Note that since the definition of *expression* is

*expression*:

*assignment-expression*

*expression* `,`

*assignment-expression*

the second line means that any *assignment-expression* can be considered an *expression*, which is why `t=3, t+2`

is a valid expression.

So why is the grammar this way? First note that the grammar for expressions builds its way in steps from the most tightly bound category *primary-expression* to the least tightly bound category *expression*. (And then the fact that "`(`

*expression* `)`

" is a *primary-expression* brings the expression grammar full circle and lets us cause any expression to be more tightly bound than everything that surrounds it by adding parentheses.)

For example, the well-known fact that binary `*`

binds tighter than binary `+`

follows from these grammar pieces:

*multiplicative-expression*:

*pm-expression*

*multiplicative-expression* `*`

*pm-expression*

*multiplicative-expression* `/`

*pm-expression*

*multiplicative-expression* `%`

*pm-expression*

*additive-expression*:

*multiplicative-expression*

*additive-expression* `+`

*multiplicative-expression*

*additive-expression* `-`

*multiplicative-expression*

In the expression `2 + 3 * 4`

, the literals `2`

, `3`

, and `4`

can be considered a *pm-expression*, or therefore also a *multiplicative-expression* or *additive-expression*. So you might say `2 + 3`

would qualify as an *additive-expression*, but it is *not* a *multiplicative-expression*, so the full `2 + 3 * 4`

can't work that way. Instead the grammar forces `3 * 4`

to be considered a *multiplicative-expression*, so that `2 + 3 * 4`

can be an *additive-expression*. Therefore `3 * 4`

is a subexpression of the binary `+`

.

Or in the expression `2 * 3 + 4`

, `3 + 4`

might be considered an *additive-expression*, but then it is not a *pm-expression*, so that doesn't work. Instead the parser must recognize that `2 * 3`

is a *multiplicative-expression*, which is also an *additive-expression*, so `2 * 3 + 4`

is a valid *additive-expression*, with `2 * 3`

as a subexpression of the binary `+`

.

The recursive nature of most grammar definitions matters when the same operator is used twice, or two operators with the same precedence are used.

Going back to the comma grammar, if we have the tokens "`a, b, c`

", we might say `b, c`

could be an *expression*, but it is not an *assignment-expression*, so `b, c`

cannot be a subexpression of the whole. Instead the grammar requires recognizing `a, b`

as an *expression*, which is allowed as a left subexpression of another comma operator, so `a, b, c`

is also an *expression* with `a, b`

as the left operand.

This doesn't make any difference for the built-in comma, since its meaning is associative: "evaluate and discard `a`

, then the result value comes from evaluating (evaluate and discard `b`

, then the result value comes from evaluating `c`

)" does the same as "evaluate and discard (evaluate and discard `a`

, then the result value comes from evaluating `b`

), then the result value comes from evaluating `c`

".

But it does give us a clearly-defined behavior in case of an overloaded `operator,`

. Given:

```
struct X {};
X operator,(X, X);
X a, b, c;
X d = (a, b, c);
```

we know that the last line means

```
X d = operator,(operator,(a,b), c);
```

and not

```
X d = operator,(a, operator,(b,c));
```

(I'd consider it particularly evil to define a non-associative `operator,`

, but it is allowed.)

assignment-expressioncannot contain a comma (outside of brackets or quotes, that is). Therefore, theassignment-expressionto the left of the operator cannot be extended to the right of`t=3`

. Second, andassignment-expressionis one thatmaycontain an assignment, it doesn't have to. So, each side of the operator is technically anassignment-expression. This is just the weird but very useful world of context-free grammars (see en.wikipedia.org/wiki/Context-free_grammar). The names of these rules often don't match what you would expect from natural language. – Arne Vogel Sep 22 '17 at 10:11