1 /* 2 * Copyright (C) 2006 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 android.graphics; 18 19 import android.annotation.CheckResult; 20 import android.annotation.ColorInt; 21 import android.annotation.ColorLong; 22 import android.annotation.NonNull; 23 import android.annotation.Nullable; 24 import android.annotation.UnsupportedAppUsage; 25 import android.annotation.WorkerThread; 26 import android.content.res.ResourcesImpl; 27 import android.hardware.HardwareBuffer; 28 import android.os.Build; 29 import android.os.Parcel; 30 import android.os.Parcelable; 31 import android.os.StrictMode; 32 import android.os.Trace; 33 import android.util.DisplayMetrics; 34 import android.util.Half; 35 import android.util.Log; 36 import android.view.ThreadedRenderer; 37 38 import dalvik.annotation.optimization.CriticalNative; 39 40 import libcore.util.NativeAllocationRegistry; 41 42 import java.io.OutputStream; 43 import java.nio.Buffer; 44 import java.nio.ByteBuffer; 45 import java.nio.IntBuffer; 46 import java.nio.ShortBuffer; 47 48 public final class Bitmap implements Parcelable { 49 private static final String TAG = "Bitmap"; 50 51 /** 52 * Indicates that the bitmap was created for an unknown pixel density. 53 * 54 * @see Bitmap#getDensity() 55 * @see Bitmap#setDensity(int) 56 */ 57 public static final int DENSITY_NONE = 0; 58 59 // Estimated size of the Bitmap native allocation, not including 60 // pixel data. 61 private static final long NATIVE_ALLOCATION_SIZE = 32; 62 63 // Convenience for JNI access 64 @UnsupportedAppUsage 65 private final long mNativePtr; 66 67 /** 68 * Represents whether the Bitmap's content is requested to be pre-multiplied. 69 * Note that isPremultiplied() does not directly return this value, because 70 * isPremultiplied() may never return true for a 565 Bitmap or a bitmap 71 * without alpha. 72 * 73 * setPremultiplied() does directly set the value so that setConfig() and 74 * setPremultiplied() aren't order dependent, despite being setters. 75 * 76 * The native bitmap's premultiplication state is kept up to date by 77 * pushing down this preference for every config change. 78 */ 79 private boolean mRequestPremultiplied; 80 81 @UnsupportedAppUsage(maxTargetSdk = Build.VERSION_CODES.P, trackingBug = 123769491) 82 private byte[] mNinePatchChunk; // may be null 83 @UnsupportedAppUsage 84 private NinePatch.InsetStruct mNinePatchInsets; // may be null 85 @UnsupportedAppUsage 86 private int mWidth; 87 @UnsupportedAppUsage 88 private int mHeight; 89 private boolean mRecycled; 90 91 private ColorSpace mColorSpace; 92 93 /** @hide */ 94 public int mDensity = getDefaultDensity(); 95 96 private static volatile int sDefaultDensity = -1; 97 98 /** @hide Used only when ResourcesImpl.TRACE_FOR_DETAILED_PRELOAD is true. */ 99 public static volatile int sPreloadTracingNumInstantiatedBitmaps; 100 101 /** @hide Used only when ResourcesImpl.TRACE_FOR_DETAILED_PRELOAD is true. */ 102 public static volatile long sPreloadTracingTotalBitmapsSize; 103 104 /** 105 * For backwards compatibility, allows the app layer to change the default 106 * density when running old apps. 107 * @hide 108 */ 109 @UnsupportedAppUsage setDefaultDensity(int density)110 public static void setDefaultDensity(int density) { 111 sDefaultDensity = density; 112 } 113 114 @SuppressWarnings("deprecation") 115 @UnsupportedAppUsage getDefaultDensity()116 static int getDefaultDensity() { 117 if (sDefaultDensity >= 0) { 118 return sDefaultDensity; 119 } 120 sDefaultDensity = DisplayMetrics.DENSITY_DEVICE; 121 return sDefaultDensity; 122 } 123 124 /** 125 * Private constructor that must receive an already allocated native bitmap 126 * int (pointer). 127 */ 128 // JNI now calls the version below this one. This is preserved due to UnsupportedAppUsage. 129 @UnsupportedAppUsage(maxTargetSdk = 28) Bitmap(long nativeBitmap, int width, int height, int density, boolean requestPremultiplied, byte[] ninePatchChunk, NinePatch.InsetStruct ninePatchInsets)130 Bitmap(long nativeBitmap, int width, int height, int density, 131 boolean requestPremultiplied, byte[] ninePatchChunk, 132 NinePatch.InsetStruct ninePatchInsets) { 133 this(nativeBitmap, width, height, density, requestPremultiplied, ninePatchChunk, 134 ninePatchInsets, true); 135 } 136 137 // called from JNI and Bitmap_Delegate. Bitmap(long nativeBitmap, int width, int height, int density, boolean requestPremultiplied, byte[] ninePatchChunk, NinePatch.InsetStruct ninePatchInsets, boolean fromMalloc)138 Bitmap(long nativeBitmap, int width, int height, int density, 139 boolean requestPremultiplied, byte[] ninePatchChunk, 140 NinePatch.InsetStruct ninePatchInsets, boolean fromMalloc) { 141 if (nativeBitmap == 0) { 142 throw new RuntimeException("internal error: native bitmap is 0"); 143 } 144 145 mWidth = width; 146 mHeight = height; 147 mRequestPremultiplied = requestPremultiplied; 148 149 mNinePatchChunk = ninePatchChunk; 150 mNinePatchInsets = ninePatchInsets; 151 if (density >= 0) { 152 mDensity = density; 153 } 154 155 mNativePtr = nativeBitmap; 156 157 final int allocationByteCount = getAllocationByteCount(); 158 NativeAllocationRegistry registry; 159 if (fromMalloc) { 160 registry = NativeAllocationRegistry.createMalloced( 161 Bitmap.class.getClassLoader(), nativeGetNativeFinalizer(), allocationByteCount); 162 } else { 163 registry = NativeAllocationRegistry.createNonmalloced( 164 Bitmap.class.getClassLoader(), nativeGetNativeFinalizer(), allocationByteCount); 165 } 166 registry.registerNativeAllocation(this, nativeBitmap); 167 168 if (ResourcesImpl.TRACE_FOR_DETAILED_PRELOAD) { 169 sPreloadTracingNumInstantiatedBitmaps++; 170 long nativeSize = NATIVE_ALLOCATION_SIZE + allocationByteCount; 171 sPreloadTracingTotalBitmapsSize += nativeSize; 172 } 173 } 174 175 /** 176 * Return the pointer to the native object. 177 * @hide 178 */ getNativeInstance()179 public long getNativeInstance() { 180 return mNativePtr; 181 } 182 183 /** 184 * Native bitmap has been reconfigured, so set premult and cached 185 * width/height values 186 */ 187 @SuppressWarnings("unused") // called from JNI 188 @UnsupportedAppUsage reinit(int width, int height, boolean requestPremultiplied)189 void reinit(int width, int height, boolean requestPremultiplied) { 190 mWidth = width; 191 mHeight = height; 192 mRequestPremultiplied = requestPremultiplied; 193 mColorSpace = null; 194 } 195 196 /** 197 * <p>Returns the density for this bitmap.</p> 198 * 199 * <p>The default density is the same density as the current display, 200 * unless the current application does not support different screen 201 * densities in which case it is 202 * {@link android.util.DisplayMetrics#DENSITY_DEFAULT}. Note that 203 * compatibility mode is determined by the application that was initially 204 * loaded into a process -- applications that share the same process should 205 * all have the same compatibility, or ensure they explicitly set the 206 * density of their bitmaps appropriately.</p> 207 * 208 * @return A scaling factor of the default density or {@link #DENSITY_NONE} 209 * if the scaling factor is unknown. 210 * 211 * @see #setDensity(int) 212 * @see android.util.DisplayMetrics#DENSITY_DEFAULT 213 * @see android.util.DisplayMetrics#densityDpi 214 * @see #DENSITY_NONE 215 */ getDensity()216 public int getDensity() { 217 if (mRecycled) { 218 Log.w(TAG, "Called getDensity() on a recycle()'d bitmap! This is undefined behavior!"); 219 } 220 return mDensity; 221 } 222 223 /** 224 * <p>Specifies the density for this bitmap. When the bitmap is 225 * drawn to a Canvas that also has a density, it will be scaled 226 * appropriately.</p> 227 * 228 * @param density The density scaling factor to use with this bitmap or 229 * {@link #DENSITY_NONE} if the density is unknown. 230 * 231 * @see #getDensity() 232 * @see android.util.DisplayMetrics#DENSITY_DEFAULT 233 * @see android.util.DisplayMetrics#densityDpi 234 * @see #DENSITY_NONE 235 */ setDensity(int density)236 public void setDensity(int density) { 237 mDensity = density; 238 } 239 240 /** 241 * <p>Modifies the bitmap to have a specified width, height, and {@link 242 * Config}, without affecting the underlying allocation backing the bitmap. 243 * Bitmap pixel data is not re-initialized for the new configuration.</p> 244 * 245 * <p>This method can be used to avoid allocating a new bitmap, instead 246 * reusing an existing bitmap's allocation for a new configuration of equal 247 * or lesser size. If the Bitmap's allocation isn't large enough to support 248 * the new configuration, an IllegalArgumentException will be thrown and the 249 * bitmap will not be modified.</p> 250 * 251 * <p>The result of {@link #getByteCount()} will reflect the new configuration, 252 * while {@link #getAllocationByteCount()} will reflect that of the initial 253 * configuration.</p> 254 * 255 * <p>Note: This may change this result of hasAlpha(). When converting to 565, 256 * the new bitmap will always be considered opaque. When converting from 565, 257 * the new bitmap will be considered non-opaque, and will respect the value 258 * set by setPremultiplied().</p> 259 * 260 * <p>WARNING: This method should NOT be called on a bitmap currently in use 261 * by the view system, Canvas, or the AndroidBitmap NDK API. It does not 262 * make guarantees about how the underlying pixel buffer is remapped to the 263 * new config, just that the allocation is reused. Additionally, the view 264 * system does not account for bitmap properties being modifying during use, 265 * e.g. while attached to drawables.</p> 266 * 267 * <p>In order to safely ensure that a Bitmap is no longer in use by the 268 * View system it is necessary to wait for a draw pass to occur after 269 * invalidate()'ing any view that had previously drawn the Bitmap in the last 270 * draw pass due to hardware acceleration's caching of draw commands. As 271 * an example, here is how this can be done for an ImageView: 272 * <pre class="prettyprint"> 273 * ImageView myImageView = ...; 274 * final Bitmap myBitmap = ...; 275 * myImageView.setImageDrawable(null); 276 * myImageView.post(new Runnable() { 277 * public void run() { 278 * // myBitmap is now no longer in use by the ImageView 279 * // and can be safely reconfigured. 280 * myBitmap.reconfigure(...); 281 * } 282 * }); 283 * </pre></p> 284 * 285 * @see #setWidth(int) 286 * @see #setHeight(int) 287 * @see #setConfig(Config) 288 */ reconfigure(int width, int height, Config config)289 public void reconfigure(int width, int height, Config config) { 290 checkRecycled("Can't call reconfigure() on a recycled bitmap"); 291 if (width <= 0 || height <= 0) { 292 throw new IllegalArgumentException("width and height must be > 0"); 293 } 294 if (!isMutable()) { 295 throw new IllegalStateException("only mutable bitmaps may be reconfigured"); 296 } 297 298 nativeReconfigure(mNativePtr, width, height, config.nativeInt, mRequestPremultiplied); 299 mWidth = width; 300 mHeight = height; 301 mColorSpace = null; 302 } 303 304 /** 305 * <p>Convenience method for calling {@link #reconfigure(int, int, Config)} 306 * with the current height and config.</p> 307 * 308 * <p>WARNING: this method should not be used on bitmaps currently used by 309 * the view system, see {@link #reconfigure(int, int, Config)} for more 310 * details.</p> 311 * 312 * @see #reconfigure(int, int, Config) 313 * @see #setHeight(int) 314 * @see #setConfig(Config) 315 */ setWidth(int width)316 public void setWidth(int width) { 317 reconfigure(width, getHeight(), getConfig()); 318 } 319 320 /** 321 * <p>Convenience method for calling {@link #reconfigure(int, int, Config)} 322 * with the current width and config.</p> 323 * 324 * <p>WARNING: this method should not be used on bitmaps currently used by 325 * the view system, see {@link #reconfigure(int, int, Config)} for more 326 * details.</p> 327 * 328 * @see #reconfigure(int, int, Config) 329 * @see #setWidth(int) 330 * @see #setConfig(Config) 331 */ setHeight(int height)332 public void setHeight(int height) { 333 reconfigure(getWidth(), height, getConfig()); 334 } 335 336 /** 337 * <p>Convenience method for calling {@link #reconfigure(int, int, Config)} 338 * with the current height and width.</p> 339 * 340 * <p>WARNING: this method should not be used on bitmaps currently used by 341 * the view system, see {@link #reconfigure(int, int, Config)} for more 342 * details.</p> 343 * 344 * @see #reconfigure(int, int, Config) 345 * @see #setWidth(int) 346 * @see #setHeight(int) 347 */ setConfig(Config config)348 public void setConfig(Config config) { 349 reconfigure(getWidth(), getHeight(), config); 350 } 351 352 /** 353 * Sets the nine patch chunk. 354 * 355 * @param chunk The definition of the nine patch 356 * 357 * @hide 358 */ 359 @UnsupportedAppUsage setNinePatchChunk(byte[] chunk)360 public void setNinePatchChunk(byte[] chunk) { 361 mNinePatchChunk = chunk; 362 } 363 364 /** 365 * Free the native object associated with this bitmap, and clear the 366 * reference to the pixel data. This will not free the pixel data synchronously; 367 * it simply allows it to be garbage collected if there are no other references. 368 * The bitmap is marked as "dead", meaning it will throw an exception if 369 * getPixels() or setPixels() is called, and will draw nothing. This operation 370 * cannot be reversed, so it should only be called if you are sure there are no 371 * further uses for the bitmap. This is an advanced call, and normally need 372 * not be called, since the normal GC process will free up this memory when 373 * there are no more references to this bitmap. 374 */ recycle()375 public void recycle() { 376 if (!mRecycled) { 377 nativeRecycle(mNativePtr); 378 mNinePatchChunk = null; 379 mRecycled = true; 380 } 381 } 382 383 /** 384 * Returns true if this bitmap has been recycled. If so, then it is an error 385 * to try to access its pixels, and the bitmap will not draw. 386 * 387 * @return true if the bitmap has been recycled 388 */ isRecycled()389 public final boolean isRecycled() { 390 return mRecycled; 391 } 392 393 /** 394 * Returns the generation ID of this bitmap. The generation ID changes 395 * whenever the bitmap is modified. This can be used as an efficient way to 396 * check if a bitmap has changed. 397 * 398 * @return The current generation ID for this bitmap. 399 */ getGenerationId()400 public int getGenerationId() { 401 if (mRecycled) { 402 Log.w(TAG, "Called getGenerationId() on a recycle()'d bitmap! This is undefined behavior!"); 403 } 404 return nativeGenerationId(mNativePtr); 405 } 406 407 /** 408 * This is called by methods that want to throw an exception if the bitmap 409 * has already been recycled. 410 */ checkRecycled(String errorMessage)411 private void checkRecycled(String errorMessage) { 412 if (mRecycled) { 413 throw new IllegalStateException(errorMessage); 414 } 415 } 416 417 /** 418 * This is called by methods that want to throw an exception if the bitmap 419 * is {@link Config#HARDWARE}. 420 */ checkHardware(String errorMessage)421 private void checkHardware(String errorMessage) { 422 if (getConfig() == Config.HARDWARE) { 423 throw new IllegalStateException(errorMessage); 424 } 425 } 426 427 /** 428 * Common code for checking that x and y are >= 0 429 * 430 * @param x x coordinate to ensure is >= 0 431 * @param y y coordinate to ensure is >= 0 432 */ checkXYSign(int x, int y)433 private static void checkXYSign(int x, int y) { 434 if (x < 0) { 435 throw new IllegalArgumentException("x must be >= 0"); 436 } 437 if (y < 0) { 438 throw new IllegalArgumentException("y must be >= 0"); 439 } 440 } 441 442 /** 443 * Common code for checking that width and height are > 0 444 * 445 * @param width width to ensure is > 0 446 * @param height height to ensure is > 0 447 */ checkWidthHeight(int width, int height)448 private static void checkWidthHeight(int width, int height) { 449 if (width <= 0) { 450 throw new IllegalArgumentException("width must be > 0"); 451 } 452 if (height <= 0) { 453 throw new IllegalArgumentException("height must be > 0"); 454 } 455 } 456 457 /** 458 * Possible bitmap configurations. A bitmap configuration describes 459 * how pixels are stored. This affects the quality (color depth) as 460 * well as the ability to display transparent/translucent colors. 461 */ 462 public enum Config { 463 // these native values must match up with the enum in SkBitmap.h 464 465 /** 466 * Each pixel is stored as a single translucency (alpha) channel. 467 * This is very useful to efficiently store masks for instance. 468 * No color information is stored. 469 * With this configuration, each pixel requires 1 byte of memory. 470 */ 471 ALPHA_8 (1), 472 473 /** 474 * Each pixel is stored on 2 bytes and only the RGB channels are 475 * encoded: red is stored with 5 bits of precision (32 possible 476 * values), green is stored with 6 bits of precision (64 possible 477 * values) and blue is stored with 5 bits of precision. 478 * 479 * This configuration can produce slight visual artifacts depending 480 * on the configuration of the source. For instance, without 481 * dithering, the result might show a greenish tint. To get better 482 * results dithering should be applied. 483 * 484 * This configuration may be useful when using opaque bitmaps 485 * that do not require high color fidelity. 486 * 487 * <p>Use this formula to pack into 16 bits:</p> 488 * <pre class="prettyprint"> 489 * short color = (R & 0x1f) << 11 | (G & 0x3f) << 5 | (B & 0x1f); 490 * </pre> 491 */ 492 RGB_565 (3), 493 494 /** 495 * Each pixel is stored on 2 bytes. The three RGB color channels 496 * and the alpha channel (translucency) are stored with a 4 bits 497 * precision (16 possible values.) 498 * 499 * This configuration is mostly useful if the application needs 500 * to store translucency information but also needs to save 501 * memory. 502 * 503 * It is recommended to use {@link #ARGB_8888} instead of this 504 * configuration. 505 * 506 * Note: as of {@link android.os.Build.VERSION_CODES#KITKAT}, 507 * any bitmap created with this configuration will be created 508 * using {@link #ARGB_8888} instead. 509 * 510 * @deprecated Because of the poor quality of this configuration, 511 * it is advised to use {@link #ARGB_8888} instead. 512 */ 513 @Deprecated 514 ARGB_4444 (4), 515 516 /** 517 * Each pixel is stored on 4 bytes. Each channel (RGB and alpha 518 * for translucency) is stored with 8 bits of precision (256 519 * possible values.) 520 * 521 * This configuration is very flexible and offers the best 522 * quality. It should be used whenever possible. 523 * 524 * <p>Use this formula to pack into 32 bits:</p> 525 * <pre class="prettyprint"> 526 * int color = (A & 0xff) << 24 | (B & 0xff) << 16 | (G & 0xff) << 8 | (R & 0xff); 527 * </pre> 528 */ 529 ARGB_8888 (5), 530 531 /** 532 * Each pixels is stored on 8 bytes. Each channel (RGB and alpha 533 * for translucency) is stored as a 534 * {@link android.util.Half half-precision floating point value}. 535 * 536 * This configuration is particularly suited for wide-gamut and 537 * HDR content. 538 * 539 * <p>Use this formula to pack into 64 bits:</p> 540 * <pre class="prettyprint"> 541 * long color = (A & 0xffff) << 48 | (B & 0xffff) << 32 | (G & 0xffff) << 16 | (R & 0xffff); 542 * </pre> 543 */ 544 RGBA_F16 (6), 545 546 /** 547 * Special configuration, when bitmap is stored only in graphic memory. 548 * Bitmaps in this configuration are always immutable. 549 * 550 * It is optimal for cases, when the only operation with the bitmap is to draw it on a 551 * screen. 552 */ 553 HARDWARE (7); 554 555 @UnsupportedAppUsage 556 final int nativeInt; 557 558 private static Config sConfigs[] = { 559 null, ALPHA_8, null, RGB_565, ARGB_4444, ARGB_8888, RGBA_F16, HARDWARE 560 }; 561 Config(int ni)562 Config(int ni) { 563 this.nativeInt = ni; 564 } 565 566 @UnsupportedAppUsage nativeToConfig(int ni)567 static Config nativeToConfig(int ni) { 568 return sConfigs[ni]; 569 } 570 } 571 572 /** 573 * <p>Copy the bitmap's pixels into the specified buffer (allocated by the 574 * caller). An exception is thrown if the buffer is not large enough to 575 * hold all of the pixels (taking into account the number of bytes per 576 * pixel) or if the Buffer subclass is not one of the support types 577 * (ByteBuffer, ShortBuffer, IntBuffer).</p> 578 * <p>The content of the bitmap is copied into the buffer as-is. This means 579 * that if this bitmap stores its pixels pre-multiplied 580 * (see {@link #isPremultiplied()}, the values in the buffer will also be 581 * pre-multiplied. The pixels remain in the color space of the bitmap.</p> 582 * <p>After this method returns, the current position of the buffer is 583 * updated: the position is incremented by the number of elements written 584 * in the buffer.</p> 585 * @throws IllegalStateException if the bitmap's config is {@link Config#HARDWARE} 586 */ copyPixelsToBuffer(Buffer dst)587 public void copyPixelsToBuffer(Buffer dst) { 588 checkHardware("unable to copyPixelsToBuffer, " 589 + "pixel access is not supported on Config#HARDWARE bitmaps"); 590 int elements = dst.remaining(); 591 int shift; 592 if (dst instanceof ByteBuffer) { 593 shift = 0; 594 } else if (dst instanceof ShortBuffer) { 595 shift = 1; 596 } else if (dst instanceof IntBuffer) { 597 shift = 2; 598 } else { 599 throw new RuntimeException("unsupported Buffer subclass"); 600 } 601 602 long bufferSize = (long)elements << shift; 603 long pixelSize = getByteCount(); 604 605 if (bufferSize < pixelSize) { 606 throw new RuntimeException("Buffer not large enough for pixels"); 607 } 608 609 nativeCopyPixelsToBuffer(mNativePtr, dst); 610 611 // now update the buffer's position 612 int position = dst.position(); 613 position += pixelSize >> shift; 614 dst.position(position); 615 } 616 617 /** 618 * <p>Copy the pixels from the buffer, beginning at the current position, 619 * overwriting the bitmap's pixels. The data in the buffer is not changed 620 * in any way (unlike setPixels(), which converts from unpremultipled 32bit 621 * to whatever the bitmap's native format is. The pixels in the source 622 * buffer are assumed to be in the bitmap's color space.</p> 623 * <p>After this method returns, the current position of the buffer is 624 * updated: the position is incremented by the number of elements read from 625 * the buffer. If you need to read the bitmap from the buffer again you must 626 * first rewind the buffer.</p> 627 * @throws IllegalStateException if the bitmap's config is {@link Config#HARDWARE} 628 */ copyPixelsFromBuffer(Buffer src)629 public void copyPixelsFromBuffer(Buffer src) { 630 checkRecycled("copyPixelsFromBuffer called on recycled bitmap"); 631 checkHardware("unable to copyPixelsFromBuffer, Config#HARDWARE bitmaps are immutable"); 632 633 int elements = src.remaining(); 634 int shift; 635 if (src instanceof ByteBuffer) { 636 shift = 0; 637 } else if (src instanceof ShortBuffer) { 638 shift = 1; 639 } else if (src instanceof IntBuffer) { 640 shift = 2; 641 } else { 642 throw new RuntimeException("unsupported Buffer subclass"); 643 } 644 645 long bufferBytes = (long) elements << shift; 646 long bitmapBytes = getByteCount(); 647 648 if (bufferBytes < bitmapBytes) { 649 throw new RuntimeException("Buffer not large enough for pixels"); 650 } 651 652 nativeCopyPixelsFromBuffer(mNativePtr, src); 653 654 // now update the buffer's position 655 int position = src.position(); 656 position += bitmapBytes >> shift; 657 src.position(position); 658 } 659 noteHardwareBitmapSlowCall()660 private void noteHardwareBitmapSlowCall() { 661 if (getConfig() == Config.HARDWARE) { 662 StrictMode.noteSlowCall("Warning: attempt to read pixels from hardware " 663 + "bitmap, which is very slow operation"); 664 } 665 } 666 667 /** 668 * Tries to make a new bitmap based on the dimensions of this bitmap, 669 * setting the new bitmap's config to the one specified, and then copying 670 * this bitmap's pixels into the new bitmap. If the conversion is not 671 * supported, or the allocator fails, then this returns NULL. The returned 672 * bitmap has the same density and color space as the original, except in 673 * the following cases. When copying to {@link Config#ALPHA_8}, the color 674 * space is dropped. When copying to or from {@link Config#RGBA_F16}, 675 * EXTENDED or non-EXTENDED variants may be adjusted as appropriate. 676 * 677 * @param config The desired config for the resulting bitmap 678 * @param isMutable True if the resulting bitmap should be mutable (i.e. 679 * its pixels can be modified) 680 * @return the new bitmap, or null if the copy could not be made. 681 * @throws IllegalArgumentException if config is {@link Config#HARDWARE} and isMutable is true 682 */ copy(Config config, boolean isMutable)683 public Bitmap copy(Config config, boolean isMutable) { 684 checkRecycled("Can't copy a recycled bitmap"); 685 if (config == Config.HARDWARE && isMutable) { 686 throw new IllegalArgumentException("Hardware bitmaps are always immutable"); 687 } 688 noteHardwareBitmapSlowCall(); 689 Bitmap b = nativeCopy(mNativePtr, config.nativeInt, isMutable); 690 if (b != null) { 691 b.setPremultiplied(mRequestPremultiplied); 692 b.mDensity = mDensity; 693 } 694 return b; 695 } 696 697 /** 698 * Creates a new immutable bitmap backed by ashmem which can efficiently 699 * be passed between processes. The bitmap is assumed to be in the sRGB 700 * color space. 701 * 702 * @hide 703 */ 704 @UnsupportedAppUsage createAshmemBitmap()705 public Bitmap createAshmemBitmap() { 706 checkRecycled("Can't copy a recycled bitmap"); 707 noteHardwareBitmapSlowCall(); 708 Bitmap b = nativeCopyAshmem(mNativePtr); 709 if (b != null) { 710 b.setPremultiplied(mRequestPremultiplied); 711 b.mDensity = mDensity; 712 } 713 return b; 714 } 715 716 /** 717 * Creates a new immutable bitmap backed by ashmem which can efficiently 718 * be passed between processes. The bitmap is assumed to be in the sRGB 719 * color space. 720 * 721 * @hide 722 */ 723 @UnsupportedAppUsage createAshmemBitmap(Config config)724 public Bitmap createAshmemBitmap(Config config) { 725 checkRecycled("Can't copy a recycled bitmap"); 726 noteHardwareBitmapSlowCall(); 727 Bitmap b = nativeCopyAshmemConfig(mNativePtr, config.nativeInt); 728 if (b != null) { 729 b.setPremultiplied(mRequestPremultiplied); 730 b.mDensity = mDensity; 731 } 732 return b; 733 } 734 735 /** 736 * Create a hardware bitmap backed by a {@link HardwareBuffer}. 737 * 738 * <p>The passed HardwareBuffer's usage flags must contain 739 * {@link HardwareBuffer#USAGE_GPU_SAMPLED_IMAGE}. 740 * 741 * <p>The bitmap will keep a reference to the buffer so that callers can safely close the 742 * HardwareBuffer without affecting the Bitmap. However the HardwareBuffer must not be 743 * modified while a wrapped Bitmap is accessing it. Doing so will result in undefined behavior. 744 * 745 * @param hardwareBuffer The HardwareBuffer to wrap. 746 * @param colorSpace The color space of the bitmap. Must be a {@link ColorSpace.Rgb} colorspace. 747 * If null, SRGB is assumed. 748 * @return A bitmap wrapping the buffer, or null if there was a problem creating the bitmap. 749 * @throws IllegalArgumentException if the HardwareBuffer has an invalid usage, or an invalid 750 * colorspace is given. 751 */ 752 @Nullable wrapHardwareBuffer(@onNull HardwareBuffer hardwareBuffer, @Nullable ColorSpace colorSpace)753 public static Bitmap wrapHardwareBuffer(@NonNull HardwareBuffer hardwareBuffer, 754 @Nullable ColorSpace colorSpace) { 755 if ((hardwareBuffer.getUsage() & HardwareBuffer.USAGE_GPU_SAMPLED_IMAGE) == 0) { 756 throw new IllegalArgumentException("usage flags must contain USAGE_GPU_SAMPLED_IMAGE."); 757 } 758 int format = hardwareBuffer.getFormat(); 759 if (colorSpace == null) { 760 colorSpace = ColorSpace.get(ColorSpace.Named.SRGB); 761 } 762 return nativeWrapHardwareBufferBitmap(hardwareBuffer, colorSpace.getNativeInstance()); 763 } 764 765 /** 766 * Utility method to create a hardware backed bitmap using the graphics buffer. 767 * @hide 768 */ 769 @Nullable wrapHardwareBuffer(@onNull GraphicBuffer graphicBuffer, @Nullable ColorSpace colorSpace)770 public static Bitmap wrapHardwareBuffer(@NonNull GraphicBuffer graphicBuffer, 771 @Nullable ColorSpace colorSpace) { 772 try (HardwareBuffer hb = HardwareBuffer.createFromGraphicBuffer(graphicBuffer)) { 773 return wrapHardwareBuffer(hb, colorSpace); 774 } 775 } 776 777 /** 778 * Creates a new bitmap, scaled from an existing bitmap, when possible. If the 779 * specified width and height are the same as the current width and height of 780 * the source bitmap, the source bitmap is returned and no new bitmap is 781 * created. 782 * 783 * @param src The source bitmap. 784 * @param dstWidth The new bitmap's desired width. 785 * @param dstHeight The new bitmap's desired height. 786 * @param filter Whether or not bilinear filtering should be used when scaling the 787 * bitmap. If this is true then bilinear filtering will be used when 788 * scaling which has better image quality at the cost of worse performance. 789 * If this is false then nearest-neighbor scaling is used instead which 790 * will have worse image quality but is faster. Recommended default 791 * is to set filter to 'true' as the cost of bilinear filtering is 792 * typically minimal and the improved image quality is significant. 793 * @return The new scaled bitmap or the source bitmap if no scaling is required. 794 * @throws IllegalArgumentException if width is <= 0, or height is <= 0 795 */ createScaledBitmap(@onNull Bitmap src, int dstWidth, int dstHeight, boolean filter)796 public static Bitmap createScaledBitmap(@NonNull Bitmap src, int dstWidth, int dstHeight, 797 boolean filter) { 798 Matrix m = new Matrix(); 799 800 final int width = src.getWidth(); 801 final int height = src.getHeight(); 802 if (width != dstWidth || height != dstHeight) { 803 final float sx = dstWidth / (float) width; 804 final float sy = dstHeight / (float) height; 805 m.setScale(sx, sy); 806 } 807 return Bitmap.createBitmap(src, 0, 0, width, height, m, filter); 808 } 809 810 /** 811 * Returns a bitmap from the source bitmap. The new bitmap may 812 * be the same object as source, or a copy may have been made. It is 813 * initialized with the same density and color space as the original bitmap. 814 */ createBitmap(@onNull Bitmap src)815 public static Bitmap createBitmap(@NonNull Bitmap src) { 816 return createBitmap(src, 0, 0, src.getWidth(), src.getHeight()); 817 } 818 819 /** 820 * Returns a bitmap from the specified subset of the source 821 * bitmap. The new bitmap may be the same object as source, or a copy may 822 * have been made. It is initialized with the same density and color space 823 * as the original bitmap. 824 * 825 * @param source The bitmap we are subsetting 826 * @param x The x coordinate of the first pixel in source 827 * @param y The y coordinate of the first pixel in source 828 * @param width The number of pixels in each row 829 * @param height The number of rows 830 * @return A copy of a subset of the source bitmap or the source bitmap itself. 831 * @throws IllegalArgumentException if the x, y, width, height values are 832 * outside of the dimensions of the source bitmap, or width is <= 0, 833 * or height is <= 0 834 */ createBitmap(@onNull Bitmap source, int x, int y, int width, int height)835 public static Bitmap createBitmap(@NonNull Bitmap source, int x, int y, int width, int height) { 836 return createBitmap(source, x, y, width, height, null, false); 837 } 838 839 /** 840 * Returns a bitmap from subset of the source bitmap, 841 * transformed by the optional matrix. The new bitmap may be the 842 * same object as source, or a copy may have been made. It is 843 * initialized with the same density and color space as the original 844 * bitmap. 845 * 846 * If the source bitmap is immutable and the requested subset is the 847 * same as the source bitmap itself, then the source bitmap is 848 * returned and no new bitmap is created. 849 * 850 * The returned bitmap will always be mutable except in the following scenarios: 851 * (1) In situations where the source bitmap is returned and the source bitmap is immutable 852 * 853 * (2) The source bitmap is a hardware bitmap. That is {@link #getConfig()} is equivalent to 854 * {@link Config#HARDWARE} 855 * 856 * @param source The bitmap we are subsetting 857 * @param x The x coordinate of the first pixel in source 858 * @param y The y coordinate of the first pixel in source 859 * @param width The number of pixels in each row 860 * @param height The number of rows 861 * @param m Optional matrix to be applied to the pixels 862 * @param filter true if the source should be filtered. 863 * Only applies if the matrix contains more than just 864 * translation. 865 * @return A bitmap that represents the specified subset of source 866 * @throws IllegalArgumentException if the x, y, width, height values are 867 * outside of the dimensions of the source bitmap, or width is <= 0, 868 * or height is <= 0, or if the source bitmap has already been recycled 869 */ createBitmap(@onNull Bitmap source, int x, int y, int width, int height, @Nullable Matrix m, boolean filter)870 public static Bitmap createBitmap(@NonNull Bitmap source, int x, int y, int width, int height, 871 @Nullable Matrix m, boolean filter) { 872 873 checkXYSign(x, y); 874 checkWidthHeight(width, height); 875 if (x + width > source.getWidth()) { 876 throw new IllegalArgumentException("x + width must be <= bitmap.width()"); 877 } 878 if (y + height > source.getHeight()) { 879 throw new IllegalArgumentException("y + height must be <= bitmap.height()"); 880 } 881 if (source.isRecycled()) { 882 throw new IllegalArgumentException("cannot use a recycled source in createBitmap"); 883 } 884 885 // check if we can just return our argument unchanged 886 if (!source.isMutable() && x == 0 && y == 0 && width == source.getWidth() && 887 height == source.getHeight() && (m == null || m.isIdentity())) { 888 return source; 889 } 890 891 boolean isHardware = source.getConfig() == Config.HARDWARE; 892 if (isHardware) { 893 source.noteHardwareBitmapSlowCall(); 894 source = nativeCopyPreserveInternalConfig(source.mNativePtr); 895 } 896 897 int neww = width; 898 int newh = height; 899 Bitmap bitmap; 900 Paint paint; 901 902 Rect srcR = new Rect(x, y, x + width, y + height); 903 RectF dstR = new RectF(0, 0, width, height); 904 RectF deviceR = new RectF(); 905 906 Config newConfig = Config.ARGB_8888; 907 final Config config = source.getConfig(); 908 // GIF files generate null configs, assume ARGB_8888 909 if (config != null) { 910 switch (config) { 911 case RGB_565: 912 newConfig = Config.RGB_565; 913 break; 914 case ALPHA_8: 915 newConfig = Config.ALPHA_8; 916 break; 917 case RGBA_F16: 918 newConfig = Config.RGBA_F16; 919 break; 920 //noinspection deprecation 921 case ARGB_4444: 922 case ARGB_8888: 923 default: 924 newConfig = Config.ARGB_8888; 925 break; 926 } 927 } 928 929 ColorSpace cs = source.getColorSpace(); 930 931 if (m == null || m.isIdentity()) { 932 bitmap = createBitmap(null, neww, newh, newConfig, source.hasAlpha(), cs); 933 paint = null; // not needed 934 } else { 935 final boolean transformed = !m.rectStaysRect(); 936 937 m.mapRect(deviceR, dstR); 938 939 neww = Math.round(deviceR.width()); 940 newh = Math.round(deviceR.height()); 941 942 Config transformedConfig = newConfig; 943 if (transformed) { 944 if (transformedConfig != Config.ARGB_8888 && transformedConfig != Config.RGBA_F16) { 945 transformedConfig = Config.ARGB_8888; 946 if (cs == null) { 947 cs = ColorSpace.get(ColorSpace.Named.SRGB); 948 } 949 } 950 } 951 952 bitmap = createBitmap(null, neww, newh, transformedConfig, 953 transformed || source.hasAlpha(), cs); 954 955 paint = new Paint(); 956 paint.setFilterBitmap(filter); 957 if (transformed) { 958 paint.setAntiAlias(true); 959 } 960 } 961 962 // The new bitmap was created from a known bitmap source so assume that 963 // they use the same density 964 bitmap.mDensity = source.mDensity; 965 bitmap.setHasAlpha(source.hasAlpha()); 966 bitmap.setPremultiplied(source.mRequestPremultiplied); 967 968 Canvas canvas = new Canvas(bitmap); 969 canvas.translate(-deviceR.left, -deviceR.top); 970 canvas.concat(m); 971 canvas.drawBitmap(source, srcR, dstR, paint); 972 canvas.setBitmap(null); 973 if (isHardware) { 974 return bitmap.copy(Config.HARDWARE, false); 975 } 976 return bitmap; 977 } 978 979 /** 980 * Returns a mutable bitmap with the specified width and height. Its 981 * initial density is as per {@link #getDensity}. The newly created 982 * bitmap is in the {@link ColorSpace.Named#SRGB sRGB} color space. 983 * 984 * @param width The width of the bitmap 985 * @param height The height of the bitmap 986 * @param config The bitmap config to create. 987 * @throws IllegalArgumentException if the width or height are <= 0, or if 988 * Config is Config.HARDWARE, because hardware bitmaps are always immutable 989 */ createBitmap(int width, int height, @NonNull Config config)990 public static Bitmap createBitmap(int width, int height, @NonNull Config config) { 991 return createBitmap(width, height, config, true); 992 } 993 994 /** 995 * Returns a mutable bitmap with the specified width and height. Its 996 * initial density is determined from the given {@link DisplayMetrics}. 997 * The newly created bitmap is in the {@link ColorSpace.Named#SRGB sRGB} 998 * color space. 999 * 1000 * @param display Display metrics for the display this bitmap will be 1001 * drawn on. 1002 * @param width The width of the bitmap 1003 * @param height The height of the bitmap 1004 * @param config The bitmap config to create. 1005 * @throws IllegalArgumentException if the width or height are <= 0, or if 1006 * Config is Config.HARDWARE, because hardware bitmaps are always immutable 1007 */ createBitmap(@ullable DisplayMetrics display, int width, int height, @NonNull Config config)1008 public static Bitmap createBitmap(@Nullable DisplayMetrics display, int width, 1009 int height, @NonNull Config config) { 1010 return createBitmap(display, width, height, config, true); 1011 } 1012 1013 /** 1014 * Returns a mutable bitmap with the specified width and height. Its 1015 * initial density is as per {@link #getDensity}. The newly created 1016 * bitmap is in the {@link ColorSpace.Named#SRGB sRGB} color space. 1017 * 1018 * @param width The width of the bitmap 1019 * @param height The height of the bitmap 1020 * @param config The bitmap config to create. 1021 * @param hasAlpha If the bitmap is ARGB_8888 or RGBA_16F this flag can be used to 1022 * mark the bitmap as opaque. Doing so will clear the bitmap in black 1023 * instead of transparent. 1024 * 1025 * @throws IllegalArgumentException if the width or height are <= 0, or if 1026 * Config is Config.HARDWARE, because hardware bitmaps are always immutable 1027 */ createBitmap(int width, int height, @NonNull Config config, boolean hasAlpha)1028 public static Bitmap createBitmap(int width, int height, 1029 @NonNull Config config, boolean hasAlpha) { 1030 return createBitmap(null, width, height, config, hasAlpha); 1031 } 1032 1033 /** 1034 * Returns a mutable bitmap with the specified width and height. Its 1035 * initial density is as per {@link #getDensity}. 1036 * 1037 * @param width The width of the bitmap 1038 * @param height The height of the bitmap 1039 * @param config The bitmap config to create. 1040 * @param hasAlpha If the bitmap is ARGB_8888 or RGBA_16F this flag can be used to 1041 * mark the bitmap as opaque. Doing so will clear the bitmap in black 1042 * instead of transparent. 1043 * @param colorSpace The color space of the bitmap. If the config is {@link Config#RGBA_F16} 1044 * and {@link ColorSpace.Named#SRGB sRGB} or 1045 * {@link ColorSpace.Named#LINEAR_SRGB Linear sRGB} is provided then the 1046 * corresponding extended range variant is assumed. 1047 * 1048 * @throws IllegalArgumentException if the width or height are <= 0, if 1049 * Config is Config.HARDWARE (because hardware bitmaps are always 1050 * immutable), if the specified color space is not {@link ColorSpace.Model#RGB RGB}, 1051 * if the specified color space's transfer function is not an 1052 * {@link ColorSpace.Rgb.TransferParameters ICC parametric curve}, or if 1053 * the color space is null 1054 */ createBitmap(int width, int height, @NonNull Config config, boolean hasAlpha, @NonNull ColorSpace colorSpace)1055 public static Bitmap createBitmap(int width, int height, @NonNull Config config, 1056 boolean hasAlpha, @NonNull ColorSpace colorSpace) { 1057 return createBitmap(null, width, height, config, hasAlpha, colorSpace); 1058 } 1059 1060 /** 1061 * Returns a mutable bitmap with the specified width and height. Its 1062 * initial density is determined from the given {@link DisplayMetrics}. 1063 * The newly created bitmap is in the {@link ColorSpace.Named#SRGB sRGB} 1064 * color space. 1065 * 1066 * @param display Display metrics for the display this bitmap will be 1067 * drawn on. 1068 * @param width The width of the bitmap 1069 * @param height The height of the bitmap 1070 * @param config The bitmap config to create. 1071 * @param hasAlpha If the bitmap is ARGB_8888 or RGBA_16F this flag can be used to 1072 * mark the bitmap as opaque. Doing so will clear the bitmap in black 1073 * instead of transparent. 1074 * 1075 * @throws IllegalArgumentException if the width or height are <= 0, or if 1076 * Config is Config.HARDWARE, because hardware bitmaps are always immutable 1077 */ createBitmap(@ullable DisplayMetrics display, int width, int height, @NonNull Config config, boolean hasAlpha)1078 public static Bitmap createBitmap(@Nullable DisplayMetrics display, int width, int height, 1079 @NonNull Config config, boolean hasAlpha) { 1080 return createBitmap(display, width, height, config, hasAlpha, 1081 ColorSpace.get(ColorSpace.Named.SRGB)); 1082 } 1083 1084 /** 1085 * Returns a mutable bitmap with the specified width and height. Its 1086 * initial density is determined from the given {@link DisplayMetrics}. 1087 * The newly created bitmap is in the {@link ColorSpace.Named#SRGB sRGB} 1088 * color space. 1089 * 1090 * @param display Display metrics for the display this bitmap will be 1091 * drawn on. 1092 * @param width The width of the bitmap 1093 * @param height The height of the bitmap 1094 * @param config The bitmap config to create. 1095 * @param hasAlpha If the bitmap is ARGB_8888 or RGBA_16F this flag can be used to 1096 * mark the bitmap as opaque. Doing so will clear the bitmap in black 1097 * instead of transparent. 1098 * @param colorSpace The color space of the bitmap. If the config is {@link Config#RGBA_F16} 1099 * and {@link ColorSpace.Named#SRGB sRGB} or 1100 * {@link ColorSpace.Named#LINEAR_SRGB Linear sRGB} is provided then the 1101 * corresponding extended range variant is assumed. 1102 * 1103 * @throws IllegalArgumentException if the width or height are <= 0, if 1104 * Config is Config.HARDWARE (because hardware bitmaps are always 1105 * immutable), if the specified color space is not {@link ColorSpace.Model#RGB RGB}, 1106 * if the specified color space's transfer function is not an 1107 * {@link ColorSpace.Rgb.TransferParameters ICC parametric curve}, or if 1108 * the color space is null 1109 */ createBitmap(@ullable DisplayMetrics display, int width, int height, @NonNull Config config, boolean hasAlpha, @NonNull ColorSpace colorSpace)1110 public static Bitmap createBitmap(@Nullable DisplayMetrics display, int width, int height, 1111 @NonNull Config config, boolean hasAlpha, @NonNull ColorSpace colorSpace) { 1112 if (width <= 0 || height <= 0) { 1113 throw new IllegalArgumentException("width and height must be > 0"); 1114 } 1115 if (config == Config.HARDWARE) { 1116 throw new IllegalArgumentException("can't create mutable bitmap with Config.HARDWARE"); 1117 } 1118 if (colorSpace == null && config != Config.ALPHA_8) { 1119 throw new IllegalArgumentException("can't create bitmap without a color space"); 1120 } 1121 1122 Bitmap bm = nativeCreate(null, 0, width, width, height, config.nativeInt, true, 1123 colorSpace == null ? 0 : colorSpace.getNativeInstance()); 1124 1125 if (display != null) { 1126 bm.mDensity = display.densityDpi; 1127 } 1128 bm.setHasAlpha(hasAlpha); 1129 if ((config == Config.ARGB_8888 || config == Config.RGBA_F16) && !hasAlpha) { 1130 nativeErase(bm.mNativePtr, 0xff000000); 1131 } 1132 // No need to initialize the bitmap to zeroes with other configs; 1133 // it is backed by a VM byte array which is by definition preinitialized 1134 // to all zeroes. 1135 return bm; 1136 } 1137 1138 /** 1139 * Returns a immutable bitmap with the specified width and height, with each 1140 * pixel value set to the corresponding value in the colors array. Its 1141 * initial density is as per {@link #getDensity}. The newly created 1142 * bitmap is in the {@link ColorSpace.Named#SRGB sRGB} color space. 1143 * 1144 * @param colors Array of sRGB {@link Color colors} used to initialize the pixels. 1145 * @param offset Number of values to skip before the first color in the 1146 * array of colors. 1147 * @param stride Number of colors in the array between rows (must be >= 1148 * width or <= -width). 1149 * @param width The width of the bitmap 1150 * @param height The height of the bitmap 1151 * @param config The bitmap config to create. If the config does not 1152 * support per-pixel alpha (e.g. RGB_565), then the alpha 1153 * bytes in the colors[] will be ignored (assumed to be FF) 1154 * @throws IllegalArgumentException if the width or height are <= 0, or if 1155 * the color array's length is less than the number of pixels. 1156 */ createBitmap(@onNull @olorInt int[] colors, int offset, int stride, int width, int height, @NonNull Config config)1157 public static Bitmap createBitmap(@NonNull @ColorInt int[] colors, int offset, int stride, 1158 int width, int height, @NonNull Config config) { 1159 return createBitmap(null, colors, offset, stride, width, height, config); 1160 } 1161 1162 /** 1163 * Returns a immutable bitmap with the specified width and height, with each 1164 * pixel value set to the corresponding value in the colors array. Its 1165 * initial density is determined from the given {@link DisplayMetrics}. 1166 * The newly created bitmap is in the {@link ColorSpace.Named#SRGB sRGB} 1167 * color space. 1168 * 1169 * @param display Display metrics for the display this bitmap will be 1170 * drawn on. 1171 * @param colors Array of sRGB {@link Color colors} used to initialize the pixels. 1172 * @param offset Number of values to skip before the first color in the 1173 * array of colors. 1174 * @param stride Number of colors in the array between rows (must be >= 1175 * width or <= -width). 1176 * @param width The width of the bitmap 1177 * @param height The height of the bitmap 1178 * @param config The bitmap config to create. If the config does not 1179 * support per-pixel alpha (e.g. RGB_565), then the alpha 1180 * bytes in the colors[] will be ignored (assumed to be FF) 1181 * @throws IllegalArgumentException if the width or height are <= 0, or if 1182 * the color array's length is less than the number of pixels. 1183 */ createBitmap(@onNull DisplayMetrics display, @NonNull @ColorInt int[] colors, int offset, int stride, int width, int height, @NonNull Config config)1184 public static Bitmap createBitmap(@NonNull DisplayMetrics display, 1185 @NonNull @ColorInt int[] colors, int offset, int stride, 1186 int width, int height, @NonNull Config config) { 1187 1188 checkWidthHeight(width, height); 1189 if (Math.abs(stride) < width) { 1190 throw new IllegalArgumentException("abs(stride) must be >= width"); 1191 } 1192 int lastScanline = offset + (height - 1) * stride; 1193 int length = colors.length; 1194 if (offset < 0 || (offset + width > length) || lastScanline < 0 || 1195 (lastScanline + width > length)) { 1196 throw new ArrayIndexOutOfBoundsException(); 1197 } 1198 if (width <= 0 || height <= 0) { 1199 throw new IllegalArgumentException("width and height must be > 0"); 1200 } 1201 ColorSpace sRGB = ColorSpace.get(ColorSpace.Named.SRGB); 1202 Bitmap bm = nativeCreate(colors, offset, stride, width, height, 1203 config.nativeInt, false, sRGB.getNativeInstance()); 1204 if (display != null) { 1205 bm.mDensity = display.densityDpi; 1206 } 1207 return bm; 1208 } 1209 1210 /** 1211 * Returns a immutable bitmap with the specified width and height, with each 1212 * pixel value set to the corresponding value in the colors array. Its 1213 * initial density is as per {@link #getDensity}. The newly created 1214 * bitmap is in the {@link ColorSpace.Named#SRGB sRGB} color space. 1215 * 1216 * @param colors Array of sRGB {@link Color colors} used to initialize the pixels. 1217 * This array must be at least as large as width * height. 1218 * @param width The width of the bitmap 1219 * @param height The height of the bitmap 1220 * @param config The bitmap config to create. If the config does not 1221 * support per-pixel alpha (e.g. RGB_565), then the alpha 1222 * bytes in the colors[] will be ignored (assumed to be FF) 1223 * @throws IllegalArgumentException if the width or height are <= 0, or if 1224 * the color array's length is less than the number of pixels. 1225 */ createBitmap(@onNull @olorInt int[] colors, int width, int height, Config config)1226 public static Bitmap createBitmap(@NonNull @ColorInt int[] colors, 1227 int width, int height, Config config) { 1228 return createBitmap(null, colors, 0, width, width, height, config); 1229 } 1230 1231 /** 1232 * Returns a immutable bitmap with the specified width and height, with each 1233 * pixel value set to the corresponding value in the colors array. Its 1234 * initial density is determined from the given {@link DisplayMetrics}. 1235 * The newly created bitmap is in the {@link ColorSpace.Named#SRGB sRGB} 1236 * color space. 1237 * 1238 * @param display Display metrics for the display this bitmap will be 1239 * drawn on. 1240 * @param colors Array of sRGB {@link Color colors} used to initialize the pixels. 1241 * This array must be at least as large as width * height. 1242 * @param width The width of the bitmap 1243 * @param height The height of the bitmap 1244 * @param config The bitmap config to create. If the config does not 1245 * support per-pixel alpha (e.g. RGB_565), then the alpha 1246 * bytes in the colors[] will be ignored (assumed to be FF) 1247 * @throws IllegalArgumentException if the width or height are <= 0, or if 1248 * the color array's length is less than the number of pixels. 1249 */ createBitmap(@ullable DisplayMetrics display, @NonNull @ColorInt int colors[], int width, int height, @NonNull Config config)1250 public static Bitmap createBitmap(@Nullable DisplayMetrics display, 1251 @NonNull @ColorInt int colors[], int width, int height, @NonNull Config config) { 1252 return createBitmap(display, colors, 0, width, width, height, config); 1253 } 1254 1255 /** 1256 * Creates a Bitmap from the given {@link Picture} source of recorded drawing commands. 1257 * 1258 * Equivalent to calling {@link #createBitmap(Picture, int, int, Config)} with 1259 * width and height the same as the Picture's width and height and a Config.HARDWARE 1260 * config. 1261 * 1262 * @param source The recorded {@link Picture} of drawing commands that will be 1263 * drawn into the returned Bitmap. 1264 * @return An immutable bitmap with a HARDWARE config whose contents are created 1265 * from the recorded drawing commands in the Picture source. 1266 */ createBitmap(@onNull Picture source)1267 public static @NonNull Bitmap createBitmap(@NonNull Picture source) { 1268 return createBitmap(source, source.getWidth(), source.getHeight(), Config.HARDWARE); 1269 } 1270 1271 /** 1272 * Creates a Bitmap from the given {@link Picture} source of recorded drawing commands. 1273 * 1274 * The bitmap will be immutable with the given width and height. If the width and height 1275 * are not the same as the Picture's width & height, the Picture will be scaled to 1276 * fit the given width and height. 1277 * 1278 * @param source The recorded {@link Picture} of drawing commands that will be 1279 * drawn into the returned Bitmap. 1280 * @param width The width of the bitmap to create. The picture's width will be 1281 * scaled to match if necessary. 1282 * @param height The height of the bitmap to create. The picture's height will be 1283 * scaled to match if necessary. 1284 * @param config The {@link Config} of the created bitmap. 1285 * 1286 * @return An immutable bitmap with a configuration specified by the config parameter 1287 */ createBitmap(@onNull Picture source, int width, int height, @NonNull Config config)1288 public static @NonNull Bitmap createBitmap(@NonNull Picture source, int width, int height, 1289 @NonNull Config config) { 1290 if (width <= 0 || height <= 0) { 1291 throw new IllegalArgumentException("width & height must be > 0"); 1292 } 1293 if (config == null) { 1294 throw new IllegalArgumentException("Config must not be null"); 1295 } 1296 source.endRecording(); 1297 if (source.requiresHardwareAcceleration() && config != Config.HARDWARE) { 1298 StrictMode.noteSlowCall("GPU readback"); 1299 } 1300 if (config == Config.HARDWARE || source.requiresHardwareAcceleration()) { 1301 final RenderNode node = RenderNode.create("BitmapTemporary", null); 1302 node.setLeftTopRightBottom(0, 0, width, height); 1303 node.setClipToBounds(false); 1304 node.setForceDarkAllowed(false); 1305 final RecordingCanvas canvas = node.beginRecording(width, height); 1306 if (source.getWidth() != width || source.getHeight() != height) { 1307 canvas.scale(width / (float) source.getWidth(), 1308 height / (float) source.getHeight()); 1309 } 1310 canvas.drawPicture(source); 1311 node.endRecording(); 1312 Bitmap bitmap = ThreadedRenderer.createHardwareBitmap(node, width, height); 1313 if (config != Config.HARDWARE) { 1314 bitmap = bitmap.copy(config, false); 1315 } 1316 return bitmap; 1317 } else { 1318 Bitmap bitmap = Bitmap.createBitmap(width, height, config); 1319 Canvas canvas = new Canvas(bitmap); 1320 if (source.getWidth() != width || source.getHeight() != height) { 1321 canvas.scale(width / (float) source.getWidth(), 1322 height / (float) source.getHeight()); 1323 } 1324 canvas.drawPicture(source); 1325 canvas.setBitmap(null); 1326 bitmap.setImmutable(); 1327 return bitmap; 1328 } 1329 } 1330 1331 /** 1332 * Returns an optional array of private data, used by the UI system for 1333 * some bitmaps. Not intended to be called by applications. 1334 */ getNinePatchChunk()1335 public byte[] getNinePatchChunk() { 1336 return mNinePatchChunk; 1337 } 1338 1339 /** 1340 * Populates a rectangle with the bitmap's optical insets. 1341 * 1342 * @param outInsets Rect to populate with optical insets 1343 * @hide 1344 */ getOpticalInsets(@onNull Rect outInsets)1345 public void getOpticalInsets(@NonNull Rect outInsets) { 1346 if (mNinePatchInsets == null) { 1347 outInsets.setEmpty(); 1348 } else { 1349 outInsets.set(mNinePatchInsets.opticalRect); 1350 } 1351 } 1352 1353 /** @hide */ getNinePatchInsets()1354 public NinePatch.InsetStruct getNinePatchInsets() { 1355 return mNinePatchInsets; 1356 } 1357 1358 /** 1359 * Specifies the known formats a bitmap can be compressed into 1360 */ 1361 public enum CompressFormat { 1362 JPEG (0), 1363 PNG (1), 1364 WEBP (2); 1365 CompressFormat(int nativeInt)1366 CompressFormat(int nativeInt) { 1367 this.nativeInt = nativeInt; 1368 } 1369 final int nativeInt; 1370 } 1371 1372 /** 1373 * Number of bytes of temp storage we use for communicating between the 1374 * native compressor and the java OutputStream. 1375 */ 1376 private final static int WORKING_COMPRESS_STORAGE = 4096; 1377 1378 /** 1379 * Write a compressed version of the bitmap to the specified outputstream. 1380 * If this returns true, the bitmap can be reconstructed by passing a 1381 * corresponding inputstream to BitmapFactory.decodeStream(). Note: not 1382 * all Formats support all bitmap configs directly, so it is possible that 1383 * the returned bitmap from BitmapFactory could be in a different bitdepth, 1384 * and/or may have lost per-pixel alpha (e.g. JPEG only supports opaque 1385 * pixels). 1386 * 1387 * @param format The format of the compressed image 1388 * @param quality Hint to the compressor, 0-100. 0 meaning compress for 1389 * small size, 100 meaning compress for max quality. Some 1390 * formats, like PNG which is lossless, will ignore the 1391 * quality setting 1392 * @param stream The outputstream to write the compressed data. 1393 * @return true if successfully compressed to the specified stream. 1394 */ 1395 @WorkerThread compress(CompressFormat format, int quality, OutputStream stream)1396 public boolean compress(CompressFormat format, int quality, OutputStream stream) { 1397 checkRecycled("Can't compress a recycled bitmap"); 1398 // do explicit check before calling the native method 1399 if (stream == null) { 1400 throw new NullPointerException(); 1401 } 1402 if (quality < 0 || quality > 100) { 1403 throw new IllegalArgumentException("quality must be 0..100"); 1404 } 1405 StrictMode.noteSlowCall("Compression of a bitmap is slow"); 1406 Trace.traceBegin(Trace.TRACE_TAG_RESOURCES, "Bitmap.compress"); 1407 boolean result = nativeCompress(mNativePtr, format.nativeInt, 1408 quality, stream, new byte[WORKING_COMPRESS_STORAGE]); 1409 Trace.traceEnd(Trace.TRACE_TAG_RESOURCES); 1410 return result; 1411 } 1412 1413 /** 1414 * Returns true if the bitmap is marked as mutable (i.e. can be drawn into) 1415 */ isMutable()1416 public final boolean isMutable() { 1417 return !nativeIsImmutable(mNativePtr); 1418 } 1419 1420 /** 1421 * Marks the Bitmap as immutable. Further modifications to this Bitmap are disallowed. 1422 * After this method is called, this Bitmap cannot be made mutable again and subsequent calls 1423 * to {@link #reconfigure(int, int, Config)}, {@link #setPixel(int, int, int)}, 1424 * {@link #setPixels(int[], int, int, int, int, int, int)} and {@link #eraseColor(int)} will 1425 * fail and throw an IllegalStateException. 1426 * 1427 * @hide 1428 */ setImmutable()1429 public void setImmutable() { 1430 if (isMutable()) { 1431 nativeSetImmutable(mNativePtr); 1432 } 1433 } 1434 1435 /** 1436 * <p>Indicates whether pixels stored in this bitmaps are stored pre-multiplied. 1437 * When a pixel is pre-multiplied, the RGB components have been multiplied by 1438 * the alpha component. For instance, if the original color is a 50% 1439 * translucent red <code>(128, 255, 0, 0)</code>, the pre-multiplied form is 1440 * <code>(128, 128, 0, 0)</code>.</p> 1441 * 1442 * <p>This method always returns false if {@link #getConfig()} is 1443 * {@link Bitmap.Config#RGB_565}.</p> 1444 * 1445 * <p>The return value is undefined if {@link #getConfig()} is 1446 * {@link Bitmap.Config#ALPHA_8}.</p> 1447 * 1448 * <p>This method only returns true if {@link #hasAlpha()} returns true. 1449 * A bitmap with no alpha channel can be used both as a pre-multiplied and 1450 * as a non pre-multiplied bitmap.</p> 1451 * 1452 * <p>Only pre-multiplied bitmaps may be drawn by the view system or 1453 * {@link Canvas}. If a non-pre-multiplied bitmap with an alpha channel is 1454 * drawn to a Canvas, a RuntimeException will be thrown.</p> 1455 * 1456 * @return true if the underlying pixels have been pre-multiplied, false 1457 * otherwise 1458 * 1459 * @see Bitmap#setPremultiplied(boolean) 1460 * @see BitmapFactory.Options#inPremultiplied 1461 */ isPremultiplied()1462 public final boolean isPremultiplied() { 1463 if (mRecycled) { 1464 Log.w(TAG, "Called isPremultiplied() on a recycle()'d bitmap! This is undefined behavior!"); 1465 } 1466 return nativeIsPremultiplied(mNativePtr); 1467 } 1468 1469 /** 1470 * Sets whether the bitmap should treat its data as pre-multiplied. 1471 * 1472 * <p>Bitmaps are always treated as pre-multiplied by the view system and 1473 * {@link Canvas} for performance reasons. Storing un-pre-multiplied data in 1474 * a Bitmap (through {@link #setPixel}, {@link #setPixels}, or {@link 1475 * BitmapFactory.Options#inPremultiplied BitmapFactory.Options.inPremultiplied}) 1476 * can lead to incorrect blending if drawn by the framework.</p> 1477 * 1478 * <p>This method will not affect the behavior of a bitmap without an alpha 1479 * channel, or if {@link #hasAlpha()} returns false.</p> 1480 * 1481 * <p>Calling {@link #createBitmap} or {@link #createScaledBitmap} with a source 1482 * Bitmap whose colors are not pre-multiplied may result in a RuntimeException, 1483 * since those functions require drawing the source, which is not supported for 1484 * un-pre-multiplied Bitmaps.</p> 1485 * 1486 * @see Bitmap#isPremultiplied() 1487 * @see BitmapFactory.Options#inPremultiplied 1488 */ setPremultiplied(boolean premultiplied)1489 public final void setPremultiplied(boolean premultiplied) { 1490 checkRecycled("setPremultiplied called on a recycled bitmap"); 1491 mRequestPremultiplied = premultiplied; 1492 nativeSetPremultiplied(mNativePtr, premultiplied); 1493 } 1494 1495 /** Returns the bitmap's width */ getWidth()1496 public final int getWidth() { 1497 if (mRecycled) { 1498 Log.w(TAG, "Called getWidth() on a recycle()'d bitmap! This is undefined behavior!"); 1499 } 1500 return mWidth; 1501 } 1502 1503 /** Returns the bitmap's height */ getHeight()1504 public final int getHeight() { 1505 if (mRecycled) { 1506 Log.w(TAG, "Called getHeight() on a recycle()'d bitmap! This is undefined behavior!"); 1507 } 1508 return mHeight; 1509 } 1510 1511 /** 1512 * Convenience for calling {@link #getScaledWidth(int)} with the target 1513 * density of the given {@link Canvas}. 1514 */ getScaledWidth(Canvas canvas)1515 public int getScaledWidth(Canvas canvas) { 1516 return scaleFromDensity(getWidth(), mDensity, canvas.mDensity); 1517 } 1518 1519 /** 1520 * Convenience for calling {@link #getScaledHeight(int)} with the target 1521 * density of the given {@link Canvas}. 1522 */ getScaledHeight(Canvas canvas)1523 public int getScaledHeight(Canvas canvas) { 1524 return scaleFromDensity(getHeight(), mDensity, canvas.mDensity); 1525 } 1526 1527 /** 1528 * Convenience for calling {@link #getScaledWidth(int)} with the target 1529 * density of the given {@link DisplayMetrics}. 1530 */ getScaledWidth(DisplayMetrics metrics)1531 public int getScaledWidth(DisplayMetrics metrics) { 1532 return scaleFromDensity(getWidth(), mDensity, metrics.densityDpi); 1533 } 1534 1535 /** 1536 * Convenience for calling {@link #getScaledHeight(int)} with the target 1537 * density of the given {@link DisplayMetrics}. 1538 */ getScaledHeight(DisplayMetrics metrics)1539 public int getScaledHeight(DisplayMetrics metrics) { 1540 return scaleFromDensity(getHeight(), mDensity, metrics.densityDpi); 1541 } 1542 1543 /** 1544 * Convenience method that returns the width of this bitmap divided 1545 * by the density scale factor. 1546 * 1547 * Returns the bitmap's width multiplied by the ratio of the target density to the bitmap's 1548 * source density 1549 * 1550 * @param targetDensity The density of the target canvas of the bitmap. 1551 * @return The scaled width of this bitmap, according to the density scale factor. 1552 */ getScaledWidth(int targetDensity)1553 public int getScaledWidth(int targetDensity) { 1554 return scaleFromDensity(getWidth(), mDensity, targetDensity); 1555 } 1556 1557 /** 1558 * Convenience method that returns the height of this bitmap divided 1559 * by the density scale factor. 1560 * 1561 * Returns the bitmap's height multiplied by the ratio of the target density to the bitmap's 1562 * source density 1563 * 1564 * @param targetDensity The density of the target canvas of the bitmap. 1565 * @return The scaled height of this bitmap, according to the density scale factor. 1566 */ getScaledHeight(int targetDensity)1567 public int getScaledHeight(int targetDensity) { 1568 return scaleFromDensity(getHeight(), mDensity, targetDensity); 1569 } 1570 1571 /** 1572 * @hide 1573 */ 1574 @UnsupportedAppUsage scaleFromDensity(int size, int sdensity, int tdensity)1575 static public int scaleFromDensity(int size, int sdensity, int tdensity) { 1576 if (sdensity == DENSITY_NONE || tdensity == DENSITY_NONE || sdensity == tdensity) { 1577 return size; 1578 } 1579 1580 // Scale by tdensity / sdensity, rounding up. 1581 return ((size * tdensity) + (sdensity >> 1)) / sdensity; 1582 } 1583 1584 /** 1585 * Return the number of bytes between rows in the bitmap's pixels. Note that 1586 * this refers to the pixels as stored natively by the bitmap. If you call 1587 * getPixels() or setPixels(), then the pixels are uniformly treated as 1588 * 32bit values, packed according to the Color class. 1589 * 1590 * <p>As of {@link android.os.Build.VERSION_CODES#KITKAT}, this method 1591 * should not be used to calculate the memory usage of the bitmap. Instead, 1592 * see {@link #getAllocationByteCount()}. 1593 * 1594 * @return number of bytes between rows of the native bitmap pixels. 1595 */ getRowBytes()1596 public final int getRowBytes() { 1597 if (mRecycled) { 1598 Log.w(TAG, "Called getRowBytes() on a recycle()'d bitmap! This is undefined behavior!"); 1599 } 1600 return nativeRowBytes(mNativePtr); 1601 } 1602 1603 /** 1604 * Returns the minimum number of bytes that can be used to store this bitmap's pixels. 1605 * 1606 * <p>As of {@link android.os.Build.VERSION_CODES#KITKAT}, the result of this method can 1607 * no longer be used to determine memory usage of a bitmap. See {@link 1608 * #getAllocationByteCount()}.</p> 1609 */ getByteCount()1610 public final int getByteCount() { 1611 if (mRecycled) { 1612 Log.w(TAG, "Called getByteCount() on a recycle()'d bitmap! " 1613 + "This is undefined behavior!"); 1614 return 0; 1615 } 1616 // int result permits bitmaps up to 46,340 x 46,340 1617 return getRowBytes() * getHeight(); 1618 } 1619 1620 /** 1621 * Returns the size of the allocated memory used to store this bitmap's pixels. 1622 * 1623 * <p>This can be larger than the result of {@link #getByteCount()} if a bitmap is reused to 1624 * decode other bitmaps of smaller size, or by manual reconfiguration. See {@link 1625 * #reconfigure(int, int, Config)}, {@link #setWidth(int)}, {@link #setHeight(int)}, {@link 1626 * #setConfig(Bitmap.Config)}, and {@link BitmapFactory.Options#inBitmap 1627 * BitmapFactory.Options.inBitmap}. If a bitmap is not modified in this way, this value will be 1628 * the same as that returned by {@link #getByteCount()}.</p> 1629 * 1630 * <p>This value will not change over the lifetime of a Bitmap.</p> 1631 * 1632 * @see #reconfigure(int, int, Config) 1633 */ getAllocationByteCount()1634 public final int getAllocationByteCount() { 1635 if (mRecycled) { 1636 Log.w(TAG, "Called getAllocationByteCount() on a recycle()'d bitmap! " 1637 + "This is undefined behavior!"); 1638 return 0; 1639 } 1640 return nativeGetAllocationByteCount(mNativePtr); 1641 } 1642 1643 /** 1644 * If the bitmap's internal config is in one of the public formats, return 1645 * that config, otherwise return null. 1646 */ getConfig()1647 public final Config getConfig() { 1648 if (mRecycled) { 1649 Log.w(TAG, "Called getConfig() on a recycle()'d bitmap! This is undefined behavior!"); 1650 } 1651 return Config.nativeToConfig(nativeConfig(mNativePtr)); 1652 } 1653 1654 /** Returns true if the bitmap's config supports per-pixel alpha, and 1655 * if the pixels may contain non-opaque alpha values. For some configs, 1656 * this is always false (e.g. RGB_565), since they do not support per-pixel 1657 * alpha. However, for configs that do, the bitmap may be flagged to be 1658 * known that all of its pixels are opaque. In this case hasAlpha() will 1659 * also return false. If a config such as ARGB_8888 is not so flagged, 1660 * it will return true by default. 1661 */ hasAlpha()1662 public final boolean hasAlpha() { 1663 if (mRecycled) { 1664 Log.w(TAG, "Called hasAlpha() on a recycle()'d bitmap! This is undefined behavior!"); 1665 } 1666 return nativeHasAlpha(mNativePtr); 1667 } 1668 1669 /** 1670 * Tell the bitmap if all of the pixels are known to be opaque (false) 1671 * or if some of the pixels may contain non-opaque alpha values (true). 1672 * Note, for some configs (e.g. RGB_565) this call is ignored, since it 1673 * does not support per-pixel alpha values. 1674 * 1675 * This is meant as a drawing hint, as in some cases a bitmap that is known 1676 * to be opaque can take a faster drawing case than one that may have 1677 * non-opaque per-pixel alpha values. 1678 */ setHasAlpha(boolean hasAlpha)1679 public void setHasAlpha(boolean hasAlpha) { 1680 checkRecycled("setHasAlpha called on a recycled bitmap"); 1681 nativeSetHasAlpha(mNativePtr, hasAlpha, mRequestPremultiplied); 1682 } 1683 1684 /** 1685 * Indicates whether the renderer responsible for drawing this 1686 * bitmap should attempt to use mipmaps when this bitmap is drawn 1687 * scaled down. 1688 * 1689 * If you know that you are going to draw this bitmap at less than 1690 * 50% of its original size, you may be able to obtain a higher 1691 * quality 1692 * 1693 * This property is only a suggestion that can be ignored by the 1694 * renderer. It is not guaranteed to have any effect. 1695 * 1696 * @return true if the renderer should attempt to use mipmaps, 1697 * false otherwise 1698 * 1699 * @see #setHasMipMap(boolean) 1700 */ hasMipMap()1701 public final boolean hasMipMap() { 1702 if (mRecycled) { 1703 Log.w(TAG, "Called hasMipMap() on a recycle()'d bitmap! This is undefined behavior!"); 1704 } 1705 return nativeHasMipMap(mNativePtr); 1706 } 1707 1708 /** 1709 * Set a hint for the renderer responsible for drawing this bitmap 1710 * indicating that it should attempt to use mipmaps when this bitmap 1711 * is drawn scaled down. 1712 * 1713 * If you know that you are going to draw this bitmap at less than 1714 * 50% of its original size, you may be able to obtain a higher 1715 * quality by turning this property on. 1716 * 1717 * Note that if the renderer respects this hint it might have to 1718 * allocate extra memory to hold the mipmap levels for this bitmap. 1719 * 1720 * This property is only a suggestion that can be ignored by the 1721 * renderer. It is not guaranteed to have any effect. 1722 * 1723 * @param hasMipMap indicates whether the renderer should attempt 1724 * to use mipmaps 1725 * 1726 * @see #hasMipMap() 1727 */ setHasMipMap(boolean hasMipMap)1728 public final void setHasMipMap(boolean hasMipMap) { 1729 checkRecycled("setHasMipMap called on a recycled bitmap"); 1730 nativeSetHasMipMap(mNativePtr, hasMipMap); 1731 } 1732 1733 /** 1734 * Returns the color space associated with this bitmap. If the color 1735 * space is unknown, this method returns null. 1736 */ 1737 @Nullable getColorSpace()1738 public final ColorSpace getColorSpace() { 1739 checkRecycled("getColorSpace called on a recycled bitmap"); 1740 if (mColorSpace == null) { 1741 mColorSpace = nativeComputeColorSpace(mNativePtr); 1742 } 1743 return mColorSpace; 1744 } 1745 1746 /** 1747 * <p>Modifies the bitmap to have the specified {@link ColorSpace}, without 1748 * affecting the underlying allocation backing the bitmap.</p> 1749 * 1750 * <p>This affects how the framework will interpret the color at each pixel. A bitmap 1751 * with {@link Config#ALPHA_8} never has a color space, since a color space does not 1752 * affect the alpha channel. Other {@code Config}s must always have a non-null 1753 * {@code ColorSpace}.</p> 1754 * 1755 * @throws IllegalArgumentException If the specified color space is {@code null}, not 1756 * {@link ColorSpace.Model#RGB RGB}, has a transfer function that is not an 1757 * {@link ColorSpace.Rgb.TransferParameters ICC parametric curve}, or whose 1758 * components min/max values reduce the numerical range compared to the 1759 * previously assigned color space. 1760 * 1761 * @throws IllegalArgumentException If the {@code Config} (returned by {@link #getConfig()}) 1762 * is {@link Config#ALPHA_8}. 1763 * 1764 * @param colorSpace to assign to the bitmap 1765 */ setColorSpace(@onNull ColorSpace colorSpace)1766 public void setColorSpace(@NonNull ColorSpace colorSpace) { 1767 checkRecycled("setColorSpace called on a recycled bitmap"); 1768 if (colorSpace == null) { 1769 throw new IllegalArgumentException("The colorSpace cannot be set to null"); 1770 } 1771 1772 if (getConfig() == Config.ALPHA_8) { 1773 throw new IllegalArgumentException("Cannot set a ColorSpace on ALPHA_8"); 1774 } 1775 1776 // Keep track of the old ColorSpace for comparison, and so we can reset it in case of an 1777 // Exception. 1778 final ColorSpace oldColorSpace = getColorSpace(); 1779 nativeSetColorSpace(mNativePtr, colorSpace.getNativeInstance()); 1780 1781 // This will update mColorSpace. It may not be the same as |colorSpace|, e.g. if we 1782 // corrected it because the Bitmap is F16. 1783 mColorSpace = null; 1784 final ColorSpace newColorSpace = getColorSpace(); 1785 1786 try { 1787 if (oldColorSpace.getComponentCount() != newColorSpace.getComponentCount()) { 1788 throw new IllegalArgumentException("The new ColorSpace must have the same " 1789 + "component count as the current ColorSpace"); 1790 } else { 1791 for (int i = 0; i < oldColorSpace.getComponentCount(); i++) { 1792 if (oldColorSpace.getMinValue(i) < newColorSpace.getMinValue(i)) { 1793 throw new IllegalArgumentException("The new ColorSpace cannot increase the " 1794 + "minimum value for any of the components compared to the current " 1795 + "ColorSpace. To perform this type of conversion create a new " 1796 + "Bitmap in the desired ColorSpace and draw this Bitmap into it."); 1797 } 1798 if (oldColorSpace.getMaxValue(i) > newColorSpace.getMaxValue(i)) { 1799 throw new IllegalArgumentException("The new ColorSpace cannot decrease the " 1800 + "maximum value for any of the components compared to the current " 1801 + "ColorSpace/ To perform this type of conversion create a new " 1802 + "Bitmap in the desired ColorSpace and draw this Bitmap into it."); 1803 } 1804 } 1805 } 1806 } catch (IllegalArgumentException e) { 1807 // Undo the change to the ColorSpace. 1808 mColorSpace = oldColorSpace; 1809 nativeSetColorSpace(mNativePtr, mColorSpace.getNativeInstance()); 1810 throw e; 1811 } 1812 } 1813 1814 /** 1815 * Fills the bitmap's pixels with the specified {@link Color}. 1816 * 1817 * @throws IllegalStateException if the bitmap is not mutable. 1818 */ eraseColor(@olorInt int c)1819 public void eraseColor(@ColorInt int c) { 1820 checkRecycled("Can't erase a recycled bitmap"); 1821 if (!isMutable()) { 1822 throw new IllegalStateException("cannot erase immutable bitmaps"); 1823 } 1824 nativeErase(mNativePtr, c); 1825 } 1826 1827 /** 1828 * Fills the bitmap's pixels with the specified {@code ColorLong}. 1829 * 1830 * @param color The color to fill as packed by the {@link Color} class. 1831 * @throws IllegalStateException if the bitmap is not mutable. 1832 * @throws IllegalArgumentException if the color space encoded in the 1833 * {@code ColorLong} is invalid or unknown. 1834 * 1835 */ eraseColor(@olorLong long color)1836 public void eraseColor(@ColorLong long color) { 1837 checkRecycled("Can't erase a recycled bitmap"); 1838 if (!isMutable()) { 1839 throw new IllegalStateException("cannot erase immutable bitmaps"); 1840 } 1841 1842 ColorSpace cs = Color.colorSpace(color); 1843 nativeErase(mNativePtr, cs.getNativeInstance(), color); 1844 } 1845 1846 /** 1847 * Returns the {@link Color} at the specified location. Throws an exception 1848 * if x or y are out of bounds (negative or >= to the width or height 1849 * respectively). The returned color is a non-premultiplied ARGB value in 1850 * the {@link ColorSpace.Named#SRGB sRGB} color space. 1851 * 1852 * @param x The x coordinate (0...width-1) of the pixel to return 1853 * @param y The y coordinate (0...height-1) of the pixel to return 1854 * @return The argb {@link Color} at the specified coordinate 1855 * @throws IllegalArgumentException if x, y exceed the bitmap's bounds 1856 * @throws IllegalStateException if the bitmap's config is {@link Config#HARDWARE} 1857 */ 1858 @ColorInt getPixel(int x, int y)1859 public int getPixel(int x, int y) { 1860 checkRecycled("Can't call getPixel() on a recycled bitmap"); 1861 checkHardware("unable to getPixel(), " 1862 + "pixel access is not supported on Config#HARDWARE bitmaps"); 1863 checkPixelAccess(x, y); 1864 return nativeGetPixel(mNativePtr, x, y); 1865 } 1866 clamp(float value, @NonNull ColorSpace cs, int index)1867 private static float clamp(float value, @NonNull ColorSpace cs, int index) { 1868 return Math.max(Math.min(value, cs.getMaxValue(index)), cs.getMinValue(index)); 1869 } 1870 1871 /** 1872 * Returns the {@link Color} at the specified location. Throws an exception 1873 * if x or y are out of bounds (negative or >= to the width or height 1874 * respectively). 1875 * 1876 * @param x The x coordinate (0...width-1) of the pixel to return 1877 * @param y The y coordinate (0...height-1) of the pixel to return 1878 * @return The {@link Color} at the specified coordinate 1879 * @throws IllegalArgumentException if x, y exceed the bitmap's bounds 1880 * @throws IllegalStateException if the bitmap's config is {@link Config#HARDWARE} 1881 * 1882 */ 1883 @NonNull getColor(int x, int y)1884 public Color getColor(int x, int y) { 1885 checkRecycled("Can't call getColor() on a recycled bitmap"); 1886 checkHardware("unable to getColor(), " 1887 + "pixel access is not supported on Config#HARDWARE bitmaps"); 1888 checkPixelAccess(x, y); 1889 1890 final ColorSpace cs = getColorSpace(); 1891 if (cs.equals(ColorSpace.get(ColorSpace.Named.SRGB))) { 1892 return Color.valueOf(nativeGetPixel(mNativePtr, x, y)); 1893 } 1894 // The returned value is in kRGBA_F16_SkColorType, which is packed as 1895 // four half-floats, r,g,b,a. 1896 long rgba = nativeGetColor(mNativePtr, x, y); 1897 float r = Half.toFloat((short) ((rgba >> 0) & 0xffff)); 1898 float g = Half.toFloat((short) ((rgba >> 16) & 0xffff)); 1899 float b = Half.toFloat((short) ((rgba >> 32) & 0xffff)); 1900 float a = Half.toFloat((short) ((rgba >> 48) & 0xffff)); 1901 1902 // Skia may draw outside of the numerical range of the colorSpace. 1903 // Clamp to get an expected value. 1904 return Color.valueOf(clamp(r, cs, 0), clamp(g, cs, 1), clamp(b, cs, 2), a, cs); 1905 } 1906 1907 /** 1908 * Returns in pixels[] a copy of the data in the bitmap. Each value is 1909 * a packed int representing a {@link Color}. The stride parameter allows 1910 * the caller to allow for gaps in the returned pixels array between 1911 * rows. For normal packed results, just pass width for the stride value. 1912 * The returned colors are non-premultiplied ARGB values in the 1913 * {@link ColorSpace.Named#SRGB sRGB} color space. 1914 * 1915 * @param pixels The array to receive the bitmap's colors 1916 * @param offset The first index to write into pixels[] 1917 * @param stride The number of entries in pixels[] to skip between 1918 * rows (must be >= bitmap's width). Can be negative. 1919 * @param x The x coordinate of the first pixel to read from 1920 * the bitmap 1921 * @param y The y coordinate of the first pixel to read from 1922 * the bitmap 1923 * @param width The number of pixels to read from each row 1924 * @param height The number of rows to read 1925 * 1926 * @throws IllegalArgumentException if x, y, width, height exceed the 1927 * bounds of the bitmap, or if abs(stride) < width. 1928 * @throws ArrayIndexOutOfBoundsException if the pixels array is too small 1929 * to receive the specified number of pixels. 1930 * @throws IllegalStateException if the bitmap's config is {@link Config#HARDWARE} 1931 */ getPixels(@olorInt int[] pixels, int offset, int stride, int x, int y, int width, int height)1932 public void getPixels(@ColorInt int[] pixels, int offset, int stride, 1933 int x, int y, int width, int height) { 1934 checkRecycled("Can't call getPixels() on a recycled bitmap"); 1935 checkHardware("unable to getPixels(), " 1936 + "pixel access is not supported on Config#HARDWARE bitmaps"); 1937 if (width == 0 || height == 0) { 1938 return; // nothing to do 1939 } 1940 checkPixelsAccess(x, y, width, height, offset, stride, pixels); 1941 nativeGetPixels(mNativePtr, pixels, offset, stride, 1942 x, y, width, height); 1943 } 1944 1945 /** 1946 * Shared code to check for illegal arguments passed to getPixel() 1947 * or setPixel() 1948 * 1949 * @param x x coordinate of the pixel 1950 * @param y y coordinate of the pixel 1951 */ checkPixelAccess(int x, int y)1952 private void checkPixelAccess(int x, int y) { 1953 checkXYSign(x, y); 1954 if (x >= getWidth()) { 1955 throw new IllegalArgumentException("x must be < bitmap.width()"); 1956 } 1957 if (y >= getHeight()) { 1958 throw new IllegalArgumentException("y must be < bitmap.height()"); 1959 } 1960 } 1961 1962 /** 1963 * Shared code to check for illegal arguments passed to getPixels() 1964 * or setPixels() 1965 * 1966 * @param x left edge of the area of pixels to access 1967 * @param y top edge of the area of pixels to access 1968 * @param width width of the area of pixels to access 1969 * @param height height of the area of pixels to access 1970 * @param offset offset into pixels[] array 1971 * @param stride number of elements in pixels[] between each logical row 1972 * @param pixels array to hold the area of pixels being accessed 1973 */ checkPixelsAccess(int x, int y, int width, int height, int offset, int stride, int pixels[])1974 private void checkPixelsAccess(int x, int y, int width, int height, 1975 int offset, int stride, int pixels[]) { 1976 checkXYSign(x, y); 1977 if (width < 0) { 1978 throw new IllegalArgumentException("width must be >= 0"); 1979 } 1980 if (height < 0) { 1981 throw new IllegalArgumentException("height must be >= 0"); 1982 } 1983 if (x + width > getWidth()) { 1984 throw new IllegalArgumentException( 1985 "x + width must be <= bitmap.width()"); 1986 } 1987 if (y + height > getHeight()) { 1988 throw new IllegalArgumentException( 1989 "y + height must be <= bitmap.height()"); 1990 } 1991 if (Math.abs(stride) < width) { 1992 throw new IllegalArgumentException("abs(stride) must be >= width"); 1993 } 1994 int lastScanline = offset + (height - 1) * stride; 1995 int length = pixels.length; 1996 if (offset < 0 || (offset + width > length) 1997 || lastScanline < 0 1998 || (lastScanline + width > length)) { 1999 throw new ArrayIndexOutOfBoundsException(); 2000 } 2001 } 2002 2003 /** 2004 * <p>Write the specified {@link Color} into the bitmap (assuming it is 2005 * mutable) at the x,y coordinate. The color must be a 2006 * non-premultiplied ARGB value in the {@link ColorSpace.Named#SRGB sRGB} 2007 * color space.</p> 2008 * 2009 * @param x The x coordinate of the pixel to replace (0...width-1) 2010 * @param y The y coordinate of the pixel to replace (0...height-1) 2011 * @param color The ARGB color to write into the bitmap 2012 * 2013 * @throws IllegalStateException if the bitmap is not mutable 2014 * @throws IllegalArgumentException if x, y are outside of the bitmap's 2015 * bounds. 2016 */ setPixel(int x, int y, @ColorInt int color)2017 public void setPixel(int x, int y, @ColorInt int color) { 2018 checkRecycled("Can't call setPixel() on a recycled bitmap"); 2019 if (!isMutable()) { 2020 throw new IllegalStateException(); 2021 } 2022 checkPixelAccess(x, y); 2023 nativeSetPixel(mNativePtr, x, y, color); 2024 } 2025 2026 /** 2027 * <p>Replace pixels in the bitmap with the colors in the array. Each element 2028 * in the array is a packed int representing a non-premultiplied ARGB 2029 * {@link Color} in the {@link ColorSpace.Named#SRGB sRGB} color space.</p> 2030 * 2031 * @param pixels The colors to write to the bitmap 2032 * @param offset The index of the first color to read from pixels[] 2033 * @param stride The number of colors in pixels[] to skip between rows. 2034 * Normally this value will be the same as the width of 2035 * the bitmap, but it can be larger (or negative). 2036 * @param x The x coordinate of the first pixel to write to in 2037 * the bitmap. 2038 * @param y The y coordinate of the first pixel to write to in 2039 * the bitmap. 2040 * @param width The number of colors to copy from pixels[] per row 2041 * @param height The number of rows to write to the bitmap 2042 * 2043 * @throws IllegalStateException if the bitmap is not mutable 2044 * @throws IllegalArgumentException if x, y, width, height are outside of 2045 * the bitmap's bounds. 2046 * @throws ArrayIndexOutOfBoundsException if the pixels array is too small 2047 * to receive the specified number of pixels. 2048 */ setPixels(@olorInt int[] pixels, int offset, int stride, int x, int y, int width, int height)2049 public void setPixels(@ColorInt int[] pixels, int offset, int stride, 2050 int x, int y, int width, int height) { 2051 checkRecycled("Can't call setPixels() on a recycled bitmap"); 2052 if (!isMutable()) { 2053 throw new IllegalStateException(); 2054 } 2055 if (width == 0 || height == 0) { 2056 return; // nothing to do 2057 } 2058 checkPixelsAccess(x, y, width, height, offset, stride, pixels); 2059 nativeSetPixels(mNativePtr, pixels, offset, stride, 2060 x, y, width, height); 2061 } 2062 2063 public static final @android.annotation.NonNull Parcelable.Creator<Bitmap> CREATOR 2064 = new Parcelable.Creator<Bitmap>() { 2065 /** 2066 * Rebuilds a bitmap previously stored with writeToParcel(). 2067 * 2068 * @param p Parcel object to read the bitmap from 2069 * @return a new bitmap created from the data in the parcel 2070 */ 2071 public Bitmap createFromParcel(Parcel p) { 2072 Bitmap bm = nativeCreateFromParcel(p); 2073 if (bm == null) { 2074 throw new RuntimeException("Failed to unparcel Bitmap"); 2075 } 2076 return bm; 2077 } 2078 public Bitmap[] newArray(int size) { 2079 return new Bitmap[size]; 2080 } 2081 }; 2082 2083 /** 2084 * No special parcel contents. 2085 */ describeContents()2086 public int describeContents() { 2087 return 0; 2088 } 2089 2090 /** 2091 * Write the bitmap and its pixels to the parcel. The bitmap can be 2092 * rebuilt from the parcel by calling CREATOR.createFromParcel(). 2093 * 2094 * If this bitmap is {@link Config#HARDWARE}, it may be unparceled with a different pixel 2095 * format (e.g. 565, 8888), but the content will be preserved to the best quality permitted 2096 * by the final pixel format 2097 * @param p Parcel object to write the bitmap data into 2098 */ writeToParcel(Parcel p, int flags)2099 public void writeToParcel(Parcel p, int flags) { 2100 checkRecycled("Can't parcel a recycled bitmap"); 2101 noteHardwareBitmapSlowCall(); 2102 if (!nativeWriteToParcel(mNativePtr, isMutable(), mDensity, p)) { 2103 throw new RuntimeException("native writeToParcel failed"); 2104 } 2105 } 2106 2107 /** 2108 * Returns a new bitmap that captures the alpha values of the original. 2109 * This may be drawn with Canvas.drawBitmap(), where the color(s) will be 2110 * taken from the paint that is passed to the draw call. 2111 * 2112 * @return new bitmap containing the alpha channel of the original bitmap. 2113 */ 2114 @CheckResult extractAlpha()2115 public Bitmap extractAlpha() { 2116 return extractAlpha(null, null); 2117 } 2118 2119 /** 2120 * Returns a new bitmap that captures the alpha values of the original. 2121 * These values may be affected by the optional Paint parameter, which 2122 * can contain its own alpha, and may also contain a MaskFilter which 2123 * could change the actual dimensions of the resulting bitmap (e.g. 2124 * a blur maskfilter might enlarge the resulting bitmap). If offsetXY 2125 * is not null, it returns the amount to offset the returned bitmap so 2126 * that it will logically align with the original. For example, if the 2127 * paint contains a blur of radius 2, then offsetXY[] would contains 2128 * -2, -2, so that drawing the alpha bitmap offset by (-2, -2) and then 2129 * drawing the original would result in the blur visually aligning with 2130 * the original. 2131 * 2132 * <p>The initial density of the returned bitmap is the same as the original's. 2133 * 2134 * @param paint Optional paint used to modify the alpha values in the 2135 * resulting bitmap. Pass null for default behavior. 2136 * @param offsetXY Optional array that returns the X (index 0) and Y 2137 * (index 1) offset needed to position the returned bitmap 2138 * so that it visually lines up with the original. 2139 * @return new bitmap containing the (optionally modified by paint) alpha 2140 * channel of the original bitmap. This may be drawn with 2141 * Canvas.drawBitmap(), where the color(s) will be taken from the 2142 * paint that is passed to the draw call. 2143 */ 2144 @CheckResult extractAlpha(Paint paint, int[] offsetXY)2145 public Bitmap extractAlpha(Paint paint, int[] offsetXY) { 2146 checkRecycled("Can't extractAlpha on a recycled bitmap"); 2147 long nativePaint = paint != null ? paint.getNativeInstance() : 0; 2148 noteHardwareBitmapSlowCall(); 2149 Bitmap bm = nativeExtractAlpha(mNativePtr, nativePaint, offsetXY); 2150 if (bm == null) { 2151 throw new RuntimeException("Failed to extractAlpha on Bitmap"); 2152 } 2153 bm.mDensity = mDensity; 2154 return bm; 2155 } 2156 2157 /** 2158 * Given another bitmap, return true if it has the same dimensions, config, 2159 * and pixel data as this bitmap. If any of those differ, return false. 2160 * If other is null, return false. 2161 */ sameAs(Bitmap other)2162 public boolean sameAs(Bitmap other) { 2163 checkRecycled("Can't call sameAs on a recycled bitmap!"); 2164 noteHardwareBitmapSlowCall(); 2165 if (this == other) return true; 2166 if (other == null) return false; 2167 other.noteHardwareBitmapSlowCall(); 2168 if (other.isRecycled()) { 2169 throw new IllegalArgumentException("Can't compare to a recycled bitmap!"); 2170 } 2171 return nativeSameAs(mNativePtr, other.mNativePtr); 2172 } 2173 2174 /** 2175 * Builds caches associated with the bitmap that are used for drawing it. 2176 * 2177 * <p>Starting in {@link android.os.Build.VERSION_CODES#N}, this call initiates an asynchronous 2178 * upload to the GPU on RenderThread, if the Bitmap is not already uploaded. With Hardware 2179 * Acceleration, Bitmaps must be uploaded to the GPU in order to be rendered. This is done by 2180 * default the first time a Bitmap is drawn, but the process can take several milliseconds, 2181 * depending on the size of the Bitmap. Each time a Bitmap is modified and drawn again, it must 2182 * be re-uploaded.</p> 2183 * 2184 * <p>Calling this method in advance can save time in the first frame it's used. For example, it 2185 * is recommended to call this on an image decoding worker thread when a decoded Bitmap is about 2186 * to be displayed. It is recommended to make any pre-draw modifications to the Bitmap before 2187 * calling this method, so the cached, uploaded copy may be reused without re-uploading.</p> 2188 * 2189 * In {@link android.os.Build.VERSION_CODES#KITKAT} and below, for purgeable bitmaps, this call 2190 * would attempt to ensure that the pixels have been decoded. 2191 */ prepareToDraw()2192 public void prepareToDraw() { 2193 checkRecycled("Can't prepareToDraw on a recycled bitmap!"); 2194 // Kick off an update/upload of the bitmap outside of the normal 2195 // draw path. 2196 nativePrepareToDraw(mNativePtr); 2197 } 2198 2199 /** 2200 * @return {@link GraphicBuffer} which is internally used by hardware bitmap 2201 * 2202 * Note: the GraphicBuffer does *not* have an associated {@link ColorSpace}. 2203 * To render this object the same as its rendered with this Bitmap, you 2204 * should also call {@link getColorSpace}. 2205 * 2206 * @hide 2207 */ 2208 @UnsupportedAppUsage createGraphicBufferHandle()2209 public GraphicBuffer createGraphicBufferHandle() { 2210 return nativeCreateGraphicBufferHandle(mNativePtr); 2211 } 2212 2213 //////////// native methods 2214 nativeCreate(int[] colors, int offset, int stride, int width, int height, int nativeConfig, boolean mutable, long nativeColorSpace)2215 private static native Bitmap nativeCreate(int[] colors, int offset, 2216 int stride, int width, int height, 2217 int nativeConfig, boolean mutable, 2218 long nativeColorSpace); nativeCopy(long nativeSrcBitmap, int nativeConfig, boolean isMutable)2219 private static native Bitmap nativeCopy(long nativeSrcBitmap, int nativeConfig, 2220 boolean isMutable); nativeCopyAshmem(long nativeSrcBitmap)2221 private static native Bitmap nativeCopyAshmem(long nativeSrcBitmap); nativeCopyAshmemConfig(long nativeSrcBitmap, int nativeConfig)2222 private static native Bitmap nativeCopyAshmemConfig(long nativeSrcBitmap, int nativeConfig); nativeGetNativeFinalizer()2223 private static native long nativeGetNativeFinalizer(); nativeRecycle(long nativeBitmap)2224 private static native void nativeRecycle(long nativeBitmap); 2225 @UnsupportedAppUsage nativeReconfigure(long nativeBitmap, int width, int height, int config, boolean isPremultiplied)2226 private static native void nativeReconfigure(long nativeBitmap, int width, int height, 2227 int config, boolean isPremultiplied); 2228 nativeCompress(long nativeBitmap, int format, int quality, OutputStream stream, byte[] tempStorage)2229 private static native boolean nativeCompress(long nativeBitmap, int format, 2230 int quality, OutputStream stream, 2231 byte[] tempStorage); nativeErase(long nativeBitmap, int color)2232 private static native void nativeErase(long nativeBitmap, int color); nativeErase(long nativeBitmap, long colorSpacePtr, long color)2233 private static native void nativeErase(long nativeBitmap, long colorSpacePtr, long color); nativeRowBytes(long nativeBitmap)2234 private static native int nativeRowBytes(long nativeBitmap); nativeConfig(long nativeBitmap)2235 private static native int nativeConfig(long nativeBitmap); 2236 nativeGetPixel(long nativeBitmap, int x, int y)2237 private static native int nativeGetPixel(long nativeBitmap, int x, int y); nativeGetColor(long nativeBitmap, int x, int y)2238 private static native long nativeGetColor(long nativeBitmap, int x, int y); nativeGetPixels(long nativeBitmap, int[] pixels, int offset, int stride, int x, int y, int width, int height)2239 private static native void nativeGetPixels(long nativeBitmap, int[] pixels, 2240 int offset, int stride, int x, int y, 2241 int width, int height); 2242 nativeSetPixel(long nativeBitmap, int x, int y, int color)2243 private static native void nativeSetPixel(long nativeBitmap, int x, int y, int color); nativeSetPixels(long nativeBitmap, int[] colors, int offset, int stride, int x, int y, int width, int height)2244 private static native void nativeSetPixels(long nativeBitmap, int[] colors, 2245 int offset, int stride, int x, int y, 2246 int width, int height); nativeCopyPixelsToBuffer(long nativeBitmap, Buffer dst)2247 private static native void nativeCopyPixelsToBuffer(long nativeBitmap, 2248 Buffer dst); nativeCopyPixelsFromBuffer(long nativeBitmap, Buffer src)2249 private static native void nativeCopyPixelsFromBuffer(long nativeBitmap, Buffer src); nativeGenerationId(long nativeBitmap)2250 private static native int nativeGenerationId(long nativeBitmap); 2251 nativeCreateFromParcel(Parcel p)2252 private static native Bitmap nativeCreateFromParcel(Parcel p); 2253 // returns true on success nativeWriteToParcel(long nativeBitmap, boolean isMutable, int density, Parcel p)2254 private static native boolean nativeWriteToParcel(long nativeBitmap, 2255 boolean isMutable, 2256 int density, 2257 Parcel p); 2258 // returns a new bitmap built from the native bitmap's alpha, and the paint nativeExtractAlpha(long nativeBitmap, long nativePaint, int[] offsetXY)2259 private static native Bitmap nativeExtractAlpha(long nativeBitmap, 2260 long nativePaint, 2261 int[] offsetXY); 2262 nativeHasAlpha(long nativeBitmap)2263 private static native boolean nativeHasAlpha(long nativeBitmap); nativeIsPremultiplied(long nativeBitmap)2264 private static native boolean nativeIsPremultiplied(long nativeBitmap); nativeSetPremultiplied(long nativeBitmap, boolean isPremul)2265 private static native void nativeSetPremultiplied(long nativeBitmap, 2266 boolean isPremul); nativeSetHasAlpha(long nativeBitmap, boolean hasAlpha, boolean requestPremul)2267 private static native void nativeSetHasAlpha(long nativeBitmap, 2268 boolean hasAlpha, 2269 boolean requestPremul); nativeHasMipMap(long nativeBitmap)2270 private static native boolean nativeHasMipMap(long nativeBitmap); nativeSetHasMipMap(long nativeBitmap, boolean hasMipMap)2271 private static native void nativeSetHasMipMap(long nativeBitmap, boolean hasMipMap); nativeSameAs(long nativeBitmap0, long nativeBitmap1)2272 private static native boolean nativeSameAs(long nativeBitmap0, long nativeBitmap1); nativePrepareToDraw(long nativeBitmap)2273 private static native void nativePrepareToDraw(long nativeBitmap); nativeGetAllocationByteCount(long nativeBitmap)2274 private static native int nativeGetAllocationByteCount(long nativeBitmap); nativeCopyPreserveInternalConfig(long nativeBitmap)2275 private static native Bitmap nativeCopyPreserveInternalConfig(long nativeBitmap); nativeWrapHardwareBufferBitmap(HardwareBuffer buffer, long nativeColorSpace)2276 private static native Bitmap nativeWrapHardwareBufferBitmap(HardwareBuffer buffer, 2277 long nativeColorSpace); nativeCreateGraphicBufferHandle(long nativeBitmap)2278 private static native GraphicBuffer nativeCreateGraphicBufferHandle(long nativeBitmap); nativeComputeColorSpace(long nativePtr)2279 private static native ColorSpace nativeComputeColorSpace(long nativePtr); nativeSetColorSpace(long nativePtr, long nativeColorSpace)2280 private static native void nativeSetColorSpace(long nativePtr, long nativeColorSpace); nativeIsSRGB(long nativePtr)2281 private static native boolean nativeIsSRGB(long nativePtr); nativeIsSRGBLinear(long nativePtr)2282 private static native boolean nativeIsSRGBLinear(long nativePtr); 2283 nativeSetImmutable(long nativePtr)2284 private static native void nativeSetImmutable(long nativePtr); 2285 2286 // ---------------- @CriticalNative ------------------- 2287 2288 @CriticalNative nativeIsImmutable(long nativePtr)2289 private static native boolean nativeIsImmutable(long nativePtr); 2290 } 2291