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DeepAndShallowEmbeddings: ran some code in OCaml
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@ -15,3 +15,4 @@ Makefile.coq
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*.vo
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frap.tgz
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.coq-native
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Deep.ml*
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234
DeepAndShallowEmbeddings.v
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234
DeepAndShallowEmbeddings.v
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(** Formal Reasoning About Programs <http://adam.chlipala.net/frap/>
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* Chapter 11: Deep and Shallow Embeddings
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* Author: Adam Chlipala
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* License: https://creativecommons.org/licenses/by-nc-nd/4.0/ *)
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Require Import Frap.
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(** * Shared notations and definitions *)
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Notation "m $! k" := (match m $? k with Some n => n | None => O end) (at level 30).
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Definition heap := fmap nat nat.
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Definition assertion := heap -> Prop.
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Hint Extern 1 (_ <= _) => linear_arithmetic.
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Hint Extern 1 (@eq nat _ _) => linear_arithmetic.
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Example h0 : heap := $0 $+ (0, 2) $+ (1, 1) $+ (2, 8) $+ (3, 6).
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Hint Rewrite max_l max_r using linear_arithmetic.
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(** * Shallow embedding of a language very similar to the one we used last chapter *)
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Module Shallow.
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Definition cmd result := heap -> heap * result.
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Definition hoare_triple (P : assertion) {result} (c : cmd result) (Q : result -> assertion) :=
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forall h, P h
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-> let (h', r) := c h in
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Q r h'.
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Notation "{{ h ~> P }} c {{ r & h' ~> Q }}" :=
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(hoare_triple (fun h => P) c (fun r h' => Q)) (at level 90, c at next level).
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Theorem consequence : forall P {result} (c : cmd result) Q
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(P' : assertion) (Q' : _ -> assertion),
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hoare_triple P c Q
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-> (forall h, P' h -> P h)
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-> (forall r h, Q r h -> Q' r h)
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-> hoare_triple P' c Q'.
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Proof.
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unfold hoare_triple; simplify.
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specialize (H h).
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specialize (H0 h).
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cases (c h).
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auto.
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Qed.
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Fixpoint array_max (i acc : nat) : cmd nat :=
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fun h =>
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match i with
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| O => (h, acc)
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| S i' =>
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let h_i' := h $! i' in
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array_max i' (max h_i' acc) h
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end.
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Lemma array_max_ok' : forall len i acc,
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{{ h ~> forall j, i <= j < len -> h $! j <= acc }}
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array_max i acc
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{{ r&h ~> forall j, j < len -> h $! j <= r }}.
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Proof.
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induct i; unfold hoare_triple in *; simplify; propositional; auto.
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specialize (IHi (max (h $! i) acc) h); propositional.
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cases (array_max i (max (h $! i) acc)); simplify; propositional; subst.
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apply IHi; auto.
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simplify.
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cases (j0 ==n i); subst; auto.
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assert (h $! j0 <= acc) by auto.
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linear_arithmetic.
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Qed.
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Theorem array_max_ok : forall len,
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{{ _ ~> True }}
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array_max len 0
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{{ r&h ~> forall i, i < len -> h $! i <= r }}.
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Proof.
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simplify.
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eapply consequence.
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apply array_max_ok' with (len := len).
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simplify.
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linear_arithmetic.
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auto.
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Qed.
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Example run_array_max0 : array_max 4 0 h0 = (h0, 8).
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Proof.
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unfold h0.
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simplify.
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reflexivity.
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Qed.
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Fixpoint increment_all (i : nat) : cmd unit :=
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fun h =>
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match i with
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| O => (h, tt)
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| S i' => increment_all i' (h $+ (i', S (h $! i')))
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end.
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Lemma increment_all_ok' : forall len h0 i,
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{{ h ~> (forall j, j < i -> h $! j = h0 $! j)
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/\ (forall j, i <= j < len -> h $! j = S (h0 $! j)) }}
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increment_all i
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{{ _&h ~> forall j, j < len -> h $! j = S (h0 $! j) }}.
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Proof.
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induct i; unfold hoare_triple in *; simplify; propositional; auto.
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specialize (IHi (h $+ (i, S (h $! i)))); propositional.
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cases (increment_all i (h $+ (i, S (h $! i)))); simplify; propositional; subst.
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apply H; simplify; auto.
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cases (j0 ==n i); subst; auto.
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simplify; auto.
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simplify; auto.
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Qed.
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Theorem increment_all_ok : forall len h0,
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{{ h ~> h = h0 }}
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increment_all len
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{{ _&h ~> forall j, j < len -> h $! j = S (h0 $! j) }}.
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Proof.
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simplify.
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eapply consequence.
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apply increment_all_ok' with (len := len).
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simplify; subst; propositional.
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linear_arithmetic.
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simplify.
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auto.
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Qed.
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Example run_increment_all0 : increment_all 4 h0 = ($0 $+ (0, 3) $+ (1, 2) $+ (2, 9) $+ (3, 7), tt).
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Proof.
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unfold h0.
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simplify.
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f_equal.
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maps_equal.
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Qed.
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End Shallow.
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(** * A basic deep embedding *)
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Module Deep.
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Inductive cmd : Type -> Type :=
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| Return {result} (r : result) : cmd result
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| Bind {result result'} (c1 : cmd result') (c2 : result' -> cmd result) : cmd result
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| Read (a : nat) : cmd nat
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| Write (a v : nat) : cmd unit.
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Notation "x <- c1 ; c2" := (Bind c1 (fun x => c2)) (right associativity, at level 80).
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Fixpoint array_max (i acc : nat) : cmd nat :=
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match i with
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| O => Return acc
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| S i' =>
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h_i' <- Read i';
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array_max i' (max h_i' acc)
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end.
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Fixpoint increment_all (i : nat) : cmd unit :=
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match i with
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| O => Return tt
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| S i' =>
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v <- Read i';
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_ <- Write i' (S v);
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increment_all i'
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end.
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Fixpoint interp {result} (c : cmd result) (h : heap) : heap * result :=
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match c with
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| Return r => (h, r)
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| Bind c1 c2 =>
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let (h', r) := interp c1 h in
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interp (c2 r) h'
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| Read a => (h, h $! a)
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| Write a v => (h $+ (a, v), tt)
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end.
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Example run_array_max0 : interp (array_max 4 0) h0 = (h0, 8).
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Proof.
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unfold h0.
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simplify.
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reflexivity.
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Qed.
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Example run_increment_all0 : interp (increment_all 4) h0 = ($0 $+ (0, 3) $+ (1, 2) $+ (2, 9) $+ (3, 7), tt).
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Proof.
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unfold h0.
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simplify.
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f_equal.
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maps_equal.
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Qed.
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Inductive hoare_triple : assertion -> forall {result}, cmd result -> (result -> assertion) -> Prop :=
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| HtReturn : forall P {result} (v : result),
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hoare_triple P (Return v) (fun r h => P h /\ r = v)
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| HtBind : forall P {result' result} (c1 : cmd result') (c2 : result' -> cmd result) Q R,
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hoare_triple P c1 Q
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-> (forall r, hoare_triple (Q r) (c2 r) R)
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-> hoare_triple P (Bind c1 c2) R
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| HtRead : forall P a,
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hoare_triple P (Read a) (fun r h => P h /\ r = h $! a)
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| HtWrite : forall P a v,
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hoare_triple P (Write a v) (fun _ h => exists h', P h' /\ h = h' $+ (a, v))
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| HtConsequence : forall {result} (c : cmd result) P Q (P' : assertion) (Q' : _ -> assertion),
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hoare_triple P c Q
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-> (forall h, P' h -> P h)
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-> (forall r h, Q r h -> Q' r h)
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-> hoare_triple P' c Q'.
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Theorem hoare_triple_sound : forall P {result} (c : cmd result) Q,
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hoare_triple P c Q
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-> forall h, P h
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-> let (h', r) := interp c h in
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Q r h'.
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Proof.
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induct 1; simplify; propositional; eauto.
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specialize (IHhoare_triple h).
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cases (interp c1 h).
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apply H1; eauto.
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specialize (IHhoare_triple h).
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cases (interp c h).
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eauto.
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Qed.
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Extraction "Deep.ml" array_max increment_all.
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End Deep.
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24
DeepInterp.ml
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24
DeepInterp.ml
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let rec i2n n =
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match n with
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| 0 -> O
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| _ -> S (i2n (n - 1))
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let interp c =
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let h : (nat, nat) Hashtbl.t = Hashtbl.create 0 in
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Hashtbl.add h (i2n 0) (i2n 2);
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Hashtbl.add h (i2n 1) (i2n 1);
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Hashtbl.add h (i2n 2) (i2n 8);
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Hashtbl.add h (i2n 3) (i2n 6);
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let rec interp' (c : 'a cmd) : 'a =
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match c with
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| Return v -> v
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| Bind (c1, c2) -> interp' (c2 (interp' c1))
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| Read a ->
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Obj.magic (try
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Hashtbl.find h a
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with Not_found -> O)
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| Write (a, v) -> Obj.magic (Hashtbl.replace h a v)
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in let v = interp' c in
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h, v
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