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SeparationLogic: object language
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SeparationLogic.v
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SeparationLogic.v
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(** Formal Reasoning About Programs <http://adam.chlipala.net/frap/>
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* Chapter 12: Separation Logic
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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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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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(** * Encore of last mixed-embedding language from last time *)
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Inductive loop_outcome acc :=
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| Done (a : acc)
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| Again (a : acc).
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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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| Loop {acc : Set} (init : acc) (body : acc -> cmd (loop_outcome acc)) : cmd acc
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| Fail {result} : cmd result
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(* But let's also add memory allocation and deallocation. *)
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| Alloc (numWords : nat) : cmd nat
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| Free (base numWords : 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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Notation "'for' x := i 'loop' c1 'done'" := (Loop i (fun x => c1)) (right associativity, at level 80).
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(* These helper functions respectively initialize a new span of memory and
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* remove a span of memory that the program is done with. *)
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Fixpoint initialize (h : heap) (base numWords : nat) : heap :=
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match numWords with
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| O => h
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| S numWords' => initialize h base numWords' $+ (base + numWords', 0)
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end.
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Fixpoint deallocate (h : heap) (base numWords : nat) : heap :=
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match numWords with
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| O => h
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| S numWords' => deallocate h base numWords' $- (base + numWords')
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end.
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(* Let's do the semantics a bit differently this time, falling back on classic
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* small-step operational semantics. *)
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Inductive step : forall A, heap * cmd A -> heap * cmd A -> Prop :=
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| StepBindRecur : forall result result' (c1 c1' : cmd result') (c2 : result' -> cmd result) h h',
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step (h, c1) (h', c1')
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-> step (h, Bind c1 c2) (h', Bind c1' c2)
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| StepBindProceed : forall (result result' : Set) (v : result') (c2 : result' -> cmd result) h,
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step (h, Bind (Return v) c2) (h, c2 v)
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| StepLoop : forall (acc : Set) (init : acc) (body : acc -> cmd (loop_outcome acc)) h,
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step (h, Loop init body) (h, o <- body init; match o with
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| Done a => Return a
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| Again a => Loop a body
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end)
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| StepRead : forall h a v,
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h $? a = Some v
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-> step (h, Read a) (h, Return v)
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| StepWrite : forall h a v v',
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h $? a = Some v
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-> step (h, Write a v') (h $+ (a, v'), Return tt)
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| StepAlloc : forall h numWords a,
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(forall i, i < numWords -> h $? (a + i) = None)
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-> step (h, Alloc numWords) (initialize h a numWords, Return a)
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| StepFree : forall h a numWords,
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step (h, Free a numWords) (deallocate h a numWords, Return tt).
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Definition trsys_of (h : heap) {result} (c : cmd result) := {|
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Initial := {(h, c)};
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Step := step (A := result)
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|}.
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