearest cell to the touch point 143 private final int[] mDragCell = new int[2]; 144 145 private boolean mDragging = false; 146 147 private TimeInterpolator mEaseOutInterpolator; 148 private CellLayoutChildren mChildren; 149 150 public CellLayout(Context context) { 151 this(context, null); 152 } 153 154 public CellLayout(Context context, AttributeSet attrs) { 155 this(context, attrs, 0); 156 } 157 158 public CellLayout(Context context, AttributeSet attrs, int defStyle) { 159 super(context, attrs, defStyle); 160 161 // A ViewGroup usually does not draw, but CellLayout needs to draw a rectangle to show 162 // the user where a dragged item will land when dropped. 163 setWillNotDraw(false); 164 165 TypedArray a = context.obtainStyledAttributes(attrs, R.styleable.CellLayout, defStyle, 0); 166 167 mOriginalCellWidth = 168 mCellWidth = a.getDimensionPixelSize(R.styleable.CellLayout_cellWidth, 10); 169 mOriginalCellHeight = 170 mCellHeight = a.getDimensionPixelSize(R.styleable.CellLayout_cellHeight, 10); 171 mWidthGap = mOriginalWidthGap = a.getDimensionPixelSize(R.styleable.CellLayout_widthGap, 0); 172 mHeightGap = mOriginalHeightGap = a.getDimensionPixelSize(R.styleable.CellLayout_heightGap, 0); 173 mMaxGap = a.getDimensionPixelSize(R.styleable.CellLayout_maxGap, 0); 174 mCountX = LauncherModel.getCellCountX(); 175 mCountY = LauncherModel.getCellCountY(); 176 mOccupied = new boolean[mCountX][mCountY]; 177 178 a.recycle(); 179 180 setAlwaysDrawnWithCacheEnabled(false); 181 182 final Resources res = getResources(); 183 184 mNormalBackground = res.getDrawable(R.drawable.homescreen_blue_normal_holo); 185 mActiveBackground = res.getDrawable(R.drawable.homescreen_blue_strong_holo); 186 mActiveGlowBackground = res.getDrawable(R.drawable.homescreen_blue_strong_holo); 187 188 mNormalBackgroundMini = res.getDrawable(R.drawable.homescreen_small_blue); 189 mNormalGlowBackgroundMini = res.getDrawable(R.drawable.homescreen_small_blue_strong); 190 mActiveBackgroundMini = res.getDrawable(R.drawable.homescreen_small_blue_strong); 191 mActiveGlowBackgroundMini = res.getDrawable(R.drawable.homescreen_small_blue_strong); 192 mOverScrollLeft = res.getDrawable(R.drawable.overscroll_glow_left); 193 mOverScrollRight = res.getDrawable(R.drawable.overscroll_glow_right); 194 mForegroundPadding = 195 res.getDimensionPixelSize(R.dimen.workspace_overscroll_drawable_padding); 196 197 mNormalBackground.setFilterBitmap(true); 198 mActiveBackground.setFilterBitmap(true); 199 mActiveGlowBackground.setFilterBitmap(true); 200 mNormalBackgroundMini.setFilterBitmap(true); 201 mNormalGlowBackgroundMini.setFilterBitmap(true); 202 mActiveBackgroundMini.setFilterBitmap(true); 203 mActiveGlowBackgroundMini.setFilterBitmap(true); 204 205 // Initialize the data structures used for the drag visualization. 206 207 mCrosshairsDrawable = res.getDrawable(R.drawable.gardening_crosshairs); 208 mEaseOutInterpolator = new DecelerateInterpolator(2.5f); // Quint ease out 209 210 // Set up the animation for fading the crosshairs in and out 211 int animDuration = res.getInteger(R.integer.config_crosshairsFadeInTime); 212 mCrosshairsAnimator = new InterruptibleInOutAnimator(animDuration, 0.0f, 1.0f); 213 mCrosshairsAnimator.getAnimator().addUpdateListener(new AnimatorUpdateListener() { 214 public void onAnimationUpdate(ValueAnimator animation) { 215 mCrosshairsVisibility = ((Float) animation.getAnimatedValue()).floatValue(); 216 invalidate(); 217 } 218 }); 219 mCrosshairsAnimator.getAnimator().setInterpolator(mEaseOutInterpolator); 220 221 mDragCell[0] = mDragCell[1] = -1; 222 for (int i = 0; i < mDragOutlines.length; i++) { 223 mDragOutlines[i] = new Point(-1, -1); 224 } 225 226 // When dragging things around the home screens, we show a green outline of 227 // where the item will land. The outlines gradually fade out, leaving a trail 228 // behind the drag path. 229 // Set up all the animations that are used to implement this fading. 230 final int duration = res.getInteger(R.integer.config_dragOutlineFadeTime); 231 final float fromAlphaValue = 0; 232 final float toAlphaValue = (float)res.getInteger(R.integer.config_dragOutlineMaxAlpha); 233 234 Arrays.fill(mDragOutlineAlphas, fromAlphaValue); 235 236 for (int i = 0; i < mDragOutlineAnims.length; i++) { 237 final InterruptibleInOutAnimator anim = 238 new InterruptibleInOutAnimator(duration, fromAlphaValue, toAlphaValue); 239 anim.getAnimator().setInterpolator(mEaseOutInterpolator); 240 final int thisIndex = i; 241 anim.getAnimator().addUpdateListener(new AnimatorUpdateListener() { 242 public void onAnimationUpdate(ValueAnimator animation) { 243 final Bitmap outline = (Bitmap)anim.getTag(); 244 245 // If an animation is started and then stopped very quickly, we can still 246 // get spurious updates we've cleared the tag. Guard against this. 247 if (outline == null) { 248 if (false) { 249 Object val = animation.getAnimatedValue(); 250 Log.d(TAG, "anim " + thisIndex + " update: " + val + 251 ", isStopped " + anim.isStopped()); 252 } 253 // Try to prevent it from continuing to run 254 animation.cancel(); 255 } else { 256 mDragOutlineAlphas[thisIndex] = (Float) animation.getAnimatedValue(); 257 final int left = mDragOutlines[thisIndex].x; 258 final int top = mDragOutlines[thisIndex].y; 259 CellLayout.this.invalidate(left, top, 260 left + outline.getWidth(), top + outline.getHeight()); 261 } 262 } 263 }); 264 // The animation holds a reference to the drag outline bitmap as long is it's 265 // running. This way the bitmap can be GCed when the animations are complete. 266 anim.getAnimator().addListener(new AnimatorListenerAdapter() { 267 @Override 268 public void onAnimationEnd(Animator animation) { 269 if ((Float) ((ValueAnimator) animation).getAnimatedValue() == 0f) { 270 anim.setTag(null); 271 } 272 } 273 }); 274 mDragOutlineAnims[i] = anim; 275 } 276 277 mBackgroundRect = new Rect(); 278 mForegroundRect = new Rect(); 279 mGlowBackgroundRect = new Rect(); 280 setHoverScale(1.0f); 281 setHoverAlpha(1.0f); 282 283 mChildren = new CellLayoutChildren(context); 284 mChildren.setCellDimensions(mCellWidth, mCellHeight, mWidthGap, mHeightGap); 285 addView(mChildren); 286 } 287 288 static int widthInPortrait(Resources r, int numCells) { 289 // We use this method from Workspace to figure out how many rows/columns Launcher should 290 // have. We ignore the left/right padding on CellLayout because it turns out in our design 291 // the padding extends outside the visible screen size, but it looked fine anyway. 292 int cellWidth = r.getDimensionPixelSize(R.dimen.workspace_cell_width); 293 int minGap = Math.min(r.getDimensionPixelSize(R.dimen.workspace_width_gap), 294 r.getDimensionPixelSize(R.dimen.workspace_height_gap)); 295 296 return minGap * (numCells - 1) + cellWidth * numCells; 297 } 298 299 static int heightInLandscape(Resources r, int numCells) { 300 // We use this method from Workspace to figure out how many rows/columns Launcher should 301 // have. We ignore the left/right padding on CellLayout because it turns out in our design 302 // the padding extends outside the visible screen size, but it looked fine anyway. 303 int cellHeight = r.getDimensionPixelSize(R.dimen.workspace_cell_height); 304 int minGap = Math.min(r.getDimensionPixelSize(R.dimen.workspace_width_gap), 305 r.getDimensionPixelSize(R.dimen.workspace_height_gap)); 306 307 return minGap * (numCells - 1) + cellHeight * numCells; 308 } 309 310 public void enableHardwareLayers() { 311 mChildren.enableHardwareLayers(); 312 } 313 314 public void setGridSize(int x, int y) { 315 mCountX = x; 316 mCountY = y; 317 mOccupied = new boolean[mCountX][mCountY]; 318 requestLayout(); 319 } 320 321 private void invalidateBubbleTextView(BubbleTextView icon) { 322 final int padding = icon.getPressedOrFocusedBackgroundPadding(); 323 invalidate(icon.getLeft() + getPaddingLeft() - padding, 324 icon.getTop() + getPaddingTop() - padding, 325 icon.getRight() + getPaddingLeft() + padding, 326 icon.getBottom() + getPaddingTop() + padding); 327 } 328 329 void setOverScrollAmount(float r, boolean left) { 330 if (left && mOverScrollForegroundDrawable != mOverScrollLeft) { 331 mOverScrollForegroundDrawable = mOverScrollLeft; 332 } else if (!left && mOverScrollForegroundDrawable != mOverScrollRight) { 333 mOverScrollForegroundDrawable = mOverScrollRight; 334 } 335 336 mForegroundAlpha = (int) Math.round((r * 255)); 337 mOverScrollForegroundDrawable.setAlpha(mForegroundAlpha); 338 invalidate(); 339 } 340 341 void setPressedOrFocusedIcon(BubbleTextView icon) { 342 // We draw the pressed or focused BubbleTextView's background in CellLayout because it 343 // requires an expanded clip rect (due to the glow's blur radius) 344 BubbleTextView oldIcon = mPressedOrFocusedIcon; 345 mPressedOrFocusedIcon = icon; 346 if (oldIcon != null) { 347 invalidateBubbleTextView(oldIcon); 348 } 349 if (mPressedOrFocusedIcon != null) { 350 invalidateBubbleTextView(mPressedOrFocusedIcon); 351 } 352 } 353 354 public CellLayoutChildren getChildrenLayout() { 355 if (getChildCount() > 0) { 356 return (CellLayoutChildren) getChildAt(0); 357 } 358 return null; 359 } 360 361 public void setIsDefaultDropTarget(boolean isDefaultDropTarget) { 362 if (mIsDefaultDropTarget != isDefaultDropTarget) { 363 mIsDefaultDropTarget = isDefaultDropTarget; 364 invalidate(); 365 } 366 } 367 368 void setIsDragOccuring(boolean isDragOccuring) { 369 if (mIsDragOccuring != isDragOccuring) { 370 mIsDragOccuring = isDragOccuring; 371 invalidate(); 372 } 373 } 374 375 void setIsDragOverlapping(boolean isDragOverlapping) { 376 if (mIsDragOverlapping != isDragOverlapping) { 377 mIsDragOverlapping = isDragOverlapping; 378 invalidate(); 379 } 380 } 381 382 boolean getIsDragOverlapping() { 383 return mIsDragOverlapping; 384 } 385 386 private void updateGlowRect() { 387 float marginFraction = (mGlowBackgroundScale - 1.0f) / 2.0f; 388 int marginX = (int) (marginFraction * (mBackgroundRect.right - mBackgroundRect.left)); 389 int marginY = (int) (marginFraction * (mBackgroundRect.bottom - mBackgroundRect.top)); 390 mGlowBackgroundRect.set(mBackgroundRect.left - marginX, mBackgroundRect.top - marginY, 391 mBackgroundRect.right + marginX, mBackgroundRect.bottom + marginY); 392 invalidate(); 393 } 394 395 public void setHoverScale(float scaleFactor) { 396 if (scaleFactor != mGlowBackgroundScale) { 397 mGlowBackgroundScale = scaleFactor; 398 updateGlowRect(); 399 if (getParent() != null) { 400 ((View) getParent()).invalidate(); 401 } 402 } 403 } 404 405 public float getHoverScale() { 406 return mGlowBackgroundScale; 407 } 408 409 public float getHoverAlpha() { 410 return mGlowBackgroundAlpha; 411 } 412 413 public void setHoverAlpha(float alpha) { 414 mGlowBackgroundAlpha = alpha; 415 invalidate(); 416 } 417 418 void animateDrop() { 419 Resources res = getResources(); 420 float onDropScale = res.getInteger(R.integer.config_screenOnDropScalePercent) / 100.0f; 421 ObjectAnimator scaleUp = ObjectAnimator.ofFloat(this, "hoverScale", onDropScale); 422 scaleUp.setDuration(res.getInteger(R.integer.config_screenOnDropScaleUpDuration)); 423 ObjectAnimator scaleDown = ObjectAnimator.ofFloat(this, "hoverScale", 1.0f); 424 scaleDown.setDuration(res.getInteger(R.integer.config_screenOnDropScaleDownDuration)); 425 ObjectAnimator alphaFadeOut = ObjectAnimator.ofFloat(this, "hoverAlpha", 0.0f); 426 427 alphaFadeOut.setStartDelay(res.getInteger(R.integer.config_screenOnDropAlphaFadeDelay)); 428 alphaFadeOut.setDuration(res.getInteger(R.integer.config_screenOnDropAlphaFadeDuration)); 429 430 AnimatorSet bouncer = new AnimatorSet(); 431 bouncer.play(scaleUp).before(scaleDown); 432 bouncer.play(scaleUp).with(alphaFadeOut); 433 bouncer.addListener(new AnimatorListenerAdapter() { 434 @Override 435 public void onAnimationStart(Animator animation) { 436 setIsDragOverlapping(true); 437 } 438 @Override 439 public void onAnimationEnd(Animator animation) { 440 setIsDragOverlapping(false); 441 setHoverScale(1.0f); 442 setHoverAlpha(1.0f); 443 } 444 }); 445 bouncer.start(); 446 } 447 448 @Override 449 protected void onDraw(Canvas canvas) { 450 // When we're large, we are either drawn in a "hover" state (ie when dragging an item to 451 // a neighboring page) or with just a normal background (if backgroundAlpha > 0.0f) 452 // When we're small, we are either drawn normally or in the "accepts drops" state (during 453 // a drag). However, we also drag the mini hover background *over* one of those two 454 // backgrounds 455 if (mBackgroundAlpha > 0.0f) { 456 Drawable bg; 457 boolean mini = getScaleX() < 0.5f; 458 459 if (mIsDragOverlapping) { 460 // In the mini case, we draw the active_glow bg *over* the active background 461 bg = mini ? mActiveBackgroundMini : mActiveGlowBackground; 462 } else if (mIsDragOccuring && mAcceptsDrops) { 463 bg = mini ? mActiveBackgroundMini : mActiveBackground; 464 } else if (mIsDefaultDropTarget && mini) { 465 bg = mNormalGlowBackgroundMini; 466 } else { 467 bg = mini ? mNormalBackgroundMini : mNormalBackground; 468 } 469 470 bg.setAlpha((int) (mBackgroundAlpha * mBackgroundAlphaMultiplier * 255)); 471 bg.setBounds(mBackgroundRect); 472 bg.draw(canvas); 473 474 if (mini && mIsDragOverlapping) { 475 boolean modifiedClipRect = false; 476 if (mGlowBackgroundScale > 1.0f) { 477 // If the hover background's scale is greater than 1, we'll be drawing outside 478 // the bounds of this CellLayout. Get around that by temporarily increasing the 479 // size of the clip rect 480 float marginFraction = (mGlowBackgroundScale - 1.0f) / 2.0f; 481 Rect clipRect = canvas.getClipBounds(); 482 int marginX = (int) (marginFraction * (clipRect.right - clipRect.left)); 483 int marginY = (int) (marginFraction * (clipRect.bottom - clipRect.top)); 484 canvas.save(Canvas.CLIP_SAVE_FLAG); 485 canvas.clipRect(-marginX, -marginY, 486 getWidth() + marginX, getHeight() + marginY, Region.Op.REPLACE); 487 modifiedClipRect = true; 488 } 489 490 mActiveGlowBackgroundMini.setAlpha( 491 (int) (mBackgroundAlpha * mGlowBackgroundAlpha * 255)); 492 mActiveGlowBackgroundMini.setBounds(mGlowBackgroundRect); 493 mActiveGlowBackgroundMini.draw(canvas); 494 if (modifiedClipRect) { 495 canvas.restore(); 496 } 497 } 498 } 499 500 if (mCrosshairsVisibility > 0.0f) { 501 final int countX = mCountX; 502 final int countY = mCountY; 503 504 final float MAX_ALPHA = 0.4f; 505 final int MAX_VISIBLE_DISTANCE = 600; 506 final float DISTANCE_MULTIPLIER = 0.002f; 507 508 final Drawable d = mCrosshairsDrawable; 509 final int width = d.getIntrinsicWidth(); 510 final int height = d.getIntrinsicHeight(); 511 512 int x = getPaddingLeft() - (mWidthGap / 2) - (width / 2); 513 for (int col = 0; col <= countX; col++) { 514 int y = getPaddingTop() - (mHeightGap / 2) - (height / 2); 515 for (int row = 0; row <= countY; row++) { 516 mTmpPointF.set(x - mDragCenter.x, y - mDragCenter.y); 517 float dist = mTmpPointF.length(); 518 // Crosshairs further from the drag point are more faint 519 float alpha = Math.min(MAX_ALPHA, 520 DISTANCE_MULTIPLIER * (MAX_VISIBLE_DISTANCE - dist)); 521 if (alpha > 0.0f) { 522 d.setBounds(x, y, x + width, y + height); 523 d.setAlpha((int) (alpha * 255 * mCrosshairsVisibility)); 524 d.draw(canvas); 525 } 526 y += mCellHeight + mHeightGap; 527 } 528 x += mCellWidth + mWidthGap; 529 } 530 } 531 532 final Paint paint = mDragOutlinePaint; 533 for (int i = 0; i < mDragOutlines.length; i++) { 534 final float alpha = mDragOutlineAlphas[i]; 535 if (alpha > 0) { 536 final Point p = mDragOutlines[i]; 537 final Bitmap b = (Bitmap) mDragOutlineAnims[i].getTag(); 538 paint.setAlpha((int)(alpha + .5f)); 539 canvas.drawBitmap(b, p.x, p.y, paint); 540 } 541 } 542 543 // We draw the pressed or focused BubbleTextView's background in CellLayout because it 544 // requires an expanded clip rect (due to the glow's blur radius) 545 if (mPressedOrFocusedIcon != null) { 546 final int padding = mPressedOrFocusedIcon.getPressedOrFocusedBackgroundPadding(); 547 final Bitmap b = mPressedOrFocusedIcon.getPressedOrFocusedBackground(); 548 if (b != null) { 549 canvas.drawBitmap(b, 550 mPressedOrFocusedIcon.getLeft() + getPaddingLeft() - padding, 551 mPressedOrFocusedIcon.getTop() + getPaddingTop() - padding, 552 null); 553 } 554 } 555 556 // The folder outer / inner ring image(s) 557 for (int i = 0; i < mFolderOuterRings.size(); i++) { 558 FolderRingAnimator fra = mFolderOuterRings.get(i); 559 560 // Draw outer ring 561 Drawable d = FolderRingAnimator.sSharedOuterRingDrawable; 562 int width = (int) fra.getOuterRingSize(); 563 int height = width; 564 cellToPoint(fra.mCellX, fra.mCellY, mTempLocation); 565 566 int centerX = mTempLocation[0] + mCellWidth / 2; 567 int centerY = mTempLocation[1] + FolderRingAnimator.sPreviewSize / 2; 568 569 canvas.save(); 570 canvas.translate(centerX - width / 2, centerY - height / 2); 571 d.setBounds(0, 0, width, height); 572 d.draw(canvas); 573 canvas.restore(); 574 575 // Draw inner ring 576 d = FolderRingAnimator.sSharedInnerRingDrawable; 577 width = (int) fra.getInnerRingSize(); 578 height = width; 579 cellToPoint(fra.mCellX, fra.mCellY, mTempLocation); 580 581 centerX = mTempLocation[0] + mCellWidth / 2; 582 centerY = mTempLocation[1] + FolderRingAnimator.sPreviewSize / 2; 583 canvas.save(); 584 canvas.translate(centerX - width / 2, centerY - width / 2); 585 d.setBounds(0, 0, width, height); 586 d.draw(canvas); 587 canvas.restore(); 588 } 589 590 if (mFolderLeaveBehindCell[0] >= 0 && mFolderLeaveBehindCell[1] >= 0) { 591 Drawable d = FolderIcon.sSharedFolderLeaveBehind; 592 int width = d.getIntrinsicWidth(); 593 int height = d.getIntrinsicHeight(); 594 595 cellToPoint(mFolderLeaveBehindCell[0], mFolderLeaveBehindCell[1], mTempLocation); 596 int centerX = mTempLocation[0] + mCellWidth / 2; 597 int centerY = mTempLocation[1] + FolderRingAnimator.sPreviewSize / 2; 598 599 canvas.save(); 600 canvas.translate(centerX - width / 2, centerY - width / 2); 601 d.setBounds(0, 0, width, height); 602 d.draw(canvas); 603 canvas.restore(); 604 } 605 } 606 607 @Override 608 protected void dispatchDraw(Canvas canvas) { 609 super.dispatchDraw(canvas); 610 if (mForegroundAlpha > 0) { 611 mOverScrollForegroundDrawable.setBounds(mForegroundRect); 612 Paint p = ((NinePatchDrawable) mOverScrollForegroundDrawable).getPaint(); 613 p.setXfermode(new PorterDuffXfermode(PorterDuff.Mode.ADD)); 614 mOverScrollForegroundDrawable.draw(canvas); 615 p.setXfermode(null); 616 } 617 } 618 619 public void showFolderAccept(FolderRingAnimator fra) { 620 mFolderOuterRings.add(fra); 621 } 622 623 public void hideFolderAccept(FolderRingAnimator fra) { 624 if (mFolderOuterRings.contains(fra)) { 625 mFolderOuterRings.remove(fra); 626 } 627 invalidate(); 628 } 629 630 public void setFolderLeaveBehindCell(int x, int y) { 631 mFolderLeaveBehindCell[0] = x; 632 mFolderLeaveBehindCell[1] = y; 633 invalidate(); 634 } 635 636 public void clearFolderLeaveBehind() { 637 mFolderLeaveBehindCell[0] = -1; 638 mFolderLeaveBehindCell[1] = -1; 639 invalidate(); 640 } 641 642 @Override 643 public boolean shouldDelayChildPressedState() { 644 return false; 645 } 646 647 @Override 648 public void cancelLongPress() { 649 super.cancelLongPress(); 650 651 // Cancel long press for all children 652 final int count = getChildCount(); 653 for (int i = 0; i < count; i++) { 654 final View child = getChildAt(i); 655 child.cancelLongPress(); 656 } 657 } 658 659 public void setOnInterceptTouchListener(View.OnTouchListener listener) { 660 mInterceptTouchListener = listener; 661 } 662 663 int getCountX() { 664 return mCountX; 665 } 666 667 int getCountY() { 668 return mCountY; 669 } 670 671 public boolean addViewToCellLayout( 672 View child, int index, int childId, LayoutParams params, boolean markCells) { 673 final LayoutParams lp = params; 674 675 // Generate an id for each view, this assumes we have at most 256x256 cells 676 // per workspace screen 677 if (lp.cellX >= 0 && lp.cellX <= mCountX - 1 && lp.cellY >= 0 && lp.cellY <= mCountY - 1) { 678 // If the horizontal or vertical span is set to -1, it is taken to 679 // mean that it spans the extent of the CellLayout 680 if (lp.cellHSpan < 0) lp.cellHSpan = mCountX; 681 if (lp.cellVSpan < 0) lp.cellVSpan = mCountY; 682 683 child.setId(childId); 684 685 mChildren.addView(child, index, lp); 686 687 if (markCells) markCellsAsOccupiedForView(child); 688 689 return true; 690 } 691 return false; 692 } 693 694 public void setAcceptsDrops(boolean acceptsDrops) { 695 if (mAcceptsDrops != acceptsDrops) { 696 mAcceptsDrops = acceptsDrops; 697 invalidate(); 698 } 699 } 700 701 @Override 702 public void removeAllViews() { 703 clearOccupiedCells(); 704 mChildren.removeAllViews(); 705 } 706 707 @Override 708 public void removeAllViewsInLayout() { 709 if (mChildren.getChildCount() > 0) { 710 clearOccupiedCells(); 711 mChildren.removeAllViewsInLayout(); 712 } 713 } 714 715 public void removeViewWithoutMarkingCells(View view) { 716 mChildren.removeView(view); 717 } 718 719 @Override 720 public void removeView(View view) { 721 markCellsAsUnoccupiedForView(view); 722 mChildren.removeView(view); 723 } 724 725 @Override 726 public void removeViewAt(int index) { 727 markCellsAsUnoccupiedForView(mChildren.getChildAt(index)); 728 mChildren.removeViewAt(index); 729 } 730 731 @Override 732 public void removeViewInLayout(View view) { 733 markCellsAsUnoccupiedForView(view); 734 mChildren.removeViewInLayout(view); 735 } 736 737 @Override 738 public void removeViews(int start, int count) { 739 for (int i = start; i < start + count; i++) { 740 markCellsAsUnoccupiedForView(mChildren.getChildAt(i)); 741 } 742 mChildren.removeViews(start, count); 743 } 744 745 @Override 746 public void removeViewsInLayout(int start, int count) { 747 for (int i = start; i < start + count; i++) { 748 markCellsAsUnoccupiedForView(mChildren.getChildAt(i)); 749 } 750 mChildren.removeViewsInLayout(start, count); 751 } 752 753 public void drawChildren(Canvas canvas) { 754 mChildren.draw(canvas); 755 } 756 757 void buildChildrenLayer() { 758 mChildren.buildLayer(); 759 } 760 761 @Override 762 protected void onAttachedToWindow() { 763 super.onAttachedToWindow(); 764 mCellInfo.screen = ((ViewGroup) getParent()).indexOfChild(this); 765 } 766 767 public void setTagToCellInfoForPoint(int touchX, int touchY) { 768 final CellInfo cellInfo = mCellInfo; 769 final Rect frame = mRect; 770 final int x = touchX + mScrollX; 771 final int y = touchY + mScrollY; 772 final int count = mChildren.getChildCount(); 773 774 boolean found = false; 775 for (int i = count - 1; i >= 0; i--) { 776 final View child = mChildren.getChildAt(i); 777 final LayoutParams lp = (LayoutParams) child.getLayoutParams(); 778 779 if ((child.getVisibility() == VISIBLE || child.getAnimation() != null) && 780 lp.isLockedToGrid) { 781 child.getHitRect(frame); 782 783 // The child hit rect is relative to the CellLayoutChildren parent, so we need to 784 // offset that by this CellLayout's padding to test an (x,y) point that is relative 785 // to this view. 786 frame.offset(mPaddingLeft, mPaddingTop); 787 788 if (frame.contains(x, y)) { 789 cellInfo.cell = child; 790 cellInfo.cellX = lp.cellX; 791 cellInfo.cellY = lp.cellY; 792 cellInfo.spanX = lp.cellHSpan; 793 cellInfo.spanY = lp.cellVSpan; 794 found = true; 795 break; 796 } 797 } 798 } 799 800 mLastDownOnOccupiedCell = found; 801 802 if (!found) { 803 final int cellXY[] = mTmpXY; 804 pointToCellExact(x, y, cellXY); 805 806 cellInfo.cell = null; 807 cellInfo.cellX = cellXY[0]; 808 cellInfo.cellY = cellXY[1]; 809 cellInfo.spanX = 1; 810 cellInfo.spanY = 1; 811 } 812 setTag(cellInfo); 813 } 814 815 @Override 816 public boolean onInterceptTouchEvent(MotionEvent ev) { 817 // First we clear the tag to ensure that on every touch down we start with a fresh slate, 818 // even in the case where we return early. Not clearing here was causing bugs whereby on 819 // long-press we'd end up picking up an item from a previous drag operation. 820 final int action = ev.getAction(); 821 822 if (action == MotionEvent.ACTION_DOWN) { 823 clearTagCellInfo(); 824 } 825 826 if (mInterceptTouchListener != null && mInterceptTouchListener.onTouch(this, ev)) { 827 return true; 828 } 829 830 if (action == MotionEvent.ACTION_DOWN) { 831 setTagToCellInfoForPoint((int) ev.getX(), (int) ev.getY()); 832 } 833 return false; 834 } 835 836 private void clearTagCellInfo() { 837 final CellInfo cellInfo = mCellInfo; 838 cellInfo.cell = null; 839 cellInfo.cellX = -1; 840 cellInfo.cellY = -1; 841 cellInfo.spanX = 0; 842 cellInfo.spanY = 0; 843 setTag(cellInfo); 844 } 845 846 public CellInfo getTag() { 847 return (CellInfo) super.getTag(); 848 } 849 850 /** 851 * Given a point, return the cell that strictly encloses that point 852 * @param x X coordinate of the point 853 * @param y Y coordinate of the point 854 * @param result Array of 2 ints to hold the x and y coordinate of the cell 855 */ 856 void pointToCellExact(int x, int y, int[] result) { 857 final int hStartPadding = getPaddingLeft(); 858 final int vStartPadding = getPaddingTop(); 859 860 result[0] = (x - hStartPadding) / (mCellWidth + mWidthGap); 861 result[1] = (y - vStartPadding) / (mCellHeight + mHeightGap); 862 863 final int xAxis = mCountX; 864 final int yAxis = mCountY; 865 866 if (result[0] < 0) result[0] = 0; 867 if (result[0] >= xAxis) result[0] = xAxis - 1; 868 if (result[1] < 0) result[1] = 0; 869 if (result[1] >= yAxis) result[1] = yAxis - 1; 870 } 871 872 /** 873 * Given a point, return the cell that most closely encloses that point 874 * @param x X coordinate of the point 875 * @param y Y coordinate of the point 876 * @param result Array of 2 ints to hold the x and y coordinate of the cell 877 */ 878 void pointToCellRounded(int x, int y, int[] result) { 879 pointToCellExact(x + (mCellWidth / 2), y + (mCellHeight / 2), result); 880 } 881 882 /** 883 * Given a cell coordinate, return the point that represents the upper left corner of that cell 884 * 885 * @param cellX X coordinate of the cell 886 * @param cellY Y coordinate of the cell 887 * 888 * @param result Array of 2 ints to hold the x and y coordinate of the point 889 */ 890 void cellToPoint(int cellX, int cellY, int[] result) { 891 final int hStartPadding = getPaddingLeft(); 892 final int vStartPadding = getPaddingTop(); 893 894 result[0] = hStartPadding + cellX * (mCellWidth + mWidthGap); 895 result[1] = vStartPadding + cellY * (mCellHeight + mHeightGap); 896 } 897 898 /** 899 * Given a cell coordinate, return the point that represents the upper left corner of that cell 900 * 901 * @param cellX X coordinate of the cell 902 * @param cellY Y coordinate of the cell 903 * 904 * @param result Array of 2 ints to hold the x and y coordinate of the point 905 */ 906 void cellToCenterPoint(int cellX, int cellY, int[] result) { 907 final int hStartPadding = getPaddingLeft(); 908 final int vStartPadding = getPaddingTop(); 909 910 result[0] = hStartPadding + cellX * (mCellWidth + mWidthGap) + mCellWidth / 2; 911 result[1] = vStartPadding + cellY * (mCellHeight + mHeightGap) + mCellHeight / 2; 912 } 913 914 int getCellWidth() { 915 return mCellWidth; 916 } 917 918 int getCellHeight() { 919 return mCellHeight; 920 } 921 922 int getWidthGap() { 923 return mWidthGap; 924 } 925 926 int getHeightGap() { 927 return mHeightGap; 928 } 929 930 Rect getContentRect(Rect r) { 931 if (r == null) { 932 r = new Rect(); 933 } 934 int left = getPaddingLeft(); 935 int top = getPaddingTop(); 936 int right = left + getWidth() - mPaddingLeft - mPaddingRight; 937 int bottom = top + getHeight() - mPaddingTop - mPaddingBottom; 938 r.set(left, top, right, bottom); 939 return r; 940 } 941 942 @Override 943 protected void onMeasure(int widthMeasureSpec, int heightMeasureSpec) { 944 // TODO: currently ignoring padding 945 946 int widthSpecMode = MeasureSpec.getMode(widthMeasureSpec); 947 int widthSpecSize = MeasureSpec.getSize(widthMeasureSpec); 948 949 int heightSpecMode = MeasureSpec.getMode(heightMeasureSpec); 950 int heightSpecSize = MeasureSpec.getSize(heightMeasureSpec); 951 952 if (widthSpecMode == MeasureSpec.UNSPECIFIED || heightSpecMode == MeasureSpec.UNSPECIFIED) { 953 throw new RuntimeException("CellLayout cannot have UNSPECIFIED dimensions"); 954 } 955 956 int numWidthGaps = mCountX - 1; 957 int numHeightGaps = mCountY - 1; 958 959 if (mOriginalWidthGap < 0 || mOriginalHeightGap < 0) { 960 int hSpace = widthSpecSize - mPaddingLeft - mPaddingRight; 961 int vSpace = heightSpecSize - mPaddingTop - mPaddingBottom; 962 int hFreeSpace = hSpace - (mCountX * mOriginalCellWidth); 963 int vFreeSpace = vSpace - (mCountY * mOriginalCellHeight); 964 mWidthGap = Math.min(mMaxGap, numWidthGaps > 0 ? (hFreeSpace / numWidthGaps) : 0); 965 mHeightGap = Math.min(mMaxGap,numHeightGaps > 0 ? (vFreeSpace / numHeightGaps) : 0); 966 mChildren.setCellDimensions(mCellWidth, mCellHeight, mWidthGap, mHeightGap); 967 } else { 968 mWidthGap = mOriginalWidthGap; 969 mHeightGap = mOriginalHeightGap; 970 } 971 972 // Initial values correspond to widthSpecMode == MeasureSpec.EXACTLY 973 int newWidth = widthSpecSize; 974 int newHeight = heightSpecSize; 975 if (widthSpecMode == MeasureSpec.AT_MOST) { 976 newWidth = mPaddingLeft + mPaddingRight + (mCountX * mCellWidth) + 977 ((mCountX - 1) * mWidthGap); 978 newHeight = mPaddingTop + mPaddingBottom + (mCountY * mCellHeight) + 979 ((mCountY - 1) * mHeightGap); 980 setMeasuredDimension(newWidth, newHeight); 981 } 982 983 int count = getChildCount(); 984 for (int i = 0; i < count; i++) { 985 View child = getChildAt(i); 986 int childWidthMeasureSpec = MeasureSpec.makeMeasureSpec(newWidth - mPaddingLeft - 987 mPaddingRight, MeasureSpec.EXACTLY); 988 int childheightMeasureSpec = MeasureSpec.makeMeasureSpec(newHeight - mPaddingTop - 989 mPaddingBottom, MeasureSpec.EXACTLY); 990 child.measure(childWidthMeasureSpec, childheightMeasureSpec); 991 } 992 setMeasuredDimension(newWidth, newHeight); 993 } 994 995 @Override 996 protected void onLayout(boolean changed, int l, int t, int r, int b) { 997 int count = getChildCount(); 998 for (int i = 0; i < count; i++) { 999 View child = getChildAt(i); 1000 child.layout(mPaddingLeft, mPaddingTop, 1001 r - l - mPaddingRight, b - t - mPaddingBottom); 1002 } 1003 } 1004 1005 @Override 1006 protected void onSizeChanged(int w, int h, int oldw, int oldh) { 1007 super.onSizeChanged(w, h, oldw, oldh); 1008 mBackgroundRect.set(0, 0, w, h); 1009 mForegroundRect.set(mForegroundPadding, mForegroundPadding, 1010 w - 2 * mForegroundPadding, h - 2 * mForegroundPadding); 1011 updateGlowRect(); 1012 } 1013 1014 @Override 1015 protected void setChildrenDrawingCacheEnabled(boolean enabled) { 1016 mChildren.setChildrenDrawingCacheEnabled(enabled); 1017 } 1018 1019 @Override 1020 protected void setChildrenDrawnWithCacheEnabled(boolean enabled) { 1021 mChildren.setChildrenDrawnWithCacheEnabled(enabled); 1022 } 1023 1024 public float getBackgroundAlpha() { 1025 return mBackgroundAlpha; 1026 } 1027 1028 public void setFastBackgroundAlpha(float alpha) { 1029 mBackgroundAlpha = alpha; 1030 } 1031 1032 public void setBackgroundAlphaMultiplier(float multiplier) { 1033 mBackgroundAlphaMultiplier = multiplier; 1034 } 1035 1036 public float getBackgroundAlphaMultiplier() { 1037 return mBackgroundAlphaMultiplier; 1038 } 1039 1040 public void setBackgroundAlpha(float alpha) { 1041 mBackgroundAlpha = alpha; 1042 invalidate(); 1043 } 1044 1045 // Need to return true to let the view system know we know how to handle alpha-- this is 1046 // because when our children have an alpha of 0.0f, they are still rendering their "dimmed" 1047 // versions 1048 @Override 1049 protected boolean onSetAlpha(int alpha) { 1050 return true; 1051 } 1052 1053 public void setAlpha(float alpha) { 1054 setChildrenAlpha(alpha); 1055 super.setAlpha(alpha); 1056 } 1057 1058 public void setFastAlpha(float alpha) { 1059 setFastChildrenAlpha(alpha); 1060 super.setFastAlpha(alpha); 1061 } 1062 1063 private void setChildrenAlpha(float alpha) { 1064 final int childCount = getChildCount(); 1065 for (int i = 0; i < childCount; i++) { 1066 getChildAt(i).setAlpha(alpha); 1067 } 1068 } 1069 1070 private void setFastChildrenAlpha(float alpha) { 1071 final int childCount = getChildCount(); 1072 for (int i = 0; i < childCount; i++) { 1073 getChildAt(i).setFastAlpha(alpha); 1074 } 1075 } 1076 1077 public View getChildAt(int x, int y) { 1078 return mChildren.getChildAt(x, y); 1079 } 1080 1081 public boolean animateChildToPosition(final View child, int cellX, int cellY, int duration, 1082 int delay) { 1083 CellLayoutChildren clc = getChildrenLayout(); 1084 if (clc.indexOfChild(child) != -1 && !mOccupied[cellX][cellY]) { 1085 final LayoutParams lp = (LayoutParams) child.getLayoutParams(); 1086 final ItemInfo info = (ItemInfo) child.getTag(); 1087 1088 // We cancel any existing animations 1089 if (mReorderAnimators.containsKey(lp)) { 1090 mReorderAnimators.get(lp).cancel(); 1091 mReorderAnimators.remove(lp); 1092 } 1093 1094 int oldX = lp.x; 1095 int oldY = lp.y; 1096 mOccupied[lp.cellX][lp.cellY] = false; 1097 mOccupied[cellX][cellY] = true; 1098 1099 lp.isLockedToGrid = true; 1100 lp.cellX = info.cellX = cellX; 1101 lp.cellY = info.cellY = cellY; 1102 clc.setupLp(lp); 1103 lp.isLockedToGrid = false; 1104 int newX = lp.x; 1105 int newY = lp.y; 1106 1107 lp.x = oldX; 1108 lp.y = oldY; 1109 child.requestLayout(); 1110 1111 PropertyValuesHolder x = PropertyValuesHolder.ofInt("x", oldX, newX); 1112 PropertyValuesHolder y = PropertyValuesHolder.ofInt("y", oldY, newY); 1113 ObjectAnimator oa = ObjectAnimator.ofPropertyValuesHolder(lp, x, y); 1114 oa.setDuration(duration); 1115 mReorderAnimators.put(lp, oa); 1116 oa.addUpdateListener(new AnimatorUpdateListener() { 1117 public void onAnimationUpdate(ValueAnimator animation) { 1118 child.requestLayout(); 1119 } 1120 }); 1121 oa.addListener(new AnimatorListenerAdapter() { 1122 boolean cancelled = false; 1123 public void onAnimationEnd(Animator animation) { 1124 // If the animation was cancelled, it means that another animation 1125 // has interrupted this one, and we don't want to lock the item into 1126 // place just yet. 1127 if (!cancelled) { 1128 lp.isLockedToGrid = true; 1129 } 1130 if (mReorderAnimators.containsKey(lp)) { 1131 mReorderAnimators.remove(lp); 1132 } 1133 } 1134 public void onAnimationCancel(Animator animation) { 1135 cancelled = true; 1136 } 1137 }); 1138 oa.setStartDelay(delay); 1139 oa.start(); 1140 return true; 1141 } 1142 return false; 1143 } 1144 1145 /** 1146 * Estimate where the top left cell of the dragged item will land if it is dropped. 1147 * 1148 * @param originX The X value of the top left corner of the item 1149 * @param originY The Y value of the top left corner of the item 1150 * @param spanX The number of horizontal cells that the item spans 1151 * @param spanY The number of vertical cells that the item spans 1152 * @param result The estimated drop cell X and Y. 1153 */ 1154 void estimateDropCell(int originX, int originY, int spanX, int spanY, int[] result) { 1155 final int countX = mCountX; 1156 final int countY = mCountY; 1157 1158 // pointToCellRounded takes the top left of a cell but will pad that with 1159 // cellWidth/2 and cellHeight/2 when finding the matching cell 1160 pointToCellRounded(originX, originY, result); 1161 1162 // If the item isn't fully on this screen, snap to the edges 1163 int rightOverhang = result[0] + spanX - countX; 1164 if (rightOverhang > 0) { 1165 result[0] -= rightOverhang; // Snap to right 1166 } 1167 result[0] = Math.max(0, result[0]); // Snap to left 1168 int bottomOverhang = result[1] + spanY - countY; 1169 if (bottomOverhang > 0) { 1170 result[1] -= bottomOverhang; // Snap to bottom 1171 } 1172 result[1] = Math.max(0, result[1]); // Snap to top 1173 } 1174 1175 void visualizeDropLocation(View v, Bitmap dragOutline, int originX, int originY, 1176 int spanX, int spanY, Point dragOffset, Rect dragRegion) { 1177 1178 final int oldDragCellX = mDragCell[0]; 1179 final int oldDragCellY = mDragCell[1]; 1180 final int[] nearest = findNearestVacantArea(originX, originY, spanX, spanY, v, mDragCell); 1181 if (v != null && dragOffset == null) { 1182 mDragCenter.set(originX + (v.getWidth() / 2), originY + (v.getHeight() / 2)); 1183 } else { 1184 mDragCenter.set(originX, originY); 1185 } 1186 1187 if (dragOutline == null && v == null) { 1188 if (mCrosshairsDrawable != null) { 1189 invalidate(); 1190 } 1191 return; 1192 } 1193 1194 if (nearest != null && (nearest[0] != oldDragCellX || nearest[1] != oldDragCellY)) { 1195 // Find the top left corner of the rect the object will occupy 1196 final int[] topLeft = mTmpPoint; 1197 cellToPoint(nearest[0], nearest[1], topLeft); 1198 1199 int left = topLeft[0]; 1200 int top = topLeft[1]; 1201 1202 if (v != null && dragOffset == null) { 1203 // When drawing the drag outline, it did not account for margin offsets 1204 // added by the view's parent. 1205 MarginLayoutParams lp = (MarginLayoutParams) v.getLayoutParams(); 1206 left += lp.leftMargin; 1207 top += lp.topMargin; 1208 1209 // Offsets due to the size difference between the View and the dragOutline. 1210 // There is a size difference to account for the outer blur, which may lie 1211 // outside the bounds of the view. 1212 top += (v.getHeight() - dragOutline.getHeight()) / 2; 1213 // We center about the x axis 1214 left += ((mCellWidth * spanX) + ((spanX - 1) * mWidthGap) 1215 - dragOutline.getWidth()) / 2; 1216 } else { 1217 if (dragOffset != null && dragRegion != null) { 1218 // Center the drag region *horizontally* in the cell and apply a drag 1219 // outline offset 1220 left += dragOffset.x + ((mCellWidth * spanX) + ((spanX - 1) * mWidthGap) 1221 - dragRegion.width()) / 2; 1222 top += dragOffset.y; 1223 } else { 1224 // Center the drag outline in the cell 1225 left += ((mCellWidth * spanX) + ((spanX - 1) * mWidthGap) 1226 - dragOutline.getWidth()) / 2; 1227 top += ((mCellHeight * spanY) + ((spanY - 1) * mHeightGap) 1228 - dragOutline.getHeight()) / 2; 1229 } 1230 } 1231 1232 final int oldIndex = mDragOutlineCurrent; 1233 mDragOutlineAnims[oldIndex].animateOut(); 1234 mDragOutlineCurrent = (oldIndex + 1) % mDragOutlines.length; 1235 1236 mDragOutlines[mDragOutlineCurrent].set(left, top); 1237 mDragOutlineAnims[mDragOutlineCurrent].setTag(dragOutline); 1238 mDragOutlineAnims[mDragOutlineCurrent].animateIn(); 1239 } 1240 1241 // If we are drawing crosshairs, the entire CellLayout needs to be invalidated 1242 if (mCrosshairsDrawable != null) { 1243 invalidate(); 1244 } 1245 } 1246 1247 public void clearDragOutlines() { 1248 final int oldIndex = mDragOutlineCurrent; 1249 mDragOutlineAnims[oldIndex].animateOut(); 1250 mDragCell[0] = -1; 1251 mDragCell[1] = -1; 1252 } 1253 1254 /** 1255 * Find a vacant area that will fit the given bounds nearest the requested 1256 * cell location. Uses Euclidean distance to score multiple vacant areas. 1257 * 1258 * @param pixelX The X location at which you want to search for a vacant area. 1259 * @param pixelY The Y location at which you want to search for a vacant area. 1260 * @param spanX Horizontal span of the object. 1261 * @param spanY Vertical span of the object. 1262 * @param result Array in which to place the result, or null (in which case a new array will 1263 * be allocated) 1264 * @return The X, Y cell of a vacant area that can contain this object, 1265 * nearest the requested location. 1266 */ 1267 int[] findNearestVacantArea( 1268 int pixelX, int pixelY, int spanX, int spanY, int[] result) { 1269 return findNearestVacantArea(pixelX, pixelY, spanX, spanY, null, result); 1270 } 1271 1272 /** 1273 * Find a vacant area that will fit the given bounds nearest the requested 1274 * cell location. Uses Euclidean distance to score multiple vacant areas. 1275 * 1276 * @param pixelX The X location at which you want to search for a vacant area. 1277 * @param pixelY The Y location at which you want to search for a vacant area. 1278 * @param spanX Horizontal span of the object. 1279 * @param spanY Vertical span of the object. 1280 * @param ignoreOccupied If true, the result can be an occupied cell 1281 * @param result Array in which to place the result, or null (in which case a new array will 1282 * be allocated) 1283 * @return The X, Y cell of a vacant area that can contain this object, 1284 * nearest the requested location. 1285 */ 1286 int[] findNearestArea(int pixelX, int pixelY, int spanX, int spanY, View ignoreView, 1287 boolean ignoreOccupied, int[] result) { 1288 // mark space take by ignoreView as available (method checks if ignoreView is null) 1289 markCellsAsUnoccupiedForView(ignoreView); 1290 1291 // For items with a spanX / spanY > 1, the passed in point (pixelX, pixelY) corresponds 1292 // to the center of the item, but we are searching based on the top-left cell, so 1293 // we translate the point over to correspond to the top-left. 1294 pixelX -= (mCellWidth + mWidthGap) * (spanX - 1) / 2f; 1295 pixelY -= (mCellHeight + mHeightGap) * (spanY - 1) / 2f; 1296 1297 // Keep track of best-scoring drop area 1298 final int[] bestXY = result != null ? result : new int[2]; 1299 double bestDistance = Double.MAX_VALUE; 1300 1301 final int countX = mCountX; 1302 final int countY = mCountY; 1303 final boolean[][] occupied = mOccupied; 1304 1305 for (int y = 0; y < countY - (spanY - 1); y++) { 1306 inner: 1307 for (int x = 0; x < countX - (spanX - 1); x++) { 1308 if (ignoreOccupied) { 1309 for (int i = 0; i < spanX; i++) { 1310 for (int j = 0; j < spanY; j++) { 1311 if (occupied[x + i][y + j]) { 1312 // small optimization: we can skip to after the column we 1313 // just found an occupied cell 1314 x += i; 1315 continue inner; 1316 } 1317 } 1318 } 1319 } 1320 final int[] cellXY = mTmpXY; 1321 cellToCenterPoint(x, y, cellXY); 1322 1323 double distance = Math.sqrt(Math.pow(cellXY[0] - pixelX, 2) 1324 + Math.pow(cellXY[1] - pixelY, 2)); 1325 if (distance <= bestDistance) { 1326 bestDistance = distance; 1327 bestXY[0] = x; 1328 bestXY[1] = y; 1329 } 1330 } 1331 } 1332 // re-mark space taken by ignoreView as occupied 1333 markCellsAsOccupiedForView(ignoreView); 1334 1335 // Return -1, -1 if no suitable location found 1336 if (bestDistance == Double.MAX_VALUE) { 1337 bestXY[0] = -1; 1338 bestXY[1] = -1; 1339 } 1340 return bestXY; 1341 } 1342 1343 /** 1344 * Find a vacant area that will fit the given bounds nearest the requested 1345 * cell location. Uses Euclidean distance to score multiple vacant areas. 1346 * 1347 * @param pixelX The X location at which you want to search for a vacant area. 1348 * @param pixelY The Y location at which you want to search for a vacant area. 1349 * @param spanX Horizontal span of the object. 1350 * @param spanY Vertical span of the object. 1351 * @param ignoreView Considers space occupied by this view as unoccupied 1352 * @param result Previously returned value to possibly recycle. 1353 * @return The X, Y cell of a vacant area that can contain this object, 1354 * nearest the requested location. 1355 */ 1356 int[] findNearestVacantArea( 1357 int pixelX, int pixelY, int spanX, int spanY, View ignoreView, int[] result) { 1358 return findNearestArea(pixelX, pixelY, spanX, spanY, ignoreView, true, result); 1359 } 1360 1361 /** 1362 * Find a starting cell position that will fit the given bounds nearest the requested 1363 * cell location. Uses Euclidean distance to score multiple vacant areas. 1364 * 1365 * @param pixelX The X location at which you want to search for a vacant area. 1366 * @param pixelY The Y location at which you want to search for a vacant area. 1367 * @param spanX Horizontal span of the object. 1368 * @param spanY Vertical span of the object. 1369 * @param ignoreView Considers space occupied by this view as unoccupied 1370 * @param result Previously returned value to possibly recycle. 1371 * @return The X, Y cell of a vacant area that can contain this object, 1372 * nearest the requested location. 1373 */ 1374 int[] findNearestArea( 1375 int pixelX, int pixelY, int spanX, int spanY, int[] result) { 1376 return findNearestArea(pixelX, pixelY, spanX, spanY, null, false, result); 1377 } 1378 1379 boolean existsEmptyCell() { 1380 return findCellForSpan(null, 1, 1); 1381 } 1382 1383 /** 1384 * Finds the upper-left coordinate of the first rectangle in the grid that can 1385 * hold a cell of the specified dimensions. If intersectX and intersectY are not -1, 1386 * then this method will only return coordinates for rectangles that contain the cell 1387 * (intersectX, intersectY) 1388 * 1389 * @param cellXY The array that will contain the position of a vacant cell if such a cell 1390 * can be found. 1391 * @param spanX The horizontal span of the cell we want to find. 1392 * @param spanY The vertical span of the cell we want to find. 1393 * 1394 * @return True if a vacant cell of the specified dimension was found, false otherwise. 1395 */ 1396 boolean findCellForSpan(int[] cellXY, int spanX, int spanY) { 1397 return findCellForSpanThatIntersectsIgnoring(cellXY, spanX, spanY, -1, -1, null); 1398 } 1399 1400 /** 1401 * Like above, but ignores any cells occupied by the item "ignoreView" 1402 * 1403 * @param cellXY The array that will contain the position of a vacant cell if such a cell 1404 * can be found. 1405 * @param spanX The horizontal span of the cell we want to find. 1406 * @param spanY The vertical span of the cell we want to find. 1407 * @param ignoreView The home screen item we should treat as not occupying any space 1408 * @return 1409 */ 1410 boolean findCellForSpanIgnoring(int[] cellXY, int spanX, int spanY, View ignoreView) { 1411 return findCellForSpanThatIntersectsIgnoring(cellXY, spanX, spanY, -1, -1, ignoreView); 1412 } 1413 1414 /** 1415 * Like above, but if intersectX and intersectY are not -1, then this method will try to 1416 * return coordinates for rectangles that contain the cell [intersectX, intersectY] 1417 * 1418 * @param spanX The horizontal span of the cell we want to find. 1419 * @param spanY The vertical span of the cell we want to find. 1420 * @param ignoreView The home screen item we should treat as not occupying any space 1421 * @param intersectX The X coordinate of the cell that we should try to overlap 1422 * @param intersectX The Y coordinate of the cell that we should try to overlap 1423 * 1424 * @return True if a vacant cell of the specified dimension was found, false otherwise. 1425 */ 1426 boolean findCellForSpanThatIntersects(int[] cellXY, int spanX, int spanY, 1427 int intersectX, int intersectY) { 1428 return findCellForSpanThatIntersectsIgnoring( 1429 cellXY, spanX, spanY, intersectX, intersectY, null); 1430 } 1431 1432 /** 1433 * The superset of the above two methods 1434 */ 1435 boolean findCellForSpanThatIntersectsIgnoring(int[] cellXY, int spanX, int spanY, 1436 int intersectX, int intersectY, View ignoreView) { 1437 // mark space take by ignoreView as available (method checks if ignoreView is null) 1438 markCellsAsUnoccupiedForView(ignoreView); 1439 1440 boolean foundCell = false; 1441 while (true) { 1442 int startX = 0; 1443 if (intersectX >= 0) { 1444 startX = Math.max(startX, intersectX - (spanX - 1)); 1445 } 1446 int endX = mCountX - (spanX - 1); 1447 if (intersectX >= 0) { 1448 endX = Math.min(endX, intersectX + (spanX - 1) + (spanX == 1 ? 1 : 0)); 1449 } 1450 int startY = 0; 1451 if (intersectY >= 0) { 1452 startY = Math.max(startY, intersectY - (spanY - 1)); 1453 } 1454 int endY = mCountY - (spanY - 1); 1455 if (intersectY >= 0) { 1456 endY = Math.min(endY, intersectY + (spanY - 1) + (spanY == 1 ? 1 : 0)); 1457 } 1458 1459 for (int y = startY; y < endY && !foundCell; y++) { 1460 inner: 1461 for (int x = startX; x < endX; x++) { 1462 for (int i = 0; i < spanX; i++) { 1463 for (int j = 0; j < spanY; j++) { 1464 if (mOccupied[x + i][y + j]) { 1465 // small optimization: we can skip to after the column we just found 1466 // an occupied cell 1467 x += i; 1468 continue inner; 1469 } 1470 } 1471 } 1472 if (cellXY != null) { 1473 cellXY[0] = x; 1474 cellXY[1] = y; 1475 } 1476 foundCell = true; 1477 break; 1478 } 1479 } 1480 if (intersectX == -1 && intersectY == -1) { 1481 break; 1482 } else { 1483 // if we failed to find anything, try again but without any requirements of 1484 // intersecting 1485 intersectX = -1; 1486 intersectY = -1; 1487 continue; 1488 } 1489 } 1490 1491 // re-mark space taken by ignoreView as occupied 1492 markCellsAsOccupiedForView(ignoreView); 1493 return foundCell; 1494 } 1495 1496 /** 1497 * A drag event has begun over this layout. 1498 * It may have begun over this layout (in which case onDragChild is called first), 1499 * or it may have begun on another layout. 1500 */ 1501 void onDragEnter() { 1502 if (!mDragging) { 1503 // Fade in the drag indicators 1504 if (mCrosshairsAnimator != null) { 1505 mCrosshairsAnimator.animateIn(); 1506 } 1507 } 1508 mDragging = true; 1509 } 1510 1511 /** 1512 * Called when drag has left this CellLayout or has been completed (successfully or not) 1513 */ 1514 void onDragExit() { 1515 // This can actually be called when we aren't in a drag, e.g. when adding a new 1516 // item to this layout via the customize drawer. 1517 // Guard against that case. 1518 if (mDragging) { 1519 mDragging = false; 1520 1521 // Fade out the drag indicators 1522 if (mCrosshairsAnimator != null) { 1523 mCrosshairsAnimator.animateOut(); 1524 } 1525 } 1526 1527 // Invalidate the drag data 1528 mDragCell[0] = -1; 1529 mDragCell[1] = -1; 1530 mDragOutlineAnims[mDragOutlineCurrent].animateOut(); 1531 mDragOutlineCurrent = (mDragOutlineCurrent + 1) % mDragOutlineAnims.length; 1532 1533 setIsDragOverlapping(false); 1534 } 1535 1536 /** 1537 * Mark a child as having been dropped. 1538 * At the beginning of the drag operation, the child may have been on another 1539 * screen, but it is re-parented before this method is called. 1540 * 1541 * @param child The child that is being dropped 1542 */ 1543 void onDropChild(View child) { 1544 if (child != null) { 1545 LayoutParams lp = (LayoutParams) child.getLayoutParams(); 1546 lp.dropped = true; 1547 child.requestLayout(); 1548 } 1549 } 1550 1551 /** 1552 * Computes a bounding rectangle for a range of cells 1553 * 1554 * @param cellX X coordinate of upper left corner expressed as a cell position 1555 * @param cellY Y coordinate of upper left corner expressed as a cell position 1556 * @param cellHSpan Width in cells 1557 * @param cellVSpan Height in cells 1558 * @param resultRect Rect into which to put the results 1559 */ 1560 public void cellToRect(int cellX, int cellY, int cellHSpan, int cellVSpan, RectF resultRect) { 1561 final int cellWidth = mCellWidth; 1562 final int cellHeight = mCellHeight; 1563 final int widthGap = mWidthGap; 1564 final int heightGap = mHeightGap; 1565 1566 final int hStartPadding = getPaddingLeft(); 1567 final int vStartPadding = getPaddingTop(); 1568 1569 int width = cellHSpan * cellWidth + ((cellHSpan - 1) * widthGap); 1570 int height = cellVSpan * cellHeight + ((cellVSpan - 1) * heightGap); 1571 1572 int x = hStartPadding + cellX * (cellWidth + widthGap); 1573 int y = vStartPadding + cellY * (cellHeight + heightGap); 1574 1575 resultRect.set(x, y, x + width, y + height); 1576 } 1577 1578 /** 1579 * Computes the required horizontal and vertical cell spans to always 1580 * fit the given rectangle. 1581 * 1582 * @param width Width in pixels 1583 * @param height Height in pixels 1584 * @param result An array of length 2 in which to store the result (may be null). 1585 */ 1586 public int[] rectToCell(int width, int height, int[] result) { 1587 return rectToCell(getResources(), width, height, result); 1588 } 1589 1590 public static int[] rectToCell(Resources resources, int width, int height, int[] result) { 1591 // Always assume we're working with the smallest span to make sure we 1592 // reserve enough space in both orientations. 1593 int actualWidth = resources.getDimensionPixelSize(R.dimen.workspace_cell_width); 1594 int actualHeight = resources.getDimensionPixelSize(R.dimen.workspace_cell_height); 1595 int smallerSize = Math.min(actualWidth, actualHeight); 1596 1597 // Always round up to next largest cell 1598 int spanX = (int) Math.ceil(width / (float) smallerSize); 1599 int spanY = (int) Math.ceil(height / (float) smallerSize); 1600 1601 if (result == null) { 1602 return new int[] { spanX, spanY }; 1603 } 1604 result[0] = spanX; 1605 result[1] = spanY; 1606 return result; 1607 } 1608 1609 public int[] cellSpansToSize(int hSpans, int vSpans) { 1610 int[] size = new int[2]; 1611 size[0] = hSpans * mCellWidth + (hSpans - 1) * mWidthGap; 1612 size[1] = vSpans * mCellHeight + (vSpans - 1) * mHeightGap; 1613 return size; 1614 } 1615 1616 /** 1617 * Calculate the grid spans needed to fit given item 1618 */ 1619 public void calculateSpans(ItemInfo info) { 1620 final int minWidth; 1621 final int minHeight; 1622 1623 if (info instanceof LauncherAppWidgetInfo) { 1624 minWidth = ((LauncherAppWidgetInfo) info).minWidth; 1625 minHeight = ((LauncherAppWidgetInfo) info).minHeight; 1626 } else if (info instanceof PendingAddWidgetInfo) { 1627 minWidth = ((PendingAddWidgetInfo) info).minWidth; 1628 minHeight = ((PendingAddWidgetInfo) info).minHeight; 1629 } else { 1630 // It's not a widget, so it must be 1x1 1631 info.spanX = info.spanY = 1; 1632 return; 1633 } 1634 int[] spans = rectToCell(minWidth, minHeight, null); 1635 info.spanX = spans[0]; 1636 info.spanY = spans[1]; 1637 } 1638 1639 /** 1640 * Find the first vacant cell, if there is one. 1641 * 1642 * @param vacant Holds the x and y coordinate of the vacant cell 1643 * @param spanX Horizontal cell span. 1644 * @param spanY Vertical cell span. 1645 * 1646 * @return True if a vacant cell was found 1647 */ 1648 public boolean getVacantCell(int[] vacant, int spanX, int spanY) { 1649 1650 return findVacantCell(vacant, spanX, spanY, mCountX, mCountY, mOccupied); 1651 } 1652 1653 static boolean findVacantCell(int[] vacant, int spanX, int spanY, 1654 int xCount, int yCount, boolean[][] occupied) { 1655 1656 for (int y = 0; y < yCount; y++) { 1657 for (int x = 0; x < xCount; x++) { 1658 boolean available = !occupied[x][y]; 1659 out: for (int i = x; i < x + spanX - 1 && x < xCount; i++) { 1660 for (int j = y; j < y + spanY - 1 && y < yCount; j++) { 1661 available = available && !occupied[i][j]; 1662 if (!available) break out; 1663 } 1664 } 1665 1666 if (available) { 1667 vacant[0] = x; 1668 vacant[1] = y; 1669 return true; 1670 } 1671 } 1672 } 1673 1674 return false; 1675 } 1676 1677 private void clearOccupiedCells() { 1678 for (int x = 0; x < mCountX; x++) { 1679 for (int y = 0; y < mCountY; y++) { 1680 mOccupied[x][y] = false; 1681 } 1682 } 1683 } 1684 1685 /** 1686 * Given a view, determines how much that view can be expanded in all directions, in terms of 1687 * whether or not there are other items occupying adjacent cells. Used by the 1688 * AppWidgetResizeFrame to determine how the widget can be resized. 1689 */ 1690 public void getExpandabilityArrayForView(View view, int[] expandability) { 1691 final LayoutParams lp = (LayoutParams) view.getLayoutParams(); 1692 boolean flag; 1693 1694 expandability[AppWidgetResizeFrame.LEFT] = 0; 1695 for (int x = lp.cellX - 1; x >= 0; x--) { 1696 flag = false; 1697 for (int y = lp.cellY; y < lp.cellY + lp.cellVSpan; y++) { 1698 if (mOccupied[x][y]) flag = true; 1699 } 1700 if (flag) break; 1701 expandability[AppWidgetResizeFrame.LEFT]++; 1702 } 1703 1704 expandability[AppWidgetResizeFrame.TOP] = 0; 1705 for (int y = lp.cellY - 1; y >= 0; y--) { 1706 flag = false; 1707 for (int x = lp.cellX; x < lp.cellX + lp.cellHSpan; x++) { 1708 if (mOccupied[x][y]) flag = true; 1709 } 1710 if (flag) break; 1711 expandability[AppWidgetResizeFrame.TOP]++; 1712 } 1713 1714 expandability[AppWidgetResizeFrame.RIGHT] = 0; 1715 for (int x = lp.cellX + lp.cellHSpan; x < mCountX; x++) { 1716 flag = false; 1717 for (int y = lp.cellY; y < lp.cellY + lp.cellVSpan; y++) { 1718 if (mOccupied[x][y]) flag = true; 1719 } 1720 if (flag) break; 1721 expandability[AppWidgetResizeFrame.RIGHT]++; 1722 } 1723 1724 expandability[AppWidgetResizeFrame.BOTTOM] = 0; 1725 for (int y = lp.cellY + lp.cellVSpan; y < mCountY; y++) { 1726 flag = false; 1727 for (int x = lp.cellX; x < lp.cellX + lp.cellHSpan; x++) { 1728 if (mOccupied[x][y]) flag = true; 1729 } 1730 if (flag) break; 1731 expandability[AppWidgetResizeFrame.BOTTOM]++; 1732 } 1733 } 1734 1735 public void onMove(View view, int newCellX, int newCellY) { 1736 LayoutParams lp = (LayoutParams) view.getLayoutParams(); 1737 markCellsAsUnoccupiedForView(view); 1738 markCellsForView(newCellX, newCellY, lp.cellHSpan, lp.cellVSpan, true); 1739 } 1740 1741 public void markCellsAsOccupiedForView(View view) { 1742 if (view == null || view.getParent() != mChildren) return; 1743 LayoutParams lp = (LayoutParams) view.getLayoutParams(); 1744 markCellsForView(lp.cellX, lp.cellY, lp.cellHSpan, lp.cellVSpan, true); 1745 } 1746 1747 public void markCellsAsUnoccupiedForView(View view) { 1748 if (view == null || view.getParent() != mChildren) return; 1749 LayoutParams lp = (LayoutParams) view.getLayoutParams(); 1750 markCellsForView(lp.cellX, lp.cellY, lp.cellHSpan, lp.cellVSpan, false); 1751 } 1752 1753 private void markCellsForView(int cellX, int cellY, int spanX, int spanY, boolean value) { 1754 for (int x = cellX; x < cellX + spanX && x < mCountX; x++) { 1755 for (int y = cellY; y < cellY + spanY && y < mCountY; y++) { 1756 mOccupied[x][y] = value; 1757 } 1758 } 1759 } 1760 1761 public int getDesiredWidth() { 1762 return mPaddingLeft + mPaddingRight + (mCountX * mCellWidth) + 1763 (Math.max((mCountX - 1), 0) * mWidthGap); 1764 } 1765 1766 public int getDesiredHeight() { 1767 return mPaddingTop + mPaddingBottom + (mCountY * mCellHeight) + 1768 (Math.max((mCountY - 1), 0) * mHeightGap); 1769 } 1770 1771 public boolean isOccupied(int x, int y) { 1772 if (x < mCountX && y < mCountY) { 1773 return mOccupied[x][y]; 1774 } else { 1775 throw new RuntimeException("Position exceeds the bound of this CellLayout"); 1776 } 1777 } 1778 1779 @Override 1780 public ViewGroup.LayoutParams generateLayoutParams(AttributeSet attrs) { 1781 return new CellLayout.LayoutParams(getContext(), attrs); 1782 } 1783 1784 @Override 1785 protected boolean checkLayoutParams(ViewGroup.LayoutParams p) { 1786 return p instanceof CellLayout.LayoutParams; 1787 } 1788 1789 @Override 1790 protected ViewGroup.LayoutParams generateLayoutParams(ViewGroup.LayoutParams p) { 1791 return new CellLayout.LayoutParams(p); 1792 } 1793 1794 public static class CellLayoutAnimationController extends LayoutAnimationController { 1795 public CellLayoutAnimationController(Animation animation, float delay) { 1796 super(animation, delay); 1797 } 1798 1799 @Override 1800 protected long getDelayForView(View view) { 1801 return (int) (Math.random() * 150); 1802 } 1803 } 1804 1805 public static class LayoutParams extends ViewGroup.MarginLayoutParams { 1806 /** 1807 * Horizontal location of the item in the grid. 1808 */ 1809 @ViewDebug.ExportedProperty 1810 public int cellX; 1811 1812 /** 1813 * Vertical location of the item in the grid. 1814 */ 1815 @ViewDebug.ExportedProperty 1816 public int cellY; 1817 1818 /** 1819 * Number of cells spanned horizontally by the item. 1820 */ 1821 @ViewDebug.ExportedProperty 1822 public int cellHSpan; 1823 1824 /** 1825 * Number of cells spanned vertically by the item. 1826 */ 1827 @ViewDebug.ExportedProperty 1828 public int cellVSpan; 1829 1830 /** 1831 * Indicates whether the item will set its x, y, width and height parameters freely, 1832 * or whether these will be computed based on cellX, cellY, cellHSpan and cellVSpan. 1833 */ 1834 public boolean isLockedToGrid = true; 1835 1836 // X coordinate of the view in the layout. 1837 @ViewDebug.ExportedProperty 1838 int x; 1839 // Y coordinate of the view in the layout. 1840 @ViewDebug.ExportedProperty 1841 int y; 1842 1843 boolean dropped; 1844 1845 public LayoutParams(Context c, AttributeSet attrs) { 1846 super(c, attrs); 1847 cellHSpan = 1; 1848 cellVSpan = 1; 1849 } 1850 1851 public LayoutParams(ViewGroup.LayoutParams source) { 1852 super(source); 1853 cellHSpan = 1; 1854 cellVSpan = 1; 1855 } 1856 1857 public LayoutParams(LayoutParams source) { 1858 super(source); 1859 this.cellX = source.cellX; 1860 this.cellY = source.cellY; 1861 this.cellHSpan = source.cellHSpan; 1862 this.cellVSpan = source.cellVSpan; 1863 } 1864 1865 public LayoutParams(int cellX, int cellY, int cellHSpan, int cellVSpan) { 1866 super(LayoutParams.MATCH_PARENT, LayoutParams.MATCH_PARENT); 1867 this.cellX = cellX; 1868 this.cellY = cellY; 1869 this.cellHSpan = cellHSpan; 1870 this.cellVSpan = cellVSpan; 1871 } 1872 1873 public void setup(int cellWidth, int cellHeight, int widthGap, int heightGap) { 1874 if (isLockedToGrid) { 1875 final int myCellHSpan = cellHSpan; 1876 final int myCellVSpan = cellVSpan; 1877 final int myCellX = cellX; 1878 final int myCellY = cellY; 1879 1880 width = myCellHSpan * cellWidth + ((myCellHSpan - 1) * widthGap) - 1881 leftMargin - rightMargin; 1882 height = myCellVSpan * cellHeight + ((myCellVSpan - 1) * heightGap) - 1883 topMargin - bottomMargin; 1884 x = myCellX * (cellWidth + widthGap) + leftMargin; 1885 y = myCellY * (cellHeight + heightGap) + topMargin; 1886 } 1887 } 1888 1889 public String toString() { 1890 return "(" + this.cellX + ", " + this.cellY + ")"; 1891 } 1892 1893 public void setWidth(int width) { 1894 this.width = width; 1895 } 1896 1897 public int getWidth() { 1898 return width; 1899 } 1900 1901 public void setHeight(int height) { 1902 this.height = height; 1903 } 1904 1905 public int getHeight() { 1906 return height; 1907 } 1908 1909 public void setX(int x) { 1910 this.x = x; 1911 } 1912 1913 public int getX() { 1914 return x; 1915 } 1916 1917 public void setY(int y) { 1918 this.y = y; 1919 } 1920 1921 public int getY() { 1922 return y; 1923 } 1924 } 1925 1926 // This class stores info for two purposes: 1927 // 1. When dragging items (mDragInfo in Workspace), we store the View, its cellX & cellY, 1928 // its spanX, spanY, and the screen it is on 1929 // 2. When long clicking on an empty cell in a CellLayout, we save information about the 1930 // cellX and cellY coordinates and which page was clicked. We then set this as a tag on 1931 // the CellLayout that was long clicked 1932 static final class CellInfo { 1933 View cell; 1934 int cellX = -1; 1935 int cellY = -1; 1936 int spanX; 1937 int spanY; 1938 int screen; 1939 long container; 1940 1941 @Override 1942 public String toString() { 1943 return "Cell[view=" + (cell == null ? "null" : cell.getClass()) 1944 + ", x=" + cellX + ", y=" + cellY + "]"; 1945 } 1946 } 1947 1948 public boolean lastDownOnOccupiedCell() { 1949 return mLastDownOnOccupiedCell; 1950 } 1951 } 1952
