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1293 lines
40 KiB
Coq
1293 lines
40 KiB
Coq
(** 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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Set Implicit Arguments.
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Set Asymmetric Patterns.
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(** * Shared notations and definitions; main material starts afterward. *)
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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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Ltac simp := repeat (simplify; subst; propositional;
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try match goal with
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| [ H : ex _ |- _ ] => invert H
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end); try linear_arithmetic.
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(** * Basic concepts of shallow, deep, and mixed embeddings *)
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(* We often have many options for how to encode some sort of formal expression.
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* The simplest way is to write it directly as a Gallina functional program,
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* which Coq knows how to evaluate directly. That style is called
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* *shallow embedding*. *)
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Module SimpleShallow.
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Definition foo (x y : nat) : nat :=
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let u := x + y in
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let v := u * y in
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u + v.
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End SimpleShallow.
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(* Alternatively, we can do as we have been through most of the chapters: define
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* inductive types of program syntax, along with semantics for syntax trees.
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* That style is called *deep embedding*. *)
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Module SimpleDeep.
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Inductive exp :=
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| Const (n : nat)
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| Var (x : var)
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| Plus (e1 e2 : exp)
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| Times (e1 e2 : exp)
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| Let (x : var) (e1 e2 : exp).
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Definition foo : exp :=
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Let "u" (Plus (Var "x") (Var "y"))
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(Let "v" (Times (Var "u") (Var "y"))
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(Plus (Var "u") (Var "v"))).
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Fixpoint interp (e : exp) (v : fmap var nat) : nat :=
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match e with
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| Const n => n
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| Var x => v $! x
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| Plus e1 e2 => interp e1 v + interp e2 v
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| Times e1 e2 => interp e1 v * interp e2 v
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| Let x e1 e2 => interp e2 (v $+ (x, interp e1 v))
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end.
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End SimpleDeep.
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(* We defined function [foo] in shallow and deep styles, and it is easy to prove
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* that the encodings are equivalent. *)
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Theorem shallow_to_deep : forall x y,
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SimpleShallow.foo x y = SimpleDeep.interp SimpleDeep.foo ($0 $+ ("x", x) $+ ("y", y)).
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Proof.
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unfold SimpleShallow.foo.
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simplify.
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reflexivity.
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Qed.
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(* More interestingly, we can mix characteristics of the two styles. To explain
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* exactly how, it's important to introduce the distinction between the
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* *metalanguage*, in which we do our proofs (e.g., Coq for us); and the
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* *object language*, which we formalize explicitly (e.g., lambda calculus,
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* simple imperative programs, ...). With *higher-order abstract syntax*, we
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* represent binders of the object language using the function types of the
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* metalanguage. *)
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Module SimpleMixed.
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Inductive exp :=
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| Const (n : nat)
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| Var (x : string)
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| Plus (e1 e2 : exp)
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| Times (e1 e2 : exp)
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| Let (e1 : exp) (e2 : nat -> exp).
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(* Note a [Let] body is a *function* over the computed value attached to the
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* variable being bound. *)
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Definition foo : exp :=
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Let (Plus (Var "x") (Var "y"))
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(fun u => Let (Times (Const u) (Var "y"))
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(fun v => Plus (Const u) (Const v))).
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Fixpoint interp (e : exp) (v : fmap var nat) : nat :=
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match e with
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| Var x => v $! x
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| Const n => n
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| Plus e1 e2 => interp e1 v + interp e2 v
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| Times e1 e2 => interp e1 v * interp e2 v
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| Let e1 e2 => interp (e2 (interp e1 v)) v
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end.
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(* We can even do useful transformations on such expressions within Gallina,
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* as in this function to recursively simplify additions of 0 and
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* multiplications by 1. *)
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Fixpoint reduce (e : exp) : exp :=
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match e with
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| Var x => Var x
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| Const n => Const n
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| Plus e1 e2 =>
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let e1' := reduce e1 in
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let e2' := reduce e2 in
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match e1' with
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| Const 0 => e2'
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| _ => match e2' with
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| Const 0 => e1'
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| _ => Plus e1' e2'
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end
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end
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| Times e1 e2 =>
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let e1' := reduce e1 in
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let e2' := reduce e2 in
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match e1' with
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| Const 1 => e2'
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| _ => match e2' with
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| Const 1 => e1'
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| _ => Times e1' e2'
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end
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end
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| Let e1 e2 =>
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let e1' := reduce e1 in
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match e1' with
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| Const n => reduce (e2 n)
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| _ => Let e1' (fun n => reduce (e2 n))
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end
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end.
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(* This example shows simplification, even under binders. *)
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Compute (reduce (Let (Plus (Const 0) (Const 1))
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(fun n => Let (Times (Var "x") (Const 2))
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(fun m => Times (Const n) (Const m))))).
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(* The transformation is provably meaning-preserving. *)
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Theorem reduce_ok : forall v e, interp (reduce e) v = interp e v.
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Proof.
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induct e; simplify;
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repeat match goal with
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| [ H : _ = interp _ _ |- _ ] => rewrite <- H
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| [ |- context[match ?E with _ => _ end] ] => cases E; simplify; subst; try linear_arithmetic
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end; eauto.
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Qed.
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End SimpleMixed.
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Theorem shallow_to_mixed : forall x y,
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SimpleShallow.foo x y = SimpleMixed.interp SimpleMixed.foo ($0 $+ ("x", x) $+ ("y", y)).
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Proof.
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unfold SimpleShallow.foo.
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simplify.
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reflexivity.
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Qed.
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(** * Shallow embedding of a language very similar to the one we used last chapter *)
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(* With the basic terminology out of the way, let's see these ideas in action,
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* to encode the sort of imperative language we studied in the previous
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* chapter. *)
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Module Shallow.
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(* As a shallow embedding, we can represent imperative programs as functional
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* programs that manipulate heaps explicitly. *)
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Definition cmd result := heap -> heap * result.
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(* Parameter [result] gives the type of the value being computed by a
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* command. The command is a function taking the initial heap as input, and
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* it returns a pair of the final heap and the command's result. *)
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(* We can redefine Hoare triples over these functional programs. *)
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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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(* Standard rules of Hoare logic can be proved as lemmas. For instance,
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* here's the rule of consequence. *)
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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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(* However, the programs themselves look quite different from those we saw in
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* the previous chapter. This function computes the maximum among the first [i]
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* cells of memory and the accumulator [acc]. *)
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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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(* We can prove its correctness via preconditions and postconditions. *)
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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) h); 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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(* We can also run the program on concrete inputs. *)
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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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(* One more example in the same style: increment each of the first [i] cells
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* of memory. *)
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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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(* One disadvantage of the last style of programs is computational efficiency:
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* real CPU architectures don't manipulate memory as functional maps that are
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* passed around, and the abstraction gap between our code and CPUs prevents us
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* from taking maximum advantage of the hardware to achieve good performance.
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* To help regain that efficiency, let's do a deep embedding of the language.
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* Actually, it's a mixed embedding, with no explicit concept of variables,
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* using higher-order abstract syntax to represent binders. *)
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Module Deep.
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Inductive cmd : Set -> Type :=
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| Return {result : Set} (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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(* These constructors are most easily explained through examples. We'll
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* translate both of the programs from the shallowly embedding above. *)
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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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(* Note how this is truly a mixed encoding: we freely use Gallina constructs
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* like [match], mixed in with instructions specific to the object language,
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* like reading or writing memory. An interpreter explains what it all means,
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* reducing programs to their original type from the shallow embedding. *)
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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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(* This time, we define a Hoare-triple relation syntactically. *)
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Inductive hoare_triple : assertion -> forall {result}, cmd result -> (result -> assertion) -> Prop :=
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| HtReturn : forall P {result : Set} (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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(* Interesting thing about this rule: the second premise uses nested
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* universal quantification over all possible results of the first command. *)
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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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Lemma HtStrengthen : forall {result} (c : cmd result) P Q (Q' : _ -> assertion),
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hoare_triple P c Q
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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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simplify.
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eapply HtConsequence; eauto.
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Qed.
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(* Here are a few tactics, whose details we won't explain, but which
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* streamline the individual program proofs below. *)
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Ltac basic := apply HtReturn || eapply HtRead || eapply HtWrite.
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Ltac step0 := basic || eapply HtBind || (eapply HtStrengthen; [ basic | ]).
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Ltac step := step0; simp.
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Ltac ht := simp; repeat step; eauto.
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Ltac conseq := simplify; eapply HtConsequence.
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Ltac use_IH H := conseq; [ apply H | .. ]; ht.
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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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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; ht.
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use_IH IHi.
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cases (j ==n i); simp.
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assert (h $! j <= 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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conseq.
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apply array_max_ok' with (len := len).
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simp.
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simp.
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auto.
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Qed.
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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; ht.
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use_IH IHi.
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cases (j ==n i); simp.
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auto.
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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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conseq.
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apply increment_all_ok' with (len := len).
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simp.
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simp.
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auto.
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Qed.
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(* It's easy to prove the syntactic Hoare-triple relation sound with
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* respect to the semantic one from the shallow embedding. *)
|
|
Theorem hoare_triple_sound : forall P {result} (c : cmd result) Q,
|
|
hoare_triple P c Q
|
|
-> forall h, P h
|
|
-> let (h', r) := interp c h in
|
|
Q r h'.
|
|
Proof.
|
|
induct 1; simplify; propositional; eauto.
|
|
|
|
specialize (IHhoare_triple h).
|
|
cases (interp c1 h).
|
|
apply H1; eauto.
|
|
|
|
specialize (IHhoare_triple h).
|
|
cases (interp c h).
|
|
eauto.
|
|
Qed.
|
|
|
|
(* We use Coq's *extraction* feature to produce OCaml versions of our deeply
|
|
* embedded programs. Then we can run them using OCaml intepreters, which are
|
|
* able to take advantage of the side effects built into OCaml, as a
|
|
* performance optimization. This command generates file "Deep.ml", which can
|
|
* be loaded along with "DeepInterp.ml" to run the generated code. Note how
|
|
* the latter file uses OCaml's built-in mutable hash-table type for efficient
|
|
* representation of program memories. *)
|
|
Extraction "Deep.ml" array_max increment_all.
|
|
End Deep.
|
|
|
|
|
|
(** * A slightly fancier deep embedding, adding unbounded loops *)
|
|
|
|
Module Deeper.
|
|
(* All programs in the last embedding must terminate, but let's add loops with
|
|
* the potential to run forever, which takes us beyond what is representable
|
|
* in the shallow embedding, since Gallina enforces terminating of all
|
|
* programs. *)
|
|
|
|
(* We use this type to represent the outcome of a single loop iteration.
|
|
* These are functional loops, where we successively modify an accumulator
|
|
* value across iterations. *)
|
|
Inductive loop_outcome acc :=
|
|
| Done (a : acc) (* The loop finished, and here is the final accumulator. *)
|
|
| Again (a : acc) (* Keep looping, with this new accumulator. *).
|
|
|
|
Inductive cmd : Set -> Type :=
|
|
| Return {result : Set} (r : result) : cmd result
|
|
| Bind {result result'} (c1 : cmd result') (c2 : result' -> cmd result) : cmd result
|
|
| Read (a : nat) : cmd nat
|
|
| Write (a v : nat) : cmd unit
|
|
| Loop {acc : Set} (init : acc) (body : acc -> cmd (loop_outcome acc)) : cmd acc.
|
|
|
|
(* Again, it's all easier to explain with an example. *)
|
|
|
|
Notation "x <- c1 ; c2" := (Bind c1 (fun x => c2)) (right associativity, at level 80).
|
|
Notation "'for' x := i 'loop' c1 'done'" := (Loop i (fun x => c1)) (right associativity, at level 80).
|
|
|
|
(* This program finds the first occurrence in memory of value [needle]. *)
|
|
Definition index_of (needle : nat) : cmd nat :=
|
|
for i := 0 loop
|
|
h_i <- Read i;
|
|
if h_i ==n needle then
|
|
Return (Done i)
|
|
else
|
|
Return (Again (S i))
|
|
done.
|
|
|
|
(* Next, we write a single-stepping interpreter for this language. We can
|
|
* know longer write a straightforward big-stepping interpeter, as programs of
|
|
* the object language can diverge, while Gallina enforces termination. *)
|
|
|
|
Inductive stepResult (result : Set) :=
|
|
| Answer (r : result)
|
|
| Stepped (h : heap) (c : cmd result).
|
|
|
|
Fixpoint step {result} (c : cmd result) (h : heap) : stepResult result :=
|
|
match c with
|
|
| Return _ r => Answer r
|
|
| Bind _ _ c1 c2 =>
|
|
match step c1 h with
|
|
| Answer r => Stepped h (c2 r)
|
|
| Stepped h' c1' => Stepped h' (Bind c1' c2)
|
|
end
|
|
| Read a => Answer (h $! a)
|
|
| Write a v => Stepped (h $+ (a, v)) (Return tt)
|
|
| Loop _ init body =>
|
|
Stepped h (r <- body init;
|
|
match r with
|
|
| Done r' => Return r'
|
|
| Again r' => Loop r' body
|
|
end)
|
|
end.
|
|
|
|
Fixpoint multiStep {result} (c : cmd result) (h : heap) (n : nat) : stepResult result :=
|
|
match n with
|
|
| O => Stepped h c
|
|
| S n' => match step c h with
|
|
| Answer r => Answer r
|
|
| Stepped h' c' => multiStep c' h' n'
|
|
end
|
|
end.
|
|
|
|
Example run_index_of : multiStep (index_of 6) h0 20 = Answer 3.
|
|
Proof.
|
|
unfold h0.
|
|
simplify.
|
|
reflexivity.
|
|
Qed.
|
|
|
|
Inductive hoare_triple : assertion -> forall {result}, cmd result -> (result -> assertion) -> Prop :=
|
|
| HtReturn : forall P {result : Set} (v : result),
|
|
hoare_triple P (Return v) (fun r h => P h /\ r = v)
|
|
| HtBind : forall P {result' result} (c1 : cmd result') (c2 : result' -> cmd result) Q R,
|
|
hoare_triple P c1 Q
|
|
-> (forall r, hoare_triple (Q r) (c2 r) R)
|
|
-> hoare_triple P (Bind c1 c2) R
|
|
| HtRead : forall P a,
|
|
hoare_triple P (Read a) (fun r h => P h /\ r = h $! a)
|
|
| HtWrite : forall P a v,
|
|
hoare_triple P (Write a v) (fun _ h => exists h', P h' /\ h = h' $+ (a, v))
|
|
| HtConsequence : forall {result} (c : cmd result) P Q (P' : assertion) (Q' : _ -> assertion),
|
|
hoare_triple P c Q
|
|
-> (forall h, P' h -> P h)
|
|
-> (forall r h, Q r h -> Q' r h)
|
|
-> hoare_triple P' c Q'
|
|
|
|
| HtLoop : forall {acc : Set} (init : acc) (body : acc -> cmd (loop_outcome acc))
|
|
(I : loop_outcome acc -> assertion),
|
|
(forall acc, hoare_triple (I (Again acc)) (body acc) I)
|
|
-> hoare_triple (I (Again init)) (Loop init body) (fun r h => I (Done r) h).
|
|
(* The loop rule contains a tricky new kind of invariant, parameterized on the
|
|
* current loop state: either [Done] for a finished loop or [Again] for a loop
|
|
* still in progress. *)
|
|
|
|
Notation "{{ h ~> P }} c {{ r & h' ~> Q }}" :=
|
|
(hoare_triple (fun h => P) c (fun r h' => Q)) (at level 90, c at next level).
|
|
|
|
Lemma HtStrengthen : forall {result} (c : cmd result) P Q (Q' : _ -> assertion),
|
|
hoare_triple P c Q
|
|
-> (forall r h, Q r h -> Q' r h)
|
|
-> hoare_triple P c Q'.
|
|
Proof.
|
|
simplify.
|
|
eapply HtConsequence; eauto.
|
|
Qed.
|
|
|
|
Lemma HtWeaken : forall {result} (c : cmd result) P Q (P' : assertion),
|
|
hoare_triple P c Q
|
|
-> (forall h, P' h -> P h)
|
|
-> hoare_triple P' c Q.
|
|
Proof.
|
|
simplify.
|
|
eapply HtConsequence; eauto.
|
|
Qed.
|
|
|
|
Ltac basic := apply HtReturn || eapply HtRead || eapply HtWrite.
|
|
Ltac step0 := basic || eapply HtBind || (eapply HtStrengthen; [ basic | ]).
|
|
Ltac step := step0; simp.
|
|
Ltac ht := simp; repeat step; eauto.
|
|
Ltac conseq := simplify; eapply HtConsequence.
|
|
Ltac use_IH H := conseq; [ apply H | .. ]; ht.
|
|
Ltac loop_inv Inv := eapply HtConsequence; [ apply HtLoop with (I := Inv) | .. ]; ht.
|
|
|
|
(* We prove our [index_of] example correct, relying crucially on a tactic
|
|
* [loop_inv] to prove a loop by giving its loop invariant, which, recall, is
|
|
* parameterized on a [loop_outcome]. *)
|
|
Theorem index_of_ok : forall hinit needle,
|
|
{{ h ~> h = hinit }}
|
|
index_of needle
|
|
{{ r&h ~> h = hinit
|
|
/\ hinit $! r = needle
|
|
/\ forall i, i < r -> hinit $! i <> needle }}.
|
|
Proof.
|
|
simplify.
|
|
loop_inv (fun r h => h = hinit
|
|
/\ match r with
|
|
| Done r' => hinit $! r' = needle
|
|
/\ forall i, i < r' -> hinit $! i <> needle
|
|
| Again r' => forall i, i < r' -> hinit $! i <> needle
|
|
end).
|
|
cases (r ==n needle); ht.
|
|
cases (i ==n acc); simp.
|
|
apply H3 with (i0 := i); auto.
|
|
Qed.
|
|
|
|
(* The single-stepping interpreter forms the basis for defining transition
|
|
* systems from commands. *)
|
|
Definition trsys_of {result} (c : cmd result) (h : heap) := {|
|
|
Initial := {(c, h)};
|
|
Step := fun p1 p2 => step (fst p1) (snd p1) = Stepped (snd p2) (fst p2)
|
|
|}.
|
|
|
|
(* We now prove soundness of [hoare_triple], starting from a number of
|
|
* inversion lemmas for it, collapsing the potential effects of many nested
|
|
* rule-of-consequence applications. *)
|
|
|
|
Lemma invert_Return : forall {result : Set} (r : result) P Q,
|
|
hoare_triple P (Return r) Q
|
|
-> forall h, P h -> Q r h.
|
|
Proof.
|
|
induct 1; propositional; eauto.
|
|
Qed.
|
|
|
|
Lemma invert_Bind : forall {result' result} (c1 : cmd result') (c2 : result' -> cmd result) P Q,
|
|
hoare_triple P (Bind c1 c2) Q
|
|
-> exists R, hoare_triple P c1 R
|
|
/\ forall r, hoare_triple (R r) (c2 r) Q.
|
|
Proof.
|
|
induct 1; propositional; eauto.
|
|
|
|
invert IHhoare_triple; propositional.
|
|
eexists; propositional.
|
|
eapply HtWeaken.
|
|
eassumption.
|
|
auto.
|
|
eapply HtStrengthen.
|
|
apply H4.
|
|
auto.
|
|
Qed.
|
|
|
|
(* Highly technical point: in some of the inductions below, we wind up needing
|
|
* to show that the cases for [Read] and [Write] can never overlap, which
|
|
* would imply that they have the same result types, which would mean that the
|
|
* types [unit] and [nat] are equal. *)
|
|
Lemma unit_not_nat : unit = nat -> False.
|
|
Proof.
|
|
simplify.
|
|
assert (exists x : unit, forall y : unit, x = y).
|
|
exists tt; simplify.
|
|
cases y; reflexivity.
|
|
rewrite H in H0.
|
|
invert H0.
|
|
specialize (H1 (S x)).
|
|
linear_arithmetic.
|
|
Qed.
|
|
|
|
Lemma invert_Read : forall a P Q,
|
|
hoare_triple P (Read a) Q
|
|
-> forall h, P h -> Q (h $! a) h.
|
|
Proof.
|
|
induct 1; propositional; eauto.
|
|
apply unit_not_nat in x0.
|
|
propositional.
|
|
Qed.
|
|
|
|
Lemma invert_Write : forall a v P Q,
|
|
hoare_triple P (Write a v) Q
|
|
-> forall h, P h -> Q tt (h $+ (a, v)).
|
|
Proof.
|
|
induct 1; propositional; eauto.
|
|
symmetry in x0.
|
|
apply unit_not_nat in x0.
|
|
propositional.
|
|
Qed.
|
|
|
|
Lemma invert_Loop : forall {acc : Set} (init : acc) (body : acc -> cmd (loop_outcome acc)) P Q,
|
|
hoare_triple P (Loop init body) Q
|
|
-> exists I, (forall acc, hoare_triple (I (Again acc)) (body acc) I)
|
|
/\ (forall h, P h -> I (Again init) h)
|
|
/\ (forall r h, I (Done r) h -> Q r h).
|
|
Proof.
|
|
induct 1; propositional; eauto.
|
|
|
|
invert IHhoare_triple; propositional.
|
|
exists x; propositional; eauto.
|
|
Qed.
|
|
|
|
Lemma step_sound : forall {result} (c : cmd result) h Q,
|
|
hoare_triple (fun h' => h' = h) c Q
|
|
-> match step c h with
|
|
| Answer r => Q r h
|
|
| Stepped h' c' => hoare_triple (fun h'' => h'' = h') c' Q
|
|
end.
|
|
Proof.
|
|
induct c; simplify; propositional.
|
|
|
|
eapply invert_Return.
|
|
eauto.
|
|
simplify; auto.
|
|
|
|
apply invert_Bind in H0.
|
|
invert H0; propositional.
|
|
apply IHc in H0.
|
|
cases (step c h); auto.
|
|
econstructor.
|
|
apply H2.
|
|
equality.
|
|
auto.
|
|
econstructor; eauto.
|
|
|
|
eapply invert_Read; eauto.
|
|
simplify; auto.
|
|
|
|
eapply HtStrengthen.
|
|
econstructor.
|
|
simplify; propositional; subst.
|
|
eapply invert_Write; eauto.
|
|
simplify; auto.
|
|
|
|
apply invert_Loop in H0.
|
|
invert H0; propositional.
|
|
econstructor.
|
|
eapply HtWeaken.
|
|
apply H0.
|
|
equality.
|
|
simplify.
|
|
cases r.
|
|
eapply HtStrengthen.
|
|
econstructor.
|
|
simplify.
|
|
propositional; subst; eauto.
|
|
eapply HtStrengthen.
|
|
eapply HtLoop.
|
|
auto.
|
|
simplify.
|
|
eauto.
|
|
Qed.
|
|
|
|
(* Clever choice of strengthened invariant here: intermediate commands are
|
|
* checked against degenerate preconditions that force equality to the current
|
|
* heap, and the postcondition is preserved across all steps. *)
|
|
Lemma hoare_triple_sound' : forall P {result} (c : cmd result) Q,
|
|
hoare_triple P c Q
|
|
-> forall h, P h
|
|
-> invariantFor (trsys_of c h)
|
|
(fun p => hoare_triple (fun h => h = snd p)
|
|
(fst p)
|
|
Q).
|
|
Proof.
|
|
simplify.
|
|
|
|
apply invariant_induction; simplify.
|
|
|
|
propositional; subst; simplify.
|
|
eapply HtConsequence.
|
|
eassumption.
|
|
equality.
|
|
auto.
|
|
|
|
eapply step_sound in H1.
|
|
rewrite H2 in H1.
|
|
auto.
|
|
Qed.
|
|
|
|
(* Proving: if we reach a [Return] state, the postcondition holds. *)
|
|
Theorem hoare_triple_sound : forall P {result} (c : cmd result) Q,
|
|
hoare_triple P c Q
|
|
-> forall h, P h
|
|
-> invariantFor (trsys_of c h)
|
|
(fun p => forall r, fst p = Return r
|
|
-> Q r (snd p)).
|
|
Proof.
|
|
simplify.
|
|
|
|
eapply invariant_weaken.
|
|
eapply hoare_triple_sound'; eauto.
|
|
simplify.
|
|
rewrite H2 in H1.
|
|
eapply invert_Return; eauto.
|
|
simplify; auto.
|
|
Qed.
|
|
|
|
Extraction "Deeper.ml" index_of.
|
|
End Deeper.
|
|
|
|
|
|
(** * Adding the possibility of program failure *)
|
|
|
|
(* Let's model another effect that can be implemented using native OCaml
|
|
* features. We'll add a very basic form of exceptions, namely just one
|
|
* (uncatchable) exception, for program failure. We'll prove, by the end, that
|
|
* verified programs never throw the exception. *)
|
|
|
|
Module DeeperWithFail.
|
|
Inductive loop_outcome acc :=
|
|
| Done (a : acc)
|
|
| Again (a : acc).
|
|
|
|
Inductive cmd : Set -> Type :=
|
|
| Return {result : Set} (r : result) : cmd result
|
|
| Bind {result result'} (c1 : cmd result') (c2 : result' -> cmd result) : cmd result
|
|
| Read (a : nat) : cmd nat
|
|
| Write (a v : nat) : cmd unit
|
|
| Loop {acc : Set} (init : acc) (body : acc -> cmd (loop_outcome acc)) : cmd acc
|
|
| Fail {result} : cmd result.
|
|
|
|
Notation "x <- c1 ; c2" := (Bind c1 (fun x => c2)) (right associativity, at level 80).
|
|
Notation "'for' x := i 'loop' c1 'done'" := (Loop i (fun x => c1)) (right associativity, at level 80).
|
|
|
|
(* This program loops forever, maintaining a tally in memory address 0.
|
|
* We periodically test that address, failing if it's ever found to be 0. *)
|
|
Definition forever : cmd nat :=
|
|
_ <- Write 0 1;
|
|
for i := 1 loop
|
|
h_i <- Read i;
|
|
acc <- Read 0;
|
|
match acc with
|
|
| 0 => Fail
|
|
| _ =>
|
|
_ <- Write 0 (acc + h_i);
|
|
Return (Again (i + 1))
|
|
end
|
|
done.
|
|
|
|
(* We adapt our single-stepper with a new result kind, for failure. *)
|
|
|
|
Inductive stepResult (result : Set) :=
|
|
| Answer (r : result)
|
|
| Stepped (h : heap) (c : cmd result)
|
|
| Failed.
|
|
|
|
Implicit Arguments Failed [result].
|
|
|
|
Fixpoint step {result} (c : cmd result) (h : heap) : stepResult result :=
|
|
match c with
|
|
| Return _ r => Answer r
|
|
| Bind _ _ c1 c2 =>
|
|
match step c1 h with
|
|
| Answer r => Stepped h (c2 r)
|
|
| Stepped h' c1' => Stepped h' (Bind c1' c2)
|
|
| Failed => Failed
|
|
end
|
|
| Read a => Answer (h $! a)
|
|
| Write a v => Stepped (h $+ (a, v)) (Return tt)
|
|
| Loop _ init body =>
|
|
Stepped h (r <- body init;
|
|
match r with
|
|
| Done r' => Return r'
|
|
| Again r' => Loop r' body
|
|
end)
|
|
| Fail _ => Failed
|
|
end.
|
|
|
|
Fixpoint multiStep {result} (c : cmd result) (h : heap) (n : nat) : stepResult result :=
|
|
match n with
|
|
| O => Stepped h c
|
|
| S n' => match step c h with
|
|
| Answer r => Answer r
|
|
| Stepped h' c' => multiStep c' h' n'
|
|
| Failed => Failed
|
|
end
|
|
end.
|
|
|
|
Extraction "DeeperWithFail.ml" forever.
|
|
|
|
Inductive hoare_triple : assertion -> forall {result}, cmd result -> (result -> assertion) -> Prop :=
|
|
| HtReturn : forall P {result : Set} (v : result),
|
|
hoare_triple P (Return v) (fun r h => P h /\ r = v)
|
|
| HtBind : forall P {result' result} (c1 : cmd result') (c2 : result' -> cmd result) Q R,
|
|
hoare_triple P c1 Q
|
|
-> (forall r, hoare_triple (Q r) (c2 r) R)
|
|
-> hoare_triple P (Bind c1 c2) R
|
|
| HtRead : forall P a,
|
|
hoare_triple P (Read a) (fun r h => P h /\ r = h $! a)
|
|
| HtWrite : forall P a v,
|
|
hoare_triple P (Write a v) (fun _ h => exists h', P h' /\ h = h' $+ (a, v))
|
|
| HtConsequence : forall {result} (c : cmd result) P Q (P' : assertion) (Q' : _ -> assertion),
|
|
hoare_triple P c Q
|
|
-> (forall h, P' h -> P h)
|
|
-> (forall r h, Q r h -> Q' r h)
|
|
-> hoare_triple P' c Q'
|
|
|
|
| HtLoop : forall {acc : Set} (init : acc) (body : acc -> cmd (loop_outcome acc)) I,
|
|
(forall acc, hoare_triple (I (Again acc)) (body acc) I)
|
|
-> hoare_triple (I (Again init)) (Loop init body) (fun r h => I (Done r) h)
|
|
|
|
| HtFail : forall {result},
|
|
hoare_triple (fun _ => False) (Fail (result := result)) (fun _ _ => False).
|
|
(* The rule for [Fail] simply enforces that this command can't be reachable,
|
|
* since it gets an unsatisfiable precondition. *)
|
|
|
|
Notation "{{ h ~> P }} c {{ r & h' ~> Q }}" :=
|
|
(hoare_triple (fun h => P) c (fun r h' => Q)) (at level 90, c at next level).
|
|
|
|
Lemma HtStrengthen : forall {result} (c : cmd result) P Q (Q' : _ -> assertion),
|
|
hoare_triple P c Q
|
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-> (forall r h, Q r h -> Q' r h)
|
|
-> hoare_triple P c Q'.
|
|
Proof.
|
|
simplify.
|
|
eapply HtConsequence; eauto.
|
|
Qed.
|
|
|
|
Lemma HtWeaken : forall {result} (c : cmd result) P Q (P' : assertion),
|
|
hoare_triple P c Q
|
|
-> (forall h, P' h -> P h)
|
|
-> hoare_triple P' c Q.
|
|
Proof.
|
|
simplify.
|
|
eapply HtConsequence; eauto.
|
|
Qed.
|
|
|
|
Ltac basic := apply HtReturn || eapply HtRead || eapply HtWrite.
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|
Ltac step0 := basic || eapply HtBind || (eapply HtStrengthen; [ basic | ])
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|| (eapply HtConsequence; [ apply HtFail | .. ]).
|
|
Ltac step := step0; simp.
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|
Ltac ht := simp; repeat step.
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|
Ltac conseq := simplify; eapply HtConsequence.
|
|
Ltac use_IH H := conseq; [ apply H | .. ]; ht.
|
|
Ltac loop_inv0 Inv := (eapply HtWeaken; [ apply HtLoop with (I := Inv) | .. ])
|
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|| (eapply HtConsequence; [ apply HtLoop with (I := Inv) | .. ]).
|
|
Ltac loop_inv Inv := loop_inv0 Inv; ht.
|
|
|
|
Theorem forever_ok :
|
|
{{ _ ~> True }}
|
|
forever
|
|
{{ _&_ ~> False }}.
|
|
Proof.
|
|
ht.
|
|
loop_inv (fun (r : loop_outcome nat) h => h $! 0 > 0 /\ match r with
|
|
| Done _ => False
|
|
| _ => True
|
|
end).
|
|
cases r1; ht.
|
|
Qed.
|
|
|
|
Definition trsys_of {result} (c : cmd result) (h : heap) := {|
|
|
Initial := {(c, h)};
|
|
Step := fun p1 p2 => step (fst p1) (snd p1) = Stepped (snd p2) (fst p2)
|
|
|}.
|
|
|
|
(* Next, we adapt the proof of soundness from before. *)
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|
|
|
Lemma invert_Return : forall {result : Set} (r : result) P Q,
|
|
hoare_triple P (Return r) Q
|
|
-> forall h, P h -> Q r h.
|
|
Proof.
|
|
induct 1; propositional; eauto.
|
|
Qed.
|
|
|
|
Lemma invert_Bind : forall {result' result} (c1 : cmd result') (c2 : result' -> cmd result) P Q,
|
|
hoare_triple P (Bind c1 c2) Q
|
|
-> exists R, hoare_triple P c1 R
|
|
/\ forall r, hoare_triple (R r) (c2 r) Q.
|
|
Proof.
|
|
induct 1; propositional; eauto.
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|
|
|
invert IHhoare_triple; propositional.
|
|
eexists; propositional.
|
|
eapply HtWeaken.
|
|
eassumption.
|
|
auto.
|
|
eapply HtStrengthen.
|
|
apply H4.
|
|
auto.
|
|
Qed.
|
|
|
|
Lemma unit_not_nat : unit = nat -> False.
|
|
Proof.
|
|
simplify.
|
|
assert (exists x : unit, forall y : unit, x = y).
|
|
exists tt; simplify.
|
|
cases y; reflexivity.
|
|
rewrite H in H0.
|
|
invert H0.
|
|
specialize (H1 (S x)).
|
|
linear_arithmetic.
|
|
Qed.
|
|
|
|
Lemma invert_Read : forall a P Q,
|
|
hoare_triple P (Read a) Q
|
|
-> forall h, P h -> Q (h $! a) h.
|
|
Proof.
|
|
induct 1; propositional; eauto.
|
|
apply unit_not_nat in x0.
|
|
propositional.
|
|
Qed.
|
|
|
|
Lemma invert_Write : forall a v P Q,
|
|
hoare_triple P (Write a v) Q
|
|
-> forall h, P h -> Q tt (h $+ (a, v)).
|
|
Proof.
|
|
induct 1; propositional; eauto.
|
|
symmetry in x0.
|
|
apply unit_not_nat in x0.
|
|
propositional.
|
|
Qed.
|
|
|
|
Lemma invert_Loop : forall {acc : Set} (init : acc) (body : acc -> cmd (loop_outcome acc)) P Q,
|
|
hoare_triple P (Loop init body) Q
|
|
-> exists I, (forall acc, hoare_triple (I (Again acc)) (body acc) I)
|
|
/\ (forall h, P h -> I (Again init) h)
|
|
/\ (forall r h, I (Done r) h -> Q r h).
|
|
Proof.
|
|
induct 1; propositional; eauto.
|
|
|
|
invert IHhoare_triple; propositional.
|
|
exists x; propositional; eauto.
|
|
Qed.
|
|
|
|
Lemma invert_Fail : forall result P Q,
|
|
hoare_triple P (Fail (result := result)) Q
|
|
-> forall h, P h -> False.
|
|
Proof.
|
|
induct 1; propositional; eauto.
|
|
Qed.
|
|
|
|
Lemma step_sound : forall {result} (c : cmd result) h Q,
|
|
hoare_triple (fun h' => h' = h) c Q
|
|
-> match step c h with
|
|
| Answer r => Q r h
|
|
| Stepped h' c' => hoare_triple (fun h'' => h'' = h') c' Q
|
|
| Failed => False
|
|
end.
|
|
Proof.
|
|
induct c; simplify; propositional.
|
|
|
|
eapply invert_Return.
|
|
eauto.
|
|
simplify; auto.
|
|
|
|
apply invert_Bind in H0.
|
|
invert H0; propositional.
|
|
apply IHc in H0.
|
|
cases (step c h); auto.
|
|
econstructor.
|
|
apply H2.
|
|
equality.
|
|
auto.
|
|
econstructor; eauto.
|
|
|
|
eapply invert_Read; eauto.
|
|
simplify; auto.
|
|
|
|
eapply HtStrengthen.
|
|
econstructor.
|
|
simplify; propositional; subst.
|
|
eapply invert_Write; eauto.
|
|
simplify; auto.
|
|
|
|
apply invert_Loop in H0.
|
|
invert H0; propositional.
|
|
econstructor.
|
|
eapply HtWeaken.
|
|
apply H0.
|
|
equality.
|
|
simplify.
|
|
cases r.
|
|
eapply HtStrengthen.
|
|
econstructor.
|
|
simplify.
|
|
propositional; subst; eauto.
|
|
eapply HtStrengthen.
|
|
eapply HtLoop.
|
|
auto.
|
|
simplify.
|
|
eauto.
|
|
|
|
eapply invert_Fail; eauto.
|
|
simplify; eauto.
|
|
Qed.
|
|
|
|
Lemma hoare_triple_sound' : forall P {result} (c : cmd result) Q,
|
|
hoare_triple P c Q
|
|
-> forall h, P h
|
|
-> invariantFor (trsys_of c h)
|
|
(fun p => hoare_triple (fun h => h = snd p)
|
|
(fst p)
|
|
Q).
|
|
Proof.
|
|
simplify.
|
|
|
|
apply invariant_induction; simplify.
|
|
|
|
propositional; subst; simplify.
|
|
eapply HtConsequence.
|
|
eassumption.
|
|
equality.
|
|
auto.
|
|
|
|
eapply step_sound in H1.
|
|
rewrite H2 in H1.
|
|
auto.
|
|
Qed.
|
|
|
|
Theorem hoare_triple_sound : forall P {result} (c : cmd result) Q,
|
|
hoare_triple P c Q
|
|
-> forall h, P h
|
|
-> invariantFor (trsys_of c h)
|
|
(fun p => step (fst p) (snd p) <> Failed).
|
|
Proof.
|
|
simplify.
|
|
|
|
eapply invariant_weaken.
|
|
eapply hoare_triple_sound'; eauto.
|
|
simplify.
|
|
eapply step_sound in H1.
|
|
cases (step (fst s) (snd s)); equality.
|
|
Qed.
|
|
|
|
|
|
(** ** Showcasing the opportunity to create new programming abstractions,
|
|
* without modifying the language definition *)
|
|
|
|
(* Here's an example of a new programming construct defined within Gallina,
|
|
* without extending the definition of object-language syntax. It's for
|
|
* folding a command over every one of the first [len] cells in memory. We
|
|
* work with some accumulator type [A], initializing the accumulator to [init]
|
|
* and calling [combine] to update the accumulator for each value we read out
|
|
* of memory. *)
|
|
Definition heapfold {A : Set} (init : A) (combine : A -> nat -> cmd A) (len : nat) : cmd A :=
|
|
p <- for p := (0, init) loop
|
|
if len <=? fst p then
|
|
Return (Done p)
|
|
else
|
|
h_i <- Read (fst p);
|
|
acc <- combine (snd p) h_i;
|
|
Return (Again (S (fst p), acc))
|
|
done;
|
|
Return (snd p).
|
|
|
|
(* Next, two pretty mundane facts about list operations. *)
|
|
|
|
Lemma firstn_nochange : forall A (ls : list A) n,
|
|
length ls <= n
|
|
-> firstn n ls = ls.
|
|
Proof.
|
|
induct ls; simplify.
|
|
|
|
cases n; simplify; auto.
|
|
|
|
cases n; simplify.
|
|
linear_arithmetic.
|
|
rewrite IHls; auto.
|
|
Qed.
|
|
|
|
Lemma fold_left_firstn : forall A B (f : A -> B -> A) (d : B) (ls : list B) (init : A) n,
|
|
n < length ls
|
|
-> f (fold_left f (firstn n ls) init) (nth_default d ls n)
|
|
= fold_left f (firstn (S n) ls) init.
|
|
Proof.
|
|
induct ls; simplify.
|
|
linear_arithmetic.
|
|
cases n; simplify.
|
|
unfold nth_default; simplify.
|
|
reflexivity.
|
|
rewrite <- IHls by linear_arithmetic.
|
|
unfold nth_default; simplify.
|
|
reflexivity.
|
|
Qed.
|
|
|
|
Hint Rewrite firstn_nochange fold_left_firstn using linear_arithmetic.
|
|
|
|
(* Here's the soundness theorem for [heapfold], relying on a hypothesis of
|
|
* soundness for [combine]. *)
|
|
Theorem heapfold_ok : forall {A : Set} (init : A) combine
|
|
(ls : list nat) (f : A -> nat -> A),
|
|
(forall P v acc,
|
|
{{h ~> P h}}
|
|
combine acc v
|
|
{{r&h ~> r = f acc v /\ P h}})
|
|
-> {{h ~> forall i, i < length ls -> h $! i = nth_default 0 ls i}}
|
|
heapfold init combine (length ls)
|
|
{{r&h ~> (forall i, i < length ls -> h $! i = nth_default 0 ls i)
|
|
/\ r = fold_left f ls init}}.
|
|
Proof.
|
|
ht.
|
|
loop_inv (fun r h => (forall i, i < length ls -> h $! i = nth_default 0 ls i)
|
|
/\ match r with
|
|
| Done (_, acc) => acc = fold_left f ls init
|
|
| Again (i, acc) => acc = fold_left f (firstn i ls) init
|
|
end).
|
|
cases (length ls <=? a); ht; auto; simp; auto.
|
|
rewrite H2 by assumption.
|
|
simplify.
|
|
reflexivity.
|
|
simp; auto.
|
|
simp.
|
|
Qed.
|
|
|
|
(* Here's a concrete use of [heapfold], to implement [array_max] more
|
|
* succinctly. *)
|
|
Definition array_max (len : nat) : cmd nat :=
|
|
heapfold 0 (fun n m => Return (max n m)) len.
|
|
|
|
(* Next, some more lemmas about lists and arithmetic *)
|
|
|
|
Lemma le_max' : forall v ls acc,
|
|
v <= acc
|
|
-> v <= fold_left max ls acc.
|
|
Proof.
|
|
induct ls; simplify; auto.
|
|
Qed.
|
|
|
|
Lemma le_max : forall ls i acc,
|
|
i < Datatypes.length ls
|
|
-> nth_default 0 ls i <= fold_left max ls acc.
|
|
Proof.
|
|
induct ls; simplify.
|
|
|
|
linear_arithmetic.
|
|
|
|
cases i; simplify.
|
|
unfold nth_default; simplify.
|
|
apply le_max'; linear_arithmetic.
|
|
unfold nth_default; simplify.
|
|
apply IHls; linear_arithmetic.
|
|
Qed.
|
|
|
|
Hint Resolve le_max.
|
|
|
|
(* Finally, a short proof of [array_max], appealing mostly to the generic
|
|
* proof of [heapfold] *)
|
|
Theorem array_max_ok : forall ls : list nat,
|
|
{{ h ~> forall i, i < length ls -> h $! i = nth_default 0 ls i}}
|
|
array_max (length ls)
|
|
{{ r&h ~> forall i, i < length ls -> h $! i <= r }}.
|
|
Proof.
|
|
conseq.
|
|
apply heapfold_ok with (f := max); ht.
|
|
simp; auto.
|
|
simp.
|
|
rewrite H1 by assumption.
|
|
auto.
|
|
Qed.
|
|
End DeeperWithFail.
|