If you want to ensure that `viewA`

is simultaneously at least as wide as both `viewB`

and `viewC`

, then use two separate VFL statements, `@"H:[viewA(>=viewB)]"`

and `@"H:[viewA(>=viewC)]"`

.

If you also want to ensure that A will not be wider than the maximum width of `viewB`

and/or `viewC`

, you would define an optional constraint (i.e. lower priority than `UILayoutPriorityRequired`

) for the width of `viewA`

to be equal to one of them, e.g.:

```
NSLayoutConstraint *constraint = [NSLayoutConstraint constraintWithItem:viewA
attribute:NSLayoutAttributeWidth
relatedBy:NSLayoutRelationEqual
toItem:viewB
attribute:NSLayoutAttributeWidth
multiplier:1.0
constant:0.0];
constraint.priority = UILayoutPriorityDefaultLow;
[viewA.superview addConstraint:constraint];
```

According to the documentation for `priority`

:

If a constraint 'a == b' is optional, the constraint-based layout system will attempt to minimize 'abs(a-b)'.

Thus, if `viewB`

is larger than `viewC`

, this optional constraint will be satisfied and `viewA`

will be as wide as `viewB`

. If `viewB`

is smaller than `viewC`

, the constraint system will satisfy the required `@"H:[viewA(>=viewC)]"`

constraint, but then will also minimize the `abs(a-b)`

, effectively making `viewA`

the same width as `viewC`

.

In practice, you probably don't need this optional `viewA==viewB`

constraint, but if you want to ensure that `viewA`

won't be wider than both `viewB`

and `viewC`

, then add this final optional constraint.