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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2012 *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
(* Created by Amokrane Saïbi, Dec 1998 *)
(* Addition of products and sorts in canonical structures by Pierre
Corbineau, Feb 2008 *)
(* This file registers properties of records: projections and
canonical structures *)
open Errors
open Util
open Pp
open Names
open Globnames
open Nametab
open Term
open Libobject
open Mod_subst
open Reductionops
(*s A structure S is a non recursive inductive type with a single
constructor (the name of which defaults to Build_S) *)
(* Table des structures: le nom de la structure (un [inductive]) donne
le nom du constructeur, le nombre de paramètres et pour chaque
argument réel du constructeur, le nom de la projection
correspondante, si valide, et un booléen disant si c'est une vraie
projection ou bien une fonction constante (associée à un LetIn) *)
type struc_typ = {
s_CONST : constructor;
s_EXPECTEDPARAM : int;
s_PROJKIND : (name * bool) list;
s_PROJ : constant option list }
let structure_table = ref (Indmap.empty : struc_typ Indmap.t)
let projection_table = ref Cmap.empty
(* TODO: could be unify struc_typ and struc_tuple ? in particular,
is the inductive always (fst constructor) ? It seems so... *)
type struc_tuple =
inductive * constructor * (name * bool) list * constant option list
let load_structure i (_,(ind,id,kl,projs)) =
let n = (fst (Global.lookup_inductive ind)).Declarations.mind_nparams in
let struc =
{ s_CONST = id; s_EXPECTEDPARAM = n; s_PROJ = projs; s_PROJKIND = kl } in
structure_table := Indmap.add ind struc !structure_table;
projection_table :=
List.fold_right (Option.fold_right (fun proj -> Cmap.add proj struc))
projs !projection_table
let cache_structure o =
load_structure 1 o
let subst_structure (subst,((kn,i),id,kl,projs as obj)) =
let kn' = subst_ind subst kn in
let projs' =
(* invariant: struc.s_PROJ is an evaluable reference. Thus we can take *)
(* the first component of subst_con. *)
List.smartmap
(Option.smartmap (fun kn -> fst (subst_con subst kn)))
projs
in
let id' = fst (subst_constructor subst id) in
if projs' == projs && kn' == kn && id' == id then obj else
((kn',i),id',kl,projs')
let discharge_constructor (ind, n) =
(Lib.discharge_inductive ind, n)
let discharge_structure (_,(ind,id,kl,projs)) =
Some (Lib.discharge_inductive ind, discharge_constructor id, kl,
List.map (Option.map Lib.discharge_con) projs)
let inStruc : struc_tuple -> obj =
declare_object {(default_object "STRUCTURE") with
cache_function = cache_structure;
load_function = load_structure;
subst_function = subst_structure;
classify_function = (fun x -> Substitute x);
discharge_function = discharge_structure }
let declare_structure (s,c,kl,pl) =
Lib.add_anonymous_leaf (inStruc (s,c,kl,pl))
let lookup_structure indsp = Indmap.find indsp !structure_table
let lookup_projections indsp = (lookup_structure indsp).s_PROJ
let find_projection_nparams = function
| ConstRef cst -> (Cmap.find cst !projection_table).s_EXPECTEDPARAM
| _ -> raise Not_found
let find_projection = function
| ConstRef cst -> Cmap.find cst !projection_table
| _ -> raise Not_found
(* Management of a field store : each field + argument of the inferred
* records are stored in a discrimination tree *)
let subst_id s (gr,ev,evm) =
(fst(subst_global s gr),ev,Evd.subst_evar_map s evm)
module MethodsDnet : Term_dnet.S
with type ident = global_reference * Evd.evar * Evd.evar_map
= Term_dnet.Make
(struct
type t = global_reference * Evd.evar * Evd.evar_map
let compare = Pervasives.compare
let subst = subst_id
let constr_of (_,ev,evm) = Evd.evar_concl (Evd.find evm ev)
end)
(struct
let reduce c = Reductionops.head_unfold_under_prod
Names.full_transparent_state (Global.env()) Evd.empty c
let direction = true
end)
let meth_dnet = ref MethodsDnet.empty
open Summary
let _ =
declare_summary "record-methods-state"
{ freeze_function = (fun () -> !meth_dnet);
unfreeze_function = (fun m -> meth_dnet := m);
init_function = (fun () -> meth_dnet := MethodsDnet.empty) }
open Libobject
let load_method (_,(ty,id)) =
meth_dnet := MethodsDnet.add ty id !meth_dnet
let in_method : constr * MethodsDnet.ident -> obj =
declare_object
{ (default_object "RECMETHODS") with
load_function = (fun _ -> load_method);
cache_function = load_method;
subst_function = (fun (s,(ty,id)) -> Mod_subst.subst_mps s ty,subst_id s id);
classify_function = (fun x -> Substitute x)
}
let methods_matching c = MethodsDnet.search_pattern !meth_dnet c
let declare_method cons ev sign =
Lib.add_anonymous_leaf (in_method ((Evd.evar_concl (Evd.find sign ev)),(cons,ev,sign)))
(************************************************************************)
(*s A canonical structure declares "canonical" conversion hints between *)
(* the effective components of a structure and the projections of the *)
(* structure *)
(* Table des definitions "object" : pour chaque object c,
c := [x1:B1]...[xk:Bk](Build_R a1...am t1...t_n)
If ti has the form (ci ui1...uir) where ci is a global reference and
if the corresponding projection Li of the structure R is defined, one
declare a "conversion" between ci and Li
x1:B1..xk:Bk |- (Li a1..am (c x1..xk)) =_conv (ci ui1...uir)
that maps the pair (Li,ci) to the following data
o_DEF = c
o_TABS = B1...Bk
o_PARAMS = a1...am
o_NARAMS = m
o_TCOMP = ui1...uir
*)
type obj_typ = {
o_DEF : constr;
o_INJ : int; (* position of trivial argument (negative= none) *)
o_TABS : constr list; (* ordered *)
o_TPARAMS : constr list; (* ordered *)
o_NPARAMS : int;
o_TCOMPS : constr list } (* ordered *)
type cs_pattern =
Const_cs of global_reference
| Prod_cs
| Sort_cs of sorts_family
| Default_cs
let object_table = ref (Refmap.empty : (cs_pattern * obj_typ) list Refmap.t)
let canonical_projections () =
Refmap.fold (fun x -> List.fold_right (fun (y,c) acc -> ((x,y),c)::acc))
!object_table []
let keep_true_projections projs kinds =
let filter (p, (_, b)) = if b then Some p else None in
List.map_filter filter (List.combine projs kinds)
let cs_pattern_of_constr t =
match kind_of_term t with
App (f,vargs) ->
begin
try Const_cs (global_of_constr f) , -1, Array.to_list vargs with
_ -> raise Not_found
end
| Rel n -> Default_cs, pred n, []
| Prod (_,a,b) when not (Termops.dependent (mkRel 1) b) -> Prod_cs, -1, [a; Termops.pop b]
| Sort s -> Sort_cs (family_of_sort s), -1, []
| _ ->
begin
try Const_cs (global_of_constr t) , -1, [] with
_ -> raise Not_found
end
(* Intended to always succeed *)
let compute_canonical_projections (con,ind) =
let v = mkConst con in
let c = Environ.constant_value (Global.env()) con in
let lt,t = Reductionops.splay_lam (Global.env()) Evd.empty c in
let lt = List.rev (List.map snd lt) in
let args = snd (decompose_app t) in
let { s_EXPECTEDPARAM = p; s_PROJ = lpj; s_PROJKIND = kl } =
lookup_structure ind in
let params, projs = List.chop p args in
let lpj = keep_true_projections lpj kl in
let lps = List.combine lpj projs in
let comp =
List.fold_left
(fun l (spopt,t) -> (* comp=components *)
match spopt with
| Some proji_sp ->
begin
try
let patt, n , args = cs_pattern_of_constr t in
((ConstRef proji_sp, patt, n, args) :: l)
with Not_found ->
if Flags.is_verbose () then
(let con_pp = Nametab.pr_global_env Idset.empty (ConstRef con)
and proji_sp_pp = Nametab.pr_global_env Idset.empty (ConstRef proji_sp) in
msg_warning (strbrk "No global reference exists for projection value"
++ Termops.print_constr t ++ strbrk " in instance "
++ con_pp ++ str " of " ++ proji_sp_pp ++ strbrk ", ignoring it."));
l
end
| _ -> l)
[] lps in
List.map (fun (refi,c,inj,argj) ->
(refi,c),
{o_DEF=v; o_INJ=inj; o_TABS=lt;
o_TPARAMS=params; o_NPARAMS=List.length params; o_TCOMPS=argj})
comp
let pr_cs_pattern = function
Const_cs c -> Nametab.pr_global_env Idset.empty c
| Prod_cs -> str "_ -> _"
| Default_cs -> str "_"
| Sort_cs s -> Termops.pr_sort_family s
let open_canonical_structure i (_,o) =
if i=1 then
let lo = compute_canonical_projections o in
List.iter (fun ((proj,cs_pat),s) ->
let l = try Refmap.find proj !object_table with Not_found -> [] in
let ocs = try Some (List.assoc cs_pat l)
with Not_found -> None
in match ocs with
| None -> object_table := Refmap.add proj ((cs_pat,s)::l) !object_table;
| Some cs ->
if Flags.is_verbose () then
let old_can_s = (Termops.print_constr cs.o_DEF)
and new_can_s = (Termops.print_constr s.o_DEF) in
let prj = (Nametab.pr_global_env Idset.empty proj)
and hd_val = (pr_cs_pattern cs_pat) in
msg_warning (strbrk "Ignoring canonical projection to " ++ hd_val
++ strbrk " by " ++ prj ++ strbrk " in "
++ new_can_s ++ strbrk ": redundant with " ++ old_can_s)) lo
let cache_canonical_structure o =
open_canonical_structure 1 o
let subst_canonical_structure (subst,(cst,ind as obj)) =
(* invariant: cst is an evaluable reference. Thus we can take *)
(* the first component of subst_con. *)
let cst' = fst (subst_con subst cst) in
let ind' = Inductiveops.subst_inductive subst ind in
if cst' == cst & ind' == ind then obj else (cst',ind')
let discharge_canonical_structure (_,(cst,ind)) =
Some (Lib.discharge_con cst,Lib.discharge_inductive ind)
let inCanonStruc : constant * inductive -> obj =
declare_object {(default_object "CANONICAL-STRUCTURE") with
open_function = open_canonical_structure;
cache_function = cache_canonical_structure;
subst_function = subst_canonical_structure;
classify_function = (fun x -> Substitute x);
discharge_function = discharge_canonical_structure }
let add_canonical_structure x = Lib.add_anonymous_leaf (inCanonStruc x)
(*s High-level declaration of a canonical structure *)
let error_not_structure ref =
errorlabstrm "object_declare"
(Nameops.pr_id (basename_of_global ref) ++ str" is not a structure object.")
let check_and_decompose_canonical_structure ref =
let sp = match ref with ConstRef sp -> sp | _ -> error_not_structure ref in
let env = Global.env () in
let vc = match Environ.constant_opt_value env sp with
| Some vc -> vc
| None -> error_not_structure ref in
let body = snd (splay_lam (Global.env()) Evd.empty vc) in
let f,args = match kind_of_term body with
| App (f,args) -> f,args
| _ -> error_not_structure ref in
let indsp = match kind_of_term f with
| Construct (indsp,1) -> indsp
| _ -> error_not_structure ref in
let s = try lookup_structure indsp with Not_found -> error_not_structure ref in
let ntrue_projs = List.length (List.filter (fun (_, x) -> x) s.s_PROJKIND) in
if s.s_EXPECTEDPARAM + ntrue_projs > Array.length args then
error_not_structure ref;
(sp,indsp)
let declare_canonical_structure ref =
add_canonical_structure (check_and_decompose_canonical_structure ref)
let lookup_canonical_conversion (proj,pat) =
List.assoc pat (Refmap.find proj !object_table)
let is_open_canonical_projection env sigma (c,args) =
try
let n = find_projection_nparams (global_of_constr c) in
try
let arg = whd_betadeltaiota env sigma (stack_nth args n) in
let hd = match kind_of_term arg with App (hd, _) -> hd | _ -> arg in
not (isConstruct hd)
with Failure _ -> false
with Not_found -> false
let freeze () =
!structure_table, !projection_table, !object_table
let unfreeze (s,p,o) =
structure_table := s; projection_table := p; object_table := o
let init () =
structure_table := Indmap.empty; projection_table := Cmap.empty;
object_table := Refmap.empty
let _ = init()
let _ =
Summary.declare_summary "objdefs"
{ Summary.freeze_function = freeze;
Summary.unfreeze_function = unfreeze;
Summary.init_function = init }
|