/*
* Copyright (C) 2014 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except
* in compliance with the License. You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software distributed under the License
* is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express
* or implied. See the License for the specific language governing permissions and limitations under
* the License.
*/
package android.graphics.drawable;
import android.annotation.NonNull;
import android.annotation.Nullable;
import android.content.res.ColorStateList;
import android.content.res.Resources;
import android.content.res.Resources.Theme;
import android.content.res.TypedArray;
import android.graphics.Bitmap;
import android.graphics.Canvas;
import android.graphics.Color;
import android.graphics.ColorFilter;
import android.graphics.Insets;
import android.graphics.Matrix;
import android.graphics.Paint;
import android.graphics.Path;
import android.graphics.PathMeasure;
import android.graphics.PixelFormat;
import android.graphics.PorterDuffColorFilter;
import android.graphics.Rect;
import android.graphics.PorterDuff.Mode;
import android.util.ArrayMap;
import android.util.AttributeSet;
import android.util.DisplayMetrics;
import android.util.LayoutDirection;
import android.util.Log;
import android.util.MathUtils;
import android.util.PathParser;
import android.util.Xml;
import com.android.internal.R;
import org.xmlpull.v1.XmlPullParser;
import org.xmlpull.v1.XmlPullParserException;
import java.io.IOException;
import java.util.ArrayList;
import java.util.Stack;
/**
* This lets you create a drawable based on an XML vector graphic. It can be
* defined in an XML file with the <code><vector></code> element.
* <p/>
* The vector drawable has the following elements:
* <p/>
* <dt><code><vector></code></dt>
* <dl>
* <dd>Used to define a vector drawable
* <dl>
* <dt><code>android:name</code></dt>
* <dd>Defines the name of this vector drawable.</dd>
* <dt><code>android:width</code></dt>
* <dd>Used to define the intrinsic width of the drawable.
* This support all the dimension units, normally specified with dp.</dd>
* <dt><code>android:height</code></dt>
* <dd>Used to define the intrinsic height the drawable.
* This support all the dimension units, normally specified with dp.</dd>
* <dt><code>android:viewportWidth</code></dt>
* <dd>Used to define the width of the viewport space. Viewport is basically
* the virtual canvas where the paths are drawn on.</dd>
* <dt><code>android:viewportHeight</code></dt>
* <dd>Used to define the height of the viewport space. Viewport is basically
* the virtual canvas where the paths are drawn on.</dd>
* <dt><code>android:tint</code></dt>
* <dd>The color to apply to the drawable as a tint. By default, no tint is applied.</dd>
* <dt><code>android:tintMode</code></dt>
* <dd>The Porter-Duff blending mode for the tint color. The default value is src_in.</dd>
* <dt><code>android:autoMirrored</code></dt>
* <dd>Indicates if the drawable needs to be mirrored when its layout direction is
* RTL (right-to-left).</dd>
* <dt><code>android:alpha</code></dt>
* <dd>The opacity of this drawable.</dd>
* </dl></dd>
* </dl>
*
* <dl>
* <dt><code><group></code></dt>
* <dd>Defines a group of paths or subgroups, plus transformation information.
* The transformations are defined in the same coordinates as the viewport.
* And the transformations are applied in the order of scale, rotate then translate.
* <dl>
* <dt><code>android:name</code></dt>
* <dd>Defines the name of the group.</dd>
* <dt><code>android:rotation</code></dt>
* <dd>The degrees of rotation of the group.</dd>
* <dt><code>android:pivotX</code></dt>
* <dd>The X coordinate of the pivot for the scale and rotation of the group.
* This is defined in the viewport space.</dd>
* <dt><code>android:pivotY</code></dt>
* <dd>The Y coordinate of the pivot for the scale and rotation of the group.
* This is defined in the viewport space.</dd>
* <dt><code>android:scaleX</code></dt>
* <dd>The amount of scale on the X Coordinate.</dd>
* <dt><code>android:scaleY</code></dt>
* <dd>The amount of scale on the Y coordinate.</dd>
* <dt><code>android:translateX</code></dt>
* <dd>The amount of translation on the X coordinate.
* This is defined in the viewport space.</dd>
* <dt><code>android:translateY</code></dt>
* <dd>The amount of translation on the Y coordinate.
* This is defined in the viewport space.</dd>
* </dl></dd>
* </dl>
*
* <dl>
* <dt><code><path></code></dt>
* <dd>Defines paths to be drawn.
* <dl>
* <dt><code>android:name</code></dt>
* <dd>Defines the name of the path.</dd>
* <dt><code>android:pathData</code></dt>
* <dd>Defines path data using exactly same format as "d" attribute
* in the SVG's path data. This is defined in the viewport space.</dd>
* <dt><code>android:fillColor</code></dt>
* <dd>Defines the color to fill the path (none if not present).</dd>
* <dt><code>android:strokeColor</code></dt>
* <dd>Defines the color to draw the path outline (none if not present).</dd>
* <dt><code>android:strokeWidth</code></dt>
* <dd>The width a path stroke.</dd>
* <dt><code>android:strokeAlpha</code></dt>
* <dd>The opacity of a path stroke.</dd>
* <dt><code>android:fillAlpha</code></dt>
* <dd>The opacity to fill the path with.</dd>
* <dt><code>android:trimPathStart</code></dt>
* <dd>The fraction of the path to trim from the start, in the range from 0 to 1.</dd>
* <dt><code>android:trimPathEnd</code></dt>
* <dd>The fraction of the path to trim from the end, in the range from 0 to 1.</dd>
* <dt><code>android:trimPathOffset</code></dt>
* <dd>Shift trim region (allows showed region to include the start and end), in the range
* from 0 to 1.</dd>
* <dt><code>android:strokeLineCap</code></dt>
* <dd>Sets the linecap for a stroked path: butt, round, square.</dd>
* <dt><code>android:strokeLineJoin</code></dt>
* <dd>Sets the lineJoin for a stroked path: miter,round,bevel.</dd>
* <dt><code>android:strokeMiterLimit</code></dt>
* <dd>Sets the Miter limit for a stroked path.</dd>
* </dl></dd>
* </dl>
*
* <dl>
* <dt><code><clip-path></code></dt>
* <dd>Defines path to be the current clip. Note that the clip path only apply to
* the current group and its children.
* <dl>
* <dt><code>android:name</code></dt>
* <dd>Defines the name of the clip path.</dd>
* <dt><code>android:pathData</code></dt>
* <dd>Defines clip path using the same format as "d" attribute
* in the SVG's path data.</dd>
* </dl></dd>
* </dl>
* <li>Here is a simple VectorDrawable in this vectordrawable.xml file.
* <pre>
* <vector xmlns:android="http://schemas.android.com/apk/res/android"
* android:height="64dp"
* android:width="64dp"
* android:viewportHeight="600"
* android:viewportWidth="600" >
* <group
* android:name="rotationGroup"
* android:pivotX="300.0"
* android:pivotY="300.0"
* android:rotation="45.0" >
* <path
* android:name="v"
* android:fillColor="#000000"
* android:pathData="M300,70 l 0,-70 70,70 0,0 -70,70z" />
* </group>
* </vector>
* </pre></li>
*/
public class VectorDrawable extends Drawable {
private static final String LOGTAG = VectorDrawable.class.getSimpleName();
private static final String SHAPE_CLIP_PATH = "clip-path";
private static final String SHAPE_GROUP = "group";
private static final String SHAPE_PATH = "path";
private static final String SHAPE_VECTOR = "vector";
private static final int LINECAP_BUTT = 0;
private static final int LINECAP_ROUND = 1;
private static final int LINECAP_SQUARE = 2;
private static final int LINEJOIN_MITER = 0;
private static final int LINEJOIN_ROUND = 1;
private static final int LINEJOIN_BEVEL = 2;
// Cap the bitmap size, such that it won't hurt the performance too much
// and it won't crash due to a very large scale.
// The drawable will look blurry above this size.
private static final int MAX_CACHED_BITMAP_SIZE = 2048;
private static final boolean DBG_VECTOR_DRAWABLE = false;
private VectorDrawableState mVectorState;
private PorterDuffColorFilter mTintFilter;
private ColorFilter mColorFilter;
private boolean mMutated;
// AnimatedVectorDrawable needs to turn off the cache all the time, otherwise,
// caching the bitmap by default is allowed.
private boolean mAllowCaching = true;
// Given the virtual display setup, the dpi can be different than the inflation's dpi.
// Therefore, we need to scale the values we got from the getDimension*().
private int mDpiScaledWidth = 0;
private int mDpiScaledHeight = 0;
private Insets mDpiScaleInsets = Insets.NONE;
// Temp variable, only for saving "new" operation at the draw() time.
private final float[] mTmpFloats = new float[9];
private final Matrix mTmpMatrix = new Matrix();
private final Rect mTmpBounds = new Rect();
public VectorDrawable() {
this(null, null);
}
private VectorDrawable(@NonNull VectorDrawableState state, @Nullable Resources res) {
if (state == null) {
mVectorState = new VectorDrawableState();
} else {
mVectorState = state;
mTintFilter = updateTintFilter(mTintFilter, state.mTint, state.mTintMode);
}
updateDimensionInfo(res, false);
}
@Override
public Drawable mutate() {
if (!mMutated && super.mutate() == this) {
mVectorState = new VectorDrawableState(mVectorState);
mMutated = true;
}
return this;
}
/**
* @hide
*/
public void clearMutated() {
super.clearMutated();
mMutated = false;
}
Object getTargetByName(String name) {
return mVectorState.mVPathRenderer.mVGTargetsMap.get(name);
}
@Override
public ConstantState getConstantState() {
mVectorState.mChangingConfigurations = getChangingConfigurations();
return mVectorState;
}
@Override
public void draw(Canvas canvas) {
// We will offset the bounds for drawBitmap, so copyBounds() here instead
// of getBounds().
copyBounds(mTmpBounds);
if (mTmpBounds.width() <= 0 || mTmpBounds.height() <= 0) {
// Nothing to draw
return;
}
// Color filters always override tint filters.
final ColorFilter colorFilter = (mColorFilter == null ? mTintFilter : mColorFilter);
// The imageView can scale the canvas in different ways, in order to
// avoid blurry scaling, we have to draw into a bitmap with exact pixel
// size first. This bitmap size is determined by the bounds and the
// canvas scale.
canvas.getMatrix(mTmpMatrix);
mTmpMatrix.getValues(mTmpFloats);
float canvasScaleX = Math.abs(mTmpFloats[Matrix.MSCALE_X]);
float canvasScaleY = Math.abs(mTmpFloats[Matrix.MSCALE_Y]);
int scaledWidth = (int) (mTmpBounds.width() * canvasScaleX);
int scaledHeight = (int) (mTmpBounds.height() * canvasScaleY);
scaledWidth = Math.min(MAX_CACHED_BITMAP_SIZE, scaledWidth);
scaledHeight = Math.min(MAX_CACHED_BITMAP_SIZE, scaledHeight);
if (scaledWidth <= 0 || scaledHeight <= 0) {
return;
}
final int saveCount = canvas.save();
canvas.translate(mTmpBounds.left, mTmpBounds.top);
// Handle RTL mirroring.
final boolean needMirroring = needMirroring();
if (needMirroring) {
canvas.translate(mTmpBounds.width(), 0);
canvas.scale(-1.0f, 1.0f);
}
// At this point, canvas has been translated to the right position.
// And we use this bound for the destination rect for the drawBitmap, so
// we offset to (0, 0);
mTmpBounds.offsetTo(0, 0);
mVectorState.createCachedBitmapIfNeeded(scaledWidth, scaledHeight);
if (!mAllowCaching) {
mVectorState.updateCachedBitmap(scaledWidth, scaledHeight);
} else {
if (!mVectorState.canReuseCache()) {
mVectorState.updateCachedBitmap(scaledWidth, scaledHeight);
mVectorState.updateCacheStates();
}
}
mVectorState.drawCachedBitmapWithRootAlpha(canvas, colorFilter, mTmpBounds);
canvas.restoreToCount(saveCount);
}
@Override
public int getAlpha() {
return mVectorState.mVPathRenderer.getRootAlpha();
}
@Override
public void setAlpha(int alpha) {
if (mVectorState.mVPathRenderer.getRootAlpha() != alpha) {
mVectorState.mVPathRenderer.setRootAlpha(alpha);
invalidateSelf();
}
}
@Override
public void setColorFilter(ColorFilter colorFilter) {
mColorFilter = colorFilter;
invalidateSelf();
}
@Override
public ColorFilter getColorFilter() {
return mColorFilter;
}
@Override
public void setTintList(ColorStateList tint) {
final VectorDrawableState state = mVectorState;
if (state.mTint != tint) {
state.mTint = tint;
mTintFilter = updateTintFilter(mTintFilter, tint, state.mTintMode);
invalidateSelf();
}
}
@Override
public void setTintMode(Mode tintMode) {
final VectorDrawableState state = mVectorState;
if (state.mTintMode != tintMode) {
state.mTintMode = tintMode;
mTintFilter = updateTintFilter(mTintFilter, state.mTint, tintMode);
invalidateSelf();
}
}
@Override
public boolean isStateful() {
return super.isStateful() || (mVectorState != null && mVectorState.mTint != null
&& mVectorState.mTint.isStateful());
}
@Override
protected boolean onStateChange(int[] stateSet) {
final VectorDrawableState state = mVectorState;
if (state.mTint != null && state.mTintMode != null) {
mTintFilter = updateTintFilter(mTintFilter, state.mTint, state.mTintMode);
invalidateSelf();
return true;
}
return false;
}
@Override
public int getOpacity() {
return PixelFormat.TRANSLUCENT;
}
@Override
public int getIntrinsicWidth() {
return mDpiScaledWidth;
}
@Override
public int getIntrinsicHeight() {
return mDpiScaledHeight;
}
/** @hide */
@Override
public Insets getOpticalInsets() {
return mDpiScaleInsets;
}
/*
* Update the VectorDrawable dimension since the res can be in different Dpi now.
* Basically, when a new instance is created or getDimension() is called, we should update
* the current VectorDrawable's dimension information.
* Only after updateStateFromTypedArray() is called, we should called this and update the
* constant state's dpi info, i.e. updateConstantStateDensity == true.
*/
void updateDimensionInfo(@Nullable Resources res, boolean updateConstantStateDensity) {
if (res != null) {
final int densityDpi = res.getDisplayMetrics().densityDpi;
final int targetDensity = densityDpi == 0 ? DisplayMetrics.DENSITY_DEFAULT : densityDpi;
if (updateConstantStateDensity) {
mVectorState.mVPathRenderer.mTargetDensity = targetDensity;
} else {
final int constantStateDensity = mVectorState.mVPathRenderer.mTargetDensity;
if (targetDensity != constantStateDensity && constantStateDensity != 0) {
mDpiScaledWidth = Bitmap.scaleFromDensity(
(int) mVectorState.mVPathRenderer.mBaseWidth, constantStateDensity,
targetDensity);
mDpiScaledHeight = Bitmap.scaleFromDensity(
(int) mVectorState.mVPathRenderer.mBaseHeight,constantStateDensity,
targetDensity);
final int left = Bitmap.scaleFromDensity(
mVectorState.mVPathRenderer.mOpticalInsets.left, constantStateDensity,
targetDensity);
final int right = Bitmap.scaleFromDensity(
mVectorState.mVPathRenderer.mOpticalInsets.right, constantStateDensity,
targetDensity);
final int top = Bitmap.scaleFromDensity(
mVectorState.mVPathRenderer.mOpticalInsets.top, constantStateDensity,
targetDensity);
final int bottom = Bitmap.scaleFromDensity(
mVectorState.mVPathRenderer.mOpticalInsets.bottom, constantStateDensity,
targetDensity);
mDpiScaleInsets = Insets.of(left, top, right, bottom);
return;
}
}
}
// For all the other cases, like either res is null, constant state is not initialized or
// target density is the same as the constant state, we will just use the constant state
// dimensions.
mDpiScaledWidth = (int) mVectorState.mVPathRenderer.mBaseWidth;
mDpiScaledHeight = (int) mVectorState.mVPathRenderer.mBaseHeight;
mDpiScaleInsets = mVectorState.mVPathRenderer.mOpticalInsets;
}
@Override
public boolean canApplyTheme() {
return (mVectorState != null && mVectorState.canApplyTheme()) || super.canApplyTheme();
}
@Override
public void applyTheme(Theme t) {
super.applyTheme(t);
final VectorDrawableState state = mVectorState;
if (state == null) {
return;
}
if (state.mThemeAttrs != null) {
final TypedArray a = t.resolveAttributes(
state.mThemeAttrs, R.styleable.VectorDrawable);
try {
state.mCacheDirty = true;
updateStateFromTypedArray(a);
updateDimensionInfo(t.getResources(), true /* update constant state */);
} catch (XmlPullParserException e) {
throw new RuntimeException(e);
} finally {
a.recycle();
}
}
// Apply theme to contained color state list.
if (state.mTint != null && state.mTint.canApplyTheme()) {
state.mTint = state.mTint.obtainForTheme(t);
}
final VPathRenderer path = state.mVPathRenderer;
if (path != null && path.canApplyTheme()) {
path.applyTheme(t);
}
// Update local state.
mTintFilter = updateTintFilter(mTintFilter, state.mTint, state.mTintMode);
}
/**
* The size of a pixel when scaled from the intrinsic dimension to the viewport dimension.
* This is used to calculate the path animation accuracy.
*
* @hide
*/
public float getPixelSize() {
if (mVectorState == null || mVectorState.mVPathRenderer == null ||
mVectorState.mVPathRenderer.mBaseWidth == 0 ||
mVectorState.mVPathRenderer.mBaseHeight == 0 ||
mVectorState.mVPathRenderer.mViewportHeight == 0 ||
mVectorState.mVPathRenderer.mViewportWidth == 0) {
return 1; // fall back to 1:1 pixel mapping.
}
float intrinsicWidth = mVectorState.mVPathRenderer.mBaseWidth;
float intrinsicHeight = mVectorState.mVPathRenderer.mBaseHeight;
float viewportWidth = mVectorState.mVPathRenderer.mViewportWidth;
float viewportHeight = mVectorState.mVPathRenderer.mViewportHeight;
float scaleX = viewportWidth / intrinsicWidth;
float scaleY = viewportHeight / intrinsicHeight;
return Math.min(scaleX, scaleY);
}
/** @hide */
public static VectorDrawable create(Resources resources, int rid) {
try {
final XmlPullParser parser = resources.getXml(rid);
final AttributeSet attrs = Xml.asAttributeSet(parser);
int type;
while ((type=parser.next()) != XmlPullParser.START_TAG &&
type != XmlPullParser.END_DOCUMENT) {
// Empty loop
}
if (type != XmlPullParser.START_TAG) {
throw new XmlPullParserException("No start tag found");
}
final VectorDrawable drawable = new VectorDrawable();
drawable.inflate(resources, parser, attrs);
return drawable;
} catch (XmlPullParserException e) {
Log.e(LOGTAG, "parser error", e);
} catch (IOException e) {
Log.e(LOGTAG, "parser error", e);
}
return null;
}
private static int applyAlpha(int color, float alpha) {
int alphaBytes = Color.alpha(color);
color &= 0x00FFFFFF;
color |= ((int) (alphaBytes * alpha)) << 24;
return color;
}
@Override
public void inflate(Resources res, XmlPullParser parser, AttributeSet attrs, Theme theme)
throws XmlPullParserException, IOException {
final VectorDrawableState state = mVectorState;
final VPathRenderer pathRenderer = new VPathRenderer();
state.mVPathRenderer = pathRenderer;
final TypedArray a = obtainAttributes(res, theme, attrs, R.styleable.VectorDrawable);
updateStateFromTypedArray(a);
a.recycle();
state.mCacheDirty = true;
inflateInternal(res, parser, attrs, theme);
mTintFilter = updateTintFilter(mTintFilter, state.mTint, state.mTintMode);
updateDimensionInfo(res, true /* update constant state */);
}
private void updateStateFromTypedArray(TypedArray a) throws XmlPullParserException {
final VectorDrawableState state = mVectorState;
final VPathRenderer pathRenderer = state.mVPathRenderer;
// Account for any configuration changes.
state.mChangingConfigurations |= a.getChangingConfigurations();
// Extract the theme attributes, if any.
state.mThemeAttrs = a.extractThemeAttrs();
final int tintMode = a.getInt(R.styleable.VectorDrawable_tintMode, -1);
if (tintMode != -1) {
state.mTintMode = Drawable.parseTintMode(tintMode, Mode.SRC_IN);
}
final ColorStateList tint = a.getColorStateList(R.styleable.VectorDrawable_tint);
if (tint != null) {
state.mTint = tint;
}
state.mAutoMirrored = a.getBoolean(
R.styleable.VectorDrawable_autoMirrored, state.mAutoMirrored);
pathRenderer.mViewportWidth = a.getFloat(
R.styleable.VectorDrawable_viewportWidth, pathRenderer.mViewportWidth);
pathRenderer.mViewportHeight = a.getFloat(
R.styleable.VectorDrawable_viewportHeight, pathRenderer.mViewportHeight);
if (pathRenderer.mViewportWidth <= 0) {
throw new XmlPullParserException(a.getPositionDescription() +
"<vector> tag requires viewportWidth > 0");
} else if (pathRenderer.mViewportHeight <= 0) {
throw new XmlPullParserException(a.getPositionDescription() +
"<vector> tag requires viewportHeight > 0");
}
pathRenderer.mBaseWidth = a.getDimension(
R.styleable.VectorDrawable_width, pathRenderer.mBaseWidth);
pathRenderer.mBaseHeight = a.getDimension(
R.styleable.VectorDrawable_height, pathRenderer.mBaseHeight);
if (pathRenderer.mBaseWidth <= 0) {
throw new XmlPullParserException(a.getPositionDescription() +
"<vector> tag requires width > 0");
} else if (pathRenderer.mBaseHeight <= 0) {
throw new XmlPullParserException(a.getPositionDescription() +
"<vector> tag requires height > 0");
}
final int insetLeft = a.getDimensionPixelSize(
R.styleable.VectorDrawable_opticalInsetLeft, pathRenderer.mOpticalInsets.left);
final int insetTop = a.getDimensionPixelSize(
R.styleable.VectorDrawable_opticalInsetTop, pathRenderer.mOpticalInsets.top);
final int insetRight = a.getDimensionPixelSize(
R.styleable.VectorDrawable_opticalInsetRight, pathRenderer.mOpticalInsets.right);
final int insetBottom = a.getDimensionPixelSize(
R.styleable.VectorDrawable_opticalInsetBottom, pathRenderer.mOpticalInsets.bottom);
pathRenderer.mOpticalInsets = Insets.of(insetLeft, insetTop, insetRight, insetBottom);
final float alphaInFloat = a.getFloat(R.styleable.VectorDrawable_alpha,
pathRenderer.getAlpha());
pathRenderer.setAlpha(alphaInFloat);
final String name = a.getString(R.styleable.VectorDrawable_name);
if (name != null) {
pathRenderer.mRootName = name;
pathRenderer.mVGTargetsMap.put(name, pathRenderer);
}
}
private void inflateInternal(Resources res, XmlPullParser parser, AttributeSet attrs,
Theme theme) throws XmlPullParserException, IOException {
final VectorDrawableState state = mVectorState;
final VPathRenderer pathRenderer = state.mVPathRenderer;
boolean noPathTag = true;
// Use a stack to help to build the group tree.
// The top of the stack is always the current group.
final Stack<VGroup> groupStack = new Stack<VGroup>();
groupStack.push(pathRenderer.mRootGroup);
int eventType = parser.getEventType();
while (eventType != XmlPullParser.END_DOCUMENT) {
if (eventType == XmlPullParser.START_TAG) {
final String tagName = parser.getName();
final VGroup currentGroup = groupStack.peek();
if (SHAPE_PATH.equals(tagName)) {
final VFullPath path = new VFullPath();
path.inflate(res, attrs, theme);
currentGroup.mChildren.add(path);
if (path.getPathName() != null) {
pathRenderer.mVGTargetsMap.put(path.getPathName(), path);
}
noPathTag = false;
state.mChangingConfigurations |= path.mChangingConfigurations;
} else if (SHAPE_CLIP_PATH.equals(tagName)) {
final VClipPath path = new VClipPath();
path.inflate(res, attrs, theme);
currentGroup.mChildren.add(path);
if (path.getPathName() != null) {
pathRenderer.mVGTargetsMap.put(path.getPathName(), path);
}
state.mChangingConfigurations |= path.mChangingConfigurations;
} else if (SHAPE_GROUP.equals(tagName)) {
VGroup newChildGroup = new VGroup();
newChildGroup.inflate(res, attrs, theme);
currentGroup.mChildren.add(newChildGroup);
groupStack.push(newChildGroup);
if (newChildGroup.getGroupName() != null) {
pathRenderer.mVGTargetsMap.put(newChildGroup.getGroupName(),
newChildGroup);
}
state.mChangingConfigurations |= newChildGroup.mChangingConfigurations;
}
} else if (eventType == XmlPullParser.END_TAG) {
final String tagName = parser.getName();
if (SHAPE_GROUP.equals(tagName)) {
groupStack.pop();
}
}
eventType = parser.next();
}
// Print the tree out for debug.
if (DBG_VECTOR_DRAWABLE) {
printGroupTree(pathRenderer.mRootGroup, 0);
}
if (noPathTag) {
final StringBuffer tag = new StringBuffer();
if (tag.length() > 0) {
tag.append(" or ");
}
tag.append(SHAPE_PATH);
throw new XmlPullParserException("no " + tag + " defined");
}
}
private void printGroupTree(VGroup currentGroup, int level) {
String indent = "";
for (int i = 0; i < level; i++) {
indent += " ";
}
// Print the current node
Log.v(LOGTAG, indent + "current group is :" + currentGroup.getGroupName()
+ " rotation is " + currentGroup.mRotate);
Log.v(LOGTAG, indent + "matrix is :" + currentGroup.getLocalMatrix().toString());
// Then print all the children groups
for (int i = 0; i < currentGroup.mChildren.size(); i++) {
Object child = currentGroup.mChildren.get(i);
if (child instanceof VGroup) {
printGroupTree((VGroup) child, level + 1);
}
}
}
@Override
public int getChangingConfigurations() {
return super.getChangingConfigurations() | mVectorState.getChangingConfigurations();
}
void setAllowCaching(boolean allowCaching) {
mAllowCaching = allowCaching;
}
private boolean needMirroring() {
return isAutoMirrored() && getLayoutDirection() == LayoutDirection.RTL;
}
@Override
public void setAutoMirrored(boolean mirrored) {
if (mVectorState.mAutoMirrored != mirrored) {
mVectorState.mAutoMirrored = mirrored;
invalidateSelf();
}
}
@Override
public boolean isAutoMirrored() {
return mVectorState.mAutoMirrored;
}
private static class VectorDrawableState extends ConstantState {
int[] mThemeAttrs;
int mChangingConfigurations;
VPathRenderer mVPathRenderer;
ColorStateList mTint = null;
Mode mTintMode = DEFAULT_TINT_MODE;
boolean mAutoMirrored;
Bitmap mCachedBitmap;
int[] mCachedThemeAttrs;
ColorStateList mCachedTint;
Mode mCachedTintMode;
int mCachedRootAlpha;
boolean mCachedAutoMirrored;
boolean mCacheDirty;
/** Temporary paint object used to draw cached bitmaps. */
Paint mTempPaint;
// Deep copy for mutate() or implicitly mutate.
public VectorDrawableState(VectorDrawableState copy) {
if (copy != null) {
mThemeAttrs = copy.mThemeAttrs;
mChangingConfigurations = copy.mChangingConfigurations;
mVPathRenderer = new VPathRenderer(copy.mVPathRenderer);
if (copy.mVPathRenderer.mFillPaint != null) {
mVPathRenderer.mFillPaint = new Paint(copy.mVPathRenderer.mFillPaint);
}
if (copy.mVPathRenderer.mStrokePaint != null) {
mVPathRenderer.mStrokePaint = new Paint(copy.mVPathRenderer.mStrokePaint);
}
mTint = copy.mTint;
mTintMode = copy.mTintMode;
mAutoMirrored = copy.mAutoMirrored;
}
}
public void drawCachedBitmapWithRootAlpha(Canvas canvas, ColorFilter filter,
Rect originalBounds) {
// The bitmap's size is the same as the bounds.
final Paint p = getPaint(filter);
canvas.drawBitmap(mCachedBitmap, null, originalBounds, p);
}
public boolean hasTranslucentRoot() {
return mVPathRenderer.getRootAlpha() < 255;
}
/**
* @return null when there is no need for alpha paint.
*/
public Paint getPaint(ColorFilter filter) {
if (!hasTranslucentRoot() && filter == null) {
return null;
}
if (mTempPaint == null) {
mTempPaint = new Paint();
mTempPaint.setFilterBitmap(true);
}
mTempPaint.setAlpha(mVPathRenderer.getRootAlpha());
mTempPaint.setColorFilter(filter);
return mTempPaint;
}
public void updateCachedBitmap(int width, int height) {
mCachedBitmap.eraseColor(Color.TRANSPARENT);
Canvas tmpCanvas = new Canvas(mCachedBitmap);
mVPathRenderer.draw(tmpCanvas, width, height, null);
}
public void createCachedBitmapIfNeeded(int width, int height) {
if (mCachedBitmap == null || !canReuseBitmap(width, height)) {
mCachedBitmap = Bitmap.createBitmap(width, height,
Bitmap.Config.ARGB_8888);
mCacheDirty = true;
}
}
public boolean canReuseBitmap(int width, int height) {
if (width == mCachedBitmap.getWidth()
&& height == mCachedBitmap.getHeight()) {
return true;
}
return false;
}
public boolean canReuseCache() {
if (!mCacheDirty
&& mCachedThemeAttrs == mThemeAttrs
&& mCachedTint == mTint
&& mCachedTintMode == mTintMode
&& mCachedAutoMirrored == mAutoMirrored
&& mCachedRootAlpha == mVPathRenderer.getRootAlpha()) {
return true;
}
return false;
}
public void updateCacheStates() {
// Use shallow copy here and shallow comparison in canReuseCache(),
// likely hit cache miss more, but practically not much difference.
mCachedThemeAttrs = mThemeAttrs;
mCachedTint = mTint;
mCachedTintMode = mTintMode;
mCachedRootAlpha = mVPathRenderer.getRootAlpha();
mCachedAutoMirrored = mAutoMirrored;
mCacheDirty = false;
}
@Override
public boolean canApplyTheme() {
return mThemeAttrs != null
|| (mVPathRenderer != null && mVPathRenderer.canApplyTheme())
|| (mTint != null && mTint.canApplyTheme())
|| super.canApplyTheme();
}
public VectorDrawableState() {
mVPathRenderer = new VPathRenderer();
}
@Override
public Drawable newDrawable() {
return new VectorDrawable(this, null);
}
@Override
public Drawable newDrawable(Resources res) {
return new VectorDrawable(this, res);
}
@Override
public int getChangingConfigurations() {
return mChangingConfigurations
| (mTint != null ? mTint.getChangingConfigurations() : 0);
}
}
private static class VPathRenderer {
/* Right now the internal data structure is organized as a tree.
* Each node can be a group node, or a path.
* A group node can have groups or paths as children, but a path node has
* no children.
* One example can be:
* Root Group
* / | \
* Group Path Group
* / \ |
* Path Path Path
*
*/
// Variables that only used temporarily inside the draw() call, so there
// is no need for deep copying.
private final Path mPath;
private final Path mRenderPath;
private final Matrix mFinalPathMatrix = new Matrix();
private Paint mStrokePaint;
private Paint mFillPaint;
private PathMeasure mPathMeasure;
/////////////////////////////////////////////////////
// Variables below need to be copied (deep copy if applicable) for mutation.
private int mChangingConfigurations;
private final VGroup mRootGroup;
float mBaseWidth = 0;
float mBaseHeight = 0;
float mViewportWidth = 0;
float mViewportHeight = 0;
Insets mOpticalInsets = Insets.NONE;
int mRootAlpha = 0xFF;
String mRootName = null;
int mTargetDensity = DisplayMetrics.DENSITY_DEFAULT;
final ArrayMap<String, Object> mVGTargetsMap = new ArrayMap<String, Object>();
public VPathRenderer() {
mRootGroup = new VGroup();
mPath = new Path();
mRenderPath = new Path();
}
public void setRootAlpha(int alpha) {
mRootAlpha = alpha;
}
public int getRootAlpha() {
return mRootAlpha;
}
// setAlpha() and getAlpha() are used mostly for animation purpose, since
// Animator like to use alpha from 0 to 1.
public void setAlpha(float alpha) {
setRootAlpha((int) (alpha * 255));
}
@SuppressWarnings("unused")
public float getAlpha() {
return getRootAlpha() / 255.0f;
}
public VPathRenderer(VPathRenderer copy) {
mRootGroup = new VGroup(copy.mRootGroup, mVGTargetsMap);
mPath = new Path(copy.mPath);
mRenderPath = new Path(copy.mRenderPath);
mBaseWidth = copy.mBaseWidth;
mBaseHeight = copy.mBaseHeight;
mViewportWidth = copy.mViewportWidth;
mViewportHeight = copy.mViewportHeight;
mOpticalInsets = copy.mOpticalInsets;
mChangingConfigurations = copy.mChangingConfigurations;
mRootAlpha = copy.mRootAlpha;
mRootName = copy.mRootName;
mTargetDensity = copy.mTargetDensity;
if (copy.mRootName != null) {
mVGTargetsMap.put(copy.mRootName, this);
}
}
public boolean canApplyTheme() {
// If one of the paths can apply theme, then return true;
return recursiveCanApplyTheme(mRootGroup);
}
private boolean recursiveCanApplyTheme(VGroup currentGroup) {
// We can do a tree traverse here, if there is one path return true,
// then we return true for the whole tree.
final ArrayList<Object> children = currentGroup.mChildren;
for (int i = 0; i < children.size(); i++) {
Object child = children.get(i);
if (child instanceof VGroup) {
VGroup childGroup = (VGroup) child;
if (childGroup.canApplyTheme()
|| recursiveCanApplyTheme(childGroup)) {
return true;
}
} else if (child instanceof VPath) {
VPath childPath = (VPath) child;
if (childPath.canApplyTheme()) {
return true;
}
}
}
return false;
}
public void applyTheme(Theme t) {
// Apply theme to every path of the tree.
recursiveApplyTheme(mRootGroup, t);
}
private void recursiveApplyTheme(VGroup currentGroup, Theme t) {
// We can do a tree traverse here, apply theme to all paths which
// can apply theme.
final ArrayList<Object> children = currentGroup.mChildren;
for (int i = 0; i < children.size(); i++) {
Object child = children.get(i);
if (child instanceof VGroup) {
VGroup childGroup = (VGroup) child;
if (childGroup.canApplyTheme()) {
childGroup.applyTheme(t);
}
recursiveApplyTheme(childGroup, t);
} else if (child instanceof VPath) {
VPath childPath = (VPath) child;
if (childPath.canApplyTheme()) {
childPath.applyTheme(t);
}
}
}
}
private void drawGroupTree(VGroup currentGroup, Matrix currentMatrix,
Canvas canvas, int w, int h, ColorFilter filter) {
// Calculate current group's matrix by preConcat the parent's and
// and the current one on the top of the stack.
// Basically the Mfinal = Mviewport * M0 * M1 * M2;
// Mi the local matrix at level i of the group tree.
currentGroup.mStackedMatrix.set(currentMatrix);
currentGroup.mStackedMatrix.preConcat(currentGroup.mLocalMatrix);
// Save the current clip information, which is local to this group.
canvas.save();
// Draw the group tree in the same order as the XML file.
for (int i = 0; i < currentGroup.mChildren.size(); i++) {
Object child = currentGroup.mChildren.get(i);
if (child instanceof VGroup) {
VGroup childGroup = (VGroup) child;
drawGroupTree(childGroup, currentGroup.mStackedMatrix,
canvas, w, h, filter);
} else if (child instanceof VPath) {
VPath childPath = (VPath) child;
drawPath(currentGroup, childPath, canvas, w, h, filter);
}
}
canvas.restore();
}
public void draw(Canvas canvas, int w, int h, ColorFilter filter) {
// Travese the tree in pre-order to draw.
drawGroupTree(mRootGroup, Matrix.IDENTITY_MATRIX, canvas, w, h, filter);
}
private void drawPath(VGroup vGroup, VPath vPath, Canvas canvas, int w, int h,
ColorFilter filter) {
final float scaleX = w / mViewportWidth;
final float scaleY = h / mViewportHeight;
final float minScale = Math.min(scaleX, scaleY);
final Matrix groupStackedMatrix = vGroup.mStackedMatrix;
mFinalPathMatrix.set(groupStackedMatrix);
mFinalPathMatrix.postScale(scaleX, scaleY);
final float matrixScale = getMatrixScale(groupStackedMatrix);
if (matrixScale == 0) {
// When either x or y is scaled to 0, we don't need to draw anything.
return;
}
vPath.toPath(mPath);
final Path path = mPath;
mRenderPath.reset();
if (vPath.isClipPath()) {
mRenderPath.addPath(path, mFinalPathMatrix);
canvas.clipPath(mRenderPath);
} else {
VFullPath fullPath = (VFullPath) vPath;
if (fullPath.mTrimPathStart != 0.0f || fullPath.mTrimPathEnd != 1.0f) {
float start = (fullPath.mTrimPathStart + fullPath.mTrimPathOffset) % 1.0f;
float end = (fullPath.mTrimPathEnd + fullPath.mTrimPathOffset) % 1.0f;
if (mPathMeasure == null) {
mPathMeasure = new PathMeasure();
}
mPathMeasure.setPath(mPath, false);
float len = mPathMeasure.getLength();
start = start * len;
end = end * len;
path.reset();
if (start > end) {
mPathMeasure.getSegment(start, len, path, true);
mPathMeasure.getSegment(0f, end, path, true);
} else {
mPathMeasure.getSegment(start, end, path, true);
}
path.rLineTo(0, 0); // fix bug in measure
}
mRenderPath.addPath(path, mFinalPathMatrix);
if (fullPath.mFillColor != Color.TRANSPARENT) {
if (mFillPaint == null) {
mFillPaint = new Paint();
mFillPaint.setStyle(Paint.Style.FILL);
mFillPaint.setAntiAlias(true);
}
final Paint fillPaint = mFillPaint;
fillPaint.setColor(applyAlpha(fullPath.mFillColor, fullPath.mFillAlpha));
fillPaint.setColorFilter(filter);
canvas.drawPath(mRenderPath, fillPaint);
}
if (fullPath.mStrokeColor != Color.TRANSPARENT) {
if (mStrokePaint == null) {
mStrokePaint = new Paint();
mStrokePaint.setStyle(Paint.Style.STROKE);
mStrokePaint.setAntiAlias(true);
}
final Paint strokePaint = mStrokePaint;
if (fullPath.mStrokeLineJoin != null) {
strokePaint.setStrokeJoin(fullPath.mStrokeLineJoin);
}
if (fullPath.mStrokeLineCap != null) {
strokePaint.setStrokeCap(fullPath.mStrokeLineCap);
}
strokePaint.setStrokeMiter(fullPath.mStrokeMiterlimit);
strokePaint.setColor(applyAlpha(fullPath.mStrokeColor, fullPath.mStrokeAlpha));
strokePaint.setColorFilter(filter);
final float finalStrokeScale = minScale * matrixScale;
strokePaint.setStrokeWidth(fullPath.mStrokeWidth * finalStrokeScale);
canvas.drawPath(mRenderPath, strokePaint);
}
}
}
private float getMatrixScale(Matrix groupStackedMatrix) {
// Given unit vectors A = (0, 1) and B = (1, 0).
// After matrix mapping, we got A' and B'. Let theta = the angel b/t A' and B'.
// Therefore, the final scale we want is min(|A'| * sin(theta), |B'| * sin(theta)),
// which is (|A'| * |B'| * sin(theta)) / max (|A'|, |B'|);
// If max (|A'|, |B'|) = 0, that means either x or y has a scale of 0.
//
// For non-skew case, which is most of the cases, matrix scale is computing exactly the
// scale on x and y axis, and take the minimal of these two.
// For skew case, an unit square will mapped to a parallelogram. And this function will
// return the minimal height of the 2 bases.
float[] unitVectors = new float[] {0, 1, 1, 0};
groupStackedMatrix.mapVectors(unitVectors);
float scaleX = MathUtils.mag(unitVectors[0], unitVectors[1]);
float scaleY = MathUtils.mag(unitVectors[2], unitVectors[3]);
float crossProduct = MathUtils.cross(unitVectors[0], unitVectors[1],
unitVectors[2], unitVectors[3]);
float maxScale = MathUtils.max(scaleX, scaleY);
float matrixScale = 0;
if (maxScale > 0) {
matrixScale = MathUtils.abs(crossProduct) / maxScale;
}
if (DBG_VECTOR_DRAWABLE) {
Log.d(LOGTAG, "Scale x " + scaleX + " y " + scaleY + " final " + matrixScale);
}
return matrixScale;
}
}
private static class VGroup {
// mStackedMatrix is only used temporarily when drawing, it combines all
// the parents' local matrices with the current one.
private final Matrix mStackedMatrix = new Matrix();
/////////////////////////////////////////////////////
// Variables below need to be copied (deep copy if applicable) for mutation.
final ArrayList<Object> mChildren = new ArrayList<Object>();
private float mRotate = 0;
private float mPivotX = 0;
private float mPivotY = 0;
private float mScaleX = 1;
private float mScaleY = 1;
private float mTranslateX = 0;
private float mTranslateY = 0;
// mLocalMatrix is updated based on the update of transformation information,
// either parsed from the XML or by animation.
private final Matrix mLocalMatrix = new Matrix();
private int mChangingConfigurations;
private int[] mThemeAttrs;
private String mGroupName = null;
public VGroup(VGroup copy, ArrayMap<String, Object> targetsMap) {
mRotate = copy.mRotate;
mPivotX = copy.mPivotX;
mPivotY = copy.mPivotY;
mScaleX = copy.mScaleX;
mScaleY = copy.mScaleY;
mTranslateX = copy.mTranslateX;
mTranslateY = copy.mTranslateY;
mThemeAttrs = copy.mThemeAttrs;
mGroupName = copy.mGroupName;
mChangingConfigurations = copy.mChangingConfigurations;
if (mGroupName != null) {
targetsMap.put(mGroupName, this);
}
mLocalMatrix.set(copy.mLocalMatrix);
final ArrayList<Object> children = copy.mChildren;
for (int i = 0; i < children.size(); i++) {
Object copyChild = children.get(i);
if (copyChild instanceof VGroup) {
VGroup copyGroup = (VGroup) copyChild;
mChildren.add(new VGroup(copyGroup, targetsMap));
} else {
VPath newPath = null;
if (copyChild instanceof VFullPath) {
newPath = new VFullPath((VFullPath) copyChild);
} else if (copyChild instanceof VClipPath) {
newPath = new VClipPath((VClipPath) copyChild);
} else {
throw new IllegalStateException("Unknown object in the tree!");
}
mChildren.add(newPath);
if (newPath.mPathName != null) {
targetsMap.put(newPath.mPathName, newPath);
}
}
}
}
public VGroup() {
}
public String getGroupName() {
return mGroupName;
}
public Matrix getLocalMatrix() {
return mLocalMatrix;
}
public void inflate(Resources res, AttributeSet attrs, Theme theme) {
final TypedArray a = obtainAttributes(res, theme, attrs,
R.styleable.VectorDrawableGroup);
updateStateFromTypedArray(a);
a.recycle();
}
private void updateStateFromTypedArray(TypedArray a) {
// Account for any configuration changes.
mChangingConfigurations |= a.getChangingConfigurations();
// Extract the theme attributes, if any.
mThemeAttrs = a.extractThemeAttrs();
mRotate = a.getFloat(R.styleable.VectorDrawableGroup_rotation, mRotate);
mPivotX = a.getFloat(R.styleable.VectorDrawableGroup_pivotX, mPivotX);
mPivotY = a.getFloat(R.styleable.VectorDrawableGroup_pivotY, mPivotY);
mScaleX = a.getFloat(R.styleable.VectorDrawableGroup_scaleX, mScaleX);
mScaleY = a.getFloat(R.styleable.VectorDrawableGroup_scaleY, mScaleY);
mTranslateX = a.getFloat(R.styleable.VectorDrawableGroup_translateX, mTranslateX);
mTranslateY = a.getFloat(R.styleable.VectorDrawableGroup_translateY, mTranslateY);
final String groupName = a.getString(R.styleable.VectorDrawableGroup_name);
if (groupName != null) {
mGroupName = groupName;
}
updateLocalMatrix();
}
public boolean canApplyTheme() {
return mThemeAttrs != null;
}
public void applyTheme(Theme t) {
if (mThemeAttrs == null) {
return;
}
final TypedArray a = t.resolveAttributes(mThemeAttrs, R.styleable.VectorDrawableGroup);
updateStateFromTypedArray(a);
a.recycle();
}
private void updateLocalMatrix() {
// The order we apply is the same as the
// RenderNode.cpp::applyViewPropertyTransforms().
mLocalMatrix.reset();
mLocalMatrix.postTranslate(-mPivotX, -mPivotY);
mLocalMatrix.postScale(mScaleX, mScaleY);
mLocalMatrix.postRotate(mRotate, 0, 0);
mLocalMatrix.postTranslate(mTranslateX + mPivotX, mTranslateY + mPivotY);
}
/* Setters and Getters, used by animator from AnimatedVectorDrawable. */
@SuppressWarnings("unused")
public float getRotation() {
return mRotate;
}
@SuppressWarnings("unused")
public void setRotation(float rotation) {
if (rotation != mRotate) {
mRotate = rotation;
updateLocalMatrix();
}
}
@SuppressWarnings("unused")
public float getPivotX() {
return mPivotX;
}
@SuppressWarnings("unused")
public void setPivotX(float pivotX) {
if (pivotX != mPivotX) {
mPivotX = pivotX;
updateLocalMatrix();
}
}
@SuppressWarnings("unused")
public float getPivotY() {
return mPivotY;
}
@SuppressWarnings("unused")
public void setPivotY(float pivotY) {
if (pivotY != mPivotY) {
mPivotY = pivotY;
updateLocalMatrix();
}
}
@SuppressWarnings("unused")
public float getScaleX() {
return mScaleX;
}
@SuppressWarnings("unused")
public void setScaleX(float scaleX) {
if (scaleX != mScaleX) {
mScaleX = scaleX;
updateLocalMatrix();
}
}
@SuppressWarnings("unused")
public float getScaleY() {
return mScaleY;
}
@SuppressWarnings("unused")
public void setScaleY(float scaleY) {
if (scaleY != mScaleY) {
mScaleY = scaleY;
updateLocalMatrix();
}
}
@SuppressWarnings("unused")
public float getTranslateX() {
return mTranslateX;
}
@SuppressWarnings("unused")
public void setTranslateX(float translateX) {
if (translateX != mTranslateX) {
mTranslateX = translateX;
updateLocalMatrix();
}
}
@SuppressWarnings("unused")
public float getTranslateY() {
return mTranslateY;
}
@SuppressWarnings("unused")
public void setTranslateY(float translateY) {
if (translateY != mTranslateY) {
mTranslateY = translateY;
updateLocalMatrix();
}
}
}
/**
* Common Path information for clip path and normal path.
*/
private static class VPath {
protected PathParser.PathDataNode[] mNodes = null;
String mPathName;
int mChangingConfigurations;
public VPath() {
// Empty constructor.
}
public VPath(VPath copy) {
mPathName = copy.mPathName;
mChangingConfigurations = copy.mChangingConfigurations;
mNodes = PathParser.deepCopyNodes(copy.mNodes);
}
public void toPath(Path path) {
path.reset();
if (mNodes != null) {
PathParser.PathDataNode.nodesToPath(mNodes, path);
}
}
public String getPathName() {
return mPathName;
}
public boolean canApplyTheme() {
return false;
}
public void applyTheme(Theme t) {
}
public boolean isClipPath() {
return false;
}
/* Setters and Getters, used by animator from AnimatedVectorDrawable. */
@SuppressWarnings("unused")
public PathParser.PathDataNode[] getPathData() {
return mNodes;
}
@SuppressWarnings("unused")
public void setPathData(PathParser.PathDataNode[] nodes) {
if (!PathParser.canMorph(mNodes, nodes)) {
// This should not happen in the middle of animation.
mNodes = PathParser.deepCopyNodes(nodes);
} else {
PathParser.updateNodes(mNodes, nodes);
}
}
}
/**
* Clip path, which only has name and pathData.
*/
private static class VClipPath extends VPath {
public VClipPath() {
// Empty constructor.
}
public VClipPath(VClipPath copy) {
super(copy);
}
public void inflate(Resources r, AttributeSet attrs, Theme theme) {
final TypedArray a = obtainAttributes(r, theme, attrs,
R.styleable.VectorDrawableClipPath);
updateStateFromTypedArray(a);
a.recycle();
}
private void updateStateFromTypedArray(TypedArray a) {
// Account for any configuration changes.
mChangingConfigurations |= a.getChangingConfigurations();
final String pathName = a.getString(R.styleable.VectorDrawableClipPath_name);
if (pathName != null) {
mPathName = pathName;
}
final String pathData = a.getString(R.styleable.VectorDrawableClipPath_pathData);
if (pathData != null) {
mNodes = PathParser.createNodesFromPathData(pathData);
}
}
@Override
public boolean isClipPath() {
return true;
}
}
/**
* Normal path, which contains all the fill / paint information.
*/
private static class VFullPath extends VPath {
/////////////////////////////////////////////////////
// Variables below need to be copied (deep copy if applicable) for mutation.
private int[] mThemeAttrs;
int mStrokeColor = Color.TRANSPARENT;
float mStrokeWidth = 0;
int mFillColor = Color.TRANSPARENT;
float mStrokeAlpha = 1.0f;
int mFillRule;
float mFillAlpha = 1.0f;
float mTrimPathStart = 0;
float mTrimPathEnd = 1;
float mTrimPathOffset = 0;
Paint.Cap mStrokeLineCap = Paint.Cap.BUTT;
Paint.Join mStrokeLineJoin = Paint.Join.MITER;
float mStrokeMiterlimit = 4;
public VFullPath() {
// Empty constructor.
}
public VFullPath(VFullPath copy) {
super(copy);
mThemeAttrs = copy.mThemeAttrs;
mStrokeColor = copy.mStrokeColor;
mStrokeWidth = copy.mStrokeWidth;
mStrokeAlpha = copy.mStrokeAlpha;
mFillColor = copy.mFillColor;
mFillRule = copy.mFillRule;
mFillAlpha = copy.mFillAlpha;
mTrimPathStart = copy.mTrimPathStart;
mTrimPathEnd = copy.mTrimPathEnd;
mTrimPathOffset = copy.mTrimPathOffset;
mStrokeLineCap = copy.mStrokeLineCap;
mStrokeLineJoin = copy.mStrokeLineJoin;
mStrokeMiterlimit = copy.mStrokeMiterlimit;
}
private Paint.Cap getStrokeLineCap(int id, Paint.Cap defValue) {
switch (id) {
case LINECAP_BUTT:
return Paint.Cap.BUTT;
case LINECAP_ROUND:
return Paint.Cap.ROUND;
case LINECAP_SQUARE:
return Paint.Cap.SQUARE;
default:
return defValue;
}
}
private Paint.Join getStrokeLineJoin(int id, Paint.Join defValue) {
switch (id) {
case LINEJOIN_MITER:
return Paint.Join.MITER;
case LINEJOIN_ROUND:
return Paint.Join.ROUND;
case LINEJOIN_BEVEL:
return Paint.Join.BEVEL;
default:
return defValue;
}
}
@Override
public boolean canApplyTheme() {
return mThemeAttrs != null;
}
public void inflate(Resources r, AttributeSet attrs, Theme theme) {
final TypedArray a = obtainAttributes(r, theme, attrs,
R.styleable.VectorDrawablePath);
updateStateFromTypedArray(a);
a.recycle();
}
private void updateStateFromTypedArray(TypedArray a) {
// Account for any configuration changes.
mChangingConfigurations |= a.getChangingConfigurations();
// Extract the theme attributes, if any.
mThemeAttrs = a.extractThemeAttrs();
final String pathName = a.getString(R.styleable.VectorDrawablePath_name);
if (pathName != null) {
mPathName = pathName;
}
final String pathData = a.getString(R.styleable.VectorDrawablePath_pathData);
if (pathData != null) {
mNodes = PathParser.createNodesFromPathData(pathData);
}
mFillColor = a.getColor(R.styleable.VectorDrawablePath_fillColor,
mFillColor);
mFillAlpha = a.getFloat(R.styleable.VectorDrawablePath_fillAlpha,
mFillAlpha);
mStrokeLineCap = getStrokeLineCap(a.getInt(
R.styleable.VectorDrawablePath_strokeLineCap, -1), mStrokeLineCap);
mStrokeLineJoin = getStrokeLineJoin(a.getInt(
R.styleable.VectorDrawablePath_strokeLineJoin, -1), mStrokeLineJoin);
mStrokeMiterlimit = a.getFloat(
R.styleable.VectorDrawablePath_strokeMiterLimit, mStrokeMiterlimit);
mStrokeColor = a.getColor(R.styleable.VectorDrawablePath_strokeColor,
mStrokeColor);
mStrokeAlpha = a.getFloat(R.styleable.VectorDrawablePath_strokeAlpha,
mStrokeAlpha);
mStrokeWidth = a.getFloat(R.styleable.VectorDrawablePath_strokeWidth,
mStrokeWidth);
mTrimPathEnd = a.getFloat(R.styleable.VectorDrawablePath_trimPathEnd,
mTrimPathEnd);
mTrimPathOffset = a.getFloat(
R.styleable.VectorDrawablePath_trimPathOffset, mTrimPathOffset);
mTrimPathStart = a.getFloat(
R.styleable.VectorDrawablePath_trimPathStart, mTrimPathStart);
}
@Override
public void applyTheme(Theme t) {
if (mThemeAttrs == null) {
return;
}
final TypedArray a = t.resolveAttributes(mThemeAttrs, R.styleable.VectorDrawablePath);
updateStateFromTypedArray(a);
a.recycle();
}
/* Setters and Getters, used by animator from AnimatedVectorDrawable. */
@SuppressWarnings("unused")
int getStrokeColor() {
return mStrokeColor;
}
@SuppressWarnings("unused")
void setStrokeColor(int strokeColor) {
mStrokeColor = strokeColor;
}
@SuppressWarnings("unused")
float getStrokeWidth() {
return mStrokeWidth;
}
@SuppressWarnings("unused")
void setStrokeWidth(float strokeWidth) {
mStrokeWidth = strokeWidth;
}
@SuppressWarnings("unused")
float getStrokeAlpha() {
return mStrokeAlpha;
}
@SuppressWarnings("unused")
void setStrokeAlpha(float strokeAlpha) {
mStrokeAlpha = strokeAlpha;
}
@SuppressWarnings("unused")
int getFillColor() {
return mFillColor;
}
@SuppressWarnings("unused")
void setFillColor(int fillColor) {
mFillColor = fillColor;
}
@SuppressWarnings("unused")
float getFillAlpha() {
return mFillAlpha;
}
@SuppressWarnings("unused")
void setFillAlpha(float fillAlpha) {
mFillAlpha = fillAlpha;
}
@SuppressWarnings("unused")
float getTrimPathStart() {
return mTrimPathStart;
}
@SuppressWarnings("unused")
void setTrimPathStart(float trimPathStart) {
mTrimPathStart = trimPathStart;
}
@SuppressWarnings("unused")
float getTrimPathEnd() {
return mTrimPathEnd;
}
@SuppressWarnings("unused")
void setTrimPathEnd(float trimPathEnd) {
mTrimPathEnd = trimPathEnd;
}
@SuppressWarnings("unused")
float getTrimPathOffset() {
return mTrimPathOffset;
}
@SuppressWarnings("unused")
void setTrimPathOffset(float trimPathOffset) {
mTrimPathOffset = trimPathOffset;
}
}
}