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Commented ProgramDerivation, with chapter renumbering in Coq code
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(** Formal Reasoning About Programs <http://adam.chlipala.net/frap/>
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* Chapter 17: Concurrent Separation Logic
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* Chapter 18: Concurrent 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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@ -1,5 +1,5 @@
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(** Formal Reasoning About Programs <http://adam.chlipala.net/frap/>
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* Chapter 18: Process Algebra and Behavioral Refinement
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* Chapter 19: Process Algebra and Behavioral Refinement
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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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@ -4,7 +4,7 @@
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* License: https://creativecommons.org/licenses/by-nc-nd/4.0/
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* Some material borrowed from Fiat <http://plv.csail.mit.edu/fiat/> *)
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Require Import FrapWithoutSets.
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Require Import Frap.
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Require Import Program Setoids.Setoid Classes.RelationClasses Classes.Morphisms Morphisms_Prop.
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Require Import Eqdep.
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@ -14,17 +14,49 @@ Ltac inv_pair :=
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end.
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(* We have generally focused so far on proving that programs meet
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* specifications. What if we could generate programs from their
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* specifications, in ways that guarantee correctness? Let's explore that
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* direction, in the tradition of *program derivation* via
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* *stepwise refinement*. *)
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(** * The computation monad *)
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Definition comp (A : Type) := A -> Prop.
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(* One counterintuitive design choice will be to represent specifications and
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* implementations in the same "language," which is essentially Gallina with the
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* added ability to pick elements nondeterministically from arbitrary sets. *)
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(* Specifically, a process producing type [A] is represents as [comp A]. *)
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Definition comp (A : Type) := A -> Prop.
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(* The computation is represented by the set of legal values it might
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* generate. *)
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(* Computations form a monad, with the following two operators. *)
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Definition ret {A} (x : A) : comp A := eq x.
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(* Note how [eq x] is one way of writing "the singleton set of [x],", using
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* partial application of the two-argument equality predicate [eq]. *)
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Definition bind {A B} (c1 : comp A) (c2 : A -> comp B) : comp B :=
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fun b => exists a, c1 a /\ c2 a b.
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Definition pick_ {A} (P : A -> Prop) : comp A := P.
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(* As in some of our earlier examples, [bind] is for sequencing one computation
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* after another. For this monad, existential quantification provides a natural
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* explanation of sequencing. *)
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Definition pick_ {A} (P : A -> Prop) : comp A := P.
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(* Here is a convenient wrapper function for injecting an arbitrary set into
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* [comp]. This operator stands for nondeterministic choice of any value in the
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* set. *)
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(* Here is the correctness condition, for when [c2] implements [c1]. From left
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* to right in the operands of [refine], we move closer to a concrete
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* implementation. *)
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Definition refine {A} (c1 c2 : comp A) :=
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forall a, c2 a -> c1 a.
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(* Note how this definition is just subset inclusion, in the right direction. *)
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(* Next, we use Coq's *setoid* feature to declare compatibility of our
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* definitions with the [rewrite] tactic. See the Coq manual on setoids for
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* background on what we are doing and why. *)
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Ltac morphisms := unfold refine, impl, pointwise_relation, bind, ret, pick_; hnf; first_order; subst; eauto.
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@ -58,12 +90,19 @@ Proof.
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morphisms.
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Qed.
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(** ** OK, back to the details we want to focus on. *)
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(* Here we have one of the monad laws, showing how traditional computational
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* reduction is compatible with refinement. *)
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Theorem bind_ret : forall A B (v : A) (c2 : A -> comp B),
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refine (bind (ret v) c2) (c2 v).
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Proof.
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morphisms.
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Qed.
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(* Here's an example specific to this monad. One way to resolve a
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* nondeterministic pick from a set is to replace it with a specific element
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* from the set. *)
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Theorem pick_one : forall {A} {P : A -> Prop} v,
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P v
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-> refine (pick_ P) (ret v).
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@ -77,6 +116,8 @@ Notation "x <- c1 ; c2" := (bind c1 (fun x => c2)) (at level 81, right associati
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(** * Picking a number not in a list *)
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(* Let's illustrate the big idea with an example derivation. *)
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(* A specification of what it means to choose a number that is not in a
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* particular list *)
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Definition notInList (ls : list nat) :=
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@ -125,6 +166,8 @@ Proof.
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linear_arithmetic.
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Qed.
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(** ** Interlude: defining some tactics for key parts of derivation *)
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(* We run this next step to hide an evar, so that rewriting isn't too eager to
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* make up values for it. *)
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Ltac hide_evars :=
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@ -134,9 +177,12 @@ Ltac hide_evars :=
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| [ |- refine _ ?f ] => set f
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end.
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(* This tactic starts a script that finds a term to refine another. *)
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Ltac begin :=
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eexists; simplify; hide_evars.
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(* This tactic ends such a derivation, in effect undoing the effect of
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* [hide_evars]. *)
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Ltac finish :=
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match goal with
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| [ |- refine ?e (?f ?arg1 ?arg2) ] =>
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@ -158,24 +204,24 @@ Ltac finish :=
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unify f' e; reflexivity
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end.
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(** ** Back to the example *)
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(* Let's derive an efficient implementation. *)
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Theorem implementation : { f : list nat -> comp nat | forall ls, refine (notInList ls) (f ls) }.
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Theorem implementation : sig (fun f : list nat -> comp nat => forall ls, refine (notInList ls) (f ls)).
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Proof.
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begin.
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rewrite notInList_decompose.
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rewrite listMax_refines.
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setoid_rewrite increment_refines.
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(* ^-- Different tactic here to let us rewrite under a binder! *)
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rewrite bind_ret.
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rewrite increment_refines.
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finish.
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Defined.
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(* We can extract the program that we found as a standlone, executable Gallina
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* term. *)
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Definition impl := Eval simpl in proj1_sig implementation.
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Print impl.
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(* We'll temporarily expose the definition of [max], so we can compute neatly
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(* We'll locally expose the definition of [max], so we can compute neatly
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* here. *)
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Transparent max.
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Eval compute in impl (1 :: 7 :: 8 :: 2 :: 13 :: 6 :: nil).
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@ -183,13 +229,32 @@ Eval compute in impl (1 :: 7 :: 8 :: 2 :: 13 :: 6 :: nil).
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(** * Abstract data types (ADTs) *)
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(* Stepwise refinement can be most satisfying to build objects with multiple
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* methods. The specification of such an object is often called an abstract
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* data type (ADT), and we studied them (from a verification perspective) in
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* module DataAbstraction. Let's see how we can build implementations
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* automatically from ADTs. First, some preliminary definitions. *)
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(* Every method inhabits this type, where [state] is the type of private state
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* for the object. *)
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Record method_ {state : Type} := {
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MethodName : string;
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MethodBody : state -> nat -> comp (state * nat)
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}.
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(* A body takes the current state as input and produces the new state as output.
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* Additionally, we have hardcoded both the parameter type and the return type
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* to [nat], for simplicity. The only wrinkle is that a body result is in the
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* [comp] monad, to let it mix features from specification and
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* implementation. *)
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Arguments method_ : clear implicits.
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Notation "'method' name [[ self , arg ]] = body" :=
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{| MethodName := name;
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MethodBody := fun self arg => body |}
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(at level 100, self at level 0, arg at level 0).
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(* Next, this type collects several method definitions, given a list of their
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* names. *)
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Inductive methods {state : Type} : list string -> Type :=
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| MethodsNil : methods []
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| MethodsCons : forall (m : method_ state) {names},
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Arguments methods : clear implicits.
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Notation "'method' name [[ self , arg ]] = body" :=
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{| MethodName := name;
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MethodBody := fun self arg => body |}
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(at level 100, self at level 0, arg at level 0).
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(* Finally, the definition of an abstract data type, which will apply to both
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* specifications (the classical sense of ADT) and implementations. *)
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Record adt {names : list string} := {
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AdtState : Type;
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AdtConstructor : comp AdtState;
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AdtMethods : methods AdtState names
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}.
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(* An ADT has a state type, one constructor to initialize the state, and a set
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* of methods that may read and write the state. *)
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Arguments adt : clear implicits.
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Notation "'and' m1 'and' .. 'and' mn" :=
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(MethodsCons m1 (.. (MethodsCons mn MethodsNil) ..)) (at level 101).
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(* Here's one quick example, of a counter with duplicate "increment" methods. *)
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Definition counter := ADT {
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rep = nat
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and constructor = ret 0
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and method "increment1"[[self, arg]] = ret (self + arg, 0)
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and method "increment2"[[self, arg]] = ret (self + arg, 0)
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and method "value"[[self, _]] = ret (self, self)
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}.
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(* This example hasn't used the power of the [comp] monad, but we will get
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* there later. *)
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(** * ADT refinement *)
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(* What does it mean to take sound implementation steps from an ADT toward an
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* efficient implementation? We formalize refinement for ADTs as well. The key
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* principle will be *simulation*, very similarly to how we used the idea for
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* compiler verification. *)
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(* For a "before" state type [state1] and an "after" state type [state2], we
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* require choice of a simulation relation [R]. This next inductive relation
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* captures when all methods are pairwise compatible with [R], between the
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* "before" and "after" ADTs. *)
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Inductive RefineMethods {state1 state2} (R : state1 -> state2 -> Prop)
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: forall {names}, methods state1 names -> methods state2 names -> Prop :=
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| RmNil : RefineMethods R MethodsNil MethodsNil
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| RmCons : forall name names (f1 : state1 -> nat -> comp (state1 * nat))
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(f2 : state2 -> nat -> comp (state2 * nat))
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(ms1 : methods state1 names) (ms2 : methods state2 names),
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(* This condition is the classic "simulation diagram." *)
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(forall s1 s2 arg s2' res,
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R s1 s2
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-> f2 s2 arg (s2', res)
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-> exists s1', f1 s1 arg (s1', res)
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/\ R s1' s2')
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-> RefineMethods R ms1 ms2
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-> RefineMethods R (MethodsCons {| MethodName := name; MethodBody := f1 |} ms1)
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(MethodsCons {| MethodName := name; MethodBody := f2 |} ms2).
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Hint Constructors RefineMethods.
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(* When does [adt2] refine [adt1]? When there exists a simulation relation,
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* with respect to which the constructors and methods all satisfy the usual
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* simulation diagram. *)
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Record adt_refine {names} (adt1 adt2 : adt names) : Prop := {
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ArRel : AdtState adt1 -> AdtState adt2 -> Prop;
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ArConstructors : forall s2,
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ArMethods : RefineMethods ArRel (AdtMethods adt1) (AdtMethods adt2)
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}.
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(* We will use this handy tactic to prove ADT refinements. *)
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Ltac choose_relation R :=
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match goal with
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| [ |- adt_refine ?a ?b ] => apply (Build_adt_refine _ a b R)
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(** ** Example: numeric counter *)
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Definition counter := ADT {
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rep = nat
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and constructor = ret 0
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and method "increment1"[[self, arg]] = ret (self + arg, 0)
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and method "increment2"[[self, arg]] = ret (self + arg, 0)
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and method "value"[[self, _]] = ret (self, self)
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}.
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(* Let's refine the previous counter spec into an implementation that maintains
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* two separate counters and adds them on demand. *)
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Definition split_counter := ADT {
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rep = nat * nat
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Hint Extern 1 (@eq nat _ _) => simplify; linear_arithmetic.
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(* Here is why the new implementation is correct. *)
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Theorem split_counter_ok : adt_refine counter split_counter.
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Proof.
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choose_relation (fun n p => n = fst p + snd p).
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@ -292,6 +381,8 @@ Qed.
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(** * General refinement strategies *)
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(* ADT refinement forms a preorder, as the next two theorems show. *)
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Lemma RefineMethods_refl : forall state names (ms : methods state names),
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RefineMethods eq ms ms.
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Proof.
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first_order.
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Qed.
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(* Note the use of relation composition for [refine_trans]. *)
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(** ** Refining constructors *)
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(* One way to refine an ADT is to perform [comp]-level refinement within its
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* constructor definition. *)
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Theorem refine_constructor : forall names state constr1 constr2 (ms : methods _ names),
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refine constr1 constr2
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-> adt_refine {| AdtState := state;
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choose_relation (@eq state); eauto.
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Qed.
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(** ** Refining methods *)
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(* Conceptually quite similar, refining within methods requires more syntactic
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* framework. *)
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(* This relation captures the process of replacing [oldbody] of method [name]
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* with [newbody]. *)
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Inductive ReplaceMethod {state} (name : string)
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(oldbody newbody : state -> nat -> comp (state * nat))
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: forall {names}, methods state names -> methods state names -> Prop :=
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(MethodsCons {| MethodName := name'; MethodBody := oldbody' |} ms1)
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(MethodsCons {| MethodName := name'; MethodBody := oldbody' |} ms2).
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Theorem ReplaceMethod_ok : forall state name
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(* Let's skip ahead to the next [Theorem]. *)
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Lemma ReplaceMethod_ok : forall state name
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(oldbody newbody : state -> nat -> comp (state * nat))
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names (ms1 ms2 : methods state names),
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(forall s arg, refine (oldbody s arg) (newbody s arg))
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Hint Resolve ReplaceMethod_ok.
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(* It is OK to replace a method body if the new refines the old as a [comp]. *)
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Theorem refine_method : forall state name (oldbody newbody : state -> nat -> comp (state * nat))
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names (ms1 ms2 : methods state names) constr,
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(forall s arg, refine (oldbody s arg) (newbody s arg))
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choose_relation (@eq state); eauto.
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Qed.
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(** ** Representation changes *)
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(* Some of the most interesting refinements select new data structures. That
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* is, they pick new state types. Here we formalize that idea in terms of
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* existence of an *abstraction function* from the new state type to the old. *)
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Inductive RepChangeMethods {state1 state2} (absfunc : state2 -> state1)
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: forall {names}, methods state1 names -> methods state2 names -> Prop :=
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| RchNil :
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p <- oldbody (absfunc s) arg;
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s' <- pick s' where absfunc s' = fst p;
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ret (s', snd p)) |} ms2).
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(* Interestingly, we managed to rewrite all method bodies automatically, to be
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* compatible with a new data structure! The catch is that our language of
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* method bodies is inherently noncomputational. We leave nontrivial work for
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* ourselves, in further refinement of method bodies to remove "pick"
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* operations. Note how the generic method template above relies on "pick"
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* operations to invert abstraction functions. *)
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Lemma RepChangeMethods_ok : forall state1 state2 (absfunc : state2 -> state1)
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names (ms1 : methods state1 names) (ms2 : methods state2 names),
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@ -461,12 +581,19 @@ Ltac refine_method nam := eapply refine_trans; [ eapply refine_method with (name
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| repeat (refine (RepmHead _ _ _ _ _)
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|| (refine (RepmSkip _ _ _ _ _ _ _ _ _ _); [ equality | ])) ];
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cbv beta; simplify; hide_evars | ].
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(* Don't be thrown off by the [refine] tactic used here. It is not related to
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* our notion of refinement! See module SubsetTypes for an explanation of
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* it. *)
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Ltac refine_finish := apply refine_refl.
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(** ** Example: the numeric counter again *)
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Definition derived_counter : { counter' | adt_refine counter counter' }.
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(* Let's generate the two-counter variant through the process of finding a
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* proof, in contrast to theorem [split_counter_ok], which started with the full
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* code of the transformed ADT. *)
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Definition derived_counter : sig (adt_refine counter).
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unfold counter; eexists.
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refine_rep (fun p => fst p + snd p).
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@ -505,15 +632,28 @@ Eval simpl in proj1_sig derived_counter.
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(** * Another refinement strategy: introducing a cache (a.k.a. finite differencing) *)
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(* Some methods begin life as expensive computations, such that it pays off to
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* precompute their values. A generic refinement strategy follows this plan by
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* introducing *caches*. *)
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(* Here, [name] names a method whose body leaves the state alone and returns the
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* result of [func] applied to that state. *)
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Inductive CachingMethods {state} (name : string) (func : state -> nat)
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: forall {names}, methods state names -> methods (state * nat) names -> Prop :=
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| CmNil :
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CachingMethods name func MethodsNil MethodsNil
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(* Here is how we rewrite [name] itself. We are extending state with an extra
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* cache of [func]'s value, so it is legal just to return that cache. *)
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| CmCached : forall names (ms1 : methods state names) (ms2 : methods _ names),
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CachingMethods name func ms1 ms2
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-> CachingMethods name func
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(MethodsCons {| MethodName := name; MethodBody := (fun s _ => ret (s, func s)) |} ms1)
|
||||
(MethodsCons {| MethodName := name; MethodBody := (fun s arg => ret (s, snd s)) |} ms2)
|
||||
|
||||
(* Any other method now picks up an obligation to recompute the cache value
|
||||
* whenever changing the state. We express that recomputation with a pick, to
|
||||
* be refined later into efficient logic. *)
|
||||
| CmDefault : forall name' names oldbody (ms1 : methods state names) (ms2 : methods _ names),
|
||||
name' <> name
|
||||
-> CachingMethods name func ms1 ms2
|
||||
|
@ -575,6 +715,8 @@ Ltac refine_cache nam := eapply refine_trans; [ eapply refine_cache with (name :
|
|||
|
||||
(** ** An example with lists of numbers *)
|
||||
|
||||
(* Let's work out an example of caching. *)
|
||||
|
||||
Definition sum := fold_right plus 0.
|
||||
|
||||
Definition nats := ADT {
|
||||
|
@ -584,7 +726,7 @@ Definition nats := ADT {
|
|||
and method "sum"[[self, _]] = ret (self, sum self)
|
||||
}.
|
||||
|
||||
Definition optimized_nats : { nats' | adt_refine nats nats' }.
|
||||
Definition optimized_nats : sig (adt_refine nats).
|
||||
unfold nats; eexists.
|
||||
|
||||
refine_cache "sum".
|
||||
|
|
|
@ -27,9 +27,10 @@ The main narrative, also present in the book PDF, presents standard program-proo
|
|||
* Chapter 13: `DeepAndShallowEmbeddings.v`
|
||||
* Chapter 14: `SeparationLogic.v`
|
||||
* Chapter 15: `Connecting.v`
|
||||
* Chapter 16: `SharedMemory.v`
|
||||
* Chapter 17: `ConcurrentSeparationLogic.v`
|
||||
* Chapter 18: `MessagesAndRefinement.v`
|
||||
* Chapter 16: `ProgramDerivation.v`
|
||||
* Chapter 17: `SharedMemory.v`
|
||||
* Chapter 18: `ConcurrentSeparationLogic.v`
|
||||
* Chapter 19: `MessagesAndRefinement.v`
|
||||
|
||||
There are also two supplementary files that are independent of the main narrative, for introducing programming with dependent types, a distinctive Coq feature that we neither use nor recommend for the problem sets, but which many students find interesting (and useful in other contexts).
|
||||
* `SubsetTypes.v`: a first introduction to dependent types by attaching predicates to normal types (used after `CompilerCorrectness.v` in the last course offering)
|
||||
|
|
|
@ -1,5 +1,5 @@
|
|||
(** Formal Reasoning About Programs <http://adam.chlipala.net/frap/>
|
||||
* Chapter 16: Operational Semantics for Shared-Memory Concurrency
|
||||
* Chapter 17: Operational Semantics for Shared-Memory Concurrency
|
||||
* Author: Adam Chlipala
|
||||
* License: https://creativecommons.org/licenses/by-nc-nd/4.0/ *)
|
||||
|
||||
|
|
Loading…
Reference in a new issue