Commit 8ed7cf25 authored by Adam Chlipala's avatar Adam Chlipala

Co-inductive non-termination monads

parent 837eb6ae
......@@ -31,7 +31,7 @@ This would leave us with [bad tt] as a proof of [P].
There are also algorithmic considerations that make universal termination very desirable. We have seen how tactics like [reflexivity] compare terms up to equivalence under computational rules. Calls to recursive, pattern-matching functions are simplified automatically, with no need for explicit proof steps. It would be very hard to hold onto that kind of benefit if it became possible to write non-terminating programs; we would be running smack into the halting problem.
One solution is to use types to contain the possibility of non-termination. For instance, we can create a %``%#"#non-termination monad,#"#%''% inside which we must write all of our general-recursive programs. This is a heavyweight solution, and so we would like to avoid it whenever possible.
One solution is to use types to contain the possibility of non-termination. For instance, we can create a %``%#"#non-termination monad,#"#%''% inside which we must write all of our general-recursive programs; several such approaches are surveyed in Chapter 7. This is a heavyweight solution, and so we would like to avoid it whenever possible.
Luckily, Coq has special support for a class of lazy data structures that happens to contain most examples found in Haskell. That mechanism, %\index{co-inductive types}\textit{%#<i>#co-inductive types#</i>#%}%, is the subject of this chapter. *)
......
......@@ -277,7 +277,7 @@ well_founded_induction
Some more recent Coq features provide more convenient syntax for defining recursive functions. Interested readers can consult the Coq manual about the commands %\index{Function}%[Function] and %\index{Program Fixpoint}%[Program Fixpoint]. *)
(** * A Non-Termination Monad *)
(** * A Non-Termination Monad Inspired by Domain Theory *)
Section computation.
Variable A : Type.
......@@ -577,3 +577,265 @@ Defined.
Lemma test_looper : run (looper true) tt.
exists 1; reflexivity.
Qed.
(** * Co-Inductive Non-Termination Monads *)
CoInductive thunk (A : Type) : Type :=
| Answer : A -> thunk A
| Think : thunk A -> thunk A.
CoFixpoint TBind (A B : Type) (m1 : thunk A) (m2 : A -> thunk B) : thunk B :=
match m1 with
| Answer x => m2 x
| Think m1' => Think (TBind m1' m2)
end.
CoInductive thunk_eq A : thunk A -> thunk A -> Prop :=
| EqAnswer : forall x, thunk_eq (Answer x) (Answer x)
| EqThinkL : forall m1 m2, thunk_eq m1 m2 -> thunk_eq (Think m1) m2
| EqThinkR : forall m1 m2, thunk_eq m1 m2 -> thunk_eq m1 (Think m2).
Section thunk_eq_coind.
Variable A : Type.
Variable P : thunk A -> thunk A -> Prop.
Hypothesis H : forall m1 m2, P m1 m2
-> match m1, m2 with
| Answer x1, Answer x2 => x1 = x2
| Think m1', Think m2' => P m1' m2'
| Think m1', _ => P m1' m2
| _, Think m2' => P m1 m2'
end.
Theorem thunk_eq_coind : forall m1 m2, P m1 m2 -> thunk_eq m1 m2.
cofix; intros;
match goal with
| [ H' : P _ _ |- _ ] => specialize (H H'); clear H'
end; destruct m1; destruct m2; subst; repeat constructor; auto.
Qed.
End thunk_eq_coind.
Definition frob A (m : thunk A) : thunk A :=
match m with
| Answer x => Answer x
| Think m' => Think m'
end.
Theorem frob_eq : forall A (m : thunk A), frob m = m.
destruct m; reflexivity.
Qed.
Theorem thunk_eq_frob : forall A (m1 m2 : thunk A),
thunk_eq (frob m1) (frob m2)
-> thunk_eq m1 m2.
intros; repeat rewrite frob_eq in *; auto.
Qed.
Ltac findDestr := match goal with
| [ |- context[match ?E with Answer _ => _ | Think _ => _ end] ] =>
match E with
| context[match _ with Answer _ => _ | Think _ => _ end] => fail 1
| _ => destruct E
end
end.
Theorem thunk_eq_refl : forall A (m : thunk A), thunk_eq m m.
intros; apply (thunk_eq_coind (fun m1 m2 => m1 = m2)); crush; findDestr; reflexivity.
Qed.
Hint Resolve thunk_eq_refl.
Theorem tleft_identity : forall A B (a : A) (f : A -> thunk B),
thunk_eq (TBind (Answer a) f) (f a).
intros; apply thunk_eq_frob; crush.
Qed.
Theorem tright_identity : forall A (m : thunk A),
thunk_eq (TBind m (@Answer _)) m.
intros; apply (thunk_eq_coind (fun m1 m2 => m1 = TBind m2 (@Answer _))); crush;
findDestr; reflexivity.
Qed.
Lemma TBind_Answer : forall (A B : Type) (v : A) (m2 : A -> thunk B),
TBind (Answer v) m2 = m2 v.
intros; rewrite <- (frob_eq (TBind (Answer v) m2));
simpl; findDestr; reflexivity.
Qed.
Hint Rewrite TBind_Answer : cpdt.
Theorem tassociativity : forall A B C (m : thunk A) (f : A -> thunk B) (g : B -> thunk C),
thunk_eq (TBind (TBind m f) g) (TBind m (fun x => TBind (f x) g)).
intros; apply (thunk_eq_coind (fun m1 m2 => (exists m,
m1 = TBind (TBind m f) g
/\ m2 = TBind m (fun x => TBind (f x) g))
\/ m1 = m2)); crush; eauto; repeat (findDestr; crush; eauto).
Qed.
CoFixpoint fact (n acc : nat) : thunk nat :=
match n with
| O => Answer acc
| S n' => Think (fact n' (S n' * acc))
end.
Inductive eval A : thunk A -> A -> Prop :=
| EvalAnswer : forall x, eval (Answer x) x
| EvalThink : forall m x, eval m x -> eval (Think m) x.
Hint Rewrite frob_eq : cpdt.
Lemma eval_frob : forall A (c : thunk A) x,
eval (frob c) x
-> eval c x.
crush.
Qed.
Theorem eval_fact : eval (fact 5 1) 120.
repeat (apply eval_frob; simpl; constructor).
Qed.
(** [[
CoFixpoint fib (n : nat) : thunk nat :=
match n with
| 0 => Answer 1
| 1 => Answer 1
| _ => TBind (fib (pred n)) (fun n1 =>
TBind (fib (pred (pred n))) (fun n2 =>
Answer (n1 + n2)))
end.
]]
*)
CoInductive comp (A : Type) : Type :=
| Ret : A -> comp A
| Bnd : forall B, comp B -> (B -> comp A) -> comp A.
Inductive exec A : comp A -> A -> Prop :=
| ExecRet : forall x, exec (Ret x) x
| ExecBnd : forall B (c : comp B) (f : B -> comp A) x1 x2, exec (A := B) c x1
-> exec (f x1) x2
-> exec (Bnd c f) x2.
Hint Constructors exec.
Definition comp_eq A (c1 c2 : comp A) := forall r, exec c1 r <-> exec c2 r.
Ltac inverter := repeat match goal with
| [ H : exec _ _ |- _ ] => inversion H; []; crush
end.
Theorem cleft_identity : forall A B (a : A) (f : A -> comp B),
comp_eq (Bnd (Ret a) f) (f a).
red; crush; inverter; eauto.
Qed.
Theorem cright_identity : forall A (m : comp A),
comp_eq (Bnd m (@Ret _)) m.
red; crush; inverter; eauto.
Qed.
Lemma cassociativity1 : forall A B C (f : A -> comp B) (g : B -> comp C) r c,
exec c r
-> forall m, c = Bnd (Bnd m f) g
-> exec (Bnd m (fun x => Bnd (f x) g)) r.
induction 1; crush.
match goal with
| [ H : Bnd _ _ = Bnd _ _ |- _ ] => injection H; clear H; intros; try subst
end.
move H3 after A.
generalize dependent B0.
do 2 intro.
subst.
crush.
inversion H; clear H; crush.
eauto.
Qed.
Lemma cassociativity2 : forall A B C (f : A -> comp B) (g : B -> comp C) r c,
exec c r
-> forall m, c = Bnd m (fun x => Bnd (f x) g)
-> exec (Bnd (Bnd m f) g) r.
induction 1; crush.
match goal with
| [ H : Bnd _ _ = Bnd _ _ |- _ ] => injection H; clear H; intros; try subst
end.
move H3 after B.
generalize dependent B0.
do 2 intro.
subst.
crush.
inversion H0; clear H0; crush.
eauto.
Qed.
Hint Resolve cassociativity1 cassociativity2.
Theorem cassociativity : forall A B C (m : comp A) (f : A -> comp B) (g : B -> comp C),
comp_eq (Bnd (Bnd m f) g) (Bnd m (fun x => Bnd (f x) g)).
red; crush; eauto.
Qed.
CoFixpoint mergeSort'' A (le : A -> A -> bool) (ls : list A) : comp (list A) :=
if le_lt_dec 2 (length ls)
then let lss := partition ls in
Bnd (mergeSort'' le (fst lss)) (fun ls1 =>
Bnd (mergeSort'' le (snd lss)) (fun ls2 =>
Ret (merge le ls1 ls2)))
else Ret ls.
Definition frob' A (c : comp A) :=
match c with
| Ret x => Ret x
| Bnd _ c' f => Bnd c' f
end.
Lemma frob'_eq : forall A (c : comp A), frob' c = c.
destruct c; reflexivity.
Qed.
Hint Rewrite frob'_eq : cpdt.
Lemma exec_frob : forall A (c : comp A) x,
exec (frob' c) x
-> exec c x.
crush.
Qed.
Lemma test_mergeSort'' : exec (mergeSort'' leb (1 :: 2 :: 36 :: 8 :: 19 :: nil))
(1 :: 2 :: 8 :: 19 :: 36 :: nil).
repeat (apply exec_frob; simpl; econstructor).
Qed.
Definition curriedAdd (n : nat) := Ret (fun m : nat => Ret (n + m)).
(** [[
Definition testCurriedAdd :=
Bnd (curriedAdd 2) (fun f => f 3).
]]
<<
Error: Universe inconsistency.
>>
*)
(** * Comparing the Options *)
Definition curriedAdd' (n : nat) := Return (fun m : nat => Return (n + m)).
Definition testCurriedAdd :=
Bind (curriedAdd' 2) (fun f => f 3).
Fixpoint map A B (f : A -> computation B) (ls : list A) : computation (list B) :=
match ls with
| nil => Return nil
| x :: ls' => Bind (f x) (fun x' =>
Bind (map f ls') (fun ls'' =>
Return (x' :: ls'')))
end.
Theorem test_map : run (map (fun x => Return (S x)) (1 :: 2 :: 3 :: nil)) (2 :: 3 :: 4 :: nil).
exists 1; reflexivity.
Qed.
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