For more information about how to use Canvas, read the * * Canvas and Drawables developer guide.
The initial target density of the canvas is the same as the given * bitmap's density. * * @param bitmap Specifies a mutable bitmap for the canvas to draw into. */ public Canvas(@NonNull Bitmap bitmap) { if (!bitmap.isMutable()) { throw new IllegalStateException("Immutable bitmap passed to Canvas constructor"); } throwIfCannotDraw(bitmap); mNativeCanvasWrapper = nInitRaster(bitmap); mFinalizer = NoImagePreloadHolder.sRegistry.registerNativeAllocation( this, mNativeCanvasWrapper); mBitmap = bitmap; mDensity = bitmap.mDensity; } /** @hide */ public Canvas(long nativeCanvas) { if (nativeCanvas == 0) { throw new IllegalStateException(); } mNativeCanvasWrapper = nativeCanvas; mFinalizer = NoImagePreloadHolder.sRegistry.registerNativeAllocation( this, mNativeCanvasWrapper); mDensity = Bitmap.getDefaultDensity(); } /** * Returns null. * * @deprecated This method is not supported and should not be invoked. * * @hide */ @Deprecated protected GL getGL() { return null; } /** * Indicates whether this Canvas uses hardware acceleration. * * Note that this method does not define what type of hardware acceleration * may or may not be used. * * @return True if drawing operations are hardware accelerated, * false otherwise. */ public boolean isHardwareAccelerated() { return false; } /** * Specify a bitmap for the canvas to draw into. All canvas state such as * layers, filters, and the save/restore stack are reset. Additionally, * the canvas' target density is updated to match that of the bitmap. * * Prior to API level {@value Build.VERSION_CODES#O} the current matrix and * clip stack were preserved. * * @param bitmap Specifies a mutable bitmap for the canvas to draw into. * @see #setDensity(int) * @see #getDensity() */ public void setBitmap(@Nullable Bitmap bitmap) { if (isHardwareAccelerated()) { throw new RuntimeException("Can't set a bitmap device on a HW accelerated canvas"); } Matrix preservedMatrix = null; if (bitmap != null && sCompatibilitySetBitmap) { preservedMatrix = getMatrix(); } if (bitmap == null) { nSetBitmap(mNativeCanvasWrapper, null); mDensity = Bitmap.DENSITY_NONE; } else { if (!bitmap.isMutable()) { throw new IllegalStateException(); } throwIfCannotDraw(bitmap); nSetBitmap(mNativeCanvasWrapper, bitmap); mDensity = bitmap.mDensity; } if (preservedMatrix != null) { setMatrix(preservedMatrix); } mBitmap = bitmap; } /** @hide */ public void setHighContrastText(boolean highContrastText) { nSetHighContrastText(mNativeCanvasWrapper, highContrastText); } /** @hide */ public void insertReorderBarrier() {} /** @hide */ public void insertInorderBarrier() {} /** * Return true if the device that the current layer draws into is opaque * (i.e. does not support per-pixel alpha). * * @return true if the device that the current layer draws into is opaque */ public boolean isOpaque() { return nIsOpaque(mNativeCanvasWrapper); } /** * Returns the width of the current drawing layer * * @return the width of the current drawing layer */ public int getWidth() { return nGetWidth(mNativeCanvasWrapper); } /** * Returns the height of the current drawing layer * * @return the height of the current drawing layer */ public int getHeight() { return nGetHeight(mNativeCanvasWrapper); } /** *
Returns the target density of the canvas. The default density is * derived from the density of its backing bitmap, or * {@link Bitmap#DENSITY_NONE} if there is not one.
* * @return Returns the current target density of the canvas, which is used * to determine the scaling factor when drawing a bitmap into it. * * @see #setDensity(int) * @see Bitmap#getDensity() */ public int getDensity() { return mDensity; } /** *Specifies the density for this Canvas' backing bitmap. This modifies * the target density of the canvas itself, as well as the density of its * backing bitmap via {@link Bitmap#setDensity(int) Bitmap.setDensity(int)}. * * @param density The new target density of the canvas, which is used * to determine the scaling factor when drawing a bitmap into it. Use * {@link Bitmap#DENSITY_NONE} to disable bitmap scaling. * * @see #getDensity() * @see Bitmap#setDensity(int) */ public void setDensity(int density) { if (mBitmap != null) { mBitmap.setDensity(density); } mDensity = density; } /** @hide */ public void setScreenDensity(int density) { mScreenDensity = density; } /** * Returns the maximum allowed width for bitmaps drawn with this canvas. * Attempting to draw with a bitmap wider than this value will result * in an error. * * @see #getMaximumBitmapHeight() */ public int getMaximumBitmapWidth() { return MAXMIMUM_BITMAP_SIZE; } /** * Returns the maximum allowed height for bitmaps drawn with this canvas. * Attempting to draw with a bitmap taller than this value will result * in an error. * * @see #getMaximumBitmapWidth() */ public int getMaximumBitmapHeight() { return MAXMIMUM_BITMAP_SIZE; } // the SAVE_FLAG constants must match their native equivalents /** @hide */ @IntDef(flag = true, value = { ALL_SAVE_FLAG }) @Retention(RetentionPolicy.SOURCE) public @interface Saveflags {} /** * Restore the current matrix when restore() is called. * * @deprecated Use the flagless version of {@link #save()}, {@link #saveLayer(RectF, Paint)} or * {@link #saveLayerAlpha(RectF, int)}. For saveLayer() calls the matrix * was always restored for {@link #isHardwareAccelerated() Hardware accelerated} * canvases and as of API level {@value Build.VERSION_CODES#O} that is the default * behavior for all canvas types. */ public static final int MATRIX_SAVE_FLAG = 0x01; /** * Restore the current clip when restore() is called. * * @deprecated Use the flagless version of {@link #save()}, {@link #saveLayer(RectF, Paint)} or * {@link #saveLayerAlpha(RectF, int)}. For saveLayer() calls the clip * was always restored for {@link #isHardwareAccelerated() Hardware accelerated} * canvases and as of API level {@value Build.VERSION_CODES#O} that is the default * behavior for all canvas types. */ public static final int CLIP_SAVE_FLAG = 0x02; /** * The layer requires a per-pixel alpha channel. * * @deprecated This flag is ignored. Use the flagless version of {@link #saveLayer(RectF, Paint)} * {@link #saveLayerAlpha(RectF, int)}. */ public static final int HAS_ALPHA_LAYER_SAVE_FLAG = 0x04; /** * The layer requires full 8-bit precision for each color channel. * * @deprecated This flag is ignored. Use the flagless version of {@link #saveLayer(RectF, Paint)} * {@link #saveLayerAlpha(RectF, int)}. */ public static final int FULL_COLOR_LAYER_SAVE_FLAG = 0x08; /** * Clip drawing to the bounds of the offscreen layer, omit at your own peril. *
Note: it is strongly recommended to not
* omit this flag for any call to saveLayer() and
* saveLayerAlpha() variants. Not passing this flag generally
* triggers extremely poor performance with hardware accelerated rendering.
*
* @deprecated This flag results in poor performance and the same effect can be achieved with
* a single layer or multiple draw commands with different clips.
*
*/
public static final int CLIP_TO_LAYER_SAVE_FLAG = 0x10;
/**
* Restore everything when restore() is called (standard save flags).
*
Note: for performance reasons, it is
* strongly recommended to pass this - the complete set of flags - to any
* call to saveLayer() and saveLayerAlpha()
* variants.
*
*
Note: all methods that accept this flag * have flagless versions that are equivalent to passing this flag. */ public static final int ALL_SAVE_FLAG = 0x1F; /** * Saves the current matrix and clip onto a private stack. *
* Subsequent calls to translate,scale,rotate,skew,concat or clipRect, * clipPath will all operate as usual, but when the balancing call to * restore() is made, those calls will be forgotten, and the settings that * existed before the save() will be reinstated. * * @return The value to pass to restoreToCount() to balance this save() */ public int save() { return nSave(mNativeCanvasWrapper, MATRIX_SAVE_FLAG | CLIP_SAVE_FLAG); } /** * Based on saveFlags, can save the current matrix and clip onto a private * stack. *
Note: if possible, use the * parameter-less save(). It is simpler and faster than individually * disabling the saving of matrix or clip with this method. *
* Subsequent calls to translate,scale,rotate,skew,concat or clipRect, * clipPath will all operate as usual, but when the balancing call to * restore() is made, those calls will be forgotten, and the settings that * existed before the save() will be reinstated. * * @deprecated Use {@link #save()} instead. * @param saveFlags flag bits that specify which parts of the Canvas state * to save/restore * @return The value to pass to restoreToCount() to balance this save() */ public int save(@Saveflags int saveFlags) { return nSave(mNativeCanvasWrapper, saveFlags); } /** * This behaves the same as save(), but in addition it allocates and * redirects drawing to an offscreen bitmap. *
Note: this method is very expensive, * incurring more than double rendering cost for contained content. Avoid * using this method, especially if the bounds provided are large, or if * the {@link #CLIP_TO_LAYER_SAVE_FLAG} is omitted from the * {@code saveFlags} parameter. It is recommended to use a * {@link android.view.View#LAYER_TYPE_HARDWARE hardware layer} on a View * to apply an xfermode, color filter, or alpha, as it will perform much * better than this method. *
* All drawing calls are directed to a newly allocated offscreen bitmap. * Only when the balancing call to restore() is made, is that offscreen * buffer drawn back to the current target of the Canvas (either the * screen, it's target Bitmap, or the previous layer). *
* Attributes of the Paint - {@link Paint#getAlpha() alpha}, * {@link Paint#getXfermode() Xfermode}, and * {@link Paint#getColorFilter() ColorFilter} are applied when the * offscreen bitmap is drawn back when restore() is called. * * @deprecated Use {@link #saveLayer(RectF, Paint)} instead. * @param bounds May be null. The maximum size the offscreen bitmap * needs to be (in local coordinates) * @param paint This is copied, and is applied to the offscreen when * restore() is called. * @param saveFlags see _SAVE_FLAG constants, generally {@link #ALL_SAVE_FLAG} is recommended * for performance reasons. * @return value to pass to restoreToCount() to balance this save() */ public int saveLayer(@Nullable RectF bounds, @Nullable Paint paint, @Saveflags int saveFlags) { if (bounds == null) { bounds = new RectF(getClipBounds()); } return saveLayer(bounds.left, bounds.top, bounds.right, bounds.bottom, paint, saveFlags); } /** * This behaves the same as save(), but in addition it allocates and * redirects drawing to an offscreen rendering target. *
Note: this method is very expensive, * incurring more than double rendering cost for contained content. Avoid * using this method when possible and instead use a * {@link android.view.View#LAYER_TYPE_HARDWARE hardware layer} on a View * to apply an xfermode, color filter, or alpha, as it will perform much * better than this method. *
* All drawing calls are directed to a newly allocated offscreen rendering target. * Only when the balancing call to restore() is made, is that offscreen * buffer drawn back to the current target of the Canvas (which can potentially be a previous * layer if these calls are nested). *
* Attributes of the Paint - {@link Paint#getAlpha() alpha}, * {@link Paint#getXfermode() Xfermode}, and * {@link Paint#getColorFilter() ColorFilter} are applied when the * offscreen rendering target is drawn back when restore() is called. * * @param bounds May be null. The maximum size the offscreen render target * needs to be (in local coordinates) * @param paint This is copied, and is applied to the offscreen when * restore() is called. * @return value to pass to restoreToCount() to balance this save() */ public int saveLayer(@Nullable RectF bounds, @Nullable Paint paint) { return saveLayer(bounds, paint, ALL_SAVE_FLAG); } /** * Helper version of saveLayer() that takes 4 values rather than a RectF. * * @deprecated Use {@link #saveLayer(float, float, float, float, Paint)} instead. */ public int saveLayer(float left, float top, float right, float bottom, @Nullable Paint paint, @Saveflags int saveFlags) { return nSaveLayer(mNativeCanvasWrapper, left, top, right, bottom, paint != null ? paint.getNativeInstance() : 0, saveFlags); } /** * Convenience for {@link #saveLayer(RectF, Paint)} that takes the four float coordinates of the * bounds rectangle. */ public int saveLayer(float left, float top, float right, float bottom, @Nullable Paint paint) { return saveLayer(left, top, right, bottom, paint, ALL_SAVE_FLAG); } /** * This behaves the same as save(), but in addition it allocates and * redirects drawing to an offscreen bitmap. *
Note: this method is very expensive, * incurring more than double rendering cost for contained content. Avoid * using this method, especially if the bounds provided are large, or if * the {@link #CLIP_TO_LAYER_SAVE_FLAG} is omitted from the * {@code saveFlags} parameter. It is recommended to use a * {@link android.view.View#LAYER_TYPE_HARDWARE hardware layer} on a View * to apply an xfermode, color filter, or alpha, as it will perform much * better than this method. *
* All drawing calls are directed to a newly allocated offscreen bitmap. * Only when the balancing call to restore() is made, is that offscreen * buffer drawn back to the current target of the Canvas (either the * screen, it's target Bitmap, or the previous layer). *
* The {@code alpha} parameter is applied when the offscreen bitmap is * drawn back when restore() is called. * * @deprecated Use {@link #saveLayerAlpha(RectF, int)} instead. * @param bounds The maximum size the offscreen bitmap needs to be * (in local coordinates) * @param alpha The alpha to apply to the offscreen when it is drawn during restore() * @param saveFlags see _SAVE_FLAG constants, generally {@link #ALL_SAVE_FLAG} is recommended * for performance reasons. * @return value to pass to restoreToCount() to balance this call */ public int saveLayerAlpha(@Nullable RectF bounds, int alpha, @Saveflags int saveFlags) { if (bounds == null) { bounds = new RectF(getClipBounds()); } return saveLayerAlpha(bounds.left, bounds.top, bounds.right, bounds.bottom, alpha, saveFlags); } /** * Convenience for {@link #saveLayer(RectF, Paint)} but instead of taking a entire Paint object * it takes only the {@code alpha} parameter. * * @param bounds The maximum size the offscreen bitmap needs to be * (in local coordinates) * @param alpha The alpha to apply to the offscreen when it is drawn during restore() */ public int saveLayerAlpha(@Nullable RectF bounds, int alpha) { return saveLayerAlpha(bounds, alpha, ALL_SAVE_FLAG); } /** * Helper for saveLayerAlpha() that takes 4 values instead of a RectF. * * @deprecated Use {@link #saveLayerAlpha(float, float, float, float, int)} instead. */ public int saveLayerAlpha(float left, float top, float right, float bottom, int alpha, @Saveflags int saveFlags) { alpha = Math.min(255, Math.max(0, alpha)); return nSaveLayerAlpha(mNativeCanvasWrapper, left, top, right, bottom, alpha, saveFlags); } /** * Convenience for {@link #saveLayerAlpha(RectF, int)} that takes the four float coordinates of * the bounds rectangle. */ public int saveLayerAlpha(float left, float top, float right, float bottom, int alpha) { return saveLayerAlpha(left, top, right, bottom, alpha, ALL_SAVE_FLAG); } /** * This call balances a previous call to save(), and is used to remove all * modifications to the matrix/clip state since the last save call. It is * an error to call restore() more times than save() was called. */ public void restore() { if (!nRestore(mNativeCanvasWrapper) && (!sCompatibilityRestore || !isHardwareAccelerated())) { throw new IllegalStateException("Underflow in restore - more restores than saves"); } } /** * Returns the number of matrix/clip states on the Canvas' private stack. * This will equal # save() calls - # restore() calls. */ public int getSaveCount() { return nGetSaveCount(mNativeCanvasWrapper); } /** * Efficient way to pop any calls to save() that happened after the save * count reached saveCount. It is an error for saveCount to be less than 1. * * Example: * int count = canvas.save(); * ... // more calls potentially to save() * canvas.restoreToCount(count); * // now the canvas is back in the same state it was before the initial * // call to save(). * * @param saveCount The save level to restore to. */ public void restoreToCount(int saveCount) { if (saveCount < 1) { if (!sCompatibilityRestore || !isHardwareAccelerated()) { // do nothing and throw without restoring throw new IllegalArgumentException( "Underflow in restoreToCount - more restores than saves"); } // compat behavior - restore as far as possible saveCount = 1; } nRestoreToCount(mNativeCanvasWrapper, saveCount); } /** * Preconcat the current matrix with the specified translation * * @param dx The distance to translate in X * @param dy The distance to translate in Y */ public void translate(float dx, float dy) { if (dx == 0.0f && dy == 0.0f) return; nTranslate(mNativeCanvasWrapper, dx, dy); } /** * Preconcat the current matrix with the specified scale. * * @param sx The amount to scale in X * @param sy The amount to scale in Y */ public void scale(float sx, float sy) { if (sx == 1.0f && sy == 1.0f) return; nScale(mNativeCanvasWrapper, sx, sy); } /** * Preconcat the current matrix with the specified scale. * * @param sx The amount to scale in X * @param sy The amount to scale in Y * @param px The x-coord for the pivot point (unchanged by the scale) * @param py The y-coord for the pivot point (unchanged by the scale) */ public final void scale(float sx, float sy, float px, float py) { if (sx == 1.0f && sy == 1.0f) return; translate(px, py); scale(sx, sy); translate(-px, -py); } /** * Preconcat the current matrix with the specified rotation. * * @param degrees The amount to rotate, in degrees */ public void rotate(float degrees) { if (degrees == 0.0f) return; nRotate(mNativeCanvasWrapper, degrees); } /** * Preconcat the current matrix with the specified rotation. * * @param degrees The amount to rotate, in degrees * @param px The x-coord for the pivot point (unchanged by the rotation) * @param py The y-coord for the pivot point (unchanged by the rotation) */ public final void rotate(float degrees, float px, float py) { if (degrees == 0.0f) return; translate(px, py); rotate(degrees); translate(-px, -py); } /** * Preconcat the current matrix with the specified skew. * * @param sx The amount to skew in X * @param sy The amount to skew in Y */ public void skew(float sx, float sy) { if (sx == 0.0f && sy == 0.0f) return; nSkew(mNativeCanvasWrapper, sx, sy); } /** * Preconcat the current matrix with the specified matrix. If the specified * matrix is null, this method does nothing. * * @param matrix The matrix to preconcatenate with the current matrix */ public void concat(@Nullable Matrix matrix) { if (matrix != null) nConcat(mNativeCanvasWrapper, matrix.native_instance); } /** * Completely replace the current matrix with the specified matrix. If the * matrix parameter is null, then the current matrix is reset to identity. * * Note: it is recommended to use {@link #concat(Matrix)}, * {@link #scale(float, float)}, {@link #translate(float, float)} and * {@link #rotate(float)} instead of this method. * * @param matrix The matrix to replace the current matrix with. If it is * null, set the current matrix to identity. * * @see #concat(Matrix) */ public void setMatrix(@Nullable Matrix matrix) { nSetMatrix(mNativeCanvasWrapper, matrix == null ? 0 : matrix.native_instance); } /** * Return, in ctm, the current transformation matrix. This does not alter * the matrix in the canvas, but just returns a copy of it. * * @deprecated {@link #isHardwareAccelerated() Hardware accelerated} canvases may have any * matrix when passed to a View or Drawable, as it is implementation defined where in the * hierarchy such canvases are created. It is recommended in such cases to either draw contents * irrespective of the current matrix, or to track relevant transform state outside of the * canvas. */ @Deprecated public void getMatrix(@NonNull Matrix ctm) { nGetMatrix(mNativeCanvasWrapper, ctm.native_instance); } /** * Return a new matrix with a copy of the canvas' current transformation * matrix. * * @deprecated {@link #isHardwareAccelerated() Hardware accelerated} canvases may have any * matrix when passed to a View or Drawable, as it is implementation defined where in the * hierarchy such canvases are created. It is recommended in such cases to either draw contents * irrespective of the current matrix, or to track relevant transform state outside of the * canvas. */ @Deprecated public final @NonNull Matrix getMatrix() { Matrix m = new Matrix(); //noinspection deprecation getMatrix(m); return m; } /** * Modify the current clip with the specified rectangle. * * @param rect The rect to intersect with the current clip * @param op How the clip is modified * @return true if the resulting clip is non-empty * * @deprecated Region.Op values other than {@link Region.Op#INTERSECT} and * {@link Region.Op#DIFFERENCE} have the ability to expand the clip. The canvas clipping APIs * are intended to only expand the clip as a result of a restore operation. This enables a view * parent to clip a canvas to clearly define the maximal drawing area of its children. The * recommended alternative calls are {@link #clipRect(RectF)} and {@link #clipOutRect(RectF)}; */ @Deprecated public boolean clipRect(@NonNull RectF rect, @NonNull Region.Op op) { return nClipRect(mNativeCanvasWrapper, rect.left, rect.top, rect.right, rect.bottom, op.nativeInt); } /** * Modify the current clip with the specified rectangle, which is * expressed in local coordinates. * * @param rect The rectangle to intersect with the current clip. * @param op How the clip is modified * @return true if the resulting clip is non-empty * * @deprecated Region.Op values other than {@link Region.Op#INTERSECT} and * {@link Region.Op#DIFFERENCE} have the ability to expand the clip. The canvas clipping APIs * are intended to only expand the clip as a result of a restore operation. This enables a view * parent to clip a canvas to clearly define the maximal drawing area of its children. The * recommended alternative calls are {@link #clipRect(Rect)} and {@link #clipOutRect(Rect)}; */ @Deprecated public boolean clipRect(@NonNull Rect rect, @NonNull Region.Op op) { return nClipRect(mNativeCanvasWrapper, rect.left, rect.top, rect.right, rect.bottom, op.nativeInt); } /** * Intersect the current clip with the specified rectangle, which is * expressed in local coordinates. * * @param rect The rectangle to intersect with the current clip. * @return true if the resulting clip is non-empty */ public boolean clipRect(@NonNull RectF rect) { return nClipRect(mNativeCanvasWrapper, rect.left, rect.top, rect.right, rect.bottom, Region.Op.INTERSECT.nativeInt); } /** * Set the clip to the difference of the current clip and the specified rectangle, which is * expressed in local coordinates. * * @param rect The rectangle to perform a difference op with the current clip. * @return true if the resulting clip is non-empty */ public boolean clipOutRect(@NonNull RectF rect) { return nClipRect(mNativeCanvasWrapper, rect.left, rect.top, rect.right, rect.bottom, Region.Op.DIFFERENCE.nativeInt); } /** * Intersect the current clip with the specified rectangle, which is * expressed in local coordinates. * * @param rect The rectangle to intersect with the current clip. * @return true if the resulting clip is non-empty */ public boolean clipRect(@NonNull Rect rect) { return nClipRect(mNativeCanvasWrapper, rect.left, rect.top, rect.right, rect.bottom, Region.Op.INTERSECT.nativeInt); } /** * Set the clip to the difference of the current clip and the specified rectangle, which is * expressed in local coordinates. * * @param rect The rectangle to perform a difference op with the current clip. * @return true if the resulting clip is non-empty */ public boolean clipOutRect(@NonNull Rect rect) { return nClipRect(mNativeCanvasWrapper, rect.left, rect.top, rect.right, rect.bottom, Region.Op.DIFFERENCE.nativeInt); } /** * Modify the current clip with the specified rectangle, which is * expressed in local coordinates. * * @param left The left side of the rectangle to intersect with the * current clip * @param top The top of the rectangle to intersect with the current * clip * @param right The right side of the rectangle to intersect with the * current clip * @param bottom The bottom of the rectangle to intersect with the current * clip * @param op How the clip is modified * @return true if the resulting clip is non-empty * * @deprecated Region.Op values other than {@link Region.Op#INTERSECT} and * {@link Region.Op#DIFFERENCE} have the ability to expand the clip. The canvas clipping APIs * are intended to only expand the clip as a result of a restore operation. This enables a view * parent to clip a canvas to clearly define the maximal drawing area of its children. The * recommended alternative calls are {@link #clipRect(float,float,float,float)} and * {@link #clipOutRect(float,float,float,float)}; */ @Deprecated public boolean clipRect(float left, float top, float right, float bottom, @NonNull Region.Op op) { return nClipRect(mNativeCanvasWrapper, left, top, right, bottom, op.nativeInt); } /** * Intersect the current clip with the specified rectangle, which is * expressed in local coordinates. * * @param left The left side of the rectangle to intersect with the * current clip * @param top The top of the rectangle to intersect with the current clip * @param right The right side of the rectangle to intersect with the * current clip * @param bottom The bottom of the rectangle to intersect with the current * clip * @return true if the resulting clip is non-empty */ public boolean clipRect(float left, float top, float right, float bottom) { return nClipRect(mNativeCanvasWrapper, left, top, right, bottom, Region.Op.INTERSECT.nativeInt); } /** * Set the clip to the difference of the current clip and the specified rectangle, which is * expressed in local coordinates. * * @param left The left side of the rectangle used in the difference operation * @param top The top of the rectangle used in the difference operation * @param right The right side of the rectangle used in the difference operation * @param bottom The bottom of the rectangle used in the difference operation * @return true if the resulting clip is non-empty */ public boolean clipOutRect(float left, float top, float right, float bottom) { return nClipRect(mNativeCanvasWrapper, left, top, right, bottom, Region.Op.DIFFERENCE.nativeInt); } /** * Intersect the current clip with the specified rectangle, which is * expressed in local coordinates. * * @param left The left side of the rectangle to intersect with the * current clip * @param top The top of the rectangle to intersect with the current clip * @param right The right side of the rectangle to intersect with the * current clip * @param bottom The bottom of the rectangle to intersect with the current * clip * @return true if the resulting clip is non-empty */ public boolean clipRect(int left, int top, int right, int bottom) { return nClipRect(mNativeCanvasWrapper, left, top, right, bottom, Region.Op.INTERSECT.nativeInt); } /** * Set the clip to the difference of the current clip and the specified rectangle, which is * expressed in local coordinates. * * @param left The left side of the rectangle used in the difference operation * @param top The top of the rectangle used in the difference operation * @param right The right side of the rectangle used in the difference operation * @param bottom The bottom of the rectangle used in the difference operation * @return true if the resulting clip is non-empty */ public boolean clipOutRect(int left, int top, int right, int bottom) { return nClipRect(mNativeCanvasWrapper, left, top, right, bottom, Region.Op.DIFFERENCE.nativeInt); } /** * Modify the current clip with the specified path. * * @param path The path to operate on the current clip * @param op How the clip is modified * @return true if the resulting is non-empty * * @deprecated Region.Op values other than {@link Region.Op#INTERSECT} and * {@link Region.Op#DIFFERENCE} have the ability to expand the clip. The canvas clipping APIs * are intended to only expand the clip as a result of a restore operation. This enables a view * parent to clip a canvas to clearly define the maximal drawing area of its children. The * recommended alternative calls are {@link #clipPath(Path)} and * {@link #clipOutPath(Path)}; */ @Deprecated public boolean clipPath(@NonNull Path path, @NonNull Region.Op op) { return nClipPath(mNativeCanvasWrapper, path.readOnlyNI(), op.nativeInt); } /** * Intersect the current clip with the specified path. * * @param path The path to intersect with the current clip * @return true if the resulting clip is non-empty */ public boolean clipPath(@NonNull Path path) { return clipPath(path, Region.Op.INTERSECT); } /** * Set the clip to the difference of the current clip and the specified path. * * @param path The path used in the difference operation * @return true if the resulting clip is non-empty */ public boolean clipOutPath(@NonNull Path path) { return clipPath(path, Region.Op.DIFFERENCE); } /** * Modify the current clip with the specified region. Note that unlike * clipRect() and clipPath() which transform their arguments by the * current matrix, clipRegion() assumes its argument is already in the * coordinate system of the current layer's bitmap, and so not * transformation is performed. * * @param region The region to operate on the current clip, based on op * @param op How the clip is modified * @return true if the resulting is non-empty * * @removed * @deprecated Unlike all other clip calls this API does not respect the * current matrix. Use {@link #clipRect(Rect)} as an alternative. */ @Deprecated public boolean clipRegion(@NonNull Region region, @NonNull Region.Op op) { return false; } /** * Intersect the current clip with the specified region. Note that unlike * clipRect() and clipPath() which transform their arguments by the * current matrix, clipRegion() assumes its argument is already in the * coordinate system of the current layer's bitmap, and so not * transformation is performed. * * @param region The region to operate on the current clip, based on op * @return true if the resulting is non-empty * * @removed * @deprecated Unlike all other clip calls this API does not respect the * current matrix. Use {@link #clipRect(Rect)} as an alternative. */ @Deprecated public boolean clipRegion(@NonNull Region region) { return false; } public @Nullable DrawFilter getDrawFilter() { return mDrawFilter; } public void setDrawFilter(@Nullable DrawFilter filter) { long nativeFilter = 0; if (filter != null) { nativeFilter = filter.mNativeInt; } mDrawFilter = filter; nSetDrawFilter(mNativeCanvasWrapper, nativeFilter); } /** * Constant values used as parameters to {@code quickReject()} calls. These values * specify how much space around the shape should be accounted for, depending on whether * the shaped area is antialiased or not. * * @see #quickReject(float, float, float, float, EdgeType) * @see #quickReject(Path, EdgeType) * @see #quickReject(RectF, EdgeType) */ public enum EdgeType { /** * Black-and-White: Treat edges by just rounding to nearest pixel boundary */ BW(0), //!< treat edges by just rounding to nearest pixel boundary /** * Antialiased: Treat edges by rounding-out, since they may be antialiased */ AA(1); EdgeType(int nativeInt) { this.nativeInt = nativeInt; } /** * @hide */ public final int nativeInt; } /** * Return true if the specified rectangle, after being transformed by the * current matrix, would lie completely outside of the current clip. Call * this to check if an area you intend to draw into is clipped out (and * therefore you can skip making the draw calls). * * @param rect the rect to compare with the current clip * @param type {@link Canvas.EdgeType#AA} if the path should be considered antialiased, * since that means it may affect a larger area (more pixels) than * non-antialiased ({@link Canvas.EdgeType#BW}). * @return true if the rect (transformed by the canvas' matrix) * does not intersect with the canvas' clip */ public boolean quickReject(@NonNull RectF rect, @NonNull EdgeType type) { return nQuickReject(mNativeCanvasWrapper, rect.left, rect.top, rect.right, rect.bottom); } /** * Return true if the specified path, after being transformed by the * current matrix, would lie completely outside of the current clip. Call * this to check if an area you intend to draw into is clipped out (and * therefore you can skip making the draw calls). Note: for speed it may * return false even if the path itself might not intersect the clip * (i.e. the bounds of the path intersects, but the path does not). * * @param path The path to compare with the current clip * @param type {@link Canvas.EdgeType#AA} if the path should be considered antialiased, * since that means it may affect a larger area (more pixels) than * non-antialiased ({@link Canvas.EdgeType#BW}). * @return true if the path (transformed by the canvas' matrix) * does not intersect with the canvas' clip */ public boolean quickReject(@NonNull Path path, @NonNull EdgeType type) { return nQuickReject(mNativeCanvasWrapper, path.readOnlyNI()); } /** * Return true if the specified rectangle, after being transformed by the * current matrix, would lie completely outside of the current clip. Call * this to check if an area you intend to draw into is clipped out (and * therefore you can skip making the draw calls). * * @param left The left side of the rectangle to compare with the * current clip * @param top The top of the rectangle to compare with the current * clip * @param right The right side of the rectangle to compare with the * current clip * @param bottom The bottom of the rectangle to compare with the * current clip * @param type {@link Canvas.EdgeType#AA} if the path should be considered antialiased, * since that means it may affect a larger area (more pixels) than * non-antialiased ({@link Canvas.EdgeType#BW}). * @return true if the rect (transformed by the canvas' matrix) * does not intersect with the canvas' clip */ public boolean quickReject(float left, float top, float right, float bottom, @NonNull EdgeType type) { return nQuickReject(mNativeCanvasWrapper, left, top, right, bottom); } /** * Return the bounds of the current clip (in local coordinates) in the * bounds parameter, and return true if it is non-empty. This can be useful * in a way similar to quickReject, in that it tells you that drawing * outside of these bounds will be clipped out. * * @param bounds Return the clip bounds here. If it is null, ignore it but * still return true if the current clip is non-empty. * @return true if the current clip is non-empty. */ public boolean getClipBounds(@Nullable Rect bounds) { return nGetClipBounds(mNativeCanvasWrapper, bounds); } /** * Retrieve the bounds of the current clip (in local coordinates). * * @return the clip bounds, or [0, 0, 0, 0] if the clip is empty. */ public final @NonNull Rect getClipBounds() { Rect r = new Rect(); getClipBounds(r); return r; } /** * Save the canvas state, draw the picture, and restore the canvas state. * This differs from picture.draw(canvas), which does not perform any * save/restore. * *
* Note: This forces the picture to internally call * {@link Picture#endRecording} in order to prepare for playback. * * @param picture The picture to be drawn */ public void drawPicture(@NonNull Picture picture) { picture.endRecording(); int restoreCount = save(); picture.draw(this); restoreToCount(restoreCount); } /** * Draw the picture, stretched to fit into the dst rectangle. */ public void drawPicture(@NonNull Picture picture, @NonNull RectF dst) { save(); translate(dst.left, dst.top); if (picture.getWidth() > 0 && picture.getHeight() > 0) { scale(dst.width() / picture.getWidth(), dst.height() / picture.getHeight()); } drawPicture(picture); restore(); } /** * Draw the picture, stretched to fit into the dst rectangle. */ public void drawPicture(@NonNull Picture picture, @NonNull Rect dst) { save(); translate(dst.left, dst.top); if (picture.getWidth() > 0 && picture.getHeight() > 0) { scale((float) dst.width() / picture.getWidth(), (float) dst.height() / picture.getHeight()); } drawPicture(picture); restore(); } public enum VertexMode { TRIANGLES(0), TRIANGLE_STRIP(1), TRIANGLE_FAN(2); VertexMode(int nativeInt) { this.nativeInt = nativeInt; } /** * @hide */ public final int nativeInt; } /** * Releases the resources associated with this canvas. * * @hide */ public void release() { mNativeCanvasWrapper = 0; if (mFinalizer != null) { mFinalizer.run(); mFinalizer = null; } } /** * Free up as much memory as possible from private caches (e.g. fonts, images) * * @hide */ public static void freeCaches() { nFreeCaches(); } /** * Free up text layout caches * * @hide */ public static void freeTextLayoutCaches() { nFreeTextLayoutCaches(); } private static native void nFreeCaches(); private static native void nFreeTextLayoutCaches(); private static native long nInitRaster(Bitmap bitmap); private static native long nGetNativeFinalizer(); // ---------------- @FastNative ------------------- @FastNative private static native void nSetBitmap(long canvasHandle, Bitmap bitmap); @FastNative private static native boolean nGetClipBounds(long nativeCanvas, Rect bounds); // ---------------- @CriticalNative ------------------- @CriticalNative private static native boolean nIsOpaque(long canvasHandle); @CriticalNative private static native void nSetHighContrastText(long renderer, boolean highContrastText); @CriticalNative private static native int nGetWidth(long canvasHandle); @CriticalNative private static native int nGetHeight(long canvasHandle); @CriticalNative private static native int nSave(long canvasHandle, int saveFlags); @CriticalNative private static native int nSaveLayer(long nativeCanvas, float l, float t, float r, float b, long nativePaint, int layerFlags); @CriticalNative private static native int nSaveLayerAlpha(long nativeCanvas, float l, float t, float r, float b, int alpha, int layerFlags); @CriticalNative private static native boolean nRestore(long canvasHandle); @CriticalNative private static native void nRestoreToCount(long canvasHandle, int saveCount); @CriticalNative private static native int nGetSaveCount(long canvasHandle); @CriticalNative private static native void nTranslate(long canvasHandle, float dx, float dy); @CriticalNative private static native void nScale(long canvasHandle, float sx, float sy); @CriticalNative private static native void nRotate(long canvasHandle, float degrees); @CriticalNative private static native void nSkew(long canvasHandle, float sx, float sy); @CriticalNative private static native void nConcat(long nativeCanvas, long nativeMatrix); @CriticalNative private static native void nSetMatrix(long nativeCanvas, long nativeMatrix); @CriticalNative private static native boolean nClipRect(long nativeCanvas, float left, float top, float right, float bottom, int regionOp); @CriticalNative private static native boolean nClipPath(long nativeCanvas, long nativePath, int regionOp); @CriticalNative private static native void nSetDrawFilter(long nativeCanvas, long nativeFilter); @CriticalNative private static native void nGetMatrix(long nativeCanvas, long nativeMatrix); @CriticalNative private static native boolean nQuickReject(long nativeCanvas, long nativePath); @CriticalNative private static native boolean nQuickReject(long nativeCanvas, float left, float top, float right, float bottom); // ---------------- Draw Methods ------------------- /** *
* Draw the specified arc, which will be scaled to fit inside the specified oval. *
** If the start angle is negative or >= 360, the start angle is treated as start angle modulo * 360. *
** If the sweep angle is >= 360, then the oval is drawn completely. Note that this differs * slightly from SkPath::arcTo, which treats the sweep angle modulo 360. If the sweep angle is * negative, the sweep angle is treated as sweep angle modulo 360 *
** The arc is drawn clockwise. An angle of 0 degrees correspond to the geometric angle of 0 * degrees (3 o'clock on a watch.) *
* * @param oval The bounds of oval used to define the shape and size of the arc * @param startAngle Starting angle (in degrees) where the arc begins * @param sweepAngle Sweep angle (in degrees) measured clockwise * @param useCenter If true, include the center of the oval in the arc, and close it if it is * being stroked. This will draw a wedge * @param paint The paint used to draw the arc */ public void drawArc(@NonNull RectF oval, float startAngle, float sweepAngle, boolean useCenter, @NonNull Paint paint) { super.drawArc(oval, startAngle, sweepAngle, useCenter, paint); } /** ** Draw the specified arc, which will be scaled to fit inside the specified oval. *
** If the start angle is negative or >= 360, the start angle is treated as start angle modulo * 360. *
** If the sweep angle is >= 360, then the oval is drawn completely. Note that this differs * slightly from SkPath::arcTo, which treats the sweep angle modulo 360. If the sweep angle is * negative, the sweep angle is treated as sweep angle modulo 360 *
** The arc is drawn clockwise. An angle of 0 degrees correspond to the geometric angle of 0 * degrees (3 o'clock on a watch.) *
* * @param startAngle Starting angle (in degrees) where the arc begins * @param sweepAngle Sweep angle (in degrees) measured clockwise * @param useCenter If true, include the center of the oval in the arc, and close it if it is * being stroked. This will draw a wedge * @param paint The paint used to draw the arc */ public void drawArc(float left, float top, float right, float bottom, float startAngle, float sweepAngle, boolean useCenter, @NonNull Paint paint) { super.drawArc(left, top, right, bottom, startAngle, sweepAngle, useCenter, paint); } /** * Fill the entire canvas' bitmap (restricted to the current clip) with the specified ARGB * color, using srcover porterduff mode. * * @param a alpha component (0..255) of the color to draw onto the canvas * @param r red component (0..255) of the color to draw onto the canvas * @param g green component (0..255) of the color to draw onto the canvas * @param b blue component (0..255) of the color to draw onto the canvas */ public void drawARGB(int a, int r, int g, int b) { super.drawARGB(a, r, g, b); } /** * Draw the specified bitmap, with its top/left corner at (x,y), using the specified paint, * transformed by the current matrix. ** Note: if the paint contains a maskfilter that generates a mask which extends beyond the * bitmap's original width/height (e.g. BlurMaskFilter), then the bitmap will be drawn as if it * were in a Shader with CLAMP mode. Thus the color outside of the original width/height will be * the edge color replicated. *
* If the bitmap and canvas have different densities, this function will take care of * automatically scaling the bitmap to draw at the same density as the canvas. * * @param bitmap The bitmap to be drawn * @param left The position of the left side of the bitmap being drawn * @param top The position of the top side of the bitmap being drawn * @param paint The paint used to draw the bitmap (may be null) */ public void drawBitmap(@NonNull Bitmap bitmap, float left, float top, @Nullable Paint paint) { super.drawBitmap(bitmap, left, top, paint); } /** * Draw the specified bitmap, scaling/translating automatically to fill the destination * rectangle. If the source rectangle is not null, it specifies the subset of the bitmap to * draw. *
* Note: if the paint contains a maskfilter that generates a mask which extends beyond the * bitmap's original width/height (e.g. BlurMaskFilter), then the bitmap will be drawn as if it * were in a Shader with CLAMP mode. Thus the color outside of the original width/height will be * the edge color replicated. *
* This function ignores the density associated with the bitmap. This is because the * source and destination rectangle coordinate spaces are in their respective densities, so must * already have the appropriate scaling factor applied. * * @param bitmap The bitmap to be drawn * @param src May be null. The subset of the bitmap to be drawn * @param dst The rectangle that the bitmap will be scaled/translated to fit into * @param paint May be null. The paint used to draw the bitmap */ public void drawBitmap(@NonNull Bitmap bitmap, @Nullable Rect src, @NonNull RectF dst, @Nullable Paint paint) { super.drawBitmap(bitmap, src, dst, paint); } /** * Draw the specified bitmap, scaling/translating automatically to fill the destination * rectangle. If the source rectangle is not null, it specifies the subset of the bitmap to * draw. *
* Note: if the paint contains a maskfilter that generates a mask which extends beyond the * bitmap's original width/height (e.g. BlurMaskFilter), then the bitmap will be drawn as if it * were in a Shader with CLAMP mode. Thus the color outside of the original width/height will be * the edge color replicated. *
* This function ignores the density associated with the bitmap. This is because the * source and destination rectangle coordinate spaces are in their respective densities, so must * already have the appropriate scaling factor applied. * * @param bitmap The bitmap to be drawn * @param src May be null. The subset of the bitmap to be drawn * @param dst The rectangle that the bitmap will be scaled/translated to fit into * @param paint May be null. The paint used to draw the bitmap */ public void drawBitmap(@NonNull Bitmap bitmap, @Nullable Rect src, @NonNull Rect dst, @Nullable Paint paint) { super.drawBitmap(bitmap, src, dst, paint); } /** * Treat the specified array of colors as a bitmap, and draw it. This gives the same result as * first creating a bitmap from the array, and then drawing it, but this method avoids * explicitly creating a bitmap object which can be more efficient if the colors are changing * often. * * @param colors Array of colors representing the pixels of the bitmap * @param offset Offset into the array of colors for the first pixel * @param stride The number of colors in the array between rows (must be >= width or <= -width). * @param x The X coordinate for where to draw the bitmap * @param y The Y coordinate for where to draw the bitmap * @param width The width of the bitmap * @param height The height of the bitmap * @param hasAlpha True if the alpha channel of the colors contains valid values. If false, the * alpha byte is ignored (assumed to be 0xFF for every pixel). * @param paint May be null. The paint used to draw the bitmap * @deprecated Usage with a {@link #isHardwareAccelerated() hardware accelerated} canvas * requires an internal copy of color buffer contents every time this method is * called. Using a Bitmap avoids this copy, and allows the application to more * explicitly control the lifetime and copies of pixel data. */ @Deprecated public void drawBitmap(@NonNull int[] colors, int offset, int stride, float x, float y, int width, int height, boolean hasAlpha, @Nullable Paint paint) { super.drawBitmap(colors, offset, stride, x, y, width, height, hasAlpha, paint); } /** * Legacy version of drawBitmap(int[] colors, ...) that took ints for x,y * * @deprecated Usage with a {@link #isHardwareAccelerated() hardware accelerated} canvas * requires an internal copy of color buffer contents every time this method is * called. Using a Bitmap avoids this copy, and allows the application to more * explicitly control the lifetime and copies of pixel data. */ @Deprecated public void drawBitmap(@NonNull int[] colors, int offset, int stride, int x, int y, int width, int height, boolean hasAlpha, @Nullable Paint paint) { super.drawBitmap(colors, offset, stride, x, y, width, height, hasAlpha, paint); } /** * Draw the bitmap using the specified matrix. * * @param bitmap The bitmap to draw * @param matrix The matrix used to transform the bitmap when it is drawn * @param paint May be null. The paint used to draw the bitmap */ public void drawBitmap(@NonNull Bitmap bitmap, @NonNull Matrix matrix, @Nullable Paint paint) { super.drawBitmap(bitmap, matrix, paint); } /** * Draw the bitmap through the mesh, where mesh vertices are evenly distributed across the * bitmap. There are meshWidth+1 vertices across, and meshHeight+1 vertices down. The verts * array is accessed in row-major order, so that the first meshWidth+1 vertices are distributed * across the top of the bitmap from left to right. A more general version of this method is * drawVertices(). * * @param bitmap The bitmap to draw using the mesh * @param meshWidth The number of columns in the mesh. Nothing is drawn if this is 0 * @param meshHeight The number of rows in the mesh. Nothing is drawn if this is 0 * @param verts Array of x,y pairs, specifying where the mesh should be drawn. There must be at * least (meshWidth+1) * (meshHeight+1) * 2 + vertOffset values in the array * @param vertOffset Number of verts elements to skip before drawing * @param colors May be null. Specifies a color at each vertex, which is interpolated across the * cell, and whose values are multiplied by the corresponding bitmap colors. If not * null, there must be at least (meshWidth+1) * (meshHeight+1) + colorOffset values * in the array. * @param colorOffset Number of color elements to skip before drawing * @param paint May be null. The paint used to draw the bitmap */ public void drawBitmapMesh(@NonNull Bitmap bitmap, int meshWidth, int meshHeight, @NonNull float[] verts, int vertOffset, @Nullable int[] colors, int colorOffset, @Nullable Paint paint) { super.drawBitmapMesh(bitmap, meshWidth, meshHeight, verts, vertOffset, colors, colorOffset, paint); } /** * Draw the specified circle using the specified paint. If radius is <= 0, then nothing will be * drawn. The circle will be filled or framed based on the Style in the paint. * * @param cx The x-coordinate of the center of the cirle to be drawn * @param cy The y-coordinate of the center of the cirle to be drawn * @param radius The radius of the cirle to be drawn * @param paint The paint used to draw the circle */ public void drawCircle(float cx, float cy, float radius, @NonNull Paint paint) { super.drawCircle(cx, cy, radius, paint); } /** * Fill the entire canvas' bitmap (restricted to the current clip) with the specified color, * using srcover porterduff mode. * * @param color the color to draw onto the canvas */ public void drawColor(@ColorInt int color) { super.drawColor(color); } /** * Fill the entire canvas' bitmap (restricted to the current clip) with the specified color and * porter-duff xfermode. * * @param color the color to draw with * @param mode the porter-duff mode to apply to the color */ public void drawColor(@ColorInt int color, @NonNull PorterDuff.Mode mode) { super.drawColor(color, mode); } /** * Draw a line segment with the specified start and stop x,y coordinates, using the specified * paint. *
* Note that since a line is always "framed", the Style is ignored in the paint. *
** Degenerate lines (length is 0) will not be drawn. *
* * @param startX The x-coordinate of the start point of the line * @param startY The y-coordinate of the start point of the line * @param paint The paint used to draw the line */ public void drawLine(float startX, float startY, float stopX, float stopY, @NonNull Paint paint) { super.drawLine(startX, startY, stopX, stopY, paint); } /** * Draw a series of lines. Each line is taken from 4 consecutive values in the pts array. Thus * to draw 1 line, the array must contain at least 4 values. This is logically the same as * drawing the array as follows: drawLine(pts[0], pts[1], pts[2], pts[3]) followed by * drawLine(pts[4], pts[5], pts[6], pts[7]) and so on. * * @param pts Array of points to draw [x0 y0 x1 y1 x2 y2 ...] * @param offset Number of values in the array to skip before drawing. * @param count The number of values in the array to process, after skipping "offset" of them. * Since each line uses 4 values, the number of "lines" that are drawn is really * (count >> 2). * @param paint The paint used to draw the points */ public void drawLines(@Size(multiple = 4) @NonNull float[] pts, int offset, int count, @NonNull Paint paint) { super.drawLines(pts, offset, count, paint); } public void drawLines(@Size(multiple = 4) @NonNull float[] pts, @NonNull Paint paint) { super.drawLines(pts, paint); } /** * Draw the specified oval using the specified paint. The oval will be filled or framed based on * the Style in the paint. * * @param oval The rectangle bounds of the oval to be drawn */ public void drawOval(@NonNull RectF oval, @NonNull Paint paint) { super.drawOval(oval, paint); } /** * Draw the specified oval using the specified paint. The oval will be filled or framed based on * the Style in the paint. */ public void drawOval(float left, float top, float right, float bottom, @NonNull Paint paint) { super.drawOval(left, top, right, bottom, paint); } /** * Fill the entire canvas' bitmap (restricted to the current clip) with the specified paint. * This is equivalent (but faster) to drawing an infinitely large rectangle with the specified * paint. * * @param paint The paint used to draw onto the canvas */ public void drawPaint(@NonNull Paint paint) { super.drawPaint(paint); } /** * Draws the specified bitmap as an N-patch (most often, a 9-patches.) * * @param patch The ninepatch object to render * @param dst The destination rectangle. * @param paint The paint to draw the bitmap with. may be null * @hide */ public void drawPatch(@NonNull NinePatch patch, @NonNull Rect dst, @Nullable Paint paint) { super.drawPatch(patch, dst, paint); } /** * Draws the specified bitmap as an N-patch (most often, a 9-patches.) * * @param patch The ninepatch object to render * @param dst The destination rectangle. * @param paint The paint to draw the bitmap with. may be null * @hide */ public void drawPatch(@NonNull NinePatch patch, @NonNull RectF dst, @Nullable Paint paint) { super.drawPatch(patch, dst, paint); } /** * Draw the specified path using the specified paint. The path will be filled or framed based on * the Style in the paint. * * @param path The path to be drawn * @param paint The paint used to draw the path */ public void drawPath(@NonNull Path path, @NonNull Paint paint) { super.drawPath(path, paint); } /** * Helper for drawPoints() for drawing a single point. */ public void drawPoint(float x, float y, @NonNull Paint paint) { super.drawPoint(x, y, paint); } /** * Draw a series of points. Each point is centered at the coordinate specified by pts[], and its * diameter is specified by the paint's stroke width (as transformed by the canvas' CTM), with * special treatment for a stroke width of 0, which always draws exactly 1 pixel (or at most 4 * if antialiasing is enabled). The shape of the point is controlled by the paint's Cap type. * The shape is a square, unless the cap type is Round, in which case the shape is a circle. * * @param pts Array of points to draw [x0 y0 x1 y1 x2 y2 ...] * @param offset Number of values to skip before starting to draw. * @param count The number of values to process, after skipping offset of them. Since one point * uses two values, the number of "points" that are drawn is really (count >> 1). * @param paint The paint used to draw the points */ public void drawPoints(@Size(multiple = 2) float[] pts, int offset, int count, @NonNull Paint paint) { super.drawPoints(pts, offset, count, paint); } /** * Helper for drawPoints() that assumes you want to draw the entire array */ public void drawPoints(@Size(multiple = 2) @NonNull float[] pts, @NonNull Paint paint) { super.drawPoints(pts, paint); } /** * Draw the text in the array, with each character's origin specified by the pos array. * * @param text The text to be drawn * @param index The index of the first character to draw * @param count The number of characters to draw, starting from index. * @param pos Array of [x,y] positions, used to position each character * @param paint The paint used for the text (e.g. color, size, style) * @deprecated This method does not support glyph composition and decomposition and should * therefore not be used to render complex scripts. It also doesn't handle * supplementary characters (eg emoji). */ @Deprecated public void drawPosText(@NonNull char[] text, int index, int count, @NonNull @Size(multiple = 2) float[] pos, @NonNull Paint paint) { super.drawPosText(text, index, count, pos, paint); } /** * Draw the text in the array, with each character's origin specified by the pos array. * * @param text The text to be drawn * @param pos Array of [x,y] positions, used to position each character * @param paint The paint used for the text (e.g. color, size, style) * @deprecated This method does not support glyph composition and decomposition and should * therefore not be used to render complex scripts. It also doesn't handle * supplementary characters (eg emoji). */ @Deprecated public void drawPosText(@NonNull String text, @NonNull @Size(multiple = 2) float[] pos, @NonNull Paint paint) { super.drawPosText(text, pos, paint); } /** * Draw the specified Rect using the specified paint. The rectangle will be filled or framed * based on the Style in the paint. * * @param rect The rect to be drawn * @param paint The paint used to draw the rect */ public void drawRect(@NonNull RectF rect, @NonNull Paint paint) { super.drawRect(rect, paint); } /** * Draw the specified Rect using the specified Paint. The rectangle will be filled or framed * based on the Style in the paint. * * @param r The rectangle to be drawn. * @param paint The paint used to draw the rectangle */ public void drawRect(@NonNull Rect r, @NonNull Paint paint) { super.drawRect(r, paint); } /** * Draw the specified Rect using the specified paint. The rectangle will be filled or framed * based on the Style in the paint. * * @param left The left side of the rectangle to be drawn * @param top The top side of the rectangle to be drawn * @param right The right side of the rectangle to be drawn * @param bottom The bottom side of the rectangle to be drawn * @param paint The paint used to draw the rect */ public void drawRect(float left, float top, float right, float bottom, @NonNull Paint paint) { super.drawRect(left, top, right, bottom, paint); } /** * Fill the entire canvas' bitmap (restricted to the current clip) with the specified RGB color, * using srcover porterduff mode. * * @param r red component (0..255) of the color to draw onto the canvas * @param g green component (0..255) of the color to draw onto the canvas * @param b blue component (0..255) of the color to draw onto the canvas */ public void drawRGB(int r, int g, int b) { super.drawRGB(r, g, b); } /** * Draw the specified round-rect using the specified paint. The roundrect will be filled or * framed based on the Style in the paint. * * @param rect The rectangular bounds of the roundRect to be drawn * @param rx The x-radius of the oval used to round the corners * @param ry The y-radius of the oval used to round the corners * @param paint The paint used to draw the roundRect */ public void drawRoundRect(@NonNull RectF rect, float rx, float ry, @NonNull Paint paint) { super.drawRoundRect(rect, rx, ry, paint); } /** * Draw the specified round-rect using the specified paint. The roundrect will be filled or * framed based on the Style in the paint. * * @param rx The x-radius of the oval used to round the corners * @param ry The y-radius of the oval used to round the corners * @param paint The paint used to draw the roundRect */ public void drawRoundRect(float left, float top, float right, float bottom, float rx, float ry, @NonNull Paint paint) { super.drawRoundRect(left, top, right, bottom, rx, ry, paint); } /** * Draw the text, with origin at (x,y), using the specified paint. The origin is interpreted * based on the Align setting in the paint. * * @param text The text to be drawn * @param x The x-coordinate of the origin of the text being drawn * @param y The y-coordinate of the baseline of the text being drawn * @param paint The paint used for the text (e.g. color, size, style) */ public void drawText(@NonNull char[] text, int index, int count, float x, float y, @NonNull Paint paint) { super.drawText(text, index, count, x, y, paint); } /** * Draw the text, with origin at (x,y), using the specified paint. The origin is interpreted * based on the Align setting in the paint. * * @param text The text to be drawn * @param x The x-coordinate of the origin of the text being drawn * @param y The y-coordinate of the baseline of the text being drawn * @param paint The paint used for the text (e.g. color, size, style) */ public void drawText(@NonNull String text, float x, float y, @NonNull Paint paint) { super.drawText(text, x, y, paint); } /** * Draw the text, with origin at (x,y), using the specified paint. The origin is interpreted * based on the Align setting in the paint. * * @param text The text to be drawn * @param start The index of the first character in text to draw * @param end (end - 1) is the index of the last character in text to draw * @param x The x-coordinate of the origin of the text being drawn * @param y The y-coordinate of the baseline of the text being drawn * @param paint The paint used for the text (e.g. color, size, style) */ public void drawText(@NonNull String text, int start, int end, float x, float y, @NonNull Paint paint) { super.drawText(text, start, end, x, y, paint); } /** * Draw the specified range of text, specified by start/end, with its origin at (x,y), in the * specified Paint. The origin is interpreted based on the Align setting in the Paint. * * @param text The text to be drawn * @param start The index of the first character in text to draw * @param end (end - 1) is the index of the last character in text to draw * @param x The x-coordinate of origin for where to draw the text * @param y The y-coordinate of origin for where to draw the text * @param paint The paint used for the text (e.g. color, size, style) */ public void drawText(@NonNull CharSequence text, int start, int end, float x, float y, @NonNull Paint paint) { super.drawText(text, start, end, x, y, paint); } /** * Draw the text, with origin at (x,y), using the specified paint, along the specified path. The * paint's Align setting determins where along the path to start the text. * * @param text The text to be drawn * @param path The path the text should follow for its baseline * @param hOffset The distance along the path to add to the text's starting position * @param vOffset The distance above(-) or below(+) the path to position the text * @param paint The paint used for the text (e.g. color, size, style) */ public void drawTextOnPath(@NonNull char[] text, int index, int count, @NonNull Path path, float hOffset, float vOffset, @NonNull Paint paint) { super.drawTextOnPath(text, index, count, path, hOffset, vOffset, paint); } /** * Draw the text, with origin at (x,y), using the specified paint, along the specified path. The * paint's Align setting determins where along the path to start the text. * * @param text The text to be drawn * @param path The path the text should follow for its baseline * @param hOffset The distance along the path to add to the text's starting position * @param vOffset The distance above(-) or below(+) the path to position the text * @param paint The paint used for the text (e.g. color, size, style) */ public void drawTextOnPath(@NonNull String text, @NonNull Path path, float hOffset, float vOffset, @NonNull Paint paint) { super.drawTextOnPath(text, path, hOffset, vOffset, paint); } /** * Draw a run of text, all in a single direction, with optional context for complex text * shaping. ** See {@link #drawTextRun(CharSequence, int, int, int, int, float, float, boolean, Paint)} for * more details. This method uses a character array rather than CharSequence to represent the * string. Also, to be consistent with the pattern established in {@link #drawText}, in this * method {@code count} and {@code contextCount} are used rather than offsets of the end * position; {@code count = end - start, contextCount = contextEnd - * contextStart}. * * @param text the text to render * @param index the start of the text to render * @param count the count of chars to render * @param contextIndex the start of the context for shaping. Must be no greater than index. * @param contextCount the number of characters in the context for shaping. contexIndex + * contextCount must be no less than index + count. * @param x the x position at which to draw the text * @param y the y position at which to draw the text * @param isRtl whether the run is in RTL direction * @param paint the paint */ public void drawTextRun(@NonNull char[] text, int index, int count, int contextIndex, int contextCount, float x, float y, boolean isRtl, @NonNull Paint paint) { super.drawTextRun(text, index, count, contextIndex, contextCount, x, y, isRtl, paint); } /** * Draw a run of text, all in a single direction, with optional context for complex text * shaping. *
* The run of text includes the characters from {@code start} to {@code end} in the text. In * addition, the range {@code contextStart} to {@code contextEnd} is used as context for the * purpose of complex text shaping, such as Arabic text potentially shaped differently based on * the text next to it. *
* All text outside the range {@code contextStart..contextEnd} is ignored. The text between * {@code start} and {@code end} will be laid out and drawn. *
* The direction of the run is explicitly specified by {@code isRtl}. Thus, this method is * suitable only for runs of a single direction. Alignment of the text is as determined by the * Paint's TextAlign value. Further, {@code 0 <= contextStart <= start <= end <= contextEnd * <= text.length} must hold on entry. *
* Also see {@link android.graphics.Paint#getRunAdvance} for a corresponding method to measure * the text; the advance width of the text drawn matches the value obtained from that method. * * @param text the text to render * @param start the start of the text to render. Data before this position can be used for * shaping context. * @param end the end of the text to render. Data at or after this position can be used for * shaping context. * @param contextStart the index of the start of the shaping context * @param contextEnd the index of the end of the shaping context * @param x the x position at which to draw the text * @param y the y position at which to draw the text * @param isRtl whether the run is in RTL direction * @param paint the paint * @see #drawTextRun(char[], int, int, int, int, float, float, boolean, Paint) */ public void drawTextRun(@NonNull CharSequence text, int start, int end, int contextStart, int contextEnd, float x, float y, boolean isRtl, @NonNull Paint paint) { super.drawTextRun(text, start, end, contextStart, contextEnd, x, y, isRtl, paint); } /** * Draw the array of vertices, interpreted as triangles (based on mode). The verts array is * required, and specifies the x,y pairs for each vertex. If texs is non-null, then it is used * to specify the coordinate in shader coordinates to use at each vertex (the paint must have a * shader in this case). If there is no texs array, but there is a color array, then each color * is interpolated across its corresponding triangle in a gradient. If both texs and colors * arrays are present, then they behave as before, but the resulting color at each pixels is the * result of multiplying the colors from the shader and the color-gradient together. The indices * array is optional, but if it is present, then it is used to specify the index of each * triangle, rather than just walking through the arrays in order. * * @param mode How to interpret the array of vertices * @param vertexCount The number of values in the vertices array (and corresponding texs and * colors arrays if non-null). Each logical vertex is two values (x, y), vertexCount * must be a multiple of 2. * @param verts Array of vertices for the mesh * @param vertOffset Number of values in the verts to skip before drawing. * @param texs May be null. If not null, specifies the coordinates to sample into the current * shader (e.g. bitmap tile or gradient) * @param texOffset Number of values in texs to skip before drawing. * @param colors May be null. If not null, specifies a color for each vertex, to be interpolated * across the triangle. * @param colorOffset Number of values in colors to skip before drawing. * @param indices If not null, array of indices to reference into the vertex (texs, colors) * array. * @param indexCount number of entries in the indices array (if not null). * @param paint Specifies the shader to use if the texs array is non-null. */ public void drawVertices(@NonNull VertexMode mode, int vertexCount, @NonNull float[] verts, int vertOffset, @Nullable float[] texs, int texOffset, @Nullable int[] colors, int colorOffset, @Nullable short[] indices, int indexOffset, int indexCount, @NonNull Paint paint) { super.drawVertices(mode, vertexCount, verts, vertOffset, texs, texOffset, colors, colorOffset, indices, indexOffset, indexCount, paint); } }