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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2016 *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
(* Created by Jean-Christophe Filliâtre out of names.ml as part of the
rebuilding of Coq around a purely functional abstract type-checker,
Aug 1999 *)
(* Miscellaneous extensions, restructurations and bug-fixes by Hugo
Herbelin and Bruno Barras *)
(* This file defines types and combinators regarding indexes-based and
names-based contexts *)
(** The modules defined below represent a {e local context}
as defined by Chapter 4 in the Reference Manual:
A {e local context} is an ordered list of of {e local declarations}
of names that we call {e variables}.
A {e local declaration} of some variable can be either:
- a {e local assumption}, or
- a {e local definition}.
*)
open Util
open Names
(** Representation of contexts that can capture anonymous as well as non-anonymous variables.
Individual declarations are then designated by de Bruijn indexes. *)
module Rel =
struct
(** Representation of {e local declarations}. *)
module Declaration =
struct
(* local declaration *)
type t =
| LocalAssum of Name.t * Constr.t (** name, type *)
| LocalDef of Name.t * Constr.t * Constr.t (** name, value, type *)
(** Return the name bound by a given declaration. *)
let get_name = function
| LocalAssum (na,_)
| LocalDef (na,_,_) -> na
(** Return [Some value] for local-declarations and [None] for local-assumptions. *)
let get_value = function
| LocalAssum _ -> None
| LocalDef (_,v,_) -> Some v
(** Return the type of the name bound by a given declaration. *)
let get_type = function
| LocalAssum (_,ty)
| LocalDef (_,_,ty) -> ty
(** Set the name that is bound by a given declaration. *)
let set_name na = function
| LocalAssum (_,ty) -> LocalAssum (na, ty)
| LocalDef (_,v,ty) -> LocalDef (na, v, ty)
(** Set the type of the bound variable in a given declaration. *)
let set_type ty = function
| LocalAssum (na,_) -> LocalAssum (na, ty)
| LocalDef (na,v,_) -> LocalDef (na, v, ty)
(** Return [true] iff a given declaration is a local assumption. *)
let is_local_assum = function
| LocalAssum _ -> true
| LocalDef _ -> false
(** Return [true] iff a given declaration is a local definition. *)
let is_local_def = function
| LocalAssum _ -> false
| LocalDef _ -> true
(** Check whether any term in a given declaration satisfies a given predicate. *)
let exists f = function
| LocalAssum (_, ty) -> f ty
| LocalDef (_, v, ty) -> f v || f ty
(** Check whether all terms in a given declaration satisfy a given predicate. *)
let for_all f = function
| LocalAssum (_, ty) -> f ty
| LocalDef (_, v, ty) -> f v && f ty
(** Check whether the two given declarations are equal. *)
let equal decl1 decl2 =
match decl1, decl2 with
| LocalAssum (n1,ty1), LocalAssum (n2, ty2) ->
Name.equal n1 n2 && Constr.equal ty1 ty2
| LocalDef (n1,v1,ty1), LocalDef (n2,v2,ty2) ->
Name.equal n1 n2 && Constr.equal v1 v2 && Constr.equal ty1 ty2
| _ ->
false
(** Map the name bound by a given declaration. *)
let map_name f = function
| LocalAssum (na, ty) as decl ->
let na' = f na in
if na == na' then decl else LocalAssum (na', ty)
| LocalDef (na, v, ty) as decl ->
let na' = f na in
if na == na' then decl else LocalDef (na', v, ty)
(** For local assumptions, this function returns the original local assumptions.
For local definitions, this function maps the value in the local definition. *)
let map_value f = function
| LocalAssum _ as decl -> decl
| LocalDef (na, v, t) as decl ->
let v' = f v in
if v == v' then decl else LocalDef (na, v', t)
(** Map the type of the name bound by a given declaration. *)
let map_type f = function
| LocalAssum (na, ty) as decl ->
let ty' = f ty in
if ty == ty' then decl else LocalAssum (na, ty')
| LocalDef (na, v, ty) as decl ->
let ty' = f ty in
if ty == ty' then decl else LocalDef (na, v, ty')
(** Map all terms in a given declaration. *)
let map_constr f = function
| LocalAssum (na, ty) as decl ->
let ty' = f ty in
if ty == ty' then decl else LocalAssum (na, ty')
| LocalDef (na, v, ty) as decl ->
let v' = f v in
let ty' = f ty in
if v == v' && ty == ty' then decl else LocalDef (na, v', ty')
(** Perform a given action on all terms in a given declaration. *)
let iter_constr f = function
| LocalAssum (_,ty) -> f ty
| LocalDef (_,v,ty) -> f v; f ty
(** Reduce all terms in a given declaration to a single value. *)
let fold f decl acc =
match decl with
| LocalAssum (n,ty) -> f ty acc
| LocalDef (n,v,ty) -> f ty (f v acc)
let to_tuple = function
| LocalAssum (na, ty) -> na, None, ty
| LocalDef (na, v, ty) -> na, Some v, ty
let of_tuple = function
| n, None, ty -> LocalAssum (n,ty)
| n, Some v, ty -> LocalDef (n,v,ty)
end
(** Rel-context is represented as a list of declarations.
Inner-most declarations are at the beginning of the list.
Outer-most declarations are at the end of the list. *)
type t = Declaration.t list
(** empty rel-context *)
let empty = []
(** Return a new rel-context enriched by with a given inner-most declaration. *)
let add d ctx = d :: ctx
(** Return the number of {e local declarations} in a given context. *)
let length = List.length
(** [extended_rel_list n Γ] builds an instance [args] such that [Γ,Δ ⊢ args:Γ]
with n = |Δ| and with the local definitions of [Γ] skipped in
[args]. Example: for [x:T,y:=c,z:U] and [n]=2, it gives [Rel 5, Rel 3]. *)
let nhyps =
let open Declaration in
let rec nhyps acc = function
| [] -> acc
| LocalAssum _ :: hyps -> nhyps (succ acc) hyps
| LocalDef _ :: hyps -> nhyps acc hyps
in
nhyps 0
(** Return a declaration designated by a given de Bruijn index.
@raise Not_found if the designated de Bruijn index is not present in the designated rel-context. *)
let rec lookup n ctx =
match n, ctx with
| 1, decl :: _ -> decl
| n, _ :: sign -> lookup (n-1) sign
| _, [] -> raise Not_found
(** Check whether given two rel-contexts are equal. *)
let equal = List.equal Declaration.equal
(** Map all terms in a given rel-context. *)
let map f = List.smartmap (Declaration.map_constr f)
(** Perform a given action on every declaration in a given rel-context. *)
let iter f = List.iter (Declaration.iter_constr f)
(** Reduce all terms in a given rel-context to a single value.
Innermost declarations are processed first. *)
let fold_inside f ~init = List.fold_left f init
(** Reduce all terms in a given rel-context to a single value.
Outermost declarations are processed first. *)
let fold_outside f l ~init = List.fold_right f l init
(** Map a given rel-context to a list where each {e local assumption} is mapped to [true]
and each {e local definition} is mapped to [false]. *)
let to_tags =
let rec aux l = function
| [] -> l
| Declaration.LocalDef _ :: ctx -> aux (true::l) ctx
| Declaration.LocalAssum _ :: ctx -> aux (false::l) ctx
in aux []
(** [extended_list n Γ] builds an instance [args] such that [Γ,Δ ⊢ args:Γ]
with n = |Δ| and with the {e local definitions} of [Γ] skipped in
[args]. Example: for [x:T, y:=c, z:U] and [n]=2, it gives [Rel 5, Rel 3]. *)
let to_extended_list n =
let rec reln l p = function
| Declaration.LocalAssum _ :: hyps -> reln (Constr.mkRel (n+p) :: l) (p+1) hyps
| Declaration.LocalDef _ :: hyps -> reln l (p+1) hyps
| [] -> l
in
reln [] 1
(** [extended_vect n Γ] does the same, returning instead an array. *)
let to_extended_vect n hyps = Array.of_list (to_extended_list n hyps)
end
(** This module represents contexts that can capture non-anonymous variables.
Individual declarations are then designated by the identifiers they bind. *)
module Named =
struct
(** Representation of {e local declarations}. *)
module Declaration =
struct
(** local declaration *)
type t =
| LocalAssum of Id.t * Constr.t (** identifier, type *)
| LocalDef of Id.t * Constr.t * Constr.t (** identifier, value, type *)
(** Return the identifier bound by a given declaration. *)
let get_id = function
| LocalAssum (id,_) -> id
| LocalDef (id,_,_) -> id
(** Return [Some value] for local-declarations and [None] for local-assumptions. *)
let get_value = function
| LocalAssum _ -> None
| LocalDef (_,v,_) -> Some v
(** Return the type of the name bound by a given declaration. *)
let get_type = function
| LocalAssum (_,ty)
| LocalDef (_,_,ty) -> ty
(** Set the identifier that is bound by a given declaration. *)
let set_id id = function
| LocalAssum (_,ty) -> LocalAssum (id, ty)
| LocalDef (_, v, ty) -> LocalDef (id, v, ty)
(** Set the type of the bound variable in a given declaration. *)
let set_type ty = function
| LocalAssum (id,_) -> LocalAssum (id, ty)
| LocalDef (id,v,_) -> LocalDef (id, v, ty)
(** Return [true] iff a given declaration is a local assumption. *)
let is_local_assum = function
| LocalAssum _ -> true
| LocalDef _ -> false
(** Return [true] iff a given declaration is a local definition. *)
let is_local_def = function
| LocalDef _ -> true
| LocalAssum _ -> false
(** Check whether any term in a given declaration satisfies a given predicate. *)
let exists f = function
| LocalAssum (_, ty) -> f ty
| LocalDef (_, v, ty) -> f v || f ty
(** Check whether all terms in a given declaration satisfy a given predicate. *)
let for_all f = function
| LocalAssum (_, ty) -> f ty
| LocalDef (_, v, ty) -> f v && f ty
(** Check whether the two given declarations are equal. *)
let equal decl1 decl2 =
match decl1, decl2 with
| LocalAssum (id1, ty1), LocalAssum (id2, ty2) ->
Id.equal id1 id2 && Constr.equal ty1 ty2
| LocalDef (id1, v1, ty1), LocalDef (id2, v2, ty2) ->
Id.equal id1 id2 && Constr.equal v1 v2 && Constr.equal ty1 ty2
| _ ->
false
(** Map the identifier bound by a given declaration. *)
let map_id f = function
| LocalAssum (id, ty) as decl ->
let id' = f id in
if id == id' then decl else LocalAssum (id', ty)
| LocalDef (id, v, ty) as decl ->
let id' = f id in
if id == id' then decl else LocalDef (id', v, ty)
(** For local assumptions, this function returns the original local assumptions.
For local definitions, this function maps the value in the local definition. *)
let map_value f = function
| LocalAssum _ as decl -> decl
| LocalDef (na, v, t) as decl ->
let v' = f v in
if v == v' then decl else LocalDef (na, v', t)
(** Map the type of the name bound by a given declaration. *)
let map_type f = function
| LocalAssum (id, ty) as decl ->
let ty' = f ty in
if ty == ty' then decl else LocalAssum (id, ty')
| LocalDef (id, v, ty) as decl ->
let ty' = f ty in
if ty == ty' then decl else LocalDef (id, v, ty')
(** Map all terms in a given declaration. *)
let map_constr f = function
| LocalAssum (id, ty) as decl ->
let ty' = f ty in
if ty == ty' then decl else LocalAssum (id, ty')
| LocalDef (id, v, ty) as decl ->
let v' = f v in
let ty' = f ty in
if v == v' && ty == ty' then decl else LocalDef (id, v', ty')
(** Perform a given action on all terms in a given declaration. *)
let iter_constr f = function
| LocalAssum (_, ty) -> f ty
| LocalDef (_, v, ty) -> f v; f ty
(** Reduce all terms in a given declaration to a single value. *)
let fold f decl a =
match decl with
| LocalAssum (_, ty) -> f ty a
| LocalDef (_, v, ty) -> a |> f v |> f ty
let to_tuple = function
| LocalAssum (id, ty) -> id, None, ty
| LocalDef (id, v, ty) -> id, Some v, ty
let of_tuple = function
| id, None, ty -> LocalAssum (id, ty)
| id, Some v, ty -> LocalDef (id, v, ty)
end
(** Named-context is represented as a list of declarations.
Inner-most declarations are at the beginning of the list.
Outer-most declarations are at the end of the list. *)
type t = Declaration.t list
(** empty named-context *)
let empty = []
(** empty named-context *)
let add d ctx = d :: ctx
(** Return the number of {e local declarations} in a given named-context. *)
let length = List.length
(** Return a declaration designated by a given de Bruijn index.
@raise Not_found if the designated identifier is not present in the designated named-context. *) let rec lookup id = function
| decl :: _ when Id.equal id (Declaration.get_id decl) -> decl
| _ :: sign -> lookup id sign
| [] -> raise Not_found
(** Check whether given two named-contexts are equal. *)
let equal = List.equal Declaration.equal
(** Map all terms in a given named-context. *)
let map f = List.smartmap (Declaration.map_constr f)
(** Perform a given action on every declaration in a given named-context. *)
let iter f = List.iter (Declaration.iter_constr f)
(** Reduce all terms in a given named-context to a single value.
Innermost declarations are processed first. *)
let fold_inside f ~init = List.fold_left f init
(** Reduce all terms in a given named-context to a single value.
Outermost declarations are processed first. *)
let fold_outside f l ~init = List.fold_right f l init
(** Return the set of all identifiers bound in a given named-context. *)
let to_vars =
List.fold_left (fun accu decl -> Id.Set.add (Declaration.get_id decl) accu) Id.Set.empty
(** [instance_from_named_context Ω] builds an instance [args] such
that [Ω ⊢ args:Ω] where [Ω] is a named context and with the local
definitions of [Ω] skipped. Example: for [id1:T,id2:=c,id3:U], it
gives [Var id1, Var id3]. All [idj] are supposed distinct. *)
let to_instance =
let filter = function
| Declaration.LocalAssum (id, _) -> Some (Constr.mkVar id)
| _ -> None
in
List.map_filter filter
end
module NamedList =
struct
module Declaration =
struct
type t = Id.t list * Constr.t option * Constr.t
let map_constr f (ids, copt, ty as decl) =
let copt' = Option.map f copt in
let ty' = f ty in
if copt == copt' && ty == ty' then decl else (ids, copt', ty')
end
type t = Declaration.t list
let fold f l ~init = List.fold_right f l init
end
type section_context = Named.t
|