Operator precedence is defined in the appropriate standard. The standards for C and C++ are the One True Definition of what exactly C and C++ are. So if you look closely, the details are there. In fact, the details are in the *grammar* of the language. For example, take a look at the grammar production rule for `+`

and `-`

in C++ (collectively, *additive-expressions*):

```
additive-expression:
multiplicative-expression
additive-expression + multiplicative-expression
additive-expression - multiplicative-expression
```

As you can see, a *multiplicative-expression* is a subrule of an *additive-expression*. This means that if you have something like `x + y * z`

, the `y * z`

expression is a subexpression of `x + y * z`

. This defines the **precedence** between these two operators.

We can also see that the left operand of an *additive-expression* expands to another *additive-expression*, which means that with `x + y + z`

, `x + y`

is a subexpression of it. This defines the **associativity**.

Associativity determines how adjacent uses of the same operator will be grouped. For example, `+`

is left-to-right associative, which means that `x + y + z`

will be grouped like so: `(x + y) + z`

.

**Don't mistake this for order of evaluation**. There is absolutely no reason why the value of `z`

could not be computed before `x + y`

is. What matters is that it is `x + y`

that is computed and not `y + z`

.

For the function call operator, left-to-right associativity means that `f()()`

(which could happen if `f`

returned a function pointer, for example) is grouped like so: `(f())()`

(of course, the other direction wouldn't make any sense).

Now let's consider the example you were looking at:

```
f1() + f2() * f3()
```

The `*`

operator has higher precedence than the `+`

operator, so the expressions are grouped like so:

```
f1() + (f2() * f3())
```

We don't even have to consider associativity here, because we don't have any of the same operator adjacent to each other.

Evaluation of the functions call expressions is, however, completely unsequenced. There's no reason `f3`

couldn't be called first, then `f1`

, and then `f2`

. The only requirement in this case is that operands of an operator are evaluated before the operator is. So that would mean `f2`

and `f3`

have to be called before the `*`

is evaluated and the `*`

must be evaluated and `f1`

must be called before the `+`

is evaluated.

Some operators do, however, impose a sequencing on the evaluation of their operands. For example, in `x && y`

, `x`

is always evaluated before `y`

. This allows for short-circuiting, where `y`

does not need to be evaluated if `x`

is known already to be `true`

.

The order of evaluation was previously defined in C and C++ with the use of *sequence points*, and both have changed terminology to define things in terms of a *sequenced before* relationship. For more information, see Undefined Behaviour and Sequence Points.

`10 + 10 * 10`

- from left to right that's`10 + 10 = 20`

,`20 * 10 = 200`

. with proper precedence it's`10 + (10 * 10) = 110`

. I'm not sure if those operators add a sequence point, so the order of the function execution might be arbitrary. – ThiefMaster♦ Dec 24 '13 at 23:31`=`

operator inside`?:`

operator, which means that precedence rules of C and C++ are different. Any table that claims to apply to both C and C++ is inaccurate. And secondly, the precedence properties of`?:`

operator can't generally be linearized, meaning that any linear table will always be inaccurate with regard to`?:`

operator. – AndreyT Dec 25 '13 at 0:59