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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 Pp
open Util
open Names
open Nameops
open Term
open Termops
open Sign
open Environ
open Global
open Declare
open Libnames
open Nametab
open Ppconstr
open Evd
open Proof_type
open Decl_mode
open Refiner
open Pfedit
open Ppconstr
open Constrextern
let emacs_str s alts =
match !Options.print_emacs, !Options.print_emacs_safechar with
| true, true -> alts
| true , false -> s
| false,_ -> ""
(**********************************************************************)
(** Terms *)
(* [at_top] means ids of env must be avoided in bound variables *)
let pr_constr_core at_top env t =
pr_constr_expr (extern_constr at_top env t)
let pr_lconstr_core at_top env t =
pr_lconstr_expr (extern_constr at_top env t)
let pr_lconstr_env_at_top env = pr_lconstr_core true env
let pr_lconstr_env env = pr_lconstr_core false env
let pr_constr_env env = pr_constr_core false env
let pr_open_lconstr_env env (_,c) = pr_lconstr_env env c
let pr_open_constr_env env (_,c) = pr_constr_env env c
(* NB do not remove the eta-redexes! Global.env() has side-effects... *)
let pr_lconstr t = pr_lconstr_env (Global.env()) t
let pr_constr t = pr_constr_env (Global.env()) t
let pr_open_lconstr (_,c) = pr_lconstr c
let pr_open_constr (_,c) = pr_constr c
let pr_type_core at_top env t =
pr_constr_expr (extern_type at_top env t)
let pr_ltype_core at_top env t =
pr_lconstr_expr (extern_type at_top env t)
let pr_ltype_env_at_top env = pr_ltype_core true env
let pr_ltype_env env = pr_ltype_core false env
let pr_type_env env = pr_type_core false env
let pr_ltype t = pr_ltype_env (Global.env()) t
let pr_type t = pr_type_env (Global.env()) t
let pr_ljudge_env env j =
(pr_lconstr_env env j.uj_val, pr_lconstr_env env j.uj_type)
let pr_ljudge j = pr_ljudge_env (Global.env()) j
let pr_lrawconstr_env env c =
pr_lconstr_expr (extern_rawconstr (vars_of_env env) c)
let pr_rawconstr_env env c =
pr_constr_expr (extern_rawconstr (vars_of_env env) c)
let pr_lrawconstr c =
pr_lconstr_expr (extern_rawconstr Idset.empty c)
let pr_rawconstr c =
pr_constr_expr (extern_rawconstr Idset.empty c)
let pr_cases_pattern t =
pr_cases_pattern_expr (extern_cases_pattern Idset.empty t)
let pr_lconstr_pattern_env env c =
pr_lconstr_expr (extern_constr_pattern (names_of_rel_context env) c)
let pr_constr_pattern_env env c =
pr_constr_expr (extern_constr_pattern (names_of_rel_context env) c)
let pr_lconstr_pattern t =
pr_lconstr_expr (extern_constr_pattern empty_names_context t)
let pr_constr_pattern t =
pr_constr_expr (extern_constr_pattern empty_names_context t)
let pr_sort s = pr_rawsort (extern_sort s)
let _ = Termops.set_print_constr pr_lconstr_env
(**********************************************************************)
(* Global references *)
let pr_global_env = pr_global_env
let pr_global = pr_global_env Idset.empty
let pr_constant env cst = pr_global_env (vars_of_env env) (ConstRef cst)
let pr_existential env ev = pr_lconstr_env env (mkEvar ev)
let pr_inductive env ind = pr_lconstr_env env (mkInd ind)
let pr_constructor env cstr = pr_lconstr_env env (mkConstruct cstr)
let pr_evaluable_reference ref =
let ref' = match ref with
| EvalConstRef const -> ConstRef const
| EvalVarRef sp -> VarRef sp in
pr_global ref'
(*let pr_rawterm t =
pr_lconstr (Constrextern.extern_rawconstr Idset.empty t)*)
(*open Pattern
let pr_pattern t = pr_pattern_env (Global.env()) empty_names_context t*)
(**********************************************************************)
(* Contexts and declarations *)
let pr_var_decl env (id,c,typ) =
let pbody = match c with
| None -> (mt ())
| Some c ->
(* Force evaluation *)
let pb = pr_lconstr_env env c in
let pb = if isCast c then surround pb else pb in
(str" := " ++ pb ++ cut () ) in
let pt = pr_ltype_env env typ in
let ptyp = (str" : " ++ pt) in
(pr_id id ++ hov 0 (pbody ++ ptyp))
let pr_rel_decl env (na,c,typ) =
let pbody = match c with
| None -> mt ()
| Some c ->
(* Force evaluation *)
let pb = pr_lconstr_env env c in
let pb = if isCast c then surround pb else pb in
(str":=" ++ spc () ++ pb ++ spc ()) in
let ptyp = pr_ltype_env env typ in
match na with
| Anonymous -> hov 0 (str"<>" ++ spc () ++ pbody ++ str":" ++ spc () ++ ptyp)
| Name id -> hov 0 (pr_id id ++ spc () ++ pbody ++ str":" ++ spc () ++ ptyp)
(* Prints out an "env" in a nice format. We print out the
* signature,then a horizontal bar, then the debruijn environment.
* It's printed out from outermost to innermost, so it's readable. *)
(* Prints a signature, all declarations on the same line if possible *)
let pr_named_context_of env =
hv 0 (fold_named_context
(fun env d pps -> pps ++ ws 2 ++ pr_var_decl env d)
env ~init:(mt ()))
let pr_named_context env ne_context =
hv 0 (Sign.fold_named_context
(fun d pps -> pps ++ ws 2 ++ pr_var_decl env d)
ne_context ~init:(mt ()))
let pr_rel_context env rel_context =
let rec prec env = function
| [] -> (mt ())
| [b] -> str "(" ++ pr_rel_decl env b ++ str")"
| b::rest ->
let pb = pr_rel_decl env b in
let penvtl = prec (push_rel b env) rest in
str "(" ++ pb ++ str")" ++ spc () ++ penvtl
in
hov 0 (prec env (List.rev rel_context))
let pr_rel_context_of env =
pr_rel_context env (rel_context env)
(* Prints an env (variables and de Bruijn). Separator: newline *)
let pr_context_unlimited env =
let sign_env =
fold_named_context
(fun env d pps ->
let pidt = pr_var_decl env d in (pps ++ fnl () ++ pidt))
env ~init:(mt ())
in
let db_env =
fold_rel_context
(fun env d pps ->
let pnat = pr_rel_decl env d in (pps ++ fnl () ++ pnat))
env ~init:(mt ())
in
(sign_env ++ db_env)
let pr_ne_context_of header env =
if Environ.rel_context env = empty_rel_context &
Environ.named_context env = empty_named_context then (mt ())
else let penv = pr_context_unlimited env in (header ++ penv ++ fnl ())
let pr_context_limit n env =
let named_context = Environ.named_context env in
let lgsign = List.length named_context in
if n >= lgsign then
pr_context_unlimited env
else
let k = lgsign-n in
let _,sign_env =
fold_named_context
(fun env d (i,pps) ->
if i < k then
(i+1, (pps ++str "."))
else
let pidt = pr_var_decl env d in
(i+1, (pps ++ fnl () ++
str (emacs_str (String.make 1 (Char.chr 253)) "") ++
pidt)))
env ~init:(0,(mt ()))
in
let db_env =
fold_rel_context
(fun env d pps ->
let pnat = pr_rel_decl env d in
(pps ++ fnl () ++
str (emacs_str (String.make 1 (Char.chr 253)) "") ++
pnat))
env ~init:(mt ())
in
(sign_env ++ db_env)
let pr_context_of env = match Options.print_hyps_limit () with
| None -> hv 0 (pr_context_unlimited env)
| Some n -> hv 0 (pr_context_limit n env)
(* display goal parts (Proof mode) *)
let pr_restricted_named_context among env =
hv 0 (fold_named_context
(fun env ((id,_,_) as d) pps ->
if true || Idset.mem id among then
pps ++
fnl () ++ str (emacs_str (String.make 1 (Char.chr 253)) "") ++
pr_var_decl env d
else
pps)
env ~init:(mt ()))
let pr_subgoal_metas metas env=
let pr_one (meta,typ) =
str "?" ++ int meta ++ str " : " ++
hov 0 (pr_ltype_env_at_top env typ) ++ fnl () ++
str (emacs_str (String.make 1 (Char.chr 253)) "") in
hv 0 (prlist_with_sep mt pr_one metas)
(* display complete goal *)
let default_pr_goal g =
let env = evar_env g in
let preamb,penv,pc =
if g.evar_extra = None then
mt (),
pr_context_of env,
pr_ltype_env_at_top env g.evar_concl
else
(str " *** Declarative Mode ***" ++ fnl ()++fnl ()),
pr_context_of env,
pr_ltype_env_at_top env g.evar_concl
in
preamb ++
str" " ++ hv 0 (penv ++ fnl () ++
str (emacs_str (String.make 1 (Char.chr 253)) "") ++
str "============================" ++ fnl () ++
str"thesis := " ++ fnl () ++ str " " ++ pc) ++ fnl ()
(* display the conclusion of a goal *)
let pr_concl n g =
let env = evar_env g in
let pc = pr_ltype_env_at_top env g.evar_concl in
str (emacs_str (String.make 1 (Char.chr 253)) "") ++
str "subgoal " ++ int n ++ str " is:" ++ cut () ++ str" " ++ pc
(* display evar type: a context and a type *)
let pr_evgl_sign gl =
let ps = pr_named_context_of (evar_env gl) in
let pc = pr_lconstr gl.evar_concl in
hov 0 (str"[" ++ ps ++ spc () ++ str"|- " ++ pc ++ str"]")
(* Print an enumerated list of existential variables *)
let rec pr_evars_int i = function
| [] -> (mt ())
| (ev,evd)::rest ->
let pegl = pr_evgl_sign evd in
let pei = pr_evars_int (i+1) rest in
(hov 0 (str "Existential " ++ int i ++ str " =" ++ spc () ++
str (string_of_existential ev) ++ str " : " ++ pegl)) ++
fnl () ++ pei
let default_pr_subgoal n =
let rec prrec p = function
| [] -> error "No such goal"
| g::rest ->
if p = 1 then
let pg = default_pr_goal g in
v 0 (str "subgoal " ++ int n ++ str " is:" ++ cut () ++ pg)
else
prrec (p-1) rest
in
prrec n
(* Print open subgoals. Checks for uninstantiated existential variables *)
let default_pr_subgoals close_cmd sigma = function
| [] ->
begin
match close_cmd with
Some cmd ->
(str "Subproof completed, now type " ++ str cmd ++
str "." ++ fnl ())
| None ->
let exl = Evarutil.non_instantiated sigma in
if exl = [] then
(str"Proof completed." ++ fnl ())
else
let pei = pr_evars_int 1 exl in
(str "No more subgoals but non-instantiated existential " ++
str "variables :" ++fnl () ++ (hov 0 pei))
end
| [g] ->
let pg = default_pr_goal g in
v 0 (str ("1 "^"subgoal") ++cut () ++ pg)
| g1::rest ->
let rec pr_rec n = function
| [] -> (mt ())
| g::rest ->
let pc = pr_concl n g in
let prest = pr_rec (n+1) rest in
(cut () ++ pc ++ prest)
in
let pg1 = default_pr_goal g1 in
let prest = pr_rec 2 rest in
v 0 (int(List.length rest+1) ++ str" subgoals" ++ cut ()
++ pg1 ++ prest ++ fnl ())
(**********************************************************************)
(* Abstraction layer *)
type printer_pr = {
pr_subgoals : string option -> evar_map -> goal list -> std_ppcmds;
pr_subgoal : int -> goal list -> std_ppcmds;
pr_goal : goal -> std_ppcmds;
}
let default_printer_pr = {
pr_subgoals = default_pr_subgoals;
pr_subgoal = default_pr_subgoal;
pr_goal = default_pr_goal;
}
let printer_pr = ref default_printer_pr
let set_printer_pr = (:=) printer_pr
let pr_subgoals x = !printer_pr.pr_subgoals x
let pr_subgoal x = !printer_pr.pr_subgoal x
let pr_goal x = !printer_pr.pr_goal x
(* End abstraction layer *)
(**********************************************************************)
let pr_subgoals_of_pfts pfts =
let close_cmd = Decl_mode.get_end_command pfts in
let gls = fst (Refiner.frontier (proof_of_pftreestate pfts)) in
let sigma = (top_goal_of_pftreestate pfts).sigma in
pr_subgoals close_cmd sigma gls
let pr_open_subgoals () =
let pfts = get_pftreestate () in
match focus() with
| 0 ->
pr_subgoals_of_pfts pfts
| n ->
let pf = proof_of_pftreestate pfts in
let gls = fst (frontier pf) in
assert (n > List.length gls);
if List.length gls < 2 then
pr_subgoal n gls
else
(* LEM TODO: this way of saying how many subgoals has to be abstracted out*)
v 0 (int(List.length gls) ++ str" subgoals" ++ cut () ++
pr_subgoal n gls)
let pr_nth_open_subgoal n =
let pf = proof_of_pftreestate (get_pftreestate ()) in
pr_subgoal n (fst (frontier pf))
(* Elementary tactics *)
let pr_prim_rule = function
| Intro id ->
str"intro " ++ pr_id id
| Intro_replacing id ->
(str"intro replacing " ++ pr_id id)
| Cut (b,id,t) ->
if b then
(str"assert " ++ pr_constr t)
else
(str"cut " ++ pr_constr t ++ str ";[intro " ++ pr_id id ++ str "|idtac]")
| FixRule (f,n,[]) ->
(str"fix " ++ pr_id f ++ str"/" ++ int n)
| FixRule (f,n,others) ->
let rec print_mut = function
| (f,n,ar)::oth ->
pr_id f ++ str"/" ++ int n ++ str" : " ++ pr_lconstr ar ++ print_mut oth
| [] -> mt () in
(str"fix " ++ pr_id f ++ str"/" ++ int n ++
str" with " ++ print_mut others)
| Cofix (f,[]) ->
(str"cofix " ++ pr_id f)
| Cofix (f,others) ->
let rec print_mut = function
| (f,ar)::oth ->
(pr_id f ++ str" : " ++ pr_lconstr ar ++ print_mut oth)
| [] -> mt () in
(str"cofix " ++ pr_id f ++ str" with " ++ print_mut others)
| Refine c ->
str(if occur_meta c then "refine " else "exact ") ++
Constrextern.with_meta_as_hole pr_constr c
| Convert_concl (c,_) ->
(str"change " ++ pr_constr c)
| Convert_hyp (id,None,t) ->
(str"change " ++ pr_constr t ++ spc () ++ str"in " ++ pr_id id)
| Convert_hyp (id,Some c,t) ->
(str"change " ++ pr_constr c ++ spc () ++ str"in "
++ pr_id id ++ str" (type of " ++ pr_id id ++ str ")")
| Thin ids ->
(str"clear " ++ prlist_with_sep pr_spc pr_id ids)
| ThinBody ids ->
(str"clearbody " ++ prlist_with_sep pr_spc pr_id ids)
| Move (withdep,id1,id2) ->
(str (if withdep then "dependent " else "") ++
str"move " ++ pr_id id1 ++ str " after " ++ pr_id id2)
| Rename (id1,id2) ->
(str "rename " ++ pr_id id1 ++ str " into " ++ pr_id id2)
| Change_evars ->
(* This is internal tactic and cannot be replayed at user-level.
Function pr_rule_dot below is used when we want to hide
Change_evars *)
str "Evar change"
(* Backwards compatibility *)
let prterm = pr_lconstr
(* spiwack a little printer function for sets of Environ.assumption *)
(* arnaud : tester "Print Assumptions" *)
let pr_assumptionset env s =
if not (Environ.AssumptionSet.is_empty s) then
let (vars, axioms) = Environ.AssumptionSet.partition
(function |Variable _ -> true | _ -> false) s
in
(if not (Environ.AssumptionSet.is_empty vars) then
str "Section Variables:" ++ fnl () ++
(Environ.AssumptionSet.fold
(function Variable (id,typ ) ->
(fun s -> s++str (string_of_identifier id)++str " : "++pr_ltype typ++spc ())
| _ -> assert false)
vars (fnl ()))
else
mt ()
)++
if not (Environ.AssumptionSet.is_empty axioms) then
str "Axioms:" ++ fnl () ++
(Environ.AssumptionSet.fold
(function Axiom (cst, typ) ->
(fun s -> s++(pr_constant env cst)++str " : "++pr_ltype typ++spc ())
| _ -> assert false)
axioms (mt ()))
else
mt ()
else
raise Not_found
|