The semantics of `tac1 ; tac2`

is to run `tac1`

and then run `tac2`

on *all* the subgoals created by `tac1`

. So you may face a variety of cases:

### There are no goals left after running `tac1`

If there are no goals left after running `tac1`

then `tac2`

is never run and Coq simply silently succeeds. For instance, in this first derivation we have a useless `; intros`

at the end of the (valid) proof:

```
Goal forall (A : Prop), A -> (A /\ A /\ A /\ A /\ A).
intros ; repeat split ; assumption ; intros.
Qed.
```

If we isolate it, then we get an `Error: No such goal.`

because we are trying to run a tactics when there is nothing to prove!

```
Goal forall (A : Prop), A -> (A /\ A /\ A /\ A /\ A).
intros ; repeat split ; assumption.
intros. (* Error! *)
```

### There is exactly one goal left after running `tac1`

.

If there is precisely one goal left after running `tac1`

then `tac1 ; tac2`

behaves a bit like `tac1. tac2`

. The main difference is that if `tac2`

fails then so does the whole of `tac1 ; tac2`

because the sequence of two tactics is seen as a unit that can either succeed as a whole or fail as a whole. But if `tac2`

succeeds, then it's pretty much equivalent.

E.g. the following proof is a valid one:

```
Goal forall (A : Prop), A -> (A /\ A /\ A /\ A /\ A).
intros.
repeat split ; assumption.
Qed.
```

### Running `tac1`

generates more than one goal.

Finally, if multiple goals are generated by running `tac1`

then `tac2`

is applied to all of the generated subgoals. In our running example, we can observe that if we cut off the sequence of tactics after `repeat split`

then we have 5 goals on our hands. Which means that we need to copy / paste `assumption`

five times to replicate the proof given earlier using `;`

:

```
Goal forall (A : Prop), A -> (A /\ A /\ A /\ A /\ A).
intros ; repeat split.
assumption.
assumption.
assumption.
assumption.
assumption.
Qed.
```