The *sequenced-before* relationship, and the rules concerning it are a "tidying up" of the prior rules on sequence points, defined in a consistent way with the other memory model relationships such as *happens-before* and *synchronizes-with* so that it can be precisely specified which operations and effects are visible under which circumstances.

The consequences of the rules are unchanged for simple single-threaded code.

Let's start with your examples:

## 1. `i = ++i;`

If `i`

is a built-in type such as `int`

then there are no function calls involved, everything is a built-in operator. There are thus 4 things that happen:

(a) The *value computation* of `++i`

, which is *original-value-of-i* `+1`

(b) The *side effect* of `++i`

, which stores *original-value-of-i* `+1`

back into `i`

(c) The *value computation* of the assignment, which is just the value stored, in this case the result of the *value computation* of `++i`

(d) The *side effect* of the assignment, which stores the new value into `i`

All of these things are *sequenced-before* the following full expression. (i.e. they are all complete by the final semicolon of the statement)

Since `++i`

is equivalent to `i+=1`

, the *side effect* of storing the value is *sequenced-before* the *value computation* of `++i`

, so (b) is *sequenced-before* (a).

The *value computation* of both operands of an assignment is *sequenced-before* the *value computation* of the assignment itself, and that is in turn *sequenced-before* the *side effect* of storing the value. Therefore (a) is *sequenced before* (c), and (c) is *sequenced-before* (d).

We therefore have (b) -> (a) -> (c) -> (d), and this is thus OK under the new rules, whereas it was not OK under C++98.

If `i`

was a `class`

, then the expression would be `i.operator=(i.operator++())`

, or `i.operator=(operator++(i))`

, and *all effects* of the `operator++`

call are *sequenced-before* the call to `operator=`

.

## 2. `a[++i] = i;`

If `a`

is an array type, and `i`

is an `int`

, then again the expression has several parts:

(a) The *value computation* of `i`

(b) The *value computation* of `++i`

(c) The *side effect* of `++i`

, which stores the new value back into `i`

(d) The *value computation* of `a[++i]`

, which returns an *lvalue* for the element of `a`

indexed by the *value computation* of `++i`

(e) The *value computation* of the assignment, which is just the value stored, in this case the result of the *value computation* of `i`

(f) The *side effect* of the assignment, which stores the new value into the array element `a[++i]`

Again, all of these things are *sequenced-before* the following full expression. (i.e. they are all complete by the final semicolon of the statement)

Again, since `++i`

is equivalent to `i+=1`

, the *side effect* of storing the value is *sequenced-before* the *value computation* of `++i`

, so (c) is *sequenced-before* (b).

The *value computation* of the array index `++i`

is *sequenced-before` the *value computation* of the element selection, so (b) is *sequenced-before* (d).

The *value computation* of both operands of an assignment is *sequenced-before* the *value computation* of the assignment itself, and that is in turn *sequenced-before* the *side effect* of storing the value. Therefore (a) and (d) are *sequenced before* (e), and (e) is *sequenced-before* (f).

We therefore have two sequences: (a) -> (d) -> (e) -> (f) and (c) -> (b) -> (d) -> (e) -> (f).

Unfortunately, there is no ordering between (a) and (c). Thus a *side effect* which stores to `i`

is *unsequenced* with respect to a *value computation* on `i`

, and the code exhibits **undefined behaviour**. This is again given by 1.9p15 of the C++11 standard.

As above, if `i`

is of class type then everything is fine, because the operators become function calls, which impose sequencing.

## The rules

The rules are relatively straightforward:

The *value computations* of the arguments of a built-in operator are *sequenced-before* the *value computation* of the operator itself.

The *side effects* of a built-in assignment operator or preincrement operator are *sequenced-before* the *value computation* of the result.

The *value computation* of any other built-in operator is *sequenced-before* the side effects of that operator.

The *value computation* **and** *side-effects* of the left-hand side of the built-in comma operator are *sequenced-before* the *value computation* **and** *side-effects* of the right-hand side.

All *value computations* and *side effects* of a full expression are *sequenced-before* the next full expression.

The *value computation* and *side effects* of the arguments of a function call are *sequenced before* the first full expression in the function.

The *value computation* and *side effects* of everything *inside* a function are *sequenced-before* the *value computation* of the result.

For any two function calls in the full expression, either the *value computation* of the result of one is *sequenced-before* the call to the other, or vice-versa. If no other rule specifies the ordering, the compiler may choose.

Thus in `a()+b()`

, either `a()`

is *sequenced-before* `b()`

, or `b()`

is *sequenced-before* `a()`

, but there is no rule to specify which.

If there are two *side effects* that modify the same variable, and neither is *sequenced-before* the other, the code has undefined behaviour.

If there is a *side effect* that modifies a variable, and a *value computation* that reads that variable, and neither is *sequenced-before* the other, the code has undefined behaviour.