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/* Copyright 2012 Harri Smatt//from w w w .j a v a 2s . c o m 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 fi.harism.wallpaper.flowers; import java.nio.ByteBuffer; import java.nio.ByteOrder; import java.nio.FloatBuffer; import java.util.Vector; import android.content.Context; import android.graphics.Bitmap; import android.graphics.Canvas; import android.graphics.Color; import android.graphics.Paint; import android.graphics.PointF; import android.opengl.GLES20; import android.opengl.GLUtils; import android.os.SystemClock; /** * Main flower handling and rendering class. */ public final class FlowerObjects { // Flower movement directions. private static final float[] DIRECTIONS = { 0, 1, 1, 1, 1, 0, 1, -1, 0, -1, -1, -1, -1, 0, -1, 1 }; // Render area aspect ratio. private final PointF mAspectRatio = new PointF(); // Branch propability preference value between [0, 1]. private float mBranchPropability; // Spline rendering buffer. private FloatBuffer mBufferSpline; // Texture rendering buffer. private ByteBuffer mBufferTexture; // Container for retrieving points and rendering them (=textures). private final Vector<StructPoint> mContainerPoint = new Vector<StructPoint>(); // Container for retrieving splines and rendering them. private final Vector<StructSpline> mContainerSpline = new Vector<StructSpline>(); // Flower movement directions. These are calculated from DIRECTIONS so that // first length is set to 1, and then multiplied with aspect ratio. private final PointF[] mDirections = new PointF[8]; // Flower element objects. private ElementFlower[] mFlowerElements = new ElementFlower[0]; // Flower texture id. private final int mFlowerTextureId[] = { -1 }; // Shader for rendering splines. private final FlowerShader mShaderSpline = new FlowerShader(); // Shader for rendering flower textures. private final FlowerShader mShaderTexture = new FlowerShader(); // Spline vertex count, private int mSplineVertexCount; // Zoom level preference value, between [0, 1]. private float mZoomLevel; /** * Default constructor. */ public FlowerObjects() { final byte[] TEXTURE_COORDS = { -1, 1, -1, -1, 1, 1, 1, -1 }; mBufferTexture = ByteBuffer.allocateDirect(2 * 4); mBufferTexture.put(TEXTURE_COORDS).position(0); for (int i = 0; i < mDirections.length; ++i) { mDirections[i] = new PointF(); } } /** * Calculates distance between point1 and point2. */ private float distance(PointF point1, PointF point2) { float dx = point1.x - point2.x; float dy = point1.y - point2.y; return (float) Math.sqrt(dx * dx + dy * dy); } /** * Calculates distance between point1 + point2 and point3. */ private float distance(PointF point1, PointF point2, PointF point3) { float dx = point1.x + point2.x - point3.x; float dy = point1.y + point2.y - point3.y; return (float) Math.sqrt(dx * dx + dy * dy); } /** * Sets spline control points based on given parameters. */ private void genArc(StructSpline spline, PointF startPos, PointF dir, float length, PointF normal, boolean straightEnd) { // Bezier curve circle estimation. // 2 * (sqrt(2) - 1) / 3 final float NORMAL_FACTOR = 0.27614237f; final float normalLen = length * NORMAL_FACTOR; // Initially set all control points to startPos. for (PointF point : spline.mPoints) { point.set(startPos); } // Move second control point into target direction plus same length in // normal direction. spline.mPoints[1].offset((dir.x + normal.x) * normalLen, (dir.y + normal.y) * normalLen); // Move third control point to (startPos + (length - normalLen) * dir). spline.mPoints[2].offset(dir.x * (length - normalLen), dir.y * (length - normalLen)); // If straight end is not requested move third control point among // normal. if (!straightEnd) { spline.mPoints[2] .offset(normal.x * normalLen, normal.y * normalLen); } // Set last control point to (startPos + dir * length). spline.mPoints[3].offset(dir.x * length, dir.y * length); } /** * Sets branch values based on given parameters. */ private void genBranch(ElementBranch branch, PointF startPos, int startDir, int rotateDir, float len) { float maxBranchWidth = FlowerConstants.FLOWER_BRANCH_WIDTH_MIN + mZoomLevel * (FlowerConstants.FLOWER_BRANCH_WIDTH_MAX - FlowerConstants.FLOWER_BRANCH_WIDTH_MIN); PointF dir = mDirections[(8 + startDir) % 8]; PointF normal = mDirections[(8 + startDir - 2 * rotateDir) % 8]; StructSpline spline = branch.getNextSpline(); spline.mWidthStart = maxBranchWidth; spline.mWidthEnd = 0f; genArc(spline, startPos, dir, len, normal, false); startPos = spline.mPoints[3]; float rand = rand(0, 3); if (rand < 1) { StructPoint point = branch.getNextPoint(); point.mPosition.set(startPos); final float rotation = rand(0, (float) (Math.PI * 2)); point.mRotationSin = (float) Math.sin(rotation); point.mRotationCos = (float) Math.cos(rotation); } if (rand >= 1) { spline.mWidthEnd = maxBranchWidth / 2; dir = mDirections[(8 + startDir + 2 * rotateDir) % 8]; normal = mDirections[(8 + startDir) % 8]; spline = branch.getNextSpline(); spline.mWidthStart = maxBranchWidth / 2; spline.mWidthEnd = 0f; genArc(spline, startPos, dir, len, normal, false); StructPoint point = branch.getNextPoint(); point.mPosition.set(spline.mPoints[3]); final float rotation = rand(0, (float) (Math.PI * 2)); point.mRotationSin = (float) Math.sin(rotation); point.mRotationCos = (float) Math.cos(rotation); } if (rand >= 2) { dir = mDirections[(8 + startDir - rotateDir) % 8]; normal = mDirections[(8 + startDir + rotateDir) % 8]; spline = branch.getNextSpline(); spline.mWidthStart = maxBranchWidth / 2; spline.mWidthEnd = 0f; genArc(spline, startPos, dir, len * .5f, normal, false); StructPoint point = branch.getNextPoint(); point.mPosition.set(spline.mPoints[3]); final float rotation = rand(0, (float) (Math.PI * 2)); point.mRotationSin = (float) Math.sin(rotation); point.mRotationCos = (float) Math.cos(rotation); } } /** * Sets spline to straight line between (start, start + length * dir). */ private void genLine(StructSpline spline, PointF start, PointF dir, float length) { for (int i = 0; i < 4; ++i) { float t = (i * length) / 3; PointF point = spline.mPoints[i]; point.set(start); point.offset(dir.x * t, dir.y * t); } } /** * Renders flowers into scene. * * @param offset * Global offset value. */ public void onDrawFrame(PointF offset) { GLES20.glEnable(GLES20.GL_BLEND); GLES20.glBlendFunc(GLES20.GL_SRC_ALPHA, GLES20.GL_ONE_MINUS_SRC_ALPHA); long renderTime = SystemClock.uptimeMillis(); for (int i = 0; i < mFlowerElements.length; ++i) { mContainerPoint.clear(); mContainerSpline.clear(); ElementFlower flower = mFlowerElements[i]; update(flower, renderTime, offset); flower.getRenderStructs(mContainerSpline, mContainerPoint, renderTime); renderSplines(mContainerSpline, flower.mColor, offset); renderFlowers(mContainerPoint, flower.mColor, offset); } GLES20.glDisable(GLES20.GL_BLEND); } /** * Called once underlying surface size has changed. * * @param width * Surface width. * @param height * Surface height. */ public void onSurfaceChanged(int width, int height) { mAspectRatio.x = (float) Math.min(width, height) / width; mAspectRatio.y = (float) Math.min(width, height) / height; for (int i = 0; i < 8; ++i) { PointF dir = mDirections[i]; dir.set(DIRECTIONS[i * 2 + 0], DIRECTIONS[i * 2 + 1]); float lenInv = 1f / dir.length(); dir.x *= mAspectRatio.x * lenInv; dir.y *= mAspectRatio.y * lenInv; } for (ElementFlower flower : mFlowerElements) { flower.reset(); } } /** * Called once Surface has been created. * * @param context * Context to read resources from. */ public void onSurfaceCreated(Context context) { mShaderSpline.setProgram(context.getString(R.string.shader_spline_vs), context.getString(R.string.shader_spline_fs)); mShaderTexture.setProgram( context.getString(R.string.shader_texture_vs), context.getString(R.string.shader_texture_fs)); GLES20.glDeleteTextures(1, mFlowerTextureId, 0); GLES20.glGenTextures(1, mFlowerTextureId, 0); GLES20.glBindTexture(GLES20.GL_TEXTURE_2D, mFlowerTextureId[0]); GLES20.glTexParameteri(GLES20.GL_TEXTURE_2D, GLES20.GL_TEXTURE_WRAP_S, GLES20.GL_CLAMP_TO_EDGE); GLES20.glTexParameteri(GLES20.GL_TEXTURE_2D, GLES20.GL_TEXTURE_WRAP_T, GLES20.GL_CLAMP_TO_EDGE); GLES20.glTexParameteri(GLES20.GL_TEXTURE_2D, GLES20.GL_TEXTURE_MIN_FILTER, GLES20.GL_NEAREST); GLES20.glTexParameteri(GLES20.GL_TEXTURE_2D, GLES20.GL_TEXTURE_MAG_FILTER, GLES20.GL_LINEAR); Bitmap bitmap = Bitmap.createBitmap(256, 256, Bitmap.Config.ARGB_8888); bitmap.eraseColor(Color.BLACK); Canvas canvas = new Canvas(bitmap); Paint paint = new Paint(); paint.setStyle(Paint.Style.FILL); int borderColor = Color.rgb((int) (.8f * 255), 0, 0); int mainColor = Color.rgb(255, 0, 0); float leafDist = 1.7f * 128 / 3f; float leafPositions[] = new float[10]; for (int i = 0; i < 5; ++i) { double r = Math.PI * 2 * i / 5; leafPositions[i * 2 + 0] = 128 + (float) (Math.sin(r) * leafDist); leafPositions[i * 2 + 1] = 128 + (float) (Math.cos(r) * leafDist); } paint.setColor(borderColor); for (int i = 0; i < 5; ++i) { canvas.drawCircle(leafPositions[i * 2 + 0], leafPositions[i * 2 + 1], 48, paint); } paint.setColor(mainColor); for (int i = 0; i < 5; ++i) { canvas.drawCircle(leafPositions[i * 2 + 0], leafPositions[i * 2 + 1], 36, paint); } paint.setColor(borderColor); canvas.drawCircle(128, 128, 48, paint); paint.setColor(Color.BLACK); canvas.drawCircle(128, 128, 36, paint); GLUtils.texImage2D(GLES20.GL_TEXTURE_2D, 0, bitmap, 0); bitmap.recycle(); } /** * Generates random value between [min, max). */ private float rand(float min, float max) { return min + (float) (Math.random() * (max - min)); } /** * Renders flower textures. */ private void renderFlowers(Vector<StructPoint> flowers, float[] color, PointF offset) { mShaderTexture.useProgram(); int uAspectRatio = mShaderTexture.getHandle("uAspectRatio"); int uOffset = mShaderTexture.getHandle("uOffset"); int uScale = mShaderTexture.getHandle("uScale"); int uRotationM = mShaderTexture.getHandle("uRotationM"); int uColor = mShaderTexture.getHandle("uColor"); int aPosition = mShaderTexture.getHandle("aPosition"); GLES20.glUniform2f(uAspectRatio, mAspectRatio.x, mAspectRatio.y); GLES20.glUniform4fv(uColor, 1, color, 0); GLES20.glVertexAttribPointer(aPosition, 2, GLES20.GL_BYTE, false, 0, mBufferTexture); GLES20.glEnableVertexAttribArray(aPosition); GLES20.glActiveTexture(GLES20.GL_TEXTURE0); GLES20.glBindTexture(GLES20.GL_TEXTURE_2D, mFlowerTextureId[0]); for (StructPoint point : flowers) { final float rotationM[] = { point.mRotationCos, point.mRotationSin, -point.mRotationSin, point.mRotationCos }; GLES20.glUniformMatrix2fv(uRotationM, 1, false, rotationM, 0); GLES20.glUniform2f(uOffset, point.mPosition.x - offset.x, point.mPosition.y - offset.y); GLES20.glUniform1f(uScale, point.mScale); GLES20.glDrawArrays(GLES20.GL_TRIANGLE_STRIP, 0, 4); } } /** * Renders splines. */ public void renderSplines(Vector<StructSpline> splines, float[] color, PointF offset) { mShaderSpline.useProgram(); int uControlPts = mShaderSpline.getHandle("uControlPts"); int uWidth = mShaderSpline.getHandle("uWidth"); int uBounds = mShaderSpline.getHandle("uBounds"); int uColor = mShaderSpline.getHandle("uColor"); int uAspectRatio = mShaderSpline.getHandle("uAspectRatio"); int aSplinePos = mShaderSpline.getHandle("aSplinePos"); GLES20.glUniform2f(uAspectRatio, mAspectRatio.x, mAspectRatio.y); GLES20.glUniform4fv(uColor, 1, color, 0); GLES20.glVertexAttribPointer(aSplinePos, 2, GLES20.GL_FLOAT, false, 0, mBufferSpline); GLES20.glEnableVertexAttribArray(aSplinePos); final float[] controlPts = new float[8]; float boundX = FlowerConstants.SPLINE_WIDTH_MIN + mZoomLevel * (FlowerConstants.SPLINE_WIDTH_MAX - FlowerConstants.SPLINE_WIDTH_MIN); float boundY = 1f + boundX * mAspectRatio.y; boundX = 1f + boundX * mAspectRatio.x; for (StructSpline spline : splines) { int visiblePointCount = 0; for (int i = 0; i < 4; ++i) { float x = spline.mPoints[i].x - offset.x; float y = spline.mPoints[i].y - offset.y; controlPts[i * 2 + 0] = x; controlPts[i * 2 + 1] = y; if (Math.abs(x) < boundX && Math.abs(y) < boundY) { ++visiblePointCount; } } if (visiblePointCount != 0) { GLES20.glUniform2fv(uControlPts, 4, controlPts, 0); GLES20.glUniform2f(uWidth, spline.mWidthStart, spline.mWidthEnd); GLES20.glUniform2f(uBounds, spline.mStartT, spline.mEndT); if (spline.mStartT != 0f || spline.mEndT != 1f) { int startIdx = (int) Math.floor(spline.mStartT * (mSplineVertexCount - 1)) * 2; int endIdx = 2 + (int) Math.ceil(spline.mEndT * (mSplineVertexCount - 1)) * 2; GLES20.glDrawArrays(GLES20.GL_TRIANGLE_STRIP, startIdx, endIdx - startIdx); } else { GLES20.glDrawArrays(GLES20.GL_TRIANGLE_STRIP, 0, mSplineVertexCount * 2); } } } } /** * Updates preference values. */ public void setPreferences(int flowerCount, float[][] flowerColors, int splineQuality, float branchPropability, float zoomLevel) { if (flowerCount != mFlowerElements.length) { mFlowerElements = new ElementFlower[flowerCount]; for (int i = 0; i < mFlowerElements.length; ++i) { mFlowerElements[i] = new ElementFlower(); mFlowerElements[i].mColor = flowerColors[i]; } } for (int i = 0; i < mFlowerElements.length; ++i) { mFlowerElements[i].mColor = flowerColors[i]; } if (mSplineVertexCount != splineQuality + 2) { mSplineVertexCount = splineQuality + 2; ByteBuffer bBuffer = ByteBuffer .allocateDirect(4 * 4 * mSplineVertexCount); mBufferSpline = bBuffer.order(ByteOrder.nativeOrder()) .asFloatBuffer(); for (int i = 0; i < mSplineVertexCount; ++i) { float t = (float) i / (mSplineVertexCount - 1); mBufferSpline.put(t).put(1); mBufferSpline.put(t).put(-1); } mBufferSpline.position(0); } mBranchPropability = branchPropability; mZoomLevel = zoomLevel; } /** * Animates flower element regarding to current time value. */ private void update(ElementFlower flower, long time, PointF offset) { // TODO: it might be best to do scaling during rendering instead. final float ROOT_WIDTH = FlowerConstants.FLOWER_ROOT_WIDTH_MIN + mZoomLevel * (FlowerConstants.FLOWER_ROOT_WIDTH_MAX - FlowerConstants.FLOWER_ROOT_WIDTH_MIN); PointF targetPos = flower.mTargetPosition; PointF currentPos = flower.mCurrentPosition; int currentDirIdx = flower.mCurrentDirIndex; ElementRoot lastElement = flower.getLastRootElement(); long additionTime = time; while (time >= lastElement.mStartTime + lastElement.mDuration) { ElementRoot element = flower.getNextRootElement(); element.mStartTime = additionTime; element.mDuration = 500 + (long) (Math.random() * 500); targetPos.set(rand(-.8f, .8f), rand(-.8f, .8f)); targetPos.offset(offset.x, offset.y); float minDist = distance(currentPos, mDirections[currentDirIdx], targetPos); int minDirIndex = currentDirIdx; for (int i = 1; i < 8; ++i) { PointF dir = mDirections[(currentDirIdx + i) % 8]; float dist = distance(currentPos, dir, targetPos); if (dist < minDist) { minDist = dist; minDirIndex = (currentDirIdx + i) % 8; } } final float splineLen = Math.max(rand(.3f, .5f), distance(currentPos, targetPos) / 2f); if (minDirIndex != currentDirIdx) { int k = minDirIndex > currentDirIdx ? 1 : -1; for (int i = currentDirIdx + k; i * k <= minDirIndex * k; i += 2 * k) { PointF dir = mDirections[i]; PointF normal = mDirections[(8 + i - 2 * k) % 8]; StructSpline spline = element.getNextSpline(); spline.mWidthStart = spline.mWidthEnd = ROOT_WIDTH; genArc(spline, currentPos, dir, splineLen, normal, i == minDirIndex); if (Math.random() < mBranchPropability) { ElementBranch b = element.getCurrentBranch(); int branchDir = Math.random() < 0.5 ? -k : k; float branchLen = Math.min(splineLen, .5f) * rand(.6f, .8f); genBranch(b, currentPos, i + branchDir, branchDir, branchLen); } currentPos.set(spline.mPoints[3]); } currentDirIdx = minDirIndex; } else { PointF dir = mDirections[currentDirIdx]; StructSpline spline = element.getNextSpline(); spline.mWidthStart = spline.mWidthEnd = ROOT_WIDTH; genLine(spline, currentPos, dir, splineLen); if (Math.random() < mBranchPropability) { ElementBranch b = element.getCurrentBranch(); int branchDir = Math.random() < 0.5 ? -1 : 1; float branchLen = Math.min(splineLen, .5f) * rand(.6f, .8f); genBranch(b, currentPos, currentDirIdx + branchDir, branchDir, branchLen); } currentPos.set(spline.mPoints[3]); } additionTime += element.mDuration; lastElement = element; } flower.mCurrentDirIndex = currentDirIdx; } /** * Branch element for handling branch data. Namely splines and points that * create a branch. */ private final class ElementBranch { public int mBranchPointCount; private final StructPoint[] mBranchPoints = new StructPoint[2]; public int mBranchSplineCount; private final StructSpline[] mBranchSplines = new StructSpline[3]; /** * Default constructor. */ public ElementBranch() { for (int i = 0; i < mBranchSplines.length; ++i) { mBranchSplines[i] = new StructSpline(); } for (int i = 0; i < mBranchPoints.length; ++i) { mBranchPoints[i] = new StructPoint(); } } /** * Returns next point structure. */ public StructPoint getNextPoint() { return mBranchPoints[mBranchPointCount++]; } /** * Returns next splien structure. */ public StructSpline getNextSpline() { return mBranchSplines[mBranchSplineCount++]; } /** * Getter for splines and points this branch holds. Parameters startT * and endT are values between [0, 1] plus additionally startT < endT. */ public void getRenderStructs(Vector<StructSpline> splines, Vector<StructPoint> points, float startT, float endT) { // First iterate over splines. for (int i = 0; i < mBranchSplineCount; ++i) { StructSpline spline = mBranchSplines[i]; switch (i) { case 0: spline.mStartT = startT > 0f ? Math.min(startT * 2, 1f) : 0f; spline.mEndT = endT < 1f ? Math.min(endT * 2, 1f) : 1f; break; default: spline.mStartT = startT > 0f ? Math.max((startT - .5f) * 2, 0f) : 0f; spline.mEndT = endT < 1f ? Math.max((endT - .5f) * 2, 0f) : 1f; break; } splines.add(spline); } // Scale factor is calculated from current zoom level. // TODO: scaling might be best done during rendering. final float PT_SCALE_FACTOR = FlowerConstants.FLOWER_POINT_SCALE_MIN + mZoomLevel * (FlowerConstants.FLOWER_POINT_SCALE_MAX - FlowerConstants.FLOWER_POINT_SCALE_MIN); // Iterate over points. for (int i = 0; i < mBranchPointCount; ++i) { StructPoint point = mBranchPoints[i]; float scale = endT - startT; if (mBranchSplineCount == 1) { scale = scale < 1f ? Math.max((scale - .5f) * 2, 0f) : 1f; } point.mScale = scale * PT_SCALE_FACTOR; points.add(point); } } /** * Resets branch to initial state. */ public void reset() { mBranchSplineCount = mBranchPointCount = 0; } } /** * Flower element for handling flower related data. Namely root elements * which are used to build a flower. */ private final class ElementFlower { public float[] mColor = new float[4]; public int mCurrentDirIndex; public final PointF mCurrentPosition = new PointF(); private int mRootElementCount; private final Vector<ElementRoot> mRootElements = new Vector<ElementRoot>(); public final PointF mTargetPosition = new PointF(); /** * Default constructor. */ public ElementFlower() { for (int i = 0; i < FlowerConstants.FLOWER_ROOT_ELEMENT_COUNT; ++i) { mRootElements.add(new ElementRoot()); } } /** * Returns last active root element. If there are none, returns next * root element. */ public ElementRoot getLastRootElement() { if (mRootElementCount == 0) { return getNextRootElement(); } else { return mRootElements.get(mRootElementCount - 1); } } /** * Returns next root element. */ public ElementRoot getNextRootElement() { ElementRoot element; if (mRootElementCount < mRootElements.size()) { element = mRootElements.get(mRootElementCount++); } else { element = mRootElements.remove(0); mRootElements.add(element); } element.reset(); return element; } /** * Getter for spline and point structures for rendering. Time is current * rendering time used for deciding which root element is fading in. */ public void getRenderStructs(Vector<StructSpline> splines, Vector<StructPoint> points, long time) { ElementRoot lastElement = mRootElements.get(mRootElementCount - 1); float t = (float) (time - lastElement.mStartTime) / lastElement.mDuration; for (int i = 0; i < mRootElementCount; ++i) { ElementRoot element = mRootElements.get(i); if (i == mRootElementCount - 1) { element.getRenderStructs(splines, points, 0f, t); } else if (i == 0 && mRootElementCount == mRootElements.size()) { element.getRenderStructs(splines, points, t, 1f); } else { element.getRenderStructs(splines, points, 0f, 1f); } } } /** * Resets this flower element to its initial state. */ public void reset() { mRootElementCount = 0; mCurrentDirIndex = 0; mCurrentPosition.set(0, 0); } } /** * Root element for handling root related data. Root element consists of * splines for actual root and branch elements. */ private final class ElementRoot { private final ElementBranch[] mBranchElements = new ElementBranch[5]; private int mRootSplineCount; private final StructSpline[] mRootSplines = new StructSpline[5]; private long mStartTime, mDuration; /** * Default constructor. */ public ElementRoot() { for (int i = 0; i < 5; ++i) { mRootSplines[i] = new StructSpline(); mBranchElements[i] = new ElementBranch(); } } /** * Returns branch for current root spline. */ public ElementBranch getCurrentBranch() { return mBranchElements[mRootSplineCount - 1]; } /** * Returns next spline structure. */ public StructSpline getNextSpline() { mBranchElements[mRootSplineCount].reset(); return mRootSplines[mRootSplineCount++]; } /** * Getter for spline and point structs for rendering. Values startT and * endT are between [0, 1] plus additionally startT <= endT. */ public void getRenderStructs(Vector<StructSpline> splines, Vector<StructPoint> points, float startT, float endT) { for (int i = 0; i < mRootSplineCount; ++i) { StructSpline spline = mRootSplines[i]; if (startT != 0f || endT != 1f) { float localStartT = (float) i / mRootSplineCount; float localEndT = (float) (i + 1) / mRootSplineCount; spline.mStartT = Math.min( Math.max((startT - localStartT) / (localEndT - localStartT), 0f), 1f); spline.mEndT = Math.min( Math.max((endT - localStartT) / (localEndT - localStartT), 0f), 1f); } else { spline.mStartT = 0f; spline.mEndT = 1f; } if (spline.mStartT != spline.mEndT) { splines.add(spline); mBranchElements[i].getRenderStructs(splines, points, spline.mStartT, spline.mEndT); } } } /** * Resets root element to its initial state. */ public void reset() { mRootSplineCount = 0; mStartTime = mDuration = 0; } } /** * Holder for point data. */ private final class StructPoint { public final PointF mPosition = new PointF(); public float mRotationSin, mRotationCos; public float mScale; } /** * Holder for spline data. */ private final class StructSpline { public final PointF mPoints[] = new PointF[4]; public float mStartT = 0f, mEndT = 1f; public float mWidthStart, mWidthEnd; public StructSpline() { for (int i = 0; i < mPoints.length; ++i) { mPoints[i] = new PointF(); } } } }