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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * CNRS-Ecole Polytechnique-INRIA Futurs-Universite Paris Sud *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
(* $Id$ *)
open Util
open Names
open Sign
open Univ
open Term
open Declarations
open Pre_env
open Csymtable
(* The type of environments. *)
type named_context_val = Pre_env.named_context_val
type env = Pre_env.env
let pre_env env = env
let empty_named_context_val = empty_named_context_val
let empty_env = empty_env
let engagement env = env.env_stratification.env_engagement
let universes env = env.env_stratification.env_universes
let named_context env = env.env_named_context
let named_context_val env = env.env_named_context,env.env_named_vals
let rel_context env = env.env_rel_context
let empty_context env =
env.env_rel_context = empty_rel_context
&& env.env_named_context = empty_named_context
(* Rel context *)
let lookup_rel n env =
Sign.lookup_rel n env.env_rel_context
let evaluable_rel n env =
try
match lookup_rel n env with
(_,Some _,_) -> true
| _ -> false
with Not_found ->
false
let nb_rel env = env.env_nb_rel
let push_rel = push_rel
let push_rel_context ctxt x = Sign.fold_rel_context push_rel ctxt ~init:x
let push_rec_types (lna,typarray,_) env =
let ctxt =
array_map2_i
(fun i na t -> (na, None, type_app (lift i) t)) lna typarray in
Array.fold_left (fun e assum -> push_rel assum e) env ctxt
let reset_rel_context env =
{ env with
env_rel_context = empty_rel_context;
env_rel_val = [];
env_nb_rel = 0 }
let fold_rel_context f env ~init =
let rec fold_right env =
match env.env_rel_context with
| [] -> init
| rd::rc ->
let env =
{ env with
env_rel_context = rc;
env_rel_val = List.tl env.env_rel_val;
env_nb_rel = env.env_nb_rel - 1 } in
f env rd (fold_right env)
in fold_right env
(* Named context *)
let named_context_of_val = fst
(* [map_named_val f ctxt] apply [f] to the body and the type of
each declarations.
*** /!\ *** [f t] should be convertible with t *)
let map_named_val f (ctxt,ctxtv) =
let ctxt =
List.map (fun (id,body,typ) -> (id, option_app f body, f typ)) ctxt in
(ctxt,ctxtv)
let empty_named_context = empty_named_context
let push_named = push_named
let push_named_context_val = push_named_context_val
let val_of_named_context ctxt =
List.fold_right push_named_context_val ctxt empty_named_context_val
let lookup_named id env = Sign.lookup_named id env.env_named_context
let lookup_named_val id (ctxt,_) = Sign.lookup_named id ctxt
let eq_named_context_val c1 c2 =
c1 == c2 || named_context_of_val c1 = named_context_of_val c2
(* A local const is evaluable if it is defined *)
let named_type id env =
let (_,_,t) = lookup_named id env in t
let named_body id env =
let (_,b,_) = lookup_named id env in b
let evaluable_named id env =
try
match named_body id env with
|Some _ -> true
| _ -> false
with Not_found -> false
let reset_with_named_context (ctxt,ctxtv) env =
{ env with
env_named_context = ctxt;
env_named_vals = ctxtv;
env_rel_context = empty_rel_context;
env_rel_val = [];
env_nb_rel = 0 }
let reset_context = reset_with_named_context empty_named_context_val
let fold_named_context f env ~init =
let rec fold_right env =
match env.env_named_context with
| [] -> init
| d::ctxt ->
let env =
reset_with_named_context (ctxt,List.tl env.env_named_vals) env in
f env d (fold_right env)
in fold_right env
let fold_named_context_reverse f ~init env =
Sign.fold_named_context_reverse f ~init:init (named_context env)
(* Global constants *)
let lookup_constant = lookup_constant
let add_constant kn cs env =
let new_constants =
Cmap.add kn (cs,ref None) env.env_globals.env_constants in
let new_globals =
{ env.env_globals with
env_constants = new_constants } in
{ env with env_globals = new_globals }
(* constant_type gives the type of a constant *)
let constant_type env kn =
let cb = lookup_constant kn env in
cb.const_type
type const_evaluation_result = NoBody | Opaque
exception NotEvaluableConst of const_evaluation_result
let constant_value env kn =
let cb = lookup_constant kn env in
if cb.const_opaque then raise (NotEvaluableConst Opaque);
match cb.const_body with
| Some l_body -> Declarations.force l_body
| None -> raise (NotEvaluableConst NoBody)
let constant_opt_value env cst =
try Some (constant_value env cst)
with NotEvaluableConst _ -> None
(* A global const is evaluable if it is defined and not opaque *)
let evaluable_constant cst env =
try let _ = constant_value env cst in true
with Not_found | NotEvaluableConst _ -> false
(* Mutual Inductives *)
let lookup_mind = lookup_mind
let add_mind kn mib env =
let new_inds = KNmap.add kn mib env.env_globals.env_inductives in
let new_globals =
{ env.env_globals with
env_inductives = new_inds } in
{ env with env_globals = new_globals }
(* Universe constraints *)
let set_universes g env =
if env.env_stratification.env_universes == g then env
else
{ env with env_stratification =
{ env.env_stratification with env_universes = g } }
let add_constraints c env =
if c == Constraint.empty then
env
else
let s = env.env_stratification in
{ env with env_stratification =
{ s with env_universes = merge_constraints c s.env_universes } }
let set_engagement c env = (* Unsafe *)
{ env with env_stratification =
{ env.env_stratification with env_engagement = Some c } }
(* Lookup of section variables *)
let lookup_constant_variables c env =
let cmap = lookup_constant c env in
Sign.vars_of_named_context cmap.const_hyps
let lookup_inductive_variables (kn,i) env =
let mis = lookup_mind kn env in
Sign.vars_of_named_context mis.mind_hyps
let lookup_constructor_variables (ind,_) env =
lookup_inductive_variables ind env
(* Returns the list of global variables in a term *)
let vars_of_global env constr =
match kind_of_term constr with
Var id -> [id]
| Const kn -> lookup_constant_variables kn env
| Ind ind -> lookup_inductive_variables ind env
| Construct cstr -> lookup_constructor_variables cstr env
| _ -> []
let global_vars_set env constr =
let rec filtrec acc c =
let vl = vars_of_global env c in
let acc = List.fold_right Idset.add vl acc in
fold_constr filtrec acc c
in
filtrec Idset.empty constr
(* [keep_hyps env ids] keeps the part of the section context of [env] which
contains the variables of the set [ids], and recursively the variables
contained in the types of the needed variables. *)
let keep_hyps env needed =
let really_needed =
Sign.fold_named_context_reverse
(fun need (id,copt,t) ->
if Idset.mem id need then
let globc =
match copt with
| None -> Idset.empty
| Some c -> global_vars_set env c in
Idset.union
(global_vars_set env t)
(Idset.union globc need)
else need)
~init:needed
(named_context env) in
Sign.fold_named_context
(fun (id,_,_ as d) nsign ->
if Idset.mem id really_needed then add_named_decl d nsign
else nsign)
(named_context env)
~init:empty_named_context
(* Modules *)
let add_modtype ln mtb env =
let new_modtypes = KNmap.add ln mtb env.env_globals.env_modtypes in
let new_globals =
{ env.env_globals with
env_modtypes = new_modtypes } in
{ env with env_globals = new_globals }
let shallow_add_module mp mb env =
let new_mods = MPmap.add mp mb env.env_globals.env_modules in
let new_globals =
{ env.env_globals with
env_modules = new_mods } in
{ env with env_globals = new_globals }
let lookup_module mp env =
MPmap.find mp env.env_globals.env_modules
let lookup_modtype ln env =
KNmap.find ln env.env_globals.env_modtypes
(*s Judgments. *)
type unsafe_judgment = {
uj_val : constr;
uj_type : types }
let make_judge v tj =
{ uj_val = v;
uj_type = tj }
let j_val j = j.uj_val
let j_type j = j.uj_type
type unsafe_type_judgment = {
utj_val : constr;
utj_type : sorts }
(*s Compilation of global declaration *)
let compile_constant_body = Cbytegen.compile_constant_body
(*s Special functions for the refiner (logic.ml) *)
let clear_hyps ids check (ctxt,vals) =
let ctxt,vals,rmv =
List.fold_right2 (fun (id,_,_ as d) v (ctxt,vals,rmv) ->
if List.mem id ids then (ctxt,vals,id::rmv)
else begin
check rmv d;
(d::ctxt,v::vals,rmv)
end) ctxt vals ([],[],[])
in ((ctxt,vals),rmv)
exception Hyp_not_found
let rec apply_to_hyp (ctxt,vals) id f =
let rec aux rtail ctxt vals =
match ctxt, vals with
| (idc,c,ct as d)::ctxt, v::vals ->
if idc = id then
(f ctxt d rtail)::ctxt, v::vals
else
let ctxt',vals' = aux (d::rtail) ctxt vals in
d::ctxt', v::vals'
| [],[] -> raise Hyp_not_found
| _, _ -> assert false
in aux [] ctxt vals
let rec apply_to_hyp_and_dependent_on (ctxt,vals) id f g =
let rec aux ctxt vals =
match ctxt,vals with
| (idc,c,ct as d)::ctxt, v::vals ->
if idc = id then
let sign = ctxt,vals in
push_named_context_val (f d sign) sign
else
let (ctxt,vals as sign) = aux ctxt vals in
push_named_context_val (g d sign) sign
| [],[] -> raise Hyp_not_found
| _,_ -> assert false
in aux ctxt vals
let insert_after_hyp (ctxt,vals) id d check =
let rec aux ctxt vals =
match ctxt, vals with
| (idc,c,ct as d')::ctxt', v::vals' ->
if idc = id then begin
check ctxt;
push_named_context_val d (ctxt,vals)
end else
let ctxt,vals = aux ctxt vals in
d::ctxt, v::vals
| [],[] -> raise Hyp_not_found
| _, _ -> assert false
in aux ctxt vals
|