自定义 ViewGroup 全屏选中效果
前言
事情是这个样子的,前几天产品丢给我一个视频,你觉得这个效果怎么样?我们的 App 也做一个这个效果吧!
我当时的反应:
开什么玩笑!就没见过这么玩的,这不是坑人吗?
此时产品幽幽的回了一句,“别人都能做,你怎么不能做,并且iOS说可以做,还很简单。”
我心里一万个不信,糟老头子太坏了,想骗我?
我立马和iOS同事统一战线,说不能做,实现不了吧。结果iOS同事幽幽的说了一句 “已经做了,四行代码完成”。
我勒个去,就指着我卷是吧。
这也没办法了,群里问问大神有什么好的方案,“xdm,车先减个速,(图片)这个效果怎么实现?”
“做不了...”
“让产品滚...”
“没做过,也没见过...”
“性能不好,不推荐,换方案吧。”
“GridView嵌套ScrollView , 要不RV嵌套RV?...”
“不理他,继续开车...”
...群里技术氛围果然没有让我失望,哎,看来还是得靠自己,抬头望了望天天,扣了扣脑阔,无语啊。
好了,说了这么多玩笑话,回归正题,其实关于标题的这种效果,确实是对性能的开销更大,且网上相关开源的项目也几乎没找到。
到底怎么做呢?相信跟着我一起复习的小伙伴们心里都有了一点雏形。自定义ViewGroup。
下面跟着我一起再次巩固一次 ViewGroup 的测量与布局,加上事件的处理,就能完成对应的功能。
话不多说,Let's go
一、布局的测量与布局
首先GridView嵌套ScrollView,RV 嵌套 RV 什么的,就宽度就限制死了,其次滚动方向也固定死了,不好做。
肯定是选用自定义 ViewGroup 的方案,自己测量,自己布局,自己实现滚动与缩放逻辑。
从产品发的竞品App的视频来看,我们需要先明确三个变量,一行显示多少个Item、垂直距离每一个Item的间距,水平距离每一个Item的间距。
然后我们测量每一个ItemView的宽度,每一个Item的宽度加起来就是ViewGroup的宽度,每一个Item的高度加起来就是ViewGroup的高度。
我们目前先不限定Item的宽高,先试着测量一下:
class CurtainViewContrainer extends ViewGroup { private int horizontalSpacing = 20; //每一个Item的左右间距 private int verticalSpacing = 20; //每一个Item的上下间距 private int mRowCount = 6; // 一行多少个Item private Adapter mAdapter; public CurtainViewContrainer(Context context) { this(context, null); } public CurtainViewContrainer(Context context, AttributeSet attrs) { this(context, attrs, 0); } public CurtainViewContrainer(Context context, AttributeSet attrs, int defStyleAttr) { super(context, attrs, defStyleAttr); init(); } private void init() { setClipChildren(false); setClipToPadding(false); } @SuppressLint("DrawAllocation") @Override protected void onMeasure(int widthMeasureSpec, int heightMeasureSpec) { final int sizeWidth = MeasureSpec.getSize(widthMeasureSpec) - this.getPaddingRight() - this.getPaddingLeft(); final int modeWidth = MeasureSpec.getMode(widthMeasureSpec); final int sizeHeight = MeasureSpec.getSize(heightMeasureSpec) - this.getPaddingTop() - this.getPaddingBottom(); final int modeHeight = MeasureSpec.getMode(heightMeasureSpec); int childCount = getChildCount(); if (mAdapter == null || mAdapter.getItemCount() == 0 || childCount == 0) { setMeasuredDimension(sizeWidth, 0); return; } int curCount = 1; int totalControlHeight = 0; int totalControlWidth = 0; int layoutChildViewCurX = this.getPaddingLeft(); int curRow = 0; int curColumn = 0; SparseArray<Integer> rowWidth = new SparseArray<>(); //全部行的宽度 //开始遍历 for (int i = 0; i < childCount; i++) { View childView = getChildAt(i); int row = curCount / mRowCount; //当前子View是第几行 int column = curCount % mRowCount; //当前子View是第几列 //测量每一个子View宽度 measureChild(childView, widthMeasureSpec, heightMeasureSpec); int width = childView.getMeasuredWidth(); int height = childView.getMeasuredHeight(); boolean isLast = (curCount + 1) % mRowCount == 0; if (row == curRow) { layoutChildViewCurX += width + horizontalSpacing; totalControlWidth += width + horizontalSpacing; rowWidth.put(row, totalControlWidth); } else { //已经换行了 layoutChildViewCurX = this.getPaddingLeft(); totalControlWidth = width + horizontalSpacing; rowWidth.put(row, totalControlWidth); //添加高度 totalControlHeight += height + verticalSpacing; } //最多只摆放9个 curCount++; curRow = row; curColumn = column; } //循环结束之后开始计算真正的宽度 List<Integer> widthList = new ArrayList<>(rowWidth.size()); for (int i = 0; i < rowWidth.size(); i++) { Integer integer = rowWidth.get(i); widthList.add(integer); } Integer maxWidth = Collections.max(widthList); setMeasuredDimension(maxWidth, totalControlHeight); } 复制代码
当遇到高度不统一的情况下,就会遇到问题,所以我们记录一下每一行的最高高度,用于计算控件的测量高度。
虽然这样测量是没有问题的,但是布局还是有坑,姑且先这么测量:
@Override protected void onLayout(boolean changed, int l, int t, int r, int b) { int childCount = getChildCount(); int curCount = 1; int layoutChildViewCurX = l; int layoutChildViewCurY = t; int curRow = 0; int curColumn = 0; SparseArray<Integer> rowWidth = new SparseArray<>(); //全部行的宽度 //开始遍历 for (int i = 0; i < childCount; i++) { View childView = getChildAt(i); int row = curCount / mRowCount; //当前子View是第几行 int column = curCount % mRowCount; //当前子View是第几列 //每一个子View宽度 int width = childView.getMeasuredWidth(); int height = childView.getMeasuredHeight(); childView.layout(layoutChildViewCurX, layoutChildViewCurY, layoutChildViewCurX + width, layoutChildViewCurY + height); if (row == curRow) { //同一行 layoutChildViewCurX += width + horizontalSpacing; } else { //换行了 layoutChildViewCurX = l; layoutChildViewCurY += height + verticalSpacing; } //最多只摆放9个 curCount++; curRow = row; curColumn = column; } performBindData(); } 复制代码
这样做并没有紧挨着头上的Item,目前我们把Item的宽高都使用同样的大小,是勉强能看的,一旦高度不统一,就不能看了。
先不管那么多,先固定大小显示出来看看效果。
反正是能看了,一个寨版的 GridView ,但是超出了宽度的限制。接下来我们先做事件的处理,让他动起来。
二、全屏滚动逻辑
首先我们需要把显示的 ViewGroup 控件封装为一个类,让此ViewGroup在另一个ViewGroup内部移动,不然还能让内部的每一个子View单独移动吗?肯定是整体一起移动更方便一点。
然后我们触摸容器 ViewGroup 中控制子 ViewGroup 移动即可,那怎么移动呢?
我知道,用 MotionEvent + Scroller 就可以滚动啦!
可以!又不可以,Scroller确实是可以动起来,但是在我们拖动与缩放之后,不能影响到内部的点击事件。
那可以不可以用 ViewDragHelper 来实现动作效果?
也不行,虽然 ViewDragHelper 是ViewGroup专门用于移动的帮助类,但是它内部其实还是封装的 MotionEvent + Scroller。
而 Scroller 为什么不行?
这种效果我们不能使用 Canvas 的移动,不能使用 Sroller 去移动,因为它们不能记录移动后的 View 变化矩阵,我们需要使用基本的 setTranslation 来实现,自己控制矩阵的变化从而控制整个视图树。
我们把触摸的拦截与事件的处理放到一个公用的事件处理类中:
public class TouchEventHandler { private static final float MAX_SCALE = 1.5f; //最大能缩放值 private static final float MIN_SCALE = 0.8f; //最小能缩放值 //当前的触摸事件类型 private static final int TOUCH_MODE_UNSET = -1; private static final int TOUCH_MODE_RELEASE = 0; private static final int TOUCH_MODE_SINGLE = 1; private static final int TOUCH_MODE_DOUBLE = 2; private View mView; private int mode = 0; private float scaleFactor = 1.0f; private float scaleBaseR; private GestureDetector mGestureDetector; private float mTouchSlop; private MotionEvent preMovingTouchEvent = null; private MotionEvent preInterceptTouchEvent = null; private boolean mIsMoving; private float minScale = MIN_SCALE; private FlingAnimation flingY = null; private FlingAnimation flingX = null; private ViewBox layoutLocationInParent = new ViewBox(); //移动中不断变化的盒模型 private final ViewBox viewportBox = new ViewBox(); //初始化的盒模型 private PointF preFocusCenter = new PointF(); private PointF postFocusCenter = new PointF(); private PointF preTranslate = new PointF(); private float preScaleFactor = 1f; private final DynamicAnimation.OnAnimationUpdateListener flingAnimateListener; private boolean isKeepInViewport = false; private TouchEventListener controlListener = null; private int scalePercentOnlyForControlListener = 0; public TouchEventHandler(Context context, View view) { this.mView = view; flingAnimateListener = (animation, value, velocity) -> keepWithinBoundaries(); mGestureDetector = new GestureDetector(context, new GestureDetector.SimpleOnGestureListener() { @Override public boolean onFling(MotionEvent e1, MotionEvent e2, float velocityX, float velocityY) { flingX = new FlingAnimation(mView, DynamicAnimation.TRANSLATION_X); flingX.setStartVelocity(velocityX) .addUpdateListener(flingAnimateListener) .start(); flingY = new FlingAnimation(mView, DynamicAnimation.TRANSLATION_Y); flingY.setStartVelocity(velocityY) .addUpdateListener(flingAnimateListener) .start(); return false; } }); ViewConfiguration vc = ViewConfiguration.get(view.getContext()); mTouchSlop = vc.getScaledTouchSlop() * 0.8f; } /** * 设置内部布局视图窗口高度和宽度 */ public void setViewport(int winWidth, int winHeight) { viewportBox.setValues(0, 0, winWidth, winHeight); } /** * 暴露的方法,内部处理事件并判断是否拦截事件 */ public boolean detectInterceptTouchEvent(MotionEvent event) { final int action = event.getAction() & MotionEvent.ACTION_MASK; onTouchEvent(event); if (action == MotionEvent.ACTION_DOWN) { preInterceptTouchEvent = MotionEvent.obtain(event); mIsMoving = false; } if (action == MotionEvent.ACTION_CANCEL || action == MotionEvent.ACTION_UP) { mIsMoving = false; } if (action == MotionEvent.ACTION_MOVE && mTouchSlop < calculateMoveDistance(event, preInterceptTouchEvent)) { mIsMoving = true; } return mIsMoving; } /** * 当前事件的真正处理逻辑 */ public boolean onTouchEvent(MotionEvent event) { mGestureDetector.onTouchEvent(event); int action = event.getAction() & MotionEvent.ACTION_MASK; switch (action) { case MotionEvent.ACTION_DOWN: mode = TOUCH_MODE_SINGLE; preMovingTouchEvent = MotionEvent.obtain(event); if (flingX != null) { flingX.cancel(); } if (flingY != null) { flingY.cancel(); } break; case MotionEvent.ACTION_UP: mode = TOUCH_MODE_RELEASE; break; case MotionEvent.ACTION_POINTER_UP: case MotionEvent.ACTION_CANCEL: mode = TOUCH_MODE_UNSET; break; case MotionEvent.ACTION_POINTER_DOWN: mode++; if (mode >= TOUCH_MODE_DOUBLE) { scaleFactor = preScaleFactor = mView.getScaleX(); preTranslate.set(mView.getTranslationX(), mView.getTranslationY()); scaleBaseR = (float) distanceBetweenFingers(event); centerPointBetweenFingers(event, preFocusCenter); centerPointBetweenFingers(event, postFocusCenter); } break; case MotionEvent.ACTION_MOVE: if (mode >= TOUCH_MODE_DOUBLE) { //双指缩放 float scaleNewR = (float) distanceBetweenFingers(event); centerPointBetweenFingers(event, postFocusCenter); if (scaleBaseR <= 0) { break; } scaleFactor = (scaleNewR / scaleBaseR) * preScaleFactor * 0.15f + scaleFactor * 0.85f; int scaleState = TouchEventListener.FREE_SCALE; float finalMinScale = isKeepInViewport ? minScale : minScale * 0.8f; if (scaleFactor >= MAX_SCALE) { scaleFactor = MAX_SCALE; scaleState = TouchEventListener.MAX_SCALE; } else if (scaleFactor <= finalMinScale) { scaleFactor = finalMinScale; scaleState = TouchEventListener.MIN_SCALE; } if (controlListener != null) { int current = (int) (scaleFactor * 100); //回调 if (scalePercentOnlyForControlListener != current) { scalePercentOnlyForControlListener = current; controlListener.onScaling(scaleState, scalePercentOnlyForControlListener); } } mView.setPivotX(0); mView.setPivotY(0); mView.setScaleX(scaleFactor); mView.setScaleY(scaleFactor); float tx = postFocusCenter.x - (preFocusCenter.x - preTranslate.x) * scaleFactor / preScaleFactor; float ty = postFocusCenter.y - (preFocusCenter.y - preTranslate.y) * scaleFactor / preScaleFactor; mView.setTranslationX(tx); mView.setTranslationY(ty); keepWithinBoundaries(); } else if (mode == TOUCH_MODE_SINGLE) { //单指移动 float deltaX = event.getRawX() - preMovingTouchEvent.getRawX(); float deltaY = event.getRawY() - preMovingTouchEvent.getRawY(); onSinglePointMoving(deltaX, deltaY); } break; case MotionEvent.ACTION_OUTSIDE: //外界的事件 break; } preMovingTouchEvent = MotionEvent.obtain(event); return true; } /** * 计算两个事件的移动距离 */ private float calculateMoveDistance(MotionEvent event1, MotionEvent event2) { if (event1 == null || event2 == null) { return 0f; } float disX = Math.abs(event1.getRawX() - event2.getRawX()); float disY = Math.abs(event1.getRawX() - event2.getRawX()); return (float) Math.sqrt(disX * disX + disY * disY); } /** * 单指移动 */ private void onSinglePointMoving(float deltaX, float deltaY) { float translationX = mView.getTranslationX() + deltaX; mView.setTranslationX(translationX); float translationY = mView.getTranslationY() + deltaY; mView.setTranslationY(translationY); keepWithinBoundaries(); } /** * 需要保持在界限之内 */ private void keepWithinBoundaries() { //默认不在界限内,不做限制,直接返回 if (!isKeepInViewport) { return; } calculateBound(); int dBottom = layoutLocationInParent.bottom - viewportBox.bottom; int dTop = layoutLocationInParent.top - viewportBox.top; int dLeft = layoutLocationInParent.left - viewportBox.left; int dRight = layoutLocationInParent.right - viewportBox.right; float translationX = mView.getTranslationX(); float translationY = mView.getTranslationY(); //边界限制 if (dLeft > 0) { mView.setTranslationX(translationX - dLeft); } if (dRight < 0) { mView.setTranslationX(translationX - dRight); } if (dBottom < 0) { mView.setTranslationY(translationY - dBottom); } if (dTop > 0) { mView.setTranslationY(translationY - dTop); } } /** * 移动时计算边界,赋值给本地的视图 */ private void calculateBound() { View v = mView; float left = v.getLeft() * v.getScaleX() + v.getTranslationX(); float top = v.getTop() * v.getScaleY() + v.getTranslationY(); float right = v.getRight() * v.getScaleX() + v.getTranslationX(); float bottom = v.getBottom() * v.getScaleY() + v.getTranslationY(); layoutLocationInParent.setValues((int) top, (int) left, (int) right, (int) bottom); } /** * 计算两个手指之间的距离 */ private double distanceBetweenFingers(MotionEvent event) { if (event.getPointerCount() > 1) { float disX = Math.abs(event.getX(0) - event.getX(1)); float disY = Math.abs(event.getY(0) - event.getY(1)); return Math.sqrt(disX * disX + disY * disY); } return 1; } /** * 计算两个手指之间的中心点 */ private void centerPointBetweenFingers(MotionEvent event, PointF point) { float xPoint0 = event.getX(0); float yPoint0 = event.getY(0); float xPoint1 = event.getX(1); float yPoint1 = event.getY(1); point.set((xPoint0 + xPoint1) / 2f, (yPoint0 + yPoint1) / 2f); } /** * 设置视图是否要保持在窗口中 */ public void setKeepInViewport(boolean keepInViewport) { isKeepInViewport = keepInViewport; } /** * 设置控制的监听回调 */ public void setControlListener(TouchEventListener controlListener) { this.controlListener = controlListener; } } 复制代码
由于内部封装了移动与缩放的处理,所以我们只需要在事件容器内部调用这个方法即可:
public class CurtainLayout extends FrameLayout { private final TouchEventHandler mGestureHandler; private CurtainViewContrainer mCurtainViewContrainer; private boolean disallowIntercept = false; public CurtainLayout(@NonNull Context context) { this(context, null); } public CurtainLayout(@NonNull Context context, @Nullable AttributeSet attrs) { this(context, attrs, 0); } public CurtainLayout(@NonNull Context context, @Nullable AttributeSet attrs, int defStyleAttr) { super(context, attrs, defStyleAttr); setClipChildren(false); setClipToPadding(false); mCurtainViewContrainer = new CurtainViewContrainer(getContext()); addView(mCurtainViewContrainer); mGestureHandler = new TouchEventHandler(getContext(), mCurtainViewContrainer); //设置是否在窗口内移动 mGestureHandler.setKeepInViewport(false); } @Override public void requestDisallowInterceptTouchEvent(boolean disallowIntercept) { super.requestDisallowInterceptTouchEvent(disallowIntercept); this.disallowIntercept = disallowIntercept; } @Override public boolean onInterceptTouchEvent(MotionEvent event) { return (!disallowIntercept && mGestureHandler.detectInterceptTouchEvent(event)) || super.onInterceptTouchEvent(event); } @Override public boolean onTouchEvent(MotionEvent event) { return !disallowIntercept && mGestureHandler.onTouchEvent(event); } @Override protected void onSizeChanged(int w, int h, int oldw, int oldh) { mGestureHandler.setViewport(w, h); } } 复制代码
对于一些复杂的处理都做了相关的注释,接下来看看加了事件处理之后的效果:
已经可以自由拖动与缩放了,但是目前的测量与布局是有问题的,加下来我们抽取与优化一下。
三、抽取Adapter与LayoutManager
首先,内部的子View肯定是不能直接写在 xml 中的,太不优雅了,加下来我们定义一个Adapter,用于填充数据,顺便做一个多类型的布局。
public abstract class CurtainAdapter { //返回总共子View的数量 public abstract int getItemCount(); //根据索引创建不同的布局类型,如果都是一样的布局则不需要重写 public int getItemViewType(int position) { return 0; } //根据类型创建对应的View布局 public abstract View onCreateItemView(@NonNull Context context, @NonNull ViewGroup parent, int itemType); //可以根据类型或索引绑定数据 public abstract void onBindItemView(@NonNull View itemView, int itemType, int position); } 复制代码
然后就是在绘制布局中通过设置 Apdater 来实现布局的添加与绑定逻辑。
public void setAdapter(CurtainAdapter adapter) { mAdapter = adapter; inflateAllViews(); } public CurtainAdapter getAdapter() { return mAdapter; } //填充Adapter布局 private void inflateAllViews() { removeAllViewsInLayout(); if (mAdapter == null || mAdapter.getItemCount() == 0) { return; } //添加布局 for (int i = 0; i < mAdapter.getItemCount(); i++) { int itemType = mAdapter.getItemViewType(i); View view = mAdapter.onCreateItemView(getContext(), this, itemType); addView(view); } requestLayout(); } //绑定布局中的数据 private void performBindData() { if (mAdapter == null || mAdapter.getItemCount() == 0) { return; } post(() -> { for (int i = 0; i < mAdapter.getItemCount(); i++) { int itemType = mAdapter.getItemViewType(i); View view = getChildAt(i); mAdapter.onBindItemView(view, itemType, i); } }); } 复制代码
当然需要在指定的地方调用了,测量与布局中都需要处理。
@Override protected void onMeasure(int widthMeasureSpec, int heightMeasureSpec) { int childCount = getChildCount(); if (mAdapter == null || mAdapter.getItemCount() == 0 || childCount == 0) { setMeasuredDimension(0, 0); return; } ... } @Override protected void onLayout(boolean changed, int l, int t, int r, int b) { if (mAdapter == null || mAdapter.getItemCount() == 0) { return; } performLayout(); performBindData(); } 复制代码
接下来的重点就是我们对布局的方式进行抽象化,最简单的肯定是上面这种宽高固定的,如果是垂直的排列,我们设置一个垂直的瀑布流管理器,设置宽度固定,高度自适应,如果宽度不固定,那么是无法到达瀑布流的效果的。
同理对另一种水平排列的瀑布流我们设置高度固定,宽度自适应。
所以必须要设置 LayoutManager,如果不设置就抛异常。
接下来就是 LayoutManager 的接口与具体调用:
public interface ILayoutManager { public static final int DIRECTION_VERITICAL = 0; public static final int DIRECTION_HORIZONTAL = 1; public abstract int[] performMeasure(ViewGroup viewGroup, int rowCount, int horizontalSpacing, int verticalSpacing, int fixedValue); public abstract void performLayout(ViewGroup viewGroup, int rowCount, int horizontalSpacing, int verticalSpacing, int fixedValue); public abstract int getLayoutDirection(); } 复制代码
有了接口之后我们就可以先写调用了:
class CurtainViewContrainer extends ViewGroup { private ILayoutManager mLayoutManager; private int horizontalSpacing = 20; //每一个Item的左右间距 private int verticalSpacing = 20; //每一个Item的上下间距 private int mRowCount = 6; // 一行多少个Item private int fixedWidth = CommUtils.dip2px(150); //如果是垂直瀑布流,需要设置宽度固定 private int fixedHeight = CommUtils.dip2px(180); //先写死,后期在抽取属性 private CurtainAdapter mAdapter; @SuppressLint("DrawAllocation") @Override protected void onMeasure(int widthMeasureSpec, int heightMeasureSpec) { int childCount = getChildCount(); if (mAdapter == null || mAdapter.getItemCount() == 0 || childCount == 0) { setMeasuredDimension(0, 0); return; } measureChildren(widthMeasureSpec, heightMeasureSpec); if (mLayoutManager != null && (fixedWidth > 0 || fixedHeight > 0)) { for (int i = 0; i < childCount; i++) { View childView = getChildAt(i); if (mLayoutManager.getLayoutDirection() == ILayoutManager.DIRECTION_VERITICAL) { measureChild(childView, MeasureSpec.makeMeasureSpec(fixedWidth, MeasureSpec.EXACTLY), heightMeasureSpec); } else { measureChild(childView, widthMeasureSpec, MeasureSpec.makeMeasureSpec(fixedHeight, MeasureSpec.EXACTLY)); } } int[] dimensions = mLayoutManager.performMeasure(this, mRowCount, horizontalSpacing, verticalSpacing, mLayoutManager.getLayoutDirection() == ILayoutManager.DIRECTION_VERITICAL ? fixedWidth : fixedHeight); setMeasuredDimension(dimensions[0], dimensions[1]); } else { throw new RuntimeException("You need to set the layoutManager first"); } } @Override protected void onLayout(boolean changed, int l, int t, int r, int b) { if (mAdapter == null || mAdapter.getItemCount() == 0) { return; } if (mLayoutManager != null && (fixedWidth > 0 || fixedHeight > 0)) { mLayoutManager.performLayout(this, mRowCount, horizontalSpacing, verticalSpacing, mLayoutManager.getLayoutDirection() == ILayoutManager.DIRECTION_VERITICAL ? fixedWidth : fixedHeight); performBindData(); } else { throw new RuntimeException("You need to set the layoutManager first"); } } 复制代码
那么我们先来水平的LayoutManager,相对简单一些,看看如何具体实现:
public class HorizontalLayoutManager implements ILayoutManager { @Override public int[] performMeasure(ViewGroup viewGroup, int rowCount, int horizontalSpacing, int verticalSpacing, int fixedHeight) { int childCount = viewGroup.getChildCount(); int curCount = 0; int totalControlHeight = 0; int totalControlWidth = 0; int curRow = 0; SparseArray<Integer> rowTotalWidth = new SparseArray<>(); //每一行的总宽度 //开始遍历 for (int i = 0; i < childCount; i++) { View childView = viewGroup.getChildAt(i); int row = curCount / rowCount; //当前子View是第几行 //已经测量过了,直接取宽高 int width = childView.getMeasuredWidth(); if (row == curRow) { //当前行 totalControlWidth += width + horizontalSpacing; } else { //换行了 totalControlWidth = width + horizontalSpacing; } rowTotalWidth.put(row, totalControlWidth); //赋值 curCount++; curRow = row; } //循环结束之后开始计算真正的宽高 totalControlHeight = (rowCount * (fixedHeight + verticalSpacing)) - verticalSpacing + viewGroup.getPaddingTop() + viewGroup.getPaddingBottom(); List<Integer> widthList = new ArrayList<>(); for (int i = 0; i < rowTotalWidth.size(); i++) { Integer width = rowTotalWidth.get(i); widthList.add(width); } totalControlWidth = Collections.max(widthList); rowTotalWidth.clear(); rowTotalWidth = null; return new int[]{totalControlWidth - horizontalSpacing, totalControlHeight - verticalSpacing}; } @Override public void performLayout(ViewGroup viewGroup, int rowCount, int horizontalSpacing, int verticalSpacing, int fixedHeight) { int childCount = viewGroup.getChildCount(); int curCount = 1; int layoutChildViewCurX = viewGroup.getPaddingLeft(); int layoutChildViewCurY = viewGroup.getPaddingTop(); int curRow = 0; //开始遍历 for (int i = 0; i < childCount; i++) { View childView = viewGroup.getChildAt(i); int row = curCount / rowCount; //当前子View是第几行 //每一个子View宽度 int width = childView.getMeasuredWidth(); childView.layout(layoutChildViewCurX, layoutChildViewCurY, layoutChildViewCurX + width, layoutChildViewCurY + fixedHeight); if (row == curRow) { //同一行 layoutChildViewCurX += width + horizontalSpacing; } else { //换行了 layoutChildViewCurX = childView.getPaddingLeft(); layoutChildViewCurY += fixedHeight + verticalSpacing; } //赋值 curCount++; curRow = row; } } @Override public int getLayoutDirection() { return DIRECTION_HORIZONTAL; } } 复制代码
对于水平的布局方式来说,高度是固定的,我们很容易的就能计算出来,但是宽度每一行的可能都不一样,我们用一个List记录每一行的总宽度,在最后设置的时候取出最大的一行作为容器的宽度,记得要减去一个间距哦。
那么不同宽度的水平布局方式效果的实现就是这样:
实现是实现了,但是这么计算是不是有问题?每一行的最高高度好像不是太准确,如果每一列都有一个最大高度,但是不是同一列,那么测量的高度就比实际高度要更高。
加一个灰色背景就可以看到效果:
我们再优化一下,它应该是计算每一列的总共高度,然后选出最大高度才对:
@Override public int[] performMeasure(ViewGroup viewGroup, int rowCount, int horizontalSpacing, int verticalSpacing, int fixedWidth) { int childCount = viewGroup.getChildCount(); int curPosition = 0; int totalControlHeight = 0; int totalControlWidth = 0; SparseArray<List<Integer>> columnAllHeight = new SparseArray<>(); //每一列的全部高度 //开始遍历 for (int i = 0; i < childCount; i++) { View childView = viewGroup.getChildAt(i); int row = curPosition / rowCount; //当前子View是第几行 int column = curPosition % rowCount; //当前子View是第几列 //已经测量过了,直接取宽高 int height = childView.getMeasuredHeight(); List<Integer> integers = columnAllHeight.get(column); if (integers == null || integers.isEmpty()) { integers = new ArrayList<>(); } integers.add(height + verticalSpacing); columnAllHeight.put(column, integers); //赋值 curPosition++; } //循环结束之后开始计算真正的宽高 totalControlWidth = (rowCount * (fixedWidth + horizontalSpacing) + viewGroup.getPaddingLeft() + viewGroup.getPaddingRight()); List<Integer> totalHeights = new ArrayList<>(); for (int i = 0; i < columnAllHeight.size(); i++) { List<Integer> heights = columnAllHeight.get(i); int totalHeight = 0; for (int j = 0; j < heights.size(); j++) { totalHeight += heights.get(j); } totalHeights.add(totalHeight); } totalControlHeight = Collections.max(totalHeights); columnAllHeight.clear(); columnAllHeight = null; return new int[]{totalControlWidth - horizontalSpacing, totalControlHeight - verticalSpacing}; } 复制代码
再看看效果:
宽高真正的测量准确之后我们接下来就开始属性的抽取与封装了。
四、自定义属性
我们先前都是使用的成员变量来控制一些间距与逻辑的触发,这就跟业务耦合了,如果想做到通用的一个效果,肯定还是要抽取自定义属性,做到对应的配置开关,就可以适应更多的场景使用,也是开源项目的必备技能。
细数一下我们需要控制的属性:
- enableScale 是否支持缩放
- maxScale 缩放的最大比例
- minScale 缩放的最小比例
- moveInViewport 是否只能在布局内部移动
- horizontalSpacing item的水平间距
- verticalSpacing item的垂直间距
- fixed_width 竖向的排列 - 宽度定死 并设置对应的LayoutManager
- fixed_height 横向的排列 - 高度定死 并设置对应的LayoutManager
定义属性如下:
复制代码
取出属性并对容器布局与触摸处理器做赋值的操作:
public class CurtainLayout extends FrameLayout { private int horizontalSpacing; private int verticalSpacing; private int rowCount; private int fixedWidth; private int fixedHeight; private boolean moveInViewport; private boolean enableScale; private float maxScale; private float minScale; public CurtainLayout(@NonNull Context context, @Nullable AttributeSet attrs, int defStyleAttr) { super(context, attrs, defStyleAttr); setClipChildren(false); setClipToPadding(false); mCurtainViewContrainer = new CurtainViewContrainer(getContext()); addView(mCurtainViewContrainer); initAttr(context, attrs); mGestureHandler = new TouchEventHandler(getContext(), mCurtainViewContrainer); //设置是否在窗口内移动 mGestureHandler.setKeepInViewport(moveInViewport); mGestureHandler.setEnableScale(enableScale); mGestureHandler.setMinScale(minScale); mGestureHandler.setMaxScale(maxScale); mCurtainViewContrainer.setHorizontalSpacing(horizontalSpacing); mCurtainViewContrainer.setVerticalSpacing(verticalSpacing); mCurtainViewContrainer.setRowCount(rowCount); mCurtainViewContrainer.setFixedWidth(fixedWidth); mCurtainViewContrainer.setFixedHeight(fixedHeight); if (fixedWidth > 0 || fixedHeight > 0) { if (fixedWidth > 0) { mCurtainViewContrainer.setLayoutDirectionVertical(fixedWidth); } else { mCurtainViewContrainer.setLayoutDirectionHorizontal(fixedHeight); } } } /** * 获取自定义属性 */ private void initAttr(Context context, AttributeSet attrs) { TypedArray mTypedArray = context.obtainStyledAttributes(attrs, R.styleable.CurtainLayout); this.horizontalSpacing = mTypedArray.getDimensionPixelSize(R.styleable.CurtainLayout_horizontalSpacing, 20); this.verticalSpacing = mTypedArray.getDimensionPixelSize(R.styleable.CurtainLayout_verticalSpacing, 20); this.rowCount = mTypedArray.getInteger(R.styleable.CurtainLayout_rowCount, 6); this.fixedWidth = mTypedArray.getDimensionPixelOffset(R.styleable.CurtainLayout_fixedWidth, 150); this.fixedHeight = mTypedArray.getDimensionPixelSize(R.styleable.CurtainLayout_fixedHeight, 180); this.moveInViewport = mTypedArray.getBoolean(R.styleable.CurtainLayout_moveInViewport, false); this.enableScale = mTypedArray.getBoolean(R.styleable.CurtainLayout_enableScale, true); this.minScale = mTypedArray.getFloat(R.styleable.CurtainLayout_minScale, 0.7f); this.maxScale = mTypedArray.getFloat(R.styleable.CurtainLayout_maxScale, 1.5f); mTypedArray.recycle(); } ... public void setMoveInViewportInViewport(boolean moveInViewport) { this.moveInViewport = moveInViewport; mGestureHandler.setKeepInViewport(moveInViewport); } public void setEnableScale(boolean enableScale) { this.enableScale = enableScale; mGestureHandler.setEnableScale(enableScale); } public void setMinScale(float minScale) { this.minScale = minScale; mGestureHandler.setMinScale(minScale); } public void setMaxScale(float maxScale) { this.maxScale = maxScale; mGestureHandler.setMaxScale(maxScale); } public void setHorizontalSpacing(int horizontalSpacing) { mCurtainViewContrainer.setHorizontalSpacing(horizontalSpacing); } public void setVerticalSpacing(int verticalSpacing) { mCurtainViewContrainer.setVerticalSpacing(verticalSpacing); } public void setRowCount(int rowCount) { mCurtainViewContrainer.setRowCount(rowCount); } public void setFixedWidth(int fixedWidth) { mCurtainViewContrainer.setLayoutDirectionVertical(fixedWidth); } public void setFixedHeight(int fixedHeight) { mCurtainViewContrainer.setLayoutDirectionHorizontal(fixedHeight); } 复制代码
然后在布局容器与事件处理类中做对应的赋值操作即可。
如何使用?
<CurtainLayout android:id="@+id/curtain_view" android:layout_width="match_parent" android:layout_height="match_parent" app:enableScale="true" app:fixedWidth="150dp" app:horizontalSpacing="10dp" app:maxScale="1.5" app:minScale="0.8" app:moveInViewport="true" app:rowCount="6" app:verticalSpacing="10dp"> </CurtainLayout> 复制代码
如果在xml中设置过 fixedWidth 或者 fixedHeight ,那么在 Activity 中也可以不设置 LayoutManager 了。
val list = listOf<String>( ... ) val adapter = Viewgroup6Adapter(list) val curtainView = findViewById<CurtainLayout>(R.id.curtain_view) curtainView.adapter = adapter 复制代码
最终效果:
后记
关于 ViewGroup 的测量与布局与事件,我们已经从易到难复习了四期了,相信同学应该是能掌握了。
话说到里就应该到了完结时刻,关于自定义View与自定义ViewGroup的复习与回顾就到此告一段落了,对于市面上能见到的一些布局效果,基本上能通过自定义ViewGroup与自定义View来实现。其实很早就想完结了,因为感觉这些东西有一点过于基础了,好像大家都不是很有兴趣看这些基础的东西,
自定义View可以很方便的做自定义的绘制与本身与内部的一些移动,而对于一些多View移动的特效,我们就算用自定义View难以实现或实现的比较复杂的话,也能使用Behivor或者MotionLayot 来实现,当然这就是另一个篇章了。
如果有兴趣也可以看看我之前的 Behivor 文章 【传送门】 或者 MotionLayot 的文章,【传送门】。
同时也可以搜索与翻看之前的文章哦。
本文的代码均可以在我的Kotlin测试项目中看到,【传送门】。你也可以关注我的这个Kotlin项目,我有时间都会持续更新。
关于本文的全屏滑动效果,我也会开源传到 MavenCentral 供大家依赖使用,【传送门】
使用:Gradle中直接依赖即可:
implementation "com.gitee.newki123456:curtain_layout:1.0.0"
好了,如果类似的效果有更多的更好的其他方式,也希望大家能评论区交流一下。
惯例,我如有讲解不到位或错漏的地方,希望同学们可以指出。
如果感觉本文对你有一点点的帮助,还望你能点赞
支持一下,你的支持是我最大的动力。
哎,找图片都找了接近一个小时,如果大家想要对应的图片也可以去项目中拿哦!
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