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I want to know: What is android:weightSum and layout weight, and how do they work?

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5 Answers

up vote 25 down vote accepted

It is better to explain with an example. You have a LinearLayout with horizontal orientation and you have three ImageViews inside it and you want these ImageViews always to take equal space. You can set the layout_weight of each ImageView to 1 and the weightSum in LinearLayout to 3 to achieve this. The good point is that this will work correctly for any device, which will not happen if you set width and height directly.

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This is not an explanation of the purpose of weightSum. The behavior in your example would be identical with weightSum omitted, and in fact weightSum should not be specified in that scenario. The documentation says, weightSum Defines the maximum weight sum. If unspecified, the sum is computed by adding the layout_weight of all of the children. –  Jeff Axelrod Oct 4 '12 at 3:26
@JeffAxelrod: It "should not" be specified? Why? I see no reason for that. So I would just say it does not need to be specified. –  Marco W. Feb 1 '13 at 11:03
@MarcoW.: It should not be specified because of maintainability. As Jeff said, setting the weightSum to be equal to the sum of the weights inside the layout accomplishes nothing, but if someone changes it in the future it could cause headaches as now there is an unnecessary modifier to the layout that would have to be found and changed. This answer is incorrect and should not be the accepted answer. –  d370urn3ur Sep 11 '13 at 12:33
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Adding on to superM's and Jeff's answer,

If there are 2 views in the LinearLayout, the first with a layout_weight of 1, the second with a layout_weight of 2 and no weightSum is specified, by default, the weightSum is calculated to be 3 (sum of the weights of the children) and the first view takes 1/3 of the space while the second takes 2/3.

However, if we were to specify the weightSum as 5, the first would take 1/5th of the space while the second would take 2/5th. So a total of 3/5th of the space would be occupied by the layout keeping the rest empty.

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The documentation says it best and includes an example, (highlighting mine).


Defines the maximum weight sum. If unspecified, the sum is computed by adding the layout_weight of all of the children. This can be used for instance to give a single child 50% of the total available space by giving it a layout_weight of 0.5 and setting the weightSum to 1.0.

So to correct superM's example, suppose you have a LinearLayout with horizontal orientation that contains two ImageViews and a TextView with. You define the TextView to have a fixed size, and you'd like the two ImageViews to take up the remaining space equally.

To accomplish this, you would apply layout_weight 1 to each ImageView, none on the TextView, and a weightSum of 2.0 on the LinearLayout.

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If unspecified, the sum is computed by adding the layout_weight of all of the children. This can be used for instance to give a single child 50% of the total available space by giving it a layout_weight of 0.5 and setting the weightSum to 1.0. Must be a floating point value, such as "1.2"

    <LinearLayout xmlns:android="http://schemas.android.com/apk/res/android"
        android:weightSum="2.0" >

            android:background="#0000FF" >

            android:background="#00FF00" >

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After some experimenting, I think the algorithm for LinearLayout is this:

Assume that weightSum is set to a value. The case of absence is discussed later.

First, divide the weightSum by the number of elements whith match_parent or fill_parent in the dimension of the LinearLayout (e.g. layout_width for orientation="horizontal"). We will call this value the weight multiplier w_m for each element. The default value for weightSum is 1.0, so the default weight multiplier is 1/n, where n is the number of fill_parent elements; wrap_content elements do not contribute to n.

w_m = weightSum / #fill_parent

E.g. when weightSum is 60, and there are 3 fill_parent elements, the weight multiplier is 20. The weight multiplier is the default value for e.g. layout_width if the attribute is absent.

Second, the maximum possible expansion of every element is computed. First, the wrap_content elements are computed according to their contents. Their expansion is deducted from the expansion of the parent container. We will call the remainer expansion_remainer. This remainder is distributed among fill_parent elements according to their layout_weight.

Third, the expansion of every fill_parent element is computed as:

w_m - ( layout_weight / w_m ) * maximum_possible_expansion


If weightSum is 60, and there are 3 fill_parent elements with the weigths 10, 20 and 30, their expansion on the screen is 2/3, 1/3 and 0/3 of the parent container.

weight | expansion
     0 | 3/3
    10 | 2/3
    20 | 1/3
    30 | 0/3
    40 | 0/3

The minimum expansion is capped at 0. The maximum expansion is capped at parent size, i.e. weights are capped at 0.

If an element is set to wrap_content, its expansion is calculated first, and the remaining expansion is subject to distribution among the fill_parent elements. If weightSum is set, this leads to layout_weight having no effect on wrap_content elements. However, wrap_content elements can still be pushed out of the visible area by elements whose weight is lower than weight multiplier (e.g. between 0-1 for weightSum= 1 or between 0-20 for the above example).

If no weightSum is specified, it is computed as the sum of all layout_weight values, including elements with wrap_content set! So having layout_weight set on wrap_content elements, can influence their expansion. E.g. a negative weight will shrink the other fill_parent elements. Before the fill_parent elements are laid out, will the above formula be applied to wrap_content elements, with maximum possible expansion being their expansion according to the wrapped content. The wrap_content elements will be shrunk, and afterwards the maximum possible expansion for the remaining fill_parent elements is computed and distributed.

This can lead to unintuitive results.

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