如何优化你的布局层级结构之RelativeLayout和LinearLayout及FrameLayout性能分析

出处：http://blog.csdn.net/hejjunlin/article/details/51159419

工作一段时间后，经常会被领导说，你这个进入速度太慢了，竞品的进入速度很快，你搞下优化吧？每当这时，你会怎么办？功能实现都有啊，进入时要加载那么多view，这也没办法啊，等等。

先看一些现象吧：用Android studio，新建一个Activity自动生成的布局文件都是RelativeLayout，或许你会认为这是IDE的默认设置问题，其实不然，这是由
android-sdk\tools\templates\activities\EmptyActivity\root\res\layout\activity_simple.xml.ftl 这个文件事先就定好了的，也就是说这是Google的选择，而非IDE的选择。那SDK为什么会默认给开发者新建一个默认的RelativeLayout布局呢？当然是因为RelativeLayout的性能更优，性能至上嘛。但是我们再看看默认新建的这个RelativeLayout的父容器，也就是当前窗口的顶级View——DecorView，它却是个垂直方向的LinearLayout，上面是标题栏，下面是内容栏。那么问题来了，Google为什么给开发者默认新建了个RelativeLayout，而自己却偷偷用了个LinearLayout，到底谁的性能更高，开发者该怎么选择呢？

View的一些基本工作原理

先通过几个问题，简单的了解写android中View的工作原理吧。

View是什么？

简单来说，View是Android系统在屏幕上的视觉呈现，也就是说你在手机屏幕上看到的东西都是View。

View是怎么绘制出来的？

View的绘制流程是从ViewRoot的performTraversals（）方法开始，依次经过measure（），layout（）和draw（）三个过程才最终将一个View绘制出来。

View是怎么呈现在界面上的？

Android中的视图都是通过Window来呈现的，不管Activity、Dialog还是Toast它们都有一个Window，然后通过WindowManager来管理View。Window和顶级View——DecorView的通信是依赖ViewRoot完成的。

View和ViewGroup什么区别？

不管简单的Button和TextView还是复杂的RelativeLayout和ListView，他们的共同基类都是View。所以说，View是一种界面层控件的抽象，他代表了一个控件。那ViewGroup是什么东西，它可以被翻译成控件组，即一组View。ViewGroup也是继承View，这就意味着View本身可以是单个控件，也可以是多个控件组成的控件组。根据这个理论，Button显然是个View，而RelativeLayout不但是一个View还可以是一个ViewGroup，而ViewGroup内部是可以有子View的，这个子View同样也可能是ViewGroup，以此类推。

RelativeLayout和LinearLayout性能PK

基于以上原理和大背景，我们要探讨的性能问题，说的简单明了一点就是：当RelativeLayout和LinearLayout分别作为ViewGroup，表达相同布局时绘制在屏幕上时谁更快一点。上面已经简单说了View的绘制，从ViewRoot的performTraversals（）方法开始依次调用perfromMeasure、performLayout和performDraw这三个方法。这三个方法分别完成顶级View的measure、layout和draw三大流程，其中perfromMeasure会调用measure，measure又会调用onMeasure，在onMeasure方法中则会对所有子元素进行measure，这个时候measure流程就从父容器传递到子元素中了，这样就完成了一次measure过程，接着子元素会重复父容器的measure，如此反复就完成了整个View树的遍历。同理，performLayout和performDraw也分别完成perfromMeasure类似的流程。通过这三大流程，分别遍历整棵View树，就实现了Measure，Layout，Draw这一过程，View就绘制出来了。那么我们就分别来追踪下RelativeLayout和LinearLayout这三大流程的执行耗时。

如下图，我们分别用两用种方式简单的实现布局测试下




LinearLayout

Measure：0.762ms

Layout：0.167ms

draw：7.665ms

RelativeLayout

Measure：2.180ms

Layout：0.156ms

draw：7.694ms

从这个数据来看无论使用RelativeLayout还是LinearLayout，layout和draw的过程两者相差无几，考虑到误差的问题，几乎可以认为两者不分伯仲，关键是Measure的过程RelativeLayout却比LinearLayout慢了一大截。

Measure都干什么了

RelativeLayout的onMeasure()方法

[java] view
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@Override

protected void onMeasure(int widthMeasureSpec, int heightMeasureSpec) {

if (mDirtyHierarchy) {

mDirtyHierarchy = false;

sortChildren();

}

int myWidth = -1;

int myHeight = -1;

int width = 0;

int height = 0;

final int widthMode = MeasureSpec.getMode(widthMeasureSpec);

final int heightMode = MeasureSpec.getMode(heightMeasureSpec);

final int widthSize = MeasureSpec.getSize(widthMeasureSpec);

final int heightSize = MeasureSpec.getSize(heightMeasureSpec);

// Record our dimensions if they are known;

if (widthMode != MeasureSpec.UNSPECIFIED) {

myWidth = widthSize;

}

if (heightMode != MeasureSpec.UNSPECIFIED) {

myHeight = heightSize;

}

if (widthMode == MeasureSpec.EXACTLY) {

width = myWidth;

}

if (heightMode == MeasureSpec.EXACTLY) {

height = myHeight;

}

View ignore = null;

int gravity = mGravity & Gravity.RELATIVE_HORIZONTAL_GRAVITY_MASK;

final boolean horizontalGravity = gravity != Gravity.START && gravity != 0;

gravity = mGravity & Gravity.VERTICAL_GRAVITY_MASK;

final boolean verticalGravity = gravity != Gravity.TOP && gravity != 0;

int left = Integer.MAX_VALUE;

int top = Integer.MAX_VALUE;

int right = Integer.MIN_VALUE;

int bottom = Integer.MIN_VALUE;

boolean offsetHorizontalAxis = false;

boolean offsetVerticalAxis = false;

if ((horizontalGravity || verticalGravity) && mIgnoreGravity != View.NO_ID) {

ignore = findViewById(mIgnoreGravity);

}

final boolean isWrapContentWidth = widthMode != MeasureSpec.EXACTLY;

final boolean isWrapContentHeight = heightMode != MeasureSpec.EXACTLY;

// We need to know our size for doing the correct computation of children positioning in RTL

// mode but there is no practical way to get it instead of running the code below.

// So, instead of running the code twice, we just set the width to a "default display width"

// before the computation and then, as a last pass, we will update their real position with

// an offset equals to "DEFAULT_WIDTH - width".

final int layoutDirection = getLayoutDirection();

if (isLayoutRtl() && myWidth == -1) {

myWidth = DEFAULT_WIDTH;

}

View[] views = mSortedHorizontalChildren;

int count = views.length;

for (int i = 0; i < count; i++) {

View child = views[i];

if (child.getVisibility() != GONE) {

LayoutParams params = (LayoutParams) child.getLayoutParams();

int[] rules = params.getRules(layoutDirection);

applyHorizontalSizeRules(params, myWidth, rules);

measureChildHorizontal(child, params, myWidth, myHeight);

if (positionChildHorizontal(child, params, myWidth, isWrapContentWidth)) {

offsetHorizontalAxis = true;

}

}

}

views = mSortedVerticalChildren;

count = views.length;

final int targetSdkVersion = getContext().getApplicationInfo().targetSdkVersion;

for (int i = 0; i < count; i++) {

final View child = views[i];

if (child.getVisibility() != GONE) {

final LayoutParams params = (LayoutParams) child.getLayoutParams();

applyVerticalSizeRules(params, myHeight, child.getBaseline());

measureChild(child, params, myWidth, myHeight);

if (positionChildVertical(child, params, myHeight, isWrapContentHeight)) {

offsetVerticalAxis = true;

}

if (isWrapContentWidth) {

if (isLayoutRtl()) {

if (targetSdkVersion < Build.VERSION_CODES.KITKAT) {

width = Math.max(width, myWidth - params.mLeft);

} else {

width = Math.max(width, myWidth - params.mLeft - params.leftMargin);

}

} else {

if (targetSdkVersion < Build.VERSION_CODES.KITKAT) {

width = Math.max(width, params.mRight);

} else {

width = Math.max(width, params.mRight + params.rightMargin);

}

}

}

if (isWrapContentHeight) {

if (targetSdkVersion < Build.VERSION_CODES.KITKAT) {

height = Math.max(height, params.mBottom);

} else {

height = Math.max(height, params.mBottom + params.bottomMargin);

}

}

if (child != ignore || verticalGravity) {

left = Math.min(left, params.mLeft - params.leftMargin);

top = Math.min(top, params.mTop - params.topMargin);

}

if (child != ignore || horizontalGravity) {

right = Math.max(right, params.mRight + params.rightMargin);

bottom = Math.max(bottom, params.mBottom + params.bottomMargin);

}

}

}

// Use the top-start-most laid out view as the baseline. RTL offsets are

// applied later, so we can use the left-most edge as the starting edge.

View baselineView = null;

LayoutParams baselineParams = null;

for (int i = 0; i < count; i++) {

final View child = views[i];

if (child.getVisibility() != GONE) {

final LayoutParams childParams = (LayoutParams) child.getLayoutParams();

if (baselineView == null || baselineParams == null

|| compareLayoutPosition(childParams, baselineParams) < 0) {

baselineView = child;

baselineParams = childParams;

}

}

}

mBaselineView = baselineView;

if (isWrapContentWidth) {

// Width already has left padding in it since it was calculated by looking at

// the right of each child view

width += mPaddingRight;

if (mLayoutParams != null && mLayoutParams.width >= 0) {

width = Math.max(width, mLayoutParams.width);

}

width = Math.max(width, getSuggestedMinimumWidth());

width = resolveSize(width, widthMeasureSpec);

if (offsetHorizontalAxis) {

for (int i = 0; i < count; i++) {

final View child = views[i];

if (child.getVisibility() != GONE) {

final LayoutParams params = (LayoutParams) child.getLayoutParams();

final int[] rules = params.getRules(layoutDirection);

if (rules[CENTER_IN_PARENT] != 0 || rules[CENTER_HORIZONTAL] != 0) {

centerHorizontal(child, params, width);

} else if (rules[ALIGN_PARENT_RIGHT] != 0) {

final int childWidth = child.getMeasuredWidth();

params.mLeft = width - mPaddingRight - childWidth;

params.mRight = params.mLeft + childWidth;

}

}

}

}

}

if (isWrapContentHeight) {

// Height already has top padding in it since it was calculated by looking at

// the bottom of each child view

height += mPaddingBottom;

if (mLayoutParams != null && mLayoutParams.height >= 0) {

height = Math.max(height, mLayoutParams.height);

}

height = Math.max(height, getSuggestedMinimumHeight());

height = resolveSize(height, heightMeasureSpec);

if (offsetVerticalAxis) {

for (int i = 0; i < count; i++) {

final View child = views[i];

if (child.getVisibility() != GONE) {

final LayoutParams params = (LayoutParams) child.getLayoutParams();

final int[] rules = params.getRules(layoutDirection);

if (rules[CENTER_IN_PARENT] != 0 || rules[CENTER_VERTICAL] != 0) {

centerVertical(child, params, height);

} else if (rules[ALIGN_PARENT_BOTTOM] != 0) {

final int childHeight = child.getMeasuredHeight();

params.mTop = height - mPaddingBottom - childHeight;

params.mBottom = params.mTop + childHeight;

}

}

}

}

}

if (horizontalGravity || verticalGravity) {

final Rect selfBounds = mSelfBounds;

selfBounds.set(mPaddingLeft, mPaddingTop, width - mPaddingRight,

height - mPaddingBottom);

final Rect contentBounds = mContentBounds;

Gravity.apply(mGravity, right - left, bottom - top, selfBounds, contentBounds,

layoutDirection);

final int horizontalOffset = contentBounds.left - left;

final int verticalOffset = contentBounds.top - top;

if (horizontalOffset != 0 || verticalOffset != 0) {

for (int i = 0; i < count; i++) {

final View child = views[i];

if (child.getVisibility() != GONE && child != ignore) {

final LayoutParams params = (LayoutParams) child.getLayoutParams();

if (horizontalGravity) {

params.mLeft += horizontalOffset;

params.mRight += horizontalOffset;

}

if (verticalGravity) {

params.mTop += verticalOffset;

params.mBottom += verticalOffset;

}

}

}

}

}

if (isLayoutRtl()) {

final int offsetWidth = myWidth - width;

for (int i = 0; i < count; i++) {

final View child = views[i];

if (child.getVisibility() != GONE) {

final LayoutParams params = (LayoutParams) child.getLayoutParams();

params.mLeft -= offsetWidth;

params.mRight -= offsetWidth;

}

}

}

setMeasuredDimension(width, height);

}

根据源码我们发现RelativeLayout会对子View做两次measure。这是为什么呢？首先RelativeLayout中子View的排列方式是基于彼此的依赖关系，而这个依赖关系可能和布局中View的顺序并不相同，在确定每个子View的位置的时候，就需要先给所有的子View排序一下。又因为RelativeLayout允许A，B 2个子View，横向上B依赖A，纵向上A依赖B。所以需要横向纵向分别进行一次排序测量。

LinearLayout的onMeasure()方法

[java] view
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@Override

protected void onMeasure(int widthMeasureSpec, int heightMeasureSpec) {

if (mOrientation == VERTICAL) {

measureVertical(widthMeasureSpec, heightMeasureSpec);

} else {

measureHorizontal(widthMeasureSpec, heightMeasureSpec);

}

}

与RelativeLayout相比LinearLayout的measure就简单明了的多了，先判断线性规则，然后执行对应方向上的测量。随便看一个吧。

[java] view
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for (int i = 0; i < count; ++i) {

final View child = getVirtualChildAt(i);

if (child == null) {

mTotalLength += measureNullChild(i);

continue;

}

if (child.getVisibility() == View.GONE) {

i += getChildrenSkipCount(child, i);

continue;

}

if (hasDividerBeforeChildAt(i)) {

mTotalLength += mDividerHeight;

}

LinearLayout.LayoutParams lp = (LinearLayout.LayoutParams) child.getLayoutParams();

totalWeight += lp.weight;

if (heightMode == MeasureSpec.EXACTLY && lp.height == 0 && lp.weight > 0) {

// Optimization: don't bother measuring children who are going to use

// leftover space. These views will get measured again down below if

// there is any leftover space.

final int totalLength = mTotalLength;

mTotalLength = Math.max(totalLength, totalLength + lp.topMargin + lp.bottomMargin);

} else {

int oldHeight = Integer.MIN_VALUE;

if (lp.height == 0 && lp.weight > 0) {

// heightMode is either UNSPECIFIED or AT_MOST, and this

// child wanted to stretch to fill available space.

// Translate that to WRAP_CONTENT so that it does not end up

// with a height of 0

oldHeight = 0;

lp.height = LayoutParams.WRAP_CONTENT;

}

// Determine how big this child would like to be. If this or

// previous children have given a weight, then we allow it to

// use all available space (and we will shrink things later

// if needed).

measureChildBeforeLayout(

child, i, widthMeasureSpec, 0, heightMeasureSpec,

totalWeight == 0 ? mTotalLength : 0);

if (oldHeight != Integer.MIN_VALUE) {

lp.height = oldHeight;

}

final int childHeight = child.getMeasuredHeight();

final int totalLength = mTotalLength;

mTotalLength = Math.max(totalLength, totalLength + childHeight + lp.topMargin +

lp.bottomMargin + getNextLocationOffset(child));

if (useLargestChild) {

largestChildHeight = Math.max(childHeight, largestChildHeight);

}

}

父视图在对子视图进行measure操作的过程中，使用变量mTotalLength保存已经measure过的child所占用的高度，该变量刚开始时是0。在for循环中调用measureChildBeforeLayout（）对每一个child进行测量，该函数实际上仅仅是调用了measureChildWithMargins(),在调用该方法时，使用了两个参数。其中一个是heightMeasureSpec，该参数为LinearLayout本身的measureSpec；另一个参数就是mTotalLength，代表该LinearLayout已经被其子视图所占用的高度。
每次for循环对child测量完毕后，调用child.getMeasuredHeight()获取该子视图最终的高度，并将这个高度添加到mTotalLength中。在本步骤中，暂时避开了lp.weight>0的子视图，即暂时先不测量这些子视图，因为后面将把父视图剩余的高度按照weight值的大小平均分配给相应的子视图。源码中使用了一个局部变量totalWeight累计所有子视图的weight值。处理lp.weight>0的情况需要注意，如果变量heightMode是EXACTLY，那么，当其他子视图占满父视图的高度后，weight>0的子视图可能分配不到布局空间，从而不被显示，只有当heightMode是AT_MOST或者UNSPECIFIED时，weight>0的视图才能优先获得布局高度。最后我们的结论是：如果不使用weight属性，LinearLayout会在当前方向上进行一次measure的过程，如果使用weight属性，LinearLayout会避开设置过weight属性的view做第一次measure，完了再对设置过weight属性的view做第二次measure。由此可见，weight属性对性能是有影响的，而且本身有大坑，请注意避让。

小结

从源码中我们似乎能看出，我们先前的测试结果中RelativeLayout不如LinearLayout快的根本原因是RelativeLayout需要对其子View进行两次measure过程。而LinearLayout则只需一次measure过程，所以显然会快于RelativeLayout，但是如果LinearLayout中有weight属性，则也需要进行两次measure，但即便如此，应该仍然会比RelativeLayout的情况好一点。

RelativeLayout另一个性能问题

对比到这里就结束了嘛？显然没有！我们再看看View的Measure（）方法都干了些什么？

[java] view
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public final void measure(int widthMeasureSpec, int heightMeasureSpec) {

if ((mPrivateFlags & PFLAG_FORCE_LAYOUT) == PFLAG_FORCE_LAYOUT ||

widthMeasureSpec != mOldWidthMeasureSpec ||

heightMeasureSpec != mOldHeightMeasureSpec) {

......

}

mOldWidthMeasureSpec = widthMeasureSpec;

mOldHeightMeasureSpec = heightMeasureSpec;

mMeasureCache.put(key, ((long) mMeasuredWidth) << 32 |

(long) mMeasuredHeight & 0xffffffffL); // suppress sign extension

}

View的measure方法里对绘制过程做了一个优化，如果我们或者我们的子View没有要求强制刷新，而父View给子View的传入值也没有变化（也就是说子View的位置没变化），就不会做无谓的measure。但是上面已经说了RelativeLayout要做两次measure，而在做横向的测量时，纵向的测量结果尚未完成，只好暂时使用myHeight传入子View系统，假如子View的Height不等于（设置了margin）myHeight的高度，那么measure中上面代码所做得优化将不起作用，这一过程将进一步影响RelativeLayout的绘制性能。而LinearLayout则无这方面的担忧。解决这个问题也很好办，如果可以，尽量使用padding代替margin。

FrameLayout和LinearLayout性能PK

FrameLayout




LinearLayout

Measure：2.058ms

Layout：0.296ms

draw：3.857ms

FrameLayout

Measure：1.334ms

Layout：0.213ms

draw：3.680ms

从这个数据来使用LinearLayout，仅嵌套一个LinearLayou，在onMeasure就相关2倍时间和FrameLayout相比，layout和draw的过程两者相差无几，考虑到误差的问题，几乎可以认为两者不分伯仲

看下FrameLayout的源码，做了什么？

[java] view
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protected void onMeasure(int widthMeasureSpec, int heightMeasureSpec) {

int count = getChildCount();

final boolean measureMatchParentChildren =

MeasureSpec.getMode(widthMeasureSpec) != MeasureSpec.EXACTLY ||

MeasureSpec.getMode(heightMeasureSpec) != MeasureSpec.EXACTLY;

//当FrameLayout的宽和高，只有同时设置为match_parent或者指定的size，那么这个

//measureMatchParentChlidren = false，否则为true。下面会用到这个变量

mMatchParentChildren.clear();

int maxHeight = 0;

int maxWidth = 0;

int childState = 0; //宽高的期望类型

for (int i = 0; i < count; i++) { //一次遍历每一个不为GONE的子view

final View child = getChildAt(i);

if (mMeasureAllChildren || child.getVisibility() != GONE) {

//去掉FrameLayout的左右padding，子view的左右margin，这时候，再去

//计算子view的期望的值

measureChildWithMargins(child, widthMeasureSpec, 0, heightMeasureSpec, 0);

final LayoutParams lp = (LayoutParams) child.getLayoutParams();

/*maxWidth找到子View中最大的宽，高同理，为什么要找到他，因为在这里，FrameLayout是wrap

-content.他的宽高肯定受子view的影响*/

maxWidth = Math.max(maxWidth,

child.getMeasuredWidth() + lp.leftMargin + lp.rightMargin);

maxHeight = Math.max(maxHeight,

child.getMeasuredHeight() + lp.topMargin + lp.bottomMargin);

childState = combineMeasuredStates(childState, child.getMeasuredState());

/*下面的判断，只有上面的FragLayout的width和height都设置为match_parent 才不会执行

此处的mMatchParentChlidren的list里存的是设置为match_parent的子view。

结合上面两句话的意思，当FrameLayout设置为wrap_content，这时候要把所有宽高设置为

match_parent的子View都记录下来，记录下来干什么呢？

这时候FrameLayout的宽高同时受子View的影响*/

if (measureMatchParentChildren) {

if (lp.width == LayoutParams.MATCH_PARENT ||

lp.height == LayoutParams.MATCH_PARENT) {

mMatchParentChildren.add(child);

}

}

}

}

// Account for padding too

maxWidth += getPaddingLeftWithForeground() + getPaddingRightWithForeground();

maxHeight += getPaddingTopWithForeground() + getPaddingBottomWithForeground();

// Check against our minimum height and width

maxHeight = Math.max(maxHeight, getSuggestedMinimumHeight());

maxWidth = Math.max(maxWidth, getSuggestedMinimumWidth());

// Check against our foreground's minimum height and width

final Drawable drawable = getForeground();

if (drawable != null) {

maxHeight = Math.max(maxHeight, drawable.getMinimumHeight());

maxWidth = Math.max(maxWidth, drawable.getMinimumWidth());

}

//设置测量过的宽高

setMeasuredDimension(resolveSizeAndState(maxWidth, widthMeasureSpec, childState),

resolveSizeAndState(maxHeight, heightMeasureSpec,

childState << MEASURED_HEIGHT_STATE_SHIFT));

count = mMatchParentChildren.size();//这个大小就是子view中设定为match_parent的个数

if (count > 1) {

for (int i = 0; i < count; i++) {

//这里看上去重新计算了一遍

final View child = mMatchParentChildren.get(i);

final MarginLayoutParams lp = (MarginLayoutParams) child.getLayoutParams();

int childWidthMeasureSpec;

int childHeightMeasureSpec;

/*如果子view的宽是match_parent，则宽度期望值是总宽度-padding-margin

如果子view的宽是指定的比如100dp，则宽度期望值是padding+margin+width

这个很容易理解,下面的高同理*/

if (lp.width == LayoutParams.MATCH_PARENT) {

childWidthMeasureSpec = MeasureSpec.makeMeasureSpec(getMeasuredWidth() -

getPaddingLeftWithForeground() - getPaddingRightWithForeground() -

lp.leftMargin - lp.rightMargin,

MeasureSpec.EXACTLY);

} else {

childWidthMeasureSpec = getChildMeasureSpec(widthMeasureSpec,

getPaddingLeftWithForeground() + getPaddingRightWithForeground() +

lp.leftMargin + lp.rightMargin,

lp.width);

}

if (lp.height == LayoutParams.MATCH_PARENT) {

childHeightMeasureSpec = MeasureSpec.makeMeasureSpec(getMeasuredHeight() -

getPaddingTopWithForeground() - getPaddingBottomWithForeground() -

lp.topMargin - lp.bottomMargin,

MeasureSpec.EXACTLY);

} else {

childHeightMeasureSpec = getChildMeasureSpec(heightMeasureSpec,

getPaddingTopWithForeground() + getPaddingBottomWithForeground() +

lp.topMargin + lp.bottomMargin,

lp.height);

}

//把这部分子view重新计算大小

child.measure(childWidthMeasureSpec, childHeightMeasureSpec);

}

}

}

加了一个嵌套，onMeasure时间，多了将近一倍，原因在于：LinearLayout在某一方向onMeasure，发现还存在LinearLayout。将触发

[java] view
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if (useLargestChild && (heightMode == MeasureSpec.AT_MOST || heightMode == MeasureSpec.UNSPECIFIED)) {

mTotalLength = 0;

for (int i = 0; i < count; ++i) {

final View child = getVirtualChildAt(i);

if (child == null) {

mTotalLength += measureNullChild(i);

continue;

}

if (child.getVisibility() == GONE) {

i += getChildrenSkipCount(child, i);

continue;

}

}

因为二级LinearLayout父类是Match_parent，所以就存在再层遍历。在时间就自然存在消耗。

结论

1.RelativeLayout会让子View调用2次onMeasure，LinearLayout 在有weight时，也会调用子View2次onMeasure

2.RelativeLayout的子View如果高度和RelativeLayout不同，则会引发效率问题，当子View很复杂时，这个问题会更加严重。如果可以，尽量使用padding代替margin。

3.在不影响层级深度的情况下,使用LinearLayout和FrameLayout而不是RelativeLayout。

最后再思考一下文章开头那个矛盾的问题，为什么Google给开发者默认新建了个RelativeLayout，而自己却在DecorView中用了个LinearLayout。因为DecorView的层级深度是已知而且固定的，上面一个标题栏，下面一个内容栏。采用RelativeLayout并不会降低层级深度，所以此时在根节点上用LinearLayout是效率最高的。而之所以给开发者默认新建了个RelativeLayout是希望开发者能采用尽量少的View层级来表达布局以实现性能最优，因为复杂的View嵌套对性能的影响会更大一些。

4.能用两层LinearLayout，尽量用一个RelativeLayout，在时间上此时RelativeLayout耗时更小。另外LinearLayout慎用layout_weight,也将会增加一倍耗时操作。由于使用LinearLayout的layout_weight,大多数时间是不一样的，这会降低测量的速度。这只是一个如何合理使用Layout的案例，必要的时候，你要小心考虑是否用layout weight。总之减少层级结构，才是王道，让onMeasure做延迟加载，用viewStub，include等一些技巧

布局重用<include />

减少视图层级<merge />

需要时使用<ViewStub />