Smallstep: Small-step Operational Semantics

(* Version of 4/21/2010 *)


Require Export Imp.
Require Import Relations.

The evaluators we have seen so far (e.g., the ones for aexps, bexps, and commands) have been formulated in a "big-step" style -- they specify how a given expression can be evaluated to its final value (or a command plus a store to a final store) "all in one big step."
This style is simple and natural for many purposes, but it there are some things it does not do well. In particular, it does not give us a natural way of talking about concurrent programming languages, where the "semantics" of a program -- i.e., the essence of how it behaves -- is not just which input states get mapped to which output states, but also includes the intermediate states that it passes through along the way, since these states can also be observed by concurrently executing code.
Another shortcoming of the big-step style is more technical, but critical for some applications. Consider the variant of Imp with lists that we introduced at the end of MoreHoare.v. We chose to define the meaning of programs like 0 + nil by specifying that a list should be interpreted as 0 when it occurs in a context expecting a number, but this was a bit of a hack. It would be better simply to say that the behavior of such a program is undefined -- it doesn't evaluate to any result. We could easily do this: we'd just have to change the definitions of aeval and beval from Fixpoints to inductive propositions, so that we can make them partial functions instead of total ones.
However, this way of defining Imp has a serious deficiency. In this language, a command might fail to map a given starting state to any ending state for two quite different reasons: either because the execution gets into an infinite loop or because, at some point, the program tries to do an operation that makes no sense, such as taking the successor of a boolean variable, and none of the evaluation rules can be applied.
These two outcomes -- nontermination vs. getting stuck in an erroneous configuration -- are quite different. In particular, we want to allow the first (permitting the possibility of infinite loops is the price we pay for the convenience of programming with general looping constructs like while) but prevent the second (which is just wrong), for example by adding some form of typechecking to the language. Indeed, this will be a major topic for the rest of the course. As a first step, we need a different way of presenting the semantics that allows us to distinguish nontermination from erroneous "stuck states."
So, for lots of reasons, we'd like to have a finer-grained way of defining and reasoning about program behaviors. This is the topic of the present chapter. We replace the "big-step" eval relation with a "small-step" relation that specifies, for a given program, how the "atomic steps" of computation are performed.

A Toy Language

To save space in the discussion, let's start with an incredibly simple language containing just constants and addition. At the end of the chapter, we'll see how to apply the same techniques to the full Imp language.

Inductive tm : Type :=
  | tm_const : nat -> tm
  | tm_plus : tm -> tm -> tm.

Tactic Notation "tm_cases" tactic(first) tactic(c) :=
  first;
  [ c "tm_const" | c "tm_plus" ].

Module SimpleArith0.

Here is a standard evaluator for this language, written in the same (big-step) style as we've been using up to this point.

Fixpoint eval (t : tm) : nat :=
  match t with
  | tm_const n => n
  | tm_plus a1 a2 => plus (eval a1) (eval a2)
  end.

We write t ==> n for "t evaluates to n."

Notation " t '==>' n " := (eval t = n) (at level 40).

End SimpleArith0.

Module SimpleArith1.

Now, here is the same evaluator, written in exactly the same style, but formulated as an inductively defined relation. Again, we use the notation t ==> n for "t evaluates to n."

Reserved Notation " t '==>' n " (at level 40).

Inductive eval : tm -> nat -> Prop :=
  | E_Const : forall n,
      tm_const n ==> n
  | E_Plus : forall t1 t2 n1 n2,
      t1 ==> n1 ->
      t2 ==> n2 ->
      tm_plus t1 t2 ==> plus n1 n2

  where " t '==>' n " := (eval t n).

End SimpleArith1.

Here is a slight variation, still in big-step style, where the final result of evaluating a term is also a term, rather than a bare number.

Reserved Notation " t '==>' t' " (at level 40).

Inductive eval : tm -> tm -> Prop :=
  | E_Const : forall n1,
        tm_const n1 ==> tm_const n1
  | E_Plus : forall t1 n1 t2 n2,
        t1 ==> tm_const n1 ->
        t2 ==> tm_const n2 ->
        tm_plus t1 t2 ==> tm_const (plus n1 n2)

  where " t '==>' t' " := (eval t t').

Tactic Notation "eval_cases" tactic(first) tactic(c) :=
  first;
  [ c "E_Const" | c "E_Plus" ].

Module SimpleArith2.

Now, here is a small-step version.

Reserved Notation " t '-->' t' " (at level 40).

Inductive step : tm -> tm -> Prop :=
  | ST_PlusConstConst : forall n1 n2,
      tm_plus (tm_const n1) (tm_const n2) --> tm_const (plus n1 n2)
  | ST_Plus1 : forall t1 t1' t2,
      t1 --> t1' ->
      tm_plus t1 t2 --> tm_plus t1' t2
  | ST_Plus2 : forall n1 t2 t2',
      t2 --> t2' ->
      tm_plus (tm_const n1) t2 --> tm_plus (tm_const n1) t2'

  where " t '-->' t' " := (step t t').

Things to notice:
  • We are defining just a single reduction step, in which one tm_plus node is replaced by its value.
  • Each step finds the leftmost tm_plus node that is ready to go (both of its operands are constants) and rewrites it in place. The first rule tells how to rewrite this tm_plus node itself; the other two rules tell how to find it.
  • A term that is just a constant cannot take a step.

Tactic Notation "step_cases" tactic(first) tactic(c) :=
  first;
  [ c "ST_PlusConstConst" | c "ST_Plus1" | c "ST_Plus2" ].

A couple of examples of reasoning with the step relation...
If t1 can take a step to t1', then tm_plus t1 t2 steps to plus t1' t2:

Example test_step_1 :
      tm_plus
        (tm_plus (tm_const 0) (tm_const 3))
        (tm_plus (tm_const 2) (tm_const 4))
      -->
      tm_plus
        (tm_const (plus 0 3))
        (tm_plus (tm_const 2) (tm_const 4)).
Proof.
  apply ST_Plus1. apply ST_PlusConstConst. Qed.

Exercise: 2 stars (test_step_2)

Right-hand sides of sums can take a step only when the left-hand side is finished: if t2 can take a step to t2', then tm_plus (tm_const n) t2 steps to tm_plus (tm_const n) t2':

Example test_step_2 :
      tm_plus
        (tm_const 0)
        (tm_plus
          (tm_const 2)
          (tm_plus (tm_const 0) (tm_const 3)))
      -->
      tm_plus
        (tm_const 0)
        (tm_plus
          (tm_const 2)
          (tm_const (plus 0 3))).
Proof.
  (* FILL IN HERE *) Admitted.
One interesting property of the --> relation is that, like the evaluation relation for our language of Imp programs, it is deterministic.
Theorem: For each t, there is at most one t' such that t --> t' is provable. Formally, this is the same as saying that --> is a partial function.
Proof sketch: We must show that if x steps to both y1 and y2 then y1 and y2 are equal. Consider the last rules used in the derivations of step x y1 and step x y2.
  • If both are ST_PlusConstConst, the result is immediate.
  • It cannot happen that one is ST_PlusConstConst and the other is ST_Plus1 or ST_Plus2, since this would imply that x has the form tm_plus t1 t2 where both t1 and t2 are constants (by ST_PlusConstConst) and one of t1 or t2 has the form tm_plus ....
  • Similarly, it cannot happen that one is ST_Plus1 and the other is ST_Plus2, since this would imply that x has the form tm_plus t1 t2 where t1 has both the form tm_plus t1 t2 and the form tm_const n.
  • The cases when both derivations end with ST_Plus1 or ST_Plus2 follow by the induction hypothesis.

Theorem step_deterministic:
  partial_function step.
Proof.
  unfold partial_function. intros x y1 y2 Hy1 Hy2.
  generalize dependent y2.
  step_cases (induction Hy1) Case.
    Case "ST_PlusConstConst". intros y2 Hy2. step_cases (inversion Hy2) SCase.
      SCase "ST_PlusConstConst". reflexivity.
      SCase "ST_Plus1". inversion H2.
      SCase "ST_Plus2". inversion H2.
    Case "ST_Plus1". intros y2 Hy2. step_cases (inversion Hy2) SCase.
      SCase "ST_PlusConstConst".
        rewrite <- H0 in Hy1. inversion Hy1.
      SCase "ST_Plus1".
        rewrite <- (IHHy1 t1'0).
        reflexivity. assumption.
      SCase "ST_Plus2". rewrite <- H in Hy1. inversion Hy1.
    Case "ST_Plus2". intros y2 Hy2. step_cases (inversion Hy2) SCase.
      SCase "ST_PlusConstConst". rewrite <- H1 in Hy1. inversion Hy1.
      SCase "ST_Plus1". inversion H2.
      SCase "ST_Plus2".
        rewrite <- (IHHy1 t2'0).
        reflexivity. assumption. Qed.

End SimpleArith2.

Values

Let's take a moment to slightly generalize the way we state the definition of single-step reduction. It is useful to think of the --> relation as defining a sort of abstract machine for evaluating programs:
  • At any moment, the state of the machine is a term.
  • A step of the machine is an atomic unit of computation -- here, a single "add" operation.
  • The final states of the machine are ones where there is no more computation to be done.
We can then think about executing a term t as follows:
  • Take t as the starting state of the machine.
  • Repeatedly use the --> relation to find a sequence of machine states such that each steps to the next.
  • When no more reduction is possible, "read out" the final state of the machine as the result of execution.
Intuitively, it is clear that the final states of the machine are always terms of the form tm_const n for some n. We call such terms values.

Inductive value : tm -> Prop :=
  v_const : forall n, value (tm_const n).

Having introduced the idea of values, we can use it in the definition of the --> relation to write ST_Plus2 rule in a slightly more intuitive way:

Reserved Notation " t '-->' t' " (at level 40).

Inductive step : tm -> tm -> Prop :=
  | ST_PlusConstConst : forall n1 n2,
          tm_plus (tm_const n1) (tm_const n2)
      --> tm_const (plus n1 n2)
  | ST_Plus1 : forall t1 t1' t2,
        t1 --> t1' ->
        tm_plus t1 t2 --> tm_plus t1' t2
  | ST_Plus2 : forall v1 t2 t2',
        value v1 -> (* <----- n.b. *)
        t2 --> t2' ->
        tm_plus v1 t2 --> tm_plus v1 t2'

  where " t '-->' t' " := (step t t').

Tactic Notation "step_cases" tactic(first) tactic(c) :=
  first;
  [ c "ST_PlusConstConst" | c "ST_Plus1" | c "ST_Plus2" ].

Exercise: 3 stars (redo_determinacy)

As a sanity check on this change, let's re-verify determinacy
Proof sketch: We must show that if x steps to both y1 and y2 then y1 and y2 are equal. Consider the final rules used in the derivations of step x y1 and step x y2.
  • If both are ST_PlusConstConst, the result is immediate.
  • It cannot happen that one is ST_PlusConstConst and the other is ST_Plus1 or ST_Plus2, since this would imply that x has the form tm_plus t1 t2 where both t1 and t2 are constants (by ST_PlusConstConst) AND one of t1 or t2 has the form tm_plus ....
  • Similarly, it cannot happen that one is ST_Plus1 and the other is ST_Plus2, since this would imply that x has the form tm_plus t1 t2 where t1 both has the form tm_plus t1 t2 and is a value (hence has the form tm_const n).
  • The cases when both derivations end with ST_Plus1 or ST_Plus2 follow by the induction hypothesis.
Most of this proof is the same as the one above. But to get maximum benefit from the exercise you should try to write it from scratch and just use the earlier one if you get stuck.

Theorem step_deterministic :
  partial_function step.
Proof.
  (* FILL IN HERE *) Admitted.

Normal Forms

Theorem: For all t:tm, either t is a value, or there exists a term t' such that t --> t'.
Proof: By induction on t.
  • Suppose t = tm_const n. Then t is a value.
  • Suppose t = tm_plus t1 t2, where (by the IH) t1 is either a value or can step to some t1', and where t2 is either a value or can step to some t2'. We must show tm_plus t1 t2 is either a value or steps to some t'.
    • If t1 and t2 are both values, then t can take a step, by ST_PlusConstConst.
    • If t1 is a value and t2 can take a step, then so can t, by ST_Plus2.
    • If t1 can take a step, then so can t, by ST_Plus1.
This important property is called progress, because every term either is a value or can "make progress" by stepping to some other term.

Theorem progress : forall t,
  value t \/ (exists t', t --> t').
Proof.
  tm_cases (induction t) Case.
    Case "tm_const". left. apply v_const.
    Case "tm_plus". right. inversion IHt1.
      SCase "l". inversion IHt2.
        SSCase "l". inversion H. inversion H0.
          exists (tm_const (plus n n0)).
          apply ST_PlusConstConst.
        SSCase "r". inversion H0 as [t' H1].
          exists (tm_plus t1 t').
          apply ST_Plus2. apply H. apply H1.
      SCase "r". inversion H as [t' H0].
          exists (tm_plus t' t2).
          apply ST_Plus1. apply H0. Qed.

The idea of "making progress" can be extended to tell us something interesting about values: they are exactly the terms that cannot make progress in this sense. To state this fact, let's begin by giving a name to terms that cannot make progress: We'll call them normal forms.

Definition normal_form {X:Type} (R:relation X) (t:X) : Prop :=
  ~ exists t', R t t'.

We've actually defined what it is to be a normal form for an arbitrary relation R over an arbitrary set X, not just for the particular reduction relation over terms that we are interested in at the moment. We'll re-use the same terminology for talking about other relations later in the course.
We can use this terminology to generalize the observation we made in the progress theorem: normal forms and values are actually the same thing.
Note that we state and prove this result as two different lemmas, rather than using an if-and-only-if (<->). That's because it will be easier to apply the separate lemmas later on; as noted before, Coq's facilities for dealing "in-line" with <-> statements are a little awkward.

Lemma value_is_nf : forall t,
  value t -> normal_form step t.
Proof.
  intros t H. unfold normal_form. intros contra. inversion H.
  rewrite <- H0 in contra. destruct contra as [t' P]. inversion P. Qed.

Lemma nf_is_value : forall t,
  normal_form step t -> value t.
Proof.
  (* This is a corollary of progress. *)
  intros t H.
  unfold normal_form in H.
  assert (value t \/ exists t', t --> t') as G.
    SCase "Proof of assertion". apply progress.
  inversion G.
    SCase "l". apply H0.
    SCase "r". apply ex_falso_quodlibet. apply H. assumption. Qed.

Why are these last two facts interesting? For two reasons:
  • Because value is a syntactic concept -- it is a defined by looking at the form of a term -- while normal_form is a semantic one -- it is defined by looking at how the term steps. Is it not obvious that these concepts should coincide.
  • Indeed, there are lots of languages in which the concepts of normal form and value do not coincide.
Let's examine how this can happen...
We might, for example, accidentally define value so that it includes some terms that are not finished reducing.

Module Temp1.
(* Open an inner module so we can redefine value and step. *)

Inductive value : tm -> Prop :=
| v_const : forall n, value (tm_const n)
| v_funny : forall t1 n2, (* <---- *)
              value (tm_plus t1 (tm_const n2)).

Reserved Notation " t '-->' t' " (at level 40).

Inductive step : tm -> tm -> Prop :=
  | ST_PlusConstConst : forall n1 n2,
      tm_plus (tm_const n1) (tm_const n2) --> tm_const (plus n1 n2)
  | ST_Plus1 : forall t1 t1' t2,
      t1 --> t1' ->
      tm_plus t1 t2 --> tm_plus t1' t2
  | ST_Plus2 : forall v1 t2 t2',
      value v1 ->
      t2 --> t2' ->
      tm_plus v1 t2 --> tm_plus v1 t2'

  where " t '-->' t' " := (step t t').

Exercise: 3 stars (value_not_same_as_normal_form)

Lemma value_not_same_as_normal_form :
  exists t, value t /\ ~ normal_form step t.
Proof.
  (* FILL IN HERE *) Admitted.

End Temp1.

Alternatively, we might accidentally define step so that it permits something designated as a value to reduce further.

Module Temp2.

Inductive value : tm -> Prop :=
| v_const : forall n, value (tm_const n).

Reserved Notation " t '-->' t' " (at level 40).

Inductive step : tm -> tm -> Prop :=
  | ST_Funny : forall n, (* <---- *)
      tm_const n --> tm_plus (tm_const n) (tm_const 0)
  | ST_PlusConstConst : forall n1 n2,
      tm_plus (tm_const n1) (tm_const n2) --> tm_const (plus n1 n2)
  | ST_Plus1 : forall t1 t1' t2,
      t1 --> t1' ->
      tm_plus t1 t2 --> tm_plus t1' t2
  | ST_Plus2 : forall v1 t2 t2',
      value v1 ->
      t2 --> t2' ->
      tm_plus v1 t2 --> tm_plus v1 t2'

  where " t '-->' t' " := (step t t').

Exercise: 3 stars (value_not_same_as_normal_form)

Lemma value_not_same_as_normal_form :
  exists t, value t /\ ~ normal_form step t.
Proof.
  (* FILL IN HERE *) Admitted.

End Temp2.

Finally, we might accidentally define value and step so that there is some term that is not a value but that cannot take a step in the step relation. Such terms are said to be stuck.

Module Temp3.

Inductive value : tm -> Prop :=
  | v_const : forall n, value (tm_const n).

Reserved Notation " t '-->' t' " (at level 40).

Inductive step : tm -> tm -> Prop :=
  | ST_PlusConstConst : forall n1 n2,
      tm_plus (tm_const n1) (tm_const n2) --> tm_const (plus n1 n2)
  | ST_Plus1 : forall t1 t1' t2,
      t1 --> t1' ->
      tm_plus t1 t2 --> tm_plus t1' t2

  where " t '-->' t' " := (step t t').

Note that ST_Plus2 is missing.

Exercise: 3 stars (value_not_same_as_normal_form')

Lemma value_not_same_as_normal_form :
  exists t, ~ value t /\ normal_form step t.
Proof.
  (* FILL IN HERE *) Admitted.

End Temp3.

Exercises


Module Temp4.

Here is another very simple language whose terms, instead of being just plus and numbers, are just the booleans true and false and a conditional expression...

Inductive tm : Type :=
  | tm_true : tm
  | tm_false : tm
  | tm_if : tm -> tm -> tm -> tm.

Inductive value : tm -> Prop :=
  | v_true : value tm_true
  | v_false : value tm_false.

Reserved Notation " t '-->' t' " (at level 40).

Inductive step : tm -> tm -> Prop :=
  | ST_IfTrue : forall t1 t2,
      tm_if tm_true t1 t2 --> t1
  | ST_IfFalse : forall t1 t2,
      tm_if tm_false t1 t2 --> t2
  | ST_If : forall t1 t1' t2 t3,
      t1 --> t1' ->
      tm_if t1 t2 t3 --> tm_if t1' t2 t3

  where " t '-->' t' " := (step t t').

Exercise: 1 star (smallstep_bools)

Which of the following propositions are provable? (This is just a thought exercise, but for an extra challenge feel free to prove your answers in Coq.)

Definition bool_step_prop1 :=
  tm_false --> tm_false.

(* FILL IN HERE *)

Definition bool_step_prop2 :=
     tm_if
       tm_true
       (tm_if tm_true tm_true tm_true)
       (tm_if tm_false tm_false tm_false)
  -->
     tm_true.

(* FILL IN HERE *)

Definition bool_step_prop3 :=
     tm_if
       (tm_if tm_true tm_true tm_true)
       (tm_if tm_true tm_true tm_true)
       tm_false
   -->
     tm_if
       tm_true
       (tm_if tm_true tm_true tm_true)
       tm_false.

(* FILL IN HERE *)

Exercise: 3 stars (progress_bool)

Just as we proved a progress theorem for plus expressions, we can do so for boolean expressions, as well.

Theorem progress : forall t,
  value t \/ (exists t', t --> t').
Proof.
  (* FILL IN HERE *) Admitted.

Exercise: 2 stars, optional (step_deterministic)

Theorem step_deterministic :
  partial_function step.
Proof.
  (* FILL IN HERE *) Admitted.

Module Temp5.

Exercise: 2 stars (smallstep_bool_shortcut)

Suppose we want to add a "short circuit" to the step relation for boolean expressions, so that it can recognize when the then and else branches of a conditional are the same value (either tm_true or tm_false) and reduce the whole conditional to this value in a single step, even if the guard has not yet been reduced to a value. For example, we would like this proposition to be provable:
Write an extra clause for the step relation that achieves this effect and prove bool_step_prop4.

Reserved Notation " t '-->' t' " (at level 40).

Inductive step : tm -> tm -> Prop :=
  | ST_IfTrue : forall t1 t2,
      tm_if tm_true t1 t2 --> t1
  | ST_IfFalse : forall t1 t2,
      tm_if tm_false t1 t2 --> t2
  | ST_If : forall t1 t1' t2 t3,
      t1 --> t1' ->
      tm_if t1 t2 t3 --> tm_if t1' t2 t3
(* FILL IN HERE *)

  where " t '-->' t' " := (step t t').

Exercise: 2 stars (bool_step_prop4_holds)

To check that your previous answer is correct, prove that the following step is now possible.

Definition bool_step_prop4 :=
         tm_if
            (tm_if tm_true tm_true tm_true)
            tm_false
            tm_false
     -->
         tm_false.

Example bool_step_prop4_holds :
  bool_step_prop4.
Proof.
  (* FILL IN HERE *) Admitted.

Exercise: 3 stars (properties_of_altered_step)

It can be shown that the determinism and progress theorems for the step relation in the lecture notes also hold for the definition of step given above. After we add the clause ST_ShortCircuit...
  • Does step_deterministic still hold? Write yes or no and briefly (1 sentence) explain your answer.
    Optional exercise: prove your answer correct in Coq.

(* FILL IN HERE *)

  • Does a progress theorem hold? Write yes or no and briefly (1 sentence) explain your answer.
    Optional exercise: prove your answer correct in Coq.

(* FILL IN HERE *)

  • In general, is there any way we could cause progress to fail if we took away one or more constructors from the original step relation? Write yes or no and briefly (1 sentence) explain your answer.
(* FILL IN HERE *)
End Temp5.
End Temp4.

Multi-Step Reduction

Until now, we've been working with the single-step reduction relation -->, which formalizes the individual steps of abstract machine for executing programs. It is also interesting to use this machine to reduce programs to completion, to find out what final result they yield. This can be formalized in two steps.
  • First, we define a multi-step reduction relation stepmany, which relates terms t and t' if t can reach t' by any number (including 0) of single reduction steps.
  • Then we can define a "result" of a term t as a normal form that t can reach by some number of reduction steps. Formally, we write normal_form_of t t' to mean that t' is a normal form reachable from t by many-step reduction.

Multi-Step Reduction

Now we're ready to define the multi-step reduction relation.

Definition stepmany := refl_step_closure step.

Notation " t '-->*' t' " := (stepmany t t') (at level 40).

A few examples...

Lemma test_stepmany_1:
      tm_plus
        (tm_plus (tm_const 0) (tm_const 3))
        (tm_plus (tm_const 2) (tm_const 4))
   -->*
      tm_const (plus (plus 0 3) (plus 2 4)).
Proof.
  apply rsc_step with
            (tm_plus
                (tm_const (plus 0 3))
                (tm_plus (tm_const 2) (tm_const 4))).
  apply ST_Plus1. apply ST_PlusConstConst.
  apply rsc_step with
            (tm_plus
                (tm_const (plus 0 3))
                (tm_const (plus 2 4))).
  apply ST_Plus2. apply v_const.
  apply ST_PlusConstConst.
  apply rsc_R.
  apply ST_PlusConstConst. Qed.

Here's an alternate proof that uses eapply to avoid explicitly constructing all the intermediate terms.

Lemma test_stepmany_1':
      tm_plus
        (tm_plus (tm_const 0) (tm_const 3))
        (tm_plus (tm_const 2) (tm_const 4))
  -->*
      tm_const (plus (plus 0 3) (plus 2 4)).
Proof.
  eapply rsc_step. apply ST_Plus1. apply ST_PlusConstConst.
  eapply rsc_step. apply ST_Plus2. split. apply ST_PlusConstConst.
  eapply rsc_step. apply ST_PlusConstConst.
  apply rsc_refl. Qed.

Exercise: 1 star (test_stepmany_2)

Lemma test_stepmany_2:
  tm_const 3 -->* tm_const 3.
Proof.
  (* FILL IN HERE *) Admitted.

Exercise: 1 star (test_stepmany_3)

Lemma test_stepmany_3:
      tm_plus (tm_const 0) (tm_const 3)
   -->*
      tm_plus (tm_const 0) (tm_const 3).
Proof.
  (* FILL IN HERE *) Admitted.

Exercise: 2 stars (test_stepmany_4)

Lemma test_stepmany_4:
      tm_plus
        (tm_const 0)
        (tm_plus
          (tm_const 2)
          (tm_plus (tm_const 0) (tm_const 3)))
  -->*
      tm_plus
        (tm_const 0)
        (tm_const (plus 2 (plus 0 3))).
Proof.
  (* FILL IN HERE *) Admitted.

Normal Forms Again

If t reduces to t' in zero or more steps and t' is a normal form, we say that "t' is a normal form of t."

Definition step_normal_form := normal_form step.

Definition normal_form_of (t t' : tm) :=
  (t -->* t' /\ step_normal_form t').

We have already seen that single-step reduction is deterministic -- i.e., a given term can take a single step in at most one way. It follows from this that, if t can reach a normal form, then this normal form is unique -- i.e., normal_form_of is a partial function. In other words, we can actually pronounce normal_form t t' as "t' is the normal form of t."

Exercise: 3 stars, optional (test_stepmany_3)

Theorem normal_forms_unique:
  partial_function normal_form_of.
Proof.
  unfold partial_function. unfold normal_form_of. intros x y1 y2 P1 P2.
  destruct P1 as [P11 P12]. destruct P2 as [P21 P22].
  generalize dependent y2.
  (* We recommend using this initial setup as-is! *)
  (* FILL IN HERE *) Admitted.
Indeed, something stronger is true for this language (though not for all languages): the reduction of any term t will eventually reach a normal form -- i.e., normal_form_of is a total function. Formally, we say the step relation is normalizing.

Definition normalizing {X:Type} (R:relation X) :=
  forall t, exists t',
    (refl_step_closure R) t t' /\ normal_form R t'.

To prove that step is normalizing, we need a couple of lemmas. First, we observe that, if t reduces to t' in many steps, then the same sequence of reduction steps is possible when t appears as the left-hand child of a tm_plus node, and similarly when t appears as the right-hand child of a tm_plus node whose left-hand child is a value.

Lemma stepmany_congr_1 : forall t1 t1' t2,
     t1 -->* t1' ->
     tm_plus t1 t2 -->* tm_plus t1' t2.
Proof.
  intros t1 t1' t2 H. rsc_cases (induction H) Case.
    Case "rsc_refl". apply rsc_refl.
    Case "rsc_step". apply rsc_step with (tm_plus y t2).
        apply ST_Plus1. apply H.
        apply IHrefl_step_closure. Qed.

Exercise: 2 stars

Lemma stepmany_congr_2 : forall t1 t2 t2',
     value t1 ->
     t2 -->* t2' ->
     tm_plus t1 t2 -->* tm_plus t1 t2'.
Proof.
  (* FILL IN HERE *) Admitted.
Theorem: The step function is normalizing -- i.e., for every t there exists some t' such that t steps to t' and t' is a normal form.
Proof sketch: By induction on terms. There are two cases to consider:
  • t = tm_const n for some n. Here t doesn't take a step, and we have t' = t. We can derive the left-hand side by reflexivity and the right-hand side by observing (a) that values are normal forms (by value_is_nf) and (b) that t is a value (by v_const).
  • t = tm_plus t1 t2 for some t1 and t2. By the IH, both t1 and t2 normalize to normal forms t1' and t2', respectively. Recall that normal forms are values (by nf_is_value); we know that t1' = tm_const n1 and t2' = tm_const n2, for some n1 and n2. We can combine the -->* derivations for t1 and t2 to prove that tm_plus t1 t2 reduces in many steps to tm_const (plus n1 n2).
    It is clear that our choice of t' = tm_const (plus n1 n2) is a value, which is in turn a normal form.

Theorem step_normalizing :
  normalizing step.
Proof.
  unfold normalizing.
  tm_cases (induction t) Case.
    Case "tm_const".
      exists (tm_const n).
      split.
      SCase "l". apply rsc_refl.
      SCase "r". apply value_is_nf. apply v_const.
    Case "tm_plus".
      destruct IHt1 as [t1' H1]. destruct IHt2 as [t2' H2].
      destruct H1 as [H11 H12]. destruct H2 as [H21 H22].
      apply nf_is_value in H12. apply nf_is_value in H22.
      inversion H12 as [n1]. inversion H22 as [n2].
      rewrite <- H in H11.
      rewrite <- H0 in H21.
      exists (tm_const (plus n1 n2)).
      split.
        SCase "l".
          apply rsc_trans with (tm_plus (tm_const n1) t2).
          apply stepmany_congr_1. apply H11.
          apply rsc_trans with
             (tm_plus (tm_const n1) (tm_const n2)).
          apply stepmany_congr_2. apply v_const. apply H21.
          apply rsc_R. apply ST_PlusConstConst.
        SCase "r".
          apply value_is_nf. apply v_const. Qed.

Equivalence of Big-Step and Small-Step Reduction

Having defined the operational semantics of our tiny programming language in two different styles, it makes sense to ask whether these definitions actually define the same thing! They do, but it is not completely straightforward to show this, or even to see how to state it exactly, since one of the relations only goes a small step at a time while the other proceeds in large chunks.

Lemma eval__value : forall t1 t2,
     eval t1 t2 ->
     value t2.
Proof.
  intros t1 t2 HE.
  (eval_cases (inversion HE) Case); apply v_const. Qed.

Exercise: 3 stars (eval__stepmany)

You'll want to use the congruences and some properties of rsc for this.

Theorem eval__stepmany : forall t v,
  eval t v -> t -->* v.
Proof.
  (* FILL IN HERE *) Admitted.

Exercise: 3 stars (eval__stepmany_inf)

Write an informal version of the proof of eval__stepmany. (* FILL IN HERE *)

Exercise: 3 stars (step__eval)

Theorem step__eval : forall t t' v,
     t --> t' ->
     t' ==> v ->
     t ==> v.
Proof.
  (* FILL IN HERE *) Admitted.

Theorem stepmany__eval : forall t v,
  normal_form_of t v -> t ==> v.
Proof.
  intros t v Hnorm.
  unfold normal_form_of in Hnorm.
  inversion Hnorm as [Hs Hnf]; clear Hnorm.
  (* v is a normal form -> v = tm_const n for some n *)
  apply nf_is_value in Hnf. inversion Hnf. clear Hnf.
  (rsc_cases (induction Hs) Case); subst.
  Case "rsc_refl".
    apply E_Const.
  Case "rsc_step".
    eapply step__eval. eassumption. apply IHHs. reflexivity. Qed.

Bringing it all together, we can crisply say that the v is the normal form of t iff t evaluates to v.

Corollary stepmany_iff_eval : forall t v,
  normal_form_of t v <-> t ==> v.
Proof.
  split.
  Case "->". apply stepmany__eval.
  Case "<-". unfold normal_form_of. intros E. split. apply eval__stepmany.
    assumption. apply value_is_nf. eapply eval__value. eassumption. Qed.

Additional exercises

Exercise: 4 stars (combined_properties)

We've considered the arithmetic and conditional expressions separately. This exercise explores how the two interact.

Module Combined.

Inductive tm : Type :=
  | tm_const : nat -> tm
  | tm_plus : tm -> tm -> tm
  | tm_true : tm
  | tm_false : tm
  | tm_if : tm -> tm -> tm -> tm.

Tactic Notation "tm_cases" tactic(first) tactic(c) :=
  first;
  [ c "tm_const" | c "tm_plus" |
    c "tm_true" | c "tm_false" | c "tm_if" ].

Inductive value : tm -> Prop :=
  | v_const : forall n, value (tm_const n)
  | v_true : value tm_true
  | v_false : value tm_false.

Reserved Notation " t '-->' t' " (at level 40).

Inductive step : tm -> tm -> Prop :=
  | ST_PlusConstConst : forall n1 n2,
      tm_plus (tm_const n1) (tm_const n2) --> tm_const (plus n1 n2)
  | ST_Plus1 : forall t1 t1' t2,
      t1 --> t1' ->
      tm_plus t1 t2 --> tm_plus t1' t2
  | ST_Plus2 : forall v1 t2 t2',
      value v1 ->
      t2 --> t2' ->
      tm_plus v1 t2 --> tm_plus v1 t2'
  | ST_IfTrue : forall t1 t2,
      tm_if tm_true t1 t2 --> t1
  | ST_IfFalse : forall t1 t2,
      tm_if tm_false t1 t2 --> t2
  | ST_If : forall t1 t1' t2 t3,
      t1 --> t1' ->
      tm_if t1 t2 t3 --> tm_if t1' t2 t3

  where " t '-->' t' " := (step t t').

Tactic Notation "step_cases" tactic(first) tactic(c) :=
  first;
  [ c "ST_PlusConstConst" | c "ST_Plus1" | c "ST_Plus2" |
    c "ST_IfTrue" | c "ST_IfFalse" | c "ST_If" ].

Earlier, we separately proved for both plus- and if-expressions
  • that the step relation was a partial function (i.e., it was deterministic), and
  • a progress lemma, stating that every term is either a value or can take a step.
Prove or disprove these for the combined langauge.
(* FILL IN HERE *)
End Combined.

Small-Step Imp

Here is the small-step version of the Imp operational semantics. Although the definitions are bigger, the basic ideas are exactly the same as what we've seen above.

Inductive aval : aexp -> Prop :=
  av_num : forall n, aval (ANum n).

Reserved Notation " t '/' st '-->a' t' " (at level 40, st at level 39).

Inductive astep : state -> aexp -> aexp -> Prop :=
  | AS_Id : forall st i,
    AId i / st -->a ANum (st i)
  | AS_Plus : forall st n1 n2,
    APlus (ANum n1) (ANum n2) / st -->a ANum (plus n1 n2)
  | AS_Plus1 : forall st a1 a1' a2,
    a1 / st -->a a1' ->
    (APlus a1 a2) / st -->a (APlus a1' a2)
  | AS_Plus2 : forall st v1 a2 a2',
    aval v1 ->
    a2 / st -->a a2' ->
    (APlus v1 a2) / st -->a (APlus v1 a2')
  | AS_Minus : forall st n1 n2,
    (AMinus (ANum n1) (ANum n2)) / st -->a (ANum (minus n1 n2))
  | AS_Minus1 : forall st a1 a1' a2,
    a1 / st -->a a1' ->
    (AMinus a1 a2) / st -->a (AMinus a1' a2)
  | AS_Minus2 : forall st v1 a2 a2',
    aval v1 ->
    a2 / st -->a a2' ->
    (AMinus v1 a2) / st -->a (AMinus v1 a2')
  | AS_Mult : forall st n1 n2,
    (AMult (ANum n1) (ANum n2)) / st -->a (ANum (mult n1 n2))
  | AS_Mult1 : forall st a1 a1' a2,
    a1 / st -->a a1' ->
    (AMult (a1) (a2)) / st -->a (AMult (a1') (a2))
  | AS_Mult2 : forall st v1 a2 a2',
    aval v1 ->
    a2 / st -->a a2' ->
    (AMult v1 a2) / st -->a (AMult v1 a2')

  where " t '/' st '-->a' t' " := (astep st t t').

Reserved Notation " t '/' st '-->b' t' " (at level 40, st at level 39).

Inductive bstep : state -> bexp -> bexp -> Prop :=
  | BS_Eq : forall st n1 n2,
    (BEq (ANum n1) (ANum n2)) / st -->b
    (if (beq_nat n1 n2) then BTrue else BFalse)
  | BS_Eq1 : forall st a1 a1' a2,
    a1 / st -->a a1' ->
    (BEq a1 a2) / st -->b (BEq a1' a2)
  | BS_Eq2 : forall st v1 a2 a2',
    aval v1 ->
    a2 / st -->a a2' ->
    (BEq v1 a2) / st -->b (BEq v1 a2')
  | BS_LtEq : forall st n1 n2,
    (BLe (ANum n1) (ANum n2)) / st -->b
             (if (ble_nat n1 n2) then BTrue else BFalse)
  | BS_LtEq1 : forall st a1 a1' a2,
    a1 / st -->a a1' ->
    (BLe a1 a2) / st -->b (BLe a1' a2)
  | BS_LtEq2 : forall st v1 a2 a2',
    aval v1 ->
    a2 / st -->a a2' ->
    (BLe v1 a2) / st -->b (BLe v1 (a2'))
  | BS_NotTrue : forall st,
    (BNot BTrue) / st -->b BFalse
  | BS_NotFalse : forall st,
    (BNot BFalse) / st -->b BTrue
  | BS_NotStep : forall st b1 b1',
    b1 / st -->b b1' ->
    (BNot b1) / st -->b (BNot b1')
  | BS_AndTrueTrue : forall st,
    (BAnd BTrue BTrue) / st -->b BTrue
  | BS_AndTrueFalse : forall st,
    (BAnd BTrue BFalse) / st -->b BFalse
  | BS_AndFalse : forall st b2,
    (BAnd BFalse b2) / st -->b BFalse
  | BS_AndTrueStep : forall st b2 b2',
    b2 / st -->b b2' ->
    (BAnd BTrue b2) / st -->b (BAnd BTrue b2')
  | BS_AndStep : forall st b1 b1' b2,
    b1 / st -->b b1' ->
    (BAnd b1 b2) / st -->b (BAnd b1' b2)

  where " t '/' st '-->b' t' " := (bstep st t t').

Notice that we didn't actually bother to define boolean values -- they aren't needed in the definition of -->b (why?), though they might be if our language were a bit larger.
The semantics of commands is the interesting part. We need two small tricks to make it work:
  • We use SKIP as a "command value" -- i.e., a command that has reached a normal form.
    • An assignment command reduces to SKIP (and an updated state).
    • The sequencing command waits until its left-hand subcommand has reduced to SKIP, then throws it away so that reduction can continue with the right-hand subcommand.
  • We reduce a WHILE command by transforming it into a conditional followed by the same WHILE. There are other ways of achieving the desired effect, but they all have the common feature that the original WHILE command needs to be saved somewhere off on the side while a single copy of the loop body is being evaluated.

Reserved Notation " t '/' st '-->' t' '/' st' " (at level 40, st at level 39, t' at level 39).

Inductive cstep : (state * com) -> (state * com) -> Prop :=
  | CS_AssStep : forall st i a a',
    a / st -->a a' ->
    (i ::= a) / st --> (i ::= a') / st
  | CS_Ass : forall st i n,
    (i ::= (ANum n)) / st --> SKIP / (update st i n)
  | CS_SeqStep : forall st c1 c1' st' c2,
    c1 / st --> c1' / st' ->
    (c1 ; c2) / st --> (c1' ; c2) / st'
  | CS_SeqFinish : forall st c2,
    (SKIP ; c2) / st --> c2 / st
  | CS_IfTrue : forall st c1 c2,
    IFB BTrue THEN c1 ELSE c2 FI / st --> c1 / st
  | CS_IfFalse : forall st c1 c2,
    IFB BFalse THEN c1 ELSE c2 FI / st --> c2 / st
  | CS_IfStep : forall st b b' c1 c2,
    b / st -->b b' ->
    IFB b THEN c1 ELSE c2 FI / st --> (IFB b' THEN c1 ELSE c2 FI) / st
  | CS_While : forall st b c1,
        (WHILE b DO c1 END) / st
    --> (IFB b THEN (c1; (WHILE b DO c1 END)) ELSE SKIP FI) / st

  where " t '/' st '-->' t' '/' st' " := (cstep (st,t) (st',t')).

Concurrent Imp


Module CImp.

Inductive com : Type :=
  | CSkip : com
  | CAss : id -> aexp -> com
  | CSeq : com -> com -> com
  | CIf : bexp -> com -> com -> com
  | CWhile : bexp -> com -> com
  (* New: *)
  | CPar : com -> com -> com.

Tactic Notation "com_cases" tactic(first) tactic(c) :=
  first;
  [ c "SKIP" | c "::=" | c ";" | c "IFB" | c "WHILE" | c "PAR" ].

Notation "'SKIP'" :=
  CSkip.
Notation "l '::=' a" :=
  (CAss l a) (at level 60).
Notation "c1 ; c2" :=
  (CSeq c1 c2) (at level 80, right associativity).
Notation "'WHILE' b 'DO' c 'END'" :=
  (CWhile b c) (at level 80, right associativity).
Notation "'IFB' e1 'THEN' e2 'ELSE' e3 'FI'" :=
  (CIf e1 e2 e3) (at level 80, right associativity).
Notation "'PAR' c1 'WITH' c2 'END'" :=
  (CPar c1 c2) (at level 80, right associativity).

Inductive cstep : state -> com -> com -> state -> Prop :=
  | CS_AssStep : forall st i a a',
    astep st a a' ->
    cstep st (i ::= a) (i ::= a') st
  | CS_Ass : forall st i n,
    cstep st (i ::= (ANum n)) SKIP (update st i n)
  | CS_SeqStep : forall st c1 c1' st' c2,
    cstep st c1 c1' st' ->
    cstep st (c1 ; c2) (c1' ; c2) st'
  | CS_SeqFinish : forall st c2,
    cstep st (SKIP ; c2) c2 st
  | CS_IfTrue : forall st c1 c2,
    cstep st (IFB BTrue THEN c1 ELSE c2 FI) c1 st
  | CS_IfFalse : forall st c1 c2,
    cstep st (IFB BFalse THEN c1 ELSE c2 FI) c2 st
  | CS_IfStep : forall st b b' c1 c2,
    bstep st b b' ->
    cstep st (IFB b THEN c1 ELSE c2 FI) (IFB b' THEN c1 ELSE c2 FI) st
  | CS_While : forall st b c1,
    cstep st (WHILE b DO c1 END)
             (IFB b THEN (c1; (WHILE b DO c1 END)) ELSE SKIP FI) st
  (* New: *)
  | CS_Par1 : forall st c1 c1' c2 st',
    cstep st c1 c1' st' ->
    cstep st (PAR c1 WITH c2 END) (PAR c1' WITH c2 END) st'
  | CS_Par2 : forall st c1 c2 c2' st',
    cstep st c2 c2' st' ->
    cstep st (PAR c1 WITH c2 END) (PAR c1 WITH c2' END) st'
  | CS_ParDone : forall st,
    cstep st (PAR SKIP WITH SKIP END) SKIP st.

A small example: the following program can terminate with X set to any value.

Inductive refl_step_closure4 {X Y : Type} (R: X -> Y -> Y -> X -> Prop)
                             : X -> Y -> Y -> X -> Prop :=
  | rsc4_refl : forall (x : X) (y : Y),
                    refl_step_closure4 R x y y x
  | rsc4_step : forall (x y z : X) (a b c : Y),
                    R x a b y ->
                    refl_step_closure4 R y b c z ->
                    refl_step_closure4 R x a c z.

Definition cstepmany := refl_step_closure4 cstep.

Definition par_loop_init : com :=
  X ::= ANum 0;
  Y ::= ANum 1.

Definition par_loop_body : com :=
  PAR
    Y ::= ANum 0
  WITH
    WHILE BNot (BEq (AId Y) (ANum 0)) DO
      X ::= APlus (AId X) (ANum 1)
    END
  END.

Definition par_loop : com :=
  par_loop_init;
  par_loop_body.

Example par_loop_example_0:
  exists st',
       cstepmany empty_state par_loop SKIP st'
    /\ st' X = 0.
Proof.
  eapply ex_intro. split.
  eapply rsc4_step. apply CS_SeqStep. apply CS_SeqStep. apply CS_Ass.
  eapply rsc4_step. apply CS_SeqStep. apply CS_SeqFinish.
  eapply rsc4_step. apply CS_SeqStep. apply CS_Ass.
  eapply rsc4_step. apply CS_SeqFinish.
  eapply rsc4_step. apply CS_Par1. apply CS_Ass.
  eapply rsc4_step. apply CS_Par2. apply CS_While.
  eapply rsc4_step. apply CS_Par2. apply CS_IfStep.
    apply BS_NotStep. apply BS_Eq1. apply AS_Id.
  eapply rsc4_step. apply CS_Par2. apply CS_IfStep.
    apply BS_NotStep. apply BS_Eq. simpl.
  eapply rsc4_step. apply CS_Par2. apply CS_IfStep.
    apply BS_NotTrue.
  eapply rsc4_step. apply CS_Par2. apply CS_IfFalse.
  eapply rsc4_step. apply CS_ParDone.
  eapply rsc4_refl.
  reflexivity. Qed.

Example par_loop_example_2:
  exists st',
       cstepmany empty_state par_loop SKIP st'
    /\ st' X = 2.
Proof.
  eapply ex_intro. split.
  eapply rsc4_step. apply CS_SeqStep. apply CS_SeqStep. apply CS_Ass.
  eapply rsc4_step. apply CS_SeqStep. apply CS_SeqFinish.
  eapply rsc4_step. apply CS_SeqStep. apply CS_Ass.
  eapply rsc4_step. apply CS_SeqFinish.
  eapply rsc4_step. apply CS_Par2. apply CS_While.
  eapply rsc4_step. apply CS_Par2. apply CS_IfStep.
    apply BS_NotStep. apply BS_Eq1. apply AS_Id.
  eapply rsc4_step. apply CS_Par2. apply CS_IfStep.
    apply BS_NotStep. apply BS_Eq. simpl.
  eapply rsc4_step. apply CS_Par2. apply CS_IfStep.
    apply BS_NotFalse.
  eapply rsc4_step. apply CS_Par2. apply CS_IfTrue.
  eapply rsc4_step. apply CS_Par2. apply CS_SeqStep.
    apply CS_AssStep. apply AS_Plus1. apply AS_Id.
  eapply rsc4_step. apply CS_Par2. apply CS_SeqStep.
    apply CS_AssStep. apply AS_Plus.
  eapply rsc4_step. apply CS_Par2. apply CS_SeqStep.
    apply CS_Ass.
  eapply rsc4_step. apply CS_Par2. apply CS_SeqFinish.

  eapply rsc4_step. apply CS_Par2. apply CS_While.
  eapply rsc4_step. apply CS_Par2. apply CS_IfStep.
    apply BS_NotStep. apply BS_Eq1. apply AS_Id.
  eapply rsc4_step. apply CS_Par2. apply CS_IfStep.
    apply BS_NotStep. apply BS_Eq. simpl.
  eapply rsc4_step. apply CS_Par2. apply CS_IfStep.
    apply BS_NotFalse.
  eapply rsc4_step. apply CS_Par2. apply CS_IfTrue.
  eapply rsc4_step. apply CS_Par2. apply CS_SeqStep.
    apply CS_AssStep. apply AS_Plus1. apply AS_Id.
  eapply rsc4_step. apply CS_Par2. apply CS_SeqStep.
    apply CS_AssStep. apply AS_Plus.
  eapply rsc4_step. apply CS_Par2. apply CS_SeqStep.
    apply CS_Ass.

  eapply rsc4_step. apply CS_Par1. apply CS_Ass.
  eapply rsc4_step. apply CS_Par2. apply CS_SeqFinish.
  eapply rsc4_step. apply CS_Par2. apply CS_While.
  eapply rsc4_step. apply CS_Par2. apply CS_IfStep.
    apply BS_NotStep. apply BS_Eq1. apply AS_Id.
  eapply rsc4_step. apply CS_Par2. apply CS_IfStep.
    apply BS_NotStep. apply BS_Eq. simpl.
  eapply rsc4_step. apply CS_Par2. apply CS_IfStep.
    apply BS_NotTrue.
  eapply rsc4_step. apply CS_Par2. apply CS_IfFalse.
  eapply rsc4_step. apply CS_ParDone.
  eapply rsc4_refl.
  reflexivity. Qed.

Exercise: 5 stars, optional

Prove that par_loop can terminate with X set to any value:
Theorem par_loop_any_X:
  forall n, exists st',
    cstepmany empty_state par_loop SKIP st'
    /\ st' X = n.
(* FILL IN HERE *)

End CImp.