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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 Nameops
open Sign
open Term
open Termops
open Environ
open Reductionops
open Evd
open Typing
open Redexpr
open Tacred
open Proof_trees
open Proof_type
open Logic
open Refiner
open Tacexpr
let re_sig it gc = { it = it; sigma = gc }
(**************************************************************)
(* Operations for handling terms under a local typing context *)
(**************************************************************)
type 'a sigma = 'a Evd.sigma;;
type validation = Proof_type.validation;;
type tactic = Proof_type.tactic;;
let unpackage = Refiner.unpackage
let repackage = Refiner.repackage
let apply_sig_tac = Refiner.apply_sig_tac
let sig_it = Refiner.sig_it
let project = Refiner.project
let pf_env = Refiner.pf_env
let pf_hyps = Refiner.pf_hyps
let pf_concl gls = (sig_it gls).evar_concl
let pf_hyps_types gls =
let sign = Environ.named_context (pf_env gls) in
List.map (fun (id,_,x) -> (id, x)) sign
let pf_nth_hyp_id gls n = let (id,c,t) = List.nth (pf_hyps gls) (n-1) in id
let pf_last_hyp gl = List.hd (pf_hyps gl)
let pf_get_hyp gls id =
try
Sign.lookup_named id (pf_hyps gls)
with Not_found ->
error ("No such hypothesis : " ^ (string_of_id id))
let pf_get_hyp_typ gls id =
let (_,_,ty)= (pf_get_hyp gls id) in
ty
let pf_ids_of_hyps gls = ids_of_named_context (pf_hyps gls)
let pf_get_new_id id gls =
next_ident_away id (pf_ids_of_hyps gls)
let pf_get_new_ids ids gls =
let avoid = pf_ids_of_hyps gls in
List.fold_right
(fun id acc -> (next_ident_away id (acc@avoid))::acc)
ids []
let pf_interp_constr gls c =
let evc = project gls in
Constrintern.interp_constr evc (pf_env gls) c
let pf_interp_type gls c =
let evc = project gls in
Constrintern.interp_type evc (pf_env gls) c
let pf_global gls id = Constrintern.construct_reference (pf_hyps gls) id
let pf_parse_const gls = compose (pf_global gls) id_of_string
let pf_reduction_of_red_expr gls re c =
(fst (reduction_of_red_expr re)) (pf_env gls) (project gls) c
let pf_apply f gls = f (pf_env gls) (project gls)
let pf_reduce = pf_apply
let pf_whd_betadeltaiota = pf_reduce whd_betadeltaiota
let pf_whd_betadeltaiota_stack = pf_reduce whd_betadeltaiota_stack
let pf_hnf_constr = pf_reduce hnf_constr
let pf_red_product = pf_reduce red_product
let pf_nf = pf_reduce nf
let pf_nf_betaiota = pf_reduce (fun _ _ -> nf_betaiota)
let pf_compute = pf_reduce compute
let pf_unfoldn ubinds = pf_reduce (unfoldn ubinds)
let pf_type_of = pf_reduce type_of
let pf_get_type_of = pf_reduce Retyping.get_type_of
let pf_conv_x = pf_reduce is_conv
let pf_conv_x_leq = pf_reduce is_conv_leq
let pf_const_value = pf_reduce (fun env _ -> constant_value env)
let pf_reduce_to_quantified_ind = pf_reduce reduce_to_quantified_ind
let pf_reduce_to_atomic_ind = pf_reduce reduce_to_atomic_ind
let hnf_type_of gls = compose (pf_whd_betadeltaiota gls) (pf_get_type_of gls)
let pf_check_type gls c1 c2 =
ignore (pf_type_of gls (mkCast (c1, DEFAULTcast, c2)))
(************************************)
(* Tactics handling a list of goals *)
(************************************)
type transformation_tactic = proof_tree -> (goal list * validation)
type validation_list = proof_tree list -> proof_tree list
type tactic_list = (goal list sigma) -> (goal list sigma) * validation_list
let first_goal = first_goal
let goal_goal_list = goal_goal_list
let apply_tac_list = apply_tac_list
let then_tactic_list = then_tactic_list
let tactic_list_tactic = tactic_list_tactic
let tclFIRSTLIST = tclFIRSTLIST
let tclIDTAC_list = tclIDTAC_list
(********************************************************)
(* Functions for handling the state of the proof editor *)
(********************************************************)
type pftreestate = Refiner.pftreestate
let proof_of_pftreestate = proof_of_pftreestate
let cursor_of_pftreestate = cursor_of_pftreestate
let is_top_pftreestate = is_top_pftreestate
let evc_of_pftreestate = evc_of_pftreestate
let top_goal_of_pftreestate = top_goal_of_pftreestate
let nth_goal_of_pftreestate = nth_goal_of_pftreestate
let traverse = traverse
let solve_nth_pftreestate = solve_nth_pftreestate
let solve_pftreestate = solve_pftreestate
let weak_undo_pftreestate = weak_undo_pftreestate
let mk_pftreestate = mk_pftreestate
let extract_pftreestate = extract_pftreestate
let extract_open_pftreestate = extract_open_pftreestate
let first_unproven = first_unproven
let last_unproven = last_unproven
let nth_unproven = nth_unproven
let node_prev_unproven = node_prev_unproven
let node_next_unproven = node_next_unproven
let next_unproven = next_unproven
let prev_unproven = prev_unproven
let top_of_tree = top_of_tree
let frontier = frontier
let change_constraints_pftreestate = change_constraints_pftreestate
(********************************************)
(* Definition of the most primitive tactics *)
(********************************************)
let refiner = refiner
(* This does not check that the variable name is not here *)
let introduction_no_check id =
refiner (Prim (Intro id))
(* This does not check that the dependencies are correct *)
let intro_replacing_no_check whereid gl =
refiner (Prim (Intro_replacing whereid)) gl
let internal_cut_no_check id t gl =
refiner (Prim (Cut (true,id,t))) gl
let internal_cut_rev_no_check id t gl =
refiner (Prim (Cut (false,id,t))) gl
let refine_no_check c gl =
refiner (Prim (Refine c)) gl
let convert_concl_no_check c sty gl =
refiner (Prim (Convert_concl (c,sty))) gl
let convert_hyp_no_check d gl =
refiner (Prim (Convert_hyp d)) gl
(* This does not check dependencies *)
let thin_no_check ids gl =
if ids = [] then tclIDTAC gl else refiner (Prim (Thin ids)) gl
(* This does not check dependencies *)
let thin_body_no_check ids gl =
if ids = [] then tclIDTAC gl else refiner (Prim (ThinBody ids)) gl
let move_hyp_no_check with_dep id1 id2 gl =
refiner (Prim (Move (with_dep,id1,id2))) gl
let rec rename_hyp_no_check l gl = match l with
| [] -> tclIDTAC gl
| (id1,id2)::l ->
tclTHEN (refiner (Prim (Rename (id1,id2))))
(rename_hyp_no_check l) gl
let mutual_fix f n others gl =
with_check (refiner (Prim (FixRule (f,n,others)))) gl
let mutual_cofix f others gl =
with_check (refiner (Prim (Cofix (f,others)))) gl
(* Versions with consistency checks *)
let introduction id = with_check (introduction_no_check id)
let intro_replacing id = with_check (intro_replacing_no_check id)
let internal_cut d t = with_check (internal_cut_no_check d t)
let internal_cut_rev d t = with_check (internal_cut_rev_no_check d t)
let refine c = with_check (refine_no_check c)
let convert_concl d sty = with_check (convert_concl_no_check d sty)
let convert_hyp d = with_check (convert_hyp_no_check d)
let thin l = with_check (thin_no_check l)
let thin_body c = with_check (thin_body_no_check c)
let move_hyp b id id' = with_check (move_hyp_no_check b id id')
let rename_hyp l = with_check (rename_hyp_no_check l)
(* Pretty-printers *)
open Pp
open Tacexpr
open Rawterm
let rec pr_list f = function
| [] -> mt ()
| a::l1 -> (f a) ++ pr_list f l1
let pr_gls gls =
hov 0 (pr_evar_map (sig_sig gls) ++ fnl () ++ db_pr_goal (sig_it gls))
let pr_glls glls =
hov 0 (pr_evar_map (sig_sig glls) ++ fnl () ++
prlist_with_sep pr_fnl db_pr_goal (sig_it glls))
|