ladder-calculus/coq/smallstep.v

From Coq Require Import Strings.String.
Require Import terms.
Require Import subst.
Require Import typing.

Include Terms.
Include Subst.
Include Typing.

Module Smallstep.

Reserved Notation " s '-->β' t " (at level 40).
Reserved Notation " s '-->δ' t " (at level 40).
Reserved Notation " s '-->eval' t " (at level 40).

Inductive beta_step : expr_term -> expr_term -> Prop :=
  | E_App1 : forall e1 e1' e2,
    e1 -->β e1' ->
    (expr_tm_app e1 e2) -->β (expr_tm_app e1' e2)

  | E_App2 : forall e1 e2 e2',
    e2 -->β e2' ->
    (expr_tm_app e1 e2) -->β (expr_tm_app e1 e2')

  | E_TypApp : forall e e' τ,
    e -->β e' ->
    (expr_ty_app e τ) -->β (expr_ty_app e' τ)

  | E_TypAppLam : forall x e a,
    (expr_ty_app (expr_ty_abs x e) a) -->β (expr_specialize x a e)

  | E_AppLam : forall x τ e a,
    (expr_tm_app (expr_tm_abs x τ e) a) -->β (expr_subst x a e)

  | E_AppLet : forall x t e a,
    (expr_let x t a e) -->β (expr_subst x a e)

where "s '-->β' t" := (beta_step s t).


Inductive delta_step : expr_term -> expr_term -> Prop :=

  | E_ImplicitCast : forall (Γ:context) (f:expr_term) (h:string) (a:expr_term) (τ:type_term) (s:type_term) (p:type_term),

    (context_contains Γ h (type_morph p s)) ->
    Γ |- f \is (type_fun s τ) ->
    Γ |- a \is p ->
    (expr_tm_app f a) -->δ (expr_tm_app f (expr_tm_app (expr_var h) a))

where "s '-->δ' t" := (delta_step s t).


Inductive eval_step : expr_term -> expr_term -> Prop :=
  | E_Beta : forall s t,
    (s -->β t) ->
    (s -->eval t)

  | E_Delta : forall s t,
    (s -->δ t) ->
    (s -->eval t)

where "s '-->eval' t" := (eval_step s t).

Inductive multi {X : Type} (R : X -> X -> Prop) : X -> X -> Prop :=
  | Multi_Refl : forall (x : X), multi R x x
  | Multi_Step : forall (x y z : X),
                    R x y ->
                    multi R y z ->
                    multi R x z.

Notation " s -->β* t " := (multi beta_step s t) (at level 40).
Notation " s -->δ* t " := (multi delta_step s t) (at level 40).
Notation " s -->eval* t " := (multi eval_step s t) (at level 40).

End Smallstep.
coq: preliminary small-step semantics 2024-07-24 11:20:13 +02:00			`From Coq Require Import Strings.String.`
			`Require Import terms.`
			`Require Import subst.`
coq: smallstep: define delta expansion 2024-07-25 12:42:32 +02:00			`Require Import typing.`
coq: preliminary small-step semantics 2024-07-24 11:20:13 +02:00
			`Include Terms.`
			`Include Subst.`
coq: smallstep: define delta expansion 2024-07-25 12:42:32 +02:00			`Include Typing.`
coq: preliminary small-step semantics 2024-07-24 11:20:13 +02:00
			`Module Smallstep.`

			`Reserved Notation " s '-->β' t " (at level 40).`
			`Reserved Notation " s '-->δ' t " (at level 40).`
coq: smallstep: define delta expansion 2024-07-25 12:42:32 +02:00			`Reserved Notation " s '-->eval' t " (at level 40).`
coq: preliminary small-step semantics 2024-07-24 11:20:13 +02:00
rename term types to `expr_term` and `type_term` and `type_abs`->`type_univ`, `type_app`->`type_spec` 2024-07-25 11:04:56 +02:00			`Inductive beta_step : expr_term -> expr_term -> Prop :=`
coq: smallstep: define delta expansion 2024-07-25 12:42:32 +02:00			`\| E_App1 : forall e1 e1' e2,`
coq: preliminary small-step semantics 2024-07-24 11:20:13 +02:00			`e1 -->β e1' ->`
			`(expr_tm_app e1 e2) -->β (expr_tm_app e1' e2)`

coq: smallstep: define delta expansion 2024-07-25 12:42:32 +02:00			`\| E_App2 : forall e1 e2 e2',`
coq: preliminary small-step semantics 2024-07-24 11:20:13 +02:00			`e2 -->β e2' ->`
			`(expr_tm_app e1 e2) -->β (expr_tm_app e1 e2')`

coq: smallstep: define delta expansion 2024-07-25 12:42:32 +02:00			`\| E_TypApp : forall e e' τ,`
			`e -->β e' ->`
			`(expr_ty_app e τ) -->β (expr_ty_app e' τ)`
coq: preliminary small-step semantics 2024-07-24 11:20:13 +02:00
coq: smallstep: define delta expansion 2024-07-25 12:42:32 +02:00			`\| E_TypAppLam : forall x e a,`
coq: preliminary small-step semantics 2024-07-24 11:20:13 +02:00			`(expr_ty_app (expr_ty_abs x e) a) -->β (expr_specialize x a e)`

coq: smallstep: define delta expansion 2024-07-25 12:42:32 +02:00			`\| E_AppLam : forall x τ e a,`
			`(expr_tm_app (expr_tm_abs x τ e) a) -->β (expr_subst x a e)`

coq: preliminary small-step semantics 2024-07-24 11:20:13 +02:00			`\| E_AppLet : forall x t e a,`
			`(expr_let x t a e) -->β (expr_subst x a e)`

			`where "s '-->β' t" := (beta_step s t).`

coq: smallstep: define delta expansion 2024-07-25 12:42:32 +02:00

			`Inductive delta_step : expr_term -> expr_term -> Prop :=`

			`\| E_ImplicitCast : forall (Γ:context) (f:expr_term) (h:string) (a:expr_term) (τ:type_term) (s:type_term) (p:type_term),`

			`(context_contains Γ h (type_morph p s)) ->`
			`Γ \|- f \is (type_fun s τ) ->`
			`Γ \|- a \is p ->`
			`(expr_tm_app f a) -->δ (expr_tm_app f (expr_tm_app (expr_var h) a))`

			`where "s '-->δ' t" := (delta_step s t).`


			`Inductive eval_step : expr_term -> expr_term -> Prop :=`
			`\| E_Beta : forall s t,`
			`(s -->β t) ->`
			`(s -->eval t)`

			`\| E_Delta : forall s t,`
			`(s -->δ t) ->`
			`(s -->eval t)`

			`where "s '-->eval' t" := (eval_step s t).`

			`Inductive multi {X : Type} (R : X -> X -> Prop) : X -> X -> Prop :=`
			`\| Multi_Refl : forall (x : X), multi R x x`
			`\| Multi_Step : forall (x y z : X),`
coq: preliminary small-step semantics 2024-07-24 11:20:13 +02:00			`R x y ->`
			`multi R y z ->`
			`multi R x z.`

			`Notation " s -->β* t " := (multi beta_step s t) (at level 40).`
coq: smallstep: define delta expansion 2024-07-25 12:42:32 +02:00			`Notation " s -->δ* t " := (multi delta_step s t) (at level 40).`
			`Notation " s -->eval* t " := (multi eval_step s t) (at level 40).`
coq: preliminary small-step semantics 2024-07-24 11:20:13 +02:00
			`End Smallstep.`