Let me say this very clearly, because people misunderstand this all the time:

**Order of evaluation of subexpressions is ***independent* of both associativity and precedence. Associativity and precedence determine in what order the *operators* are executed but **do not** determine in what order the *subexpressions* are evaluated. Your question is about the order in which *subexpressions* are evaluated.

Consider `A() + B() + C() * D()`

. Multiplication is higher precedence than addition, and addition is left-associative, so this is equivalent to `(A() + B()) + (C() * D())`

But knowing that only tells you that the first addition will happen before the second addition, and that the multiplication will happen before the second addition. **It does not tell you in what order A(), B(), C() and D() will be called!** (It also does not tell you whether the multiplication happens before or after the first addition.) It would be perfectly possible to obey the rules of *precedence and associativity* by compiling this as:

```
d = D() // these four computations can happen in any order
b = B()
c = C()
a = A()
sum = a + b // these two computations can happen in any order
product = c * d
result = sum + product // this has to happen last
```

All the rules of precedence and associativity are followed there -- the first addition happens before the second addition, and the multiplication happens before the second addition. Clearly we can do the calls to A(), B(), C() and D() in *any* order and still obey the rules of precedence and associativity!

We need a rule *unrelated* to the rules of precedence and associativity to explain the order in which the subexpressions are evaluated. **The relevant rule in Java (and C#) is "subexpressions are evaluated left to right".** Since A() appears to the left of C(), A() is evaluated first, *regardless of the fact that C() is involved in a multiplication and A() is involved only in an addition.*

So now you have enough information to answer your question. In `a[b] = b = 0`

the rules of associativity say that this is `a[b] = (b = 0);`

but that does not mean that the `b=0`

runs first! The rules of precedence say that indexing is higher precedence than assignment, but **that does not mean that the indexer runs before the rightmost assignment**.

(UPDATE: An earlier version of this answer had some small and practically unimportant omissions in the section which follows which I have corrected. I've also written a blog article describing why these rules are sensible in Java and C# here: https://ericlippert.com/2019/01/18/indexer-error-cases/)

Precedence and associativity only tell us that *the assignment of zero* to `b`

must happen *before* the assignment to `a[b]`

, because the assignment of zero computes the value that is assigned in the indexing operation. Precedence and associativity alone say nothing about whether the `a[b]`

is evaluated *before* or *after* the `b=0`

.

Again, this is just the same as: `A()[B()] = C()`

-- All we know is that the indexing has to happen before the assignment. We don't know whether A(), B(), or C() runs first *based on precedence and associativity*. We need another rule to tell us that.

The rule is, again, "when you have a choice about what to do first, always go left to right". However, there is an interesting wrinkle in this specific scenario. **Is the side effect of a thrown exception caused by a null collection or out-of-range index considered part of the computation of the left side of the assignment, or part of the computation of the assignment itself?** Java chooses the latter. (Of course, this is a distinction that only matters *if the code is already wrong*, because correct code does not dereference null or pass a bad index in the first place.)

So what happens?

- The
`a[b]`

is to the left of the `b=0`

, so the `a[b]`

runs *first*, resulting in `a[1]`

. However, checking the *validity* of this indexing operation is delayed.
- Then the
`b=0`

happens.
- Then the verification that
`a`

is valid and `a[1]`

is in range happens
- The assignment of the value to
`a[1]`

happens last.

So, though in this *specific* case there are some subtleties to consider for those rare error cases that should not be occurring in correct code in the first place, in general you can reason: **things to the left happen before things to the right**. That's the rule you're looking for. Talk of precedence and associativity is both confusing and irrelevant.

People get this stuff wrong *all the time*, even people who should know better. I have edited *far too many* programming books that stated the rules incorrectly, so it is no surprise that lots of people have completely incorrect beliefs about the relationship between precedence/associativity, and evaluation order -- namely, that in reality there is no such relationship; they are independent.

If this topic interests you, see my articles on the subject for further reading:

http://blogs.msdn.com/b/ericlippert/archive/tags/precedence/

They are about C#, but most of this stuff applies equally well to Java.