起源
在Activity中,所有的View都是DecorView的子View,然后DecorView又是被ViewRootImpl所控制,当Activity显示的时候,ViewRootImpl的performTranversals
方法开始运行,这个方法很长,不过核心的三个流程就是依次调用performMeasure、performLayout、performDraw三个方法,从而完成DecorView的绘制。
ViewRootImpl#performMeasure
private void performMeasure(int childWidthMeasureSpec, int childHeightMeasureSpec) { Trace.traceBegin(Trace.TRACE_TAG_VIEW, "measure"); try { mView.measure(childWidthMeasureSpec, childHeightMeasureSpec); } finally { Trace.traceEnd(Trace.TRACE_TAG_VIEW); } } |
这里直接调用了mView的measure
方法,参数是两个经过设置的MeasureSpec,接下来我们分析一下MeasureSpec是如何设置的。
MeasureSpec
这个MeasureSpec不是实际测绘值,而是父View传递给子View的布局要求,MeasureSpec涵盖了对子View大小和模式的要求。其中,三种模式要求分别是:
UNSPECIFIED:对子View无任何要求,想要测绘多少由子View决定。
EXACTLY:父View已确定了自己确切的大小。子View将在这个边界内测绘自己的宽高。
AT_MOST:父View对子View没有要求,子View可以达到它想要的大小。
首先这个MeasureSpec是个32位的int值,其中31,32两位代表的是三种模式的要求,分别是00….、01….、11….,makeMeasureSpec
方法中,sUseBrokenMakeMeasureSpec默认是false,所以一般执行(size & ~MODE_MASK) | (mode & MODE_MASK)这个语句,这个意思就是说,MeasureSpec的高两位代表的是模式,低30位代表父View的尺寸。
下面是对应的方法:
private static final int MODE_SHIFT = 30; private static final int MODE_MASK = 0x3 << MODE_SHIFT; public static final int UNSPECIFIED = 0 << MODE_SHIFT; public static final int EXACTLY = 1 << MODE_SHIFT; public static final int AT_MOST = 2 << MODE_SHIFT; public static int makeMeasureSpec(@IntRange(from = 0, to = (1 << MeasureSpec.MODE_SHIFT) - 1) int size, @MeasureSpecMode int mode) { if (sUseBrokenMakeMeasureSpec) { return size + mode; } else { return (size & ~MODE_MASK) | (mode & MODE_MASK); } } |
View#measure
计算完MeasureSpec,DecorView就该执行measure
方法了。
public final void measure(int widthMeasureSpec, int heightMeasureSpec) { ··· final boolean forceLayout = (mPrivateFlags & PFLAG_FORCE_LAYOUT) == PFLAG_FORCE_LAYOUT; ··· final boolean needsLayout = specChanged && (sAlwaysRemeasureExactly || !isSpecExactly || !matchesSpecSize); if (forceLayout || needsLayout) { ··· int cacheIndex = forceLayout ? -1 : mMeasureCache.indexOfKey(key); if (cacheIndex < 0 || sIgnoreMeasureCache) { // measure ourselves, this should set the measured dimension flag back onMeasure(widthMeasureSpec, heightMeasureSpec); mPrivateFlags3 &= ~PFLAG3_MEASURE_NEEDED_BEFORE_LAYOUT; } else { ··· } ··· } ··· } ··· } |
measure方法是final的,所以不能重写,不过measure方法最主要的作用就是调用了onMeasure方法,由于DecorView是继承的FrameLayout,所以本篇文章我们主要分析FrameLayout的onMeasure方法。
FrameLayout#onMeasure
这个onMeasure方法,可能是View绘制中最难理解的了,所以我们逐步分析。
protected void onMeasure(int widthMeasureSpec, int heightMeasureSpec) { //获取子View个数 int count = getChildCount(); //判断是否是确定宽高的 //如果宽高都确定,那么boolean为false //如果有一个不确定,那么boolean为true final boolean measureMatchParentChildren = MeasureSpec.getMode(widthMeasureSpec) != MeasureSpec.EXACTLY || MeasureSpec.getMode(heightMeasureSpec) != MeasureSpec.EXACTLY; mMatchParentChildren.clear(); int maxHeight = 0; int maxWidth = 0; int childState = 0; //遍历所有不为GONE的子View,并加以计算 for (int i = 0; i < count; i++) { final View child = getChildAt(i); if (mMeasureAllChildren || child.getVisibility() != GONE) { //计算各个子View宽高,包括Margin参数以及padding参数 //该方法详细分析见下文 measureChildWithMargins(child, widthMeasureSpec, 0, heightMeasureSpec, 0); final LayoutParams lp = (LayoutParams) child.getLayoutParams(); maxWidth = Math.max(maxWidth, child.getMeasuredWidth() + lp.leftMargin + lp.rightMargin); maxHeight = Math.max(maxHeight, child.getMeasuredHeight() + lp.topMargin + lp.bottomMargin); //用按位或的方法合并所有子View的State //getMeasuredState方法详细解析在下面 childState = combineMeasuredStates(childState, child.getMeasuredState()); //如果宽高有不确定的(即warp_content模式),将子View中宽或高是match_parent的添加到mMatchParentChildren中。 if (measureMatchParentChildren) { if (lp.width == LayoutParams.MATCH_PARENT || lp.height == LayoutParams.MATCH_PARENT) { mMatchParentChildren.add(child); } } } } // 计算padding maxWidth += getPaddingLeftWithForeground() + getPaddingRightWithForeground(); maxHeight += getPaddingTopWithForeground() + getPaddingBottomWithForeground(); // 与最小宽高作比较,二者取较大的 maxHeight = Math.max(maxHeight, getSuggestedMinimumHeight()); maxWidth = Math.max(maxWidth, getSuggestedMinimumWidth()); // 与前景图宽高作比较,二者取较大的 final Drawable drawable = getForeground(); if (drawable != null) { maxHeight = Math.max(maxHeight, drawable.getMinimumHeight()); maxWidth = Math.max(maxWidth, drawable.getMinimumWidth()); } //计算并保存measured宽高 //resolveSizeAndState方法分析在下面 //setMeasuredDimension方法分析在下面 setMeasuredDimension(resolveSizeAndState(maxWidth, widthMeasureSpec, childState), resolveSizeAndState(maxHeight, heightMeasureSpec, childState << MEASURED_HEIGHT_STATE_SHIFT)); //计算macth_parent的子View的个数 count = mMatchParentChildren.size(); //只有FrameLayout中宽或者高有warp_content属性, //并且match_parent的子view个数大于1才会执行下面代码。 //因为如果宽高都是match_parent的,或者设置好dp数值的,则mMatchParentChildren永远是空的。 //在这里会重新计算传递给子View的MeasureSpec值,并重新测绘子View。 //关于MeasureSpec值的计算,可以参考下文ViewGroup#getChildMeasureSpec的表格。 //这里需要注意的是,match_parent行所有的结果均改为:EXACTLY + parentSize if (count > 1) { for (int i = 0; i < count; i++) { final View child = mMatchParentChildren.get(i); final MarginLayoutParams lp = (MarginLayoutParams) child.getLayoutParams(); final int childWidthMeasureSpec; if (lp.width == LayoutParams.MATCH_PARENT) { final int width = Math.max(0, getMeasuredWidth() - getPaddingLeftWithForeground() - getPaddingRightWithForeground() - lp.leftMargin - lp.rightMargin); childWidthMeasureSpec = MeasureSpec.makeMeasureSpec( width, MeasureSpec.EXACTLY); } else { childWidthMeasureSpec = getChildMeasureSpec(widthMeasureSpec, getPaddingLeftWithForeground() + getPaddingRightWithForeground() + lp.leftMargin + lp.rightMargin, lp.width); } final int childHeightMeasureSpec; if (lp.height == LayoutParams.MATCH_PARENT) { final int height = Math.max(0, getMeasuredHeight() - getPaddingTopWithForeground() - getPaddingBottomWithForeground() - lp.topMargin - lp.bottomMargin); childHeightMeasureSpec = MeasureSpec.makeMeasureSpec( height, MeasureSpec.EXACTLY); } else { childHeightMeasureSpec = getChildMeasureSpec(heightMeasureSpec, getPaddingTopWithForeground() + getPaddingBottomWithForeground() + lp.topMargin + lp.bottomMargin, lp.height); } child.measure(childWidthMeasureSpec, childHeightMeasureSpec); } } } |
ViewGroup#measureChildWithMargins
该方法作用是测绘子View,在父View的onMeasure中循环调用,达到遍历的效果。
protected void measureChildWithMargins(View child, int parentWidthMeasureSpec, int widthUsed, int parentHeightMeasureSpec, int heightUsed) { //获取子View的LayoutParams final MarginLayoutParams lp = (MarginLayoutParams) child.getLayoutParams(); //计算子View的MeasureSpec //getChildMeasureSpec方法分析见下文 final int childWidthMeasureSpec = getChildMeasureSpec(parentWidthMeasureSpec, mPaddingLeft + mPaddingRight + lp.leftMargin + lp.rightMargin + widthUsed, lp.width); final int childHeightMeasureSpec = getChildMeasureSpec(parentHeightMeasureSpec, mPaddingTop + mPaddingBottom + lp.topMargin + lp.bottomMargin + heightUsed, lp.height); //调用子View的measure方法,对子View进行测绘 child.measure(childWidthMeasureSpec, childHeightMeasureSpec); } |
ViewGroup#getChildMeasureSpec
此方法通过父View的MeasureSpec值以及LayoutParams的宽高,来生成子View的MeasureSpec值,具体代码如下:
public static int getChildMeasureSpec(int spec, int padding, int childDimension) { //计算父View的size和mode int specMode = MeasureSpec.getMode(spec); int specSize = MeasureSpec.getSize(spec); //计算刨除padding的size int size = Math.max(0, specSize - padding); int resultSize = 0; int resultMode = 0; switch (specMode) { // Parent has imposed an exact size on us case MeasureSpec.EXACTLY: if (childDimension >= 0) { resultSize = childDimension; resultMode = MeasureSpec.EXACTLY; } else if (childDimension == LayoutParams.MATCH_PARENT) { // Child wants to be our size. So be it. resultSize = size; resultMode = MeasureSpec.EXACTLY; } else if (childDimension == LayoutParams.WRAP_CONTENT) { // Child wants to determine its own size. It can't be // bigger than us. resultSize = size; resultMode = MeasureSpec.AT_MOST; } break; // Parent has imposed a maximum size on us case MeasureSpec.AT_MOST: if (childDimension >= 0) { // Child wants a specific size... so be it resultSize = childDimension; resultMode = MeasureSpec.EXACTLY; } else if (childDimension == LayoutParams.MATCH_PARENT) { // Child wants to be our size, but our size is not fixed. // Constrain child to not be bigger than us. resultSize = size; resultMode = MeasureSpec.AT_MOST; } else if (childDimension == LayoutParams.WRAP_CONTENT) { // Child wants to determine its own size. It can't be // bigger than us. resultSize = size; resultMode = MeasureSpec.AT_MOST; } break; // Parent asked to see how big we want to be case MeasureSpec.UNSPECIFIED: if (childDimension >= 0) { // Child wants a specific size... let him have it resultSize = childDimension; resultMode = MeasureSpec.EXACTLY; } else if (childDimension == LayoutParams.MATCH_PARENT) { // Child wants to be our size... find out how big it should // be resultSize = View.sUseZeroUnspecifiedMeasureSpec ? 0 : size; resultMode = MeasureSpec.UNSPECIFIED; } else if (childDimension == LayoutParams.WRAP_CONTENT) { // Child wants to determine its own size.... find out how // big it should be resultSize = View.sUseZeroUnspecifiedMeasureSpec ? 0 : size; resultMode = MeasureSpec.UNSPECIFIED; } break; } //noinspection ResourceType return MeasureSpec.makeMeasureSpec(resultSize, resultMode); } |
上面代码,其实通过一张表格,就能很清楚的解释转换规律
竖列代表LayoutParams的宽或高属性\横行父View传递的Mode | EXACTLY | AT_MOST | UNSPECIFIED |
---|---|---|---|
精确值 | EXACTLY + childSize | EXACTLY + childSize | EXACTLY + childSize |
match_parent | EXACTLY + parentSize | AT_MOST + parentSize | UNSPECIFIED + parentSize |
warp_content | AT_MOST + parentSize | AT_MOST + parentSize | UNSPECIFIED + parentSize |
View#getMeasuredState
public final int getMeasuredState() { return (mMeasuredWidth&MEASURED_STATE_MASK) | ((mMeasuredHeight>>MEASURED_HEIGHT_STATE_SHIFT) & (MEASURED_STATE_MASK>>MEASURED_HEIGHT_STATE_SHIFT)); } |
该方法返回一个表达View宽高measure_state值的整数,第8位代表height是否是MEASURED_STATE_TOO_SMALL,第24为代表width是否是MEASURED_STATE_TOO_SMALL的。
例如:
宽是MEASURED_STATE_TOO_SMALL的
返回:0000 0001 0000 0000 0000 0000 0000 0000
高是MEASURED_STATE_TOO_SMALL的
返回:0000 0000 0000 0000 0000 0001 0000 0000
宽高均是MEASURED_STATE_TOO_SMALL的
返回:0000 0001 0000 0000 0000 0001 0000 0000
View#resolveSizeAndState
public static final int MEASURED_STATE_TOO_SMALL = 0x01000000; public static int resolveSizeAndState(int size, int measureSpec, int childMeasuredState) { //计算父view传递的size和mode final int specMode = MeasureSpec.getMode(measureSpec); final int specSize = MeasureSpec.getSize(measureSpec); final int result; switch (specMode) { case MeasureSpec.AT_MOST: if (specSize < size) { //如果父View给的size小于自身测绘出的size, //则在第24位上加上measure_state标记。 result = specSize | MEASURED_STATE_TOO_SMALL; } else { result = size; } break; case MeasureSpec.EXACTLY: result = specSize; break; case MeasureSpec.UNSPECIFIED: default: result = size; } //如果child在第24为上有measure_state标记,则在result的第24位上也加上measure_state标记,然后返回result。 return result | (childMeasuredState & MEASURED_STATE_MASK); } |
View#setMeasuredDimension
该方法将计算好的measuredWidth和measuredHeight设置给成员变量mMeasuredWidth及mMeasuredHeight,并且将flag设置成PFLAG_MEASURED_DIMENSION_SET。
在4.3版本以上,如果设置了optical模式,则还要对width、height进一步修改,然后再设置mMeasuredWidth、mMeasuredHeight。
mMeasuredWidth和mMeasuredHeight的值,不光包括size,同时还包括state,具体请看getMeasuredWidth
、getMeasuredWidthAndState
、getMeasuredHeight
、getMeasuredHeightAndState
方法
protected final void setMeasuredDimension(int measuredWidth, int measuredHeight) { boolean optical = isLayoutModeOptical(this); if (optical != isLayoutModeOptical(mParent)) { Insets insets = getOpticalInsets(); int opticalWidth = insets.left + insets.right; int opticalHeight = insets.top + insets.bottom; measuredWidth += optical ? opticalWidth : -opticalWidth; measuredHeight += optical ? opticalHeight : -opticalHeight; } setMeasuredDimensionRaw(measuredWidth, measuredHeight); } private void setMeasuredDimensionRaw(int measuredWidth, int measuredHeight) { mMeasuredWidth = measuredWidth; mMeasuredHeight = measuredHeight; mPrivateFlags |= PFLAG_MEASURED_DIMENSION_SET; } |
时序图
小结
到这里,关于View的测绘我们大概的走了一遍。Measure的原理就是通过遍历,从上至下,利用传递的MeasureSpec以及子View的LayoutParams,依次进行测绘。不同的layout可能会进行多次的measure,所以熟读源码,合理布局,可以帮我们避免不必要的measure开销,达到提升性能的效果。
最后,感谢阅读,也希望可以和大家多多交流,共同进步。