Remember that `a += x`

really means `a = a + x`

. The key point to understand is that **addition is evaluated from left to right** -- that is, the `a`

in `a + x`

is evaluated before `x`

.

So let's figure out what `b = (a += (a += a))`

does. First we use the rule `a += x`

means `a = a + x`

, and then we start evaluating the expression carefully in the correct order:

`b = (a = a + (a = a + a))`

because `a += x`

means `a = a + x`

`b = (a = 1 + (a = a + a))`

because `a`

is currently `1`

. Remember we evaluate the left term `a`

before the right term `(a = a + a)`

`b = (a = 1 + (a = 1 + a))`

because `a`

is still `1`

`b = (a = 1 + (a = 1 + 1))`

because `a`

is still `1`

`b = (a = 1 + (a = 2))`

because `1 + 1`

is `2`

`b = (a = 1 + 2)`

because `a`

is now `2`

`b = (a = 3)`

because `1 + 2`

is `3`

`b = 3`

because `a`

is now `3`

This leaves us with `a = 3`

and `b = 3`

as reasoned above.

Let's try this with the other expression, `b = (a += a) + (a += a)`

:

`b = (a = a + a) + (a = a + a)`

`b = (a = 1 + 1) + (a = a + a)`

, remember we evaluate the left term before the right one
`b = (a = 2) + (a = a + a)`

`b = 2 + (a = a + a)`

and `a`

is now 2. Start evaluating the right term
`b = 2 + (a = 2 + 2)`

`b = 2 + (a = 4)`

`b = 2 + 4`

and `a`

is now `4`

`b = 6`

This leaves us with `a = 4`

and `b = 6`

. This can be verified by printing out both `a`

and `b`

in Java/JavaScript (both have the same behavior here).

It might also help to think of these expressions as parse trees. When we evaluate `a + (b + c)`

, the LHS `a`

is evaluated before the RHS `(b + c)`

. This is encoded in the tree structure:

```
+
/ \
a +
/ \
b c
```

Note that we don't have any parentheses anymore -- the order of operations is encoded into the tree structure. When we evaluate the nodes in the tree, we process the node's children in a **fixed order** (i.e., left-to-right for `+`

). For instance, when we process the root node `+`

, we evaluate the left subtree `a`

before the right subtree `(b + c)`

, regardless of whether the right subtree is enclosed in parentheses or not (since the parentheses aren't even present in the parse tree).

Because of this, Java/JavaScript do **not** always evaluate the "most nested parentheses" first, in contrast to rules you might have been taught for arithmetic.

See the Java Language Specification:

## 15.7. Evaluation Order

The Java programming language guarantees that the operands of operators appear to be evaluated in a specific *evaluation order*, namely, from left to right.

...

### 15.7.1. Evaluate Left-Hand Operand First

The left-hand operand of a binary operator appears to be fully evaluated before any part of the right-hand operand is evaluated.

If the operator is a compound-assignment operator (§15.26.2), then evaluation of the left-hand operand includes both remembering the variable that the left-hand operand denotes and fetching and saving that variable's value for use in the implied binary operation.

More examples similar to your question can be found in the linked part of the JLS, such as:

**Example 15.7.1-1. Left-Hand Operand Is Evaluated First**

In the following program, the * operator has a left-hand operand that
contains an assignment to a variable and a right-hand operand that
contains a reference to the same variable. The value produced by the
reference will reflect the fact that the assignment occurred first.

```
class Test1 {
public static void main(String[] args) {
int i = 2;
int j = (i=3) * i;
System.out.println(j);
}
}
```

This program produces the output:

```
9
```

It is not permitted for evaluation of the * operator to produce 6
instead of 9.

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