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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 *)
(************************************************************************)
(*i*)
open Errors
open Util
open Pp
open Names
open Nameops
open Libnames
open Pputils
open Ppextend
open Constrexpr
open Constrexpr_ops
open Decl_kinds
open Misctypes
open Locus
open Genredexpr
(*i*)
let sep_v = fun _ -> str"," ++ spc()
let pr_tight_coma () = str "," ++ cut ()
let latom = 0
let lprod = 200
let llambda = 200
let lif = 200
let lletin = 200
let lletpattern = 200
let lfix = 200
let lcast = 100
let larg = 9
let lapp = 10
let lposint = 0
let lnegint = 35 (* must be consistent with Notation "- x" *)
let ltop = (200,E)
let lproj = 1
let ldelim = 1
let lsimpleconstr = (8,E)
let lsimplepatt = (1,E)
let prec_less child (parent,assoc) =
if parent < 0 && Int.equal child lprod then true
else
let parent = abs parent in
match assoc with
| E -> (<=) child parent
| L -> (<) child parent
| Prec n -> child<=n
| Any -> true
let prec_of_prim_token = function
| Numeral p -> if Bigint.is_pos_or_zero p then lposint else lnegint
| String _ -> latom
open Notation
let print_hunks n pr pr_binders (terms,termlists,binders) unp =
let env = ref terms and envlist = ref termlists and bll = ref binders in
let pop r = let a = List.hd !r in r := List.tl !r; a in
let rec aux = function
| [] -> mt ()
| UnpMetaVar (_,prec) :: l ->
let c = pop env in pr (n,prec) c ++ aux l
| UnpListMetaVar (_,prec,sl) :: l ->
let cl = pop envlist in
let pp1 = prlist_with_sep (fun () -> aux sl) (pr (n,prec)) cl in
let pp2 = aux l in
pp1 ++ pp2
| UnpBinderListMetaVar (_,isopen,sl) :: l ->
let cl = pop bll in pr_binders (fun () -> aux sl) isopen cl ++ aux l
| UnpTerminal s :: l -> str s ++ aux l
| UnpBox (b,sub) :: l ->
(* Keep order: side-effects *)
let pp1 = ppcmd_of_box b (aux sub) in
let pp2 = aux l in
pp1 ++ pp2
| UnpCut cut :: l -> ppcmd_of_cut cut ++ aux l in
aux unp
let pr_notation pr pr_binders s env =
let unpl, level = find_notation_printing_rule s in
print_hunks level pr pr_binders env unpl, level
let pr_delimiters key strm =
strm ++ str ("%"^key)
let pr_generalization bk ak c =
let hd, tl =
match bk with
| Implicit -> "{", "}"
| Explicit -> "(", ")"
in (* TODO: syntax Abstraction Kind *)
str "`" ++ str hd ++ c ++ str tl
let pr_com_at n =
if Flags.do_beautify() && not (Int.equal n 0) then comment n
else mt()
let pr_with_comments loc pp = pr_located (fun x -> x) (loc,pp)
let pr_sep_com sep f c = pr_with_comments (constr_loc c) (sep() ++ f c)
let pr_in_comment pr x = str "(* " ++ pr x ++ str " *)"
let pr_univ_annot pr x = str "@{" ++ pr x ++ str "}"
let pr_glob_sort = function
| GProp -> str "Prop"
| GSet -> str "Set"
| GType u -> hov 0 (str "Type" ++ pr_opt_no_spc (pr_univ_annot str) u)
let pr_id = pr_id
let pr_name = pr_name
let pr_qualid = pr_qualid
let pr_patvar = pr_id
let pr_glob_sort_instance = function
| GProp -> str "Prop"
| GSet -> str "Set"
| GType u ->
(match u with
| Some u -> str u
| None -> str "Type")
let pr_universe_instance l =
pr_opt_no_spc (pr_univ_annot (prlist_with_sep spc pr_glob_sort_instance)) l
let pr_cref ref us =
pr_reference ref ++ pr_universe_instance us
let pr_expl_args pr (a,expl) =
match expl with
| None -> pr (lapp,L) a
| Some (_,ExplByPos (n,_id)) ->
anomaly (Pp.str "Explicitation by position not implemented")
| Some (_,ExplByName id) ->
str "(" ++ pr_id id ++ str ":=" ++ pr ltop a ++ str ")"
let pr_opt_type pr = function
| CHole _ -> mt ()
| t -> cut () ++ str ":" ++ pr t
let pr_opt_type_spc pr = function
| CHole _ -> mt ()
| t -> str " :" ++ pr_sep_com (fun()->brk(1,2)) (pr ltop) t
let pr_lident (loc,id) =
if not (Loc.is_ghost loc) then
let (b,_) = Loc.unloc loc in
pr_located pr_id (Loc.make_loc (b,b+String.length(Id.to_string id)),id)
else pr_id id
let pr_lname = function
(loc,Name id) -> pr_lident (loc,id)
| lna -> pr_located pr_name lna
let pr_or_var pr = function
| ArgArg x -> pr x
| ArgVar (loc,s) -> pr_lident (loc,s)
let pr_prim_token = function
| Numeral n -> str (Bigint.to_string n)
| String s -> qs s
let pr_evar pr n l =
hov 0 (str (Evd.string_of_existential n) ++
(match l with
| Some l ->
spc () ++ pr_in_comment
(fun l ->
str"[" ++ hov 0 (prlist_with_sep pr_comma (pr ltop) l) ++ str"]")
(List.rev l)
| None -> mt()))
let las = lapp
let lpator = 100
let lpatrec = 0
let rec pr_patt sep inh p =
let (strm,prec) = match p with
| CPatRecord (_, l) ->
let pp (c, p) =
pr_reference c ++ spc() ++ str ":=" ++ pr_patt spc (lpatrec, Any) p in
str "{| " ++ prlist_with_sep pr_semicolon pp l ++ str " |}", lpatrec
| CPatAlias (_,p,id) ->
pr_patt mt (las,E) p ++ str " as " ++ pr_id id, las
| CPatCstr (_,c,[],[]) -> pr_reference c, latom
| CPatCstr (_,c,[],args) ->
pr_reference c ++ prlist (pr_patt spc (lapp,L)) args, lapp
| CPatCstr (_,c,args,[]) ->
str "@" ++ pr_reference c ++ prlist (pr_patt spc (lapp,L)) args, lapp
| CPatCstr (_,c,expl_args,extra_args) ->
surround (str "@" ++ pr_reference c ++ prlist (pr_patt spc (lapp,L)) expl_args)
++ prlist (pr_patt spc (lapp,L)) extra_args, lapp
| CPatAtom (_,None) -> str "_", latom
| CPatAtom (_,Some r) -> pr_reference r, latom
| CPatOr (_,pl) ->
hov 0 (prlist_with_sep pr_bar (pr_patt spc (lpator,L)) pl), lpator
| CPatNotation (_,"( _ )",([p],[]),[]) ->
pr_patt (fun()->str"(") (max_int,E) p ++ str")", latom
| CPatNotation (_,s,(l,ll),args) ->
let strm_not, l_not = pr_notation (pr_patt mt) (fun _ _ _ -> mt()) s (l,ll,[]) in
(if List.is_empty args||prec_less l_not (lapp,L) then strm_not else surround strm_not)
++ prlist (pr_patt spc (lapp,L)) args, if not (List.is_empty args) then lapp else l_not
| CPatPrim (_,p) -> pr_prim_token p, latom
| CPatDelimiters (_,k,p) -> pr_delimiters k (pr_patt mt lsimplepatt p), 1
in
let loc = cases_pattern_expr_loc p in
pr_with_comments loc
(sep() ++ if prec_less prec inh then strm else surround strm)
let pr_patt = pr_patt mt
let pr_eqn pr (loc,pl,rhs) =
let pl = List.map snd pl in
spc() ++ hov 4
(pr_with_comments loc
(str "| " ++
hov 0 (prlist_with_sep pr_bar (prlist_with_sep sep_v (pr_patt ltop)) pl
++ str " =>") ++
pr_sep_com spc (pr ltop) rhs))
let begin_of_binder = function
LocalRawDef((loc,_),_) -> fst (Loc.unloc loc)
| LocalRawAssum((loc,_)::_,_,_) -> fst (Loc.unloc loc)
| _ -> assert false
let begin_of_binders = function
| b::_ -> begin_of_binder b
| _ -> 0
let surround_impl k p =
match k with
| Explicit -> str"(" ++ p ++ str")"
| Implicit -> str"{" ++ p ++ str"}"
let surround_implicit k p =
match k with
| Explicit -> p
| Implicit -> (str"{" ++ p ++ str"}")
let pr_binder many pr (nal,k,t) =
match k with
| Generalized (b, b', t') ->
assert (match b with Implicit -> true | _ -> false);
begin match nal with
|[loc,Anonymous] ->
hov 1 (str"`" ++ (surround_impl b'
((if t' then str "!" else mt ()) ++ pr t)))
|[loc,Name id] ->
hov 1 (str "`" ++ (surround_impl b'
(pr_lident (loc,id) ++ str " : " ++
(if t' then str "!" else mt()) ++ pr t)))
|_ -> anomaly (Pp.str "List of generalized binders have alwais one element.")
end
| Default b ->
match t with
| CHole _ ->
let s = prlist_with_sep spc pr_lname nal in
hov 1 (surround_implicit b s)
| _ ->
let s = prlist_with_sep spc pr_lname nal ++ str " : " ++ pr t in
hov 1 (if many then surround_impl b s else surround_implicit b s)
let pr_binder_among_many pr_c = function
| LocalRawAssum (nal,k,t) ->
pr_binder true pr_c (nal,k,t)
| LocalRawDef (na,c) ->
let c,topt = match c with
| CCast(_,c, (CastConv t|CastVM t|CastNative t)) -> c, t
| _ -> c, CHole (Loc.ghost, None, None) in
surround (pr_lname na ++ pr_opt_type pr_c topt ++
str":=" ++ cut() ++ pr_c c)
let pr_undelimited_binders sep pr_c =
prlist_with_sep sep (pr_binder_among_many pr_c)
let pr_delimited_binders kw sep pr_c bl =
let n = begin_of_binders bl in
match bl with
| [LocalRawAssum (nal,k,t)] ->
pr_com_at n ++ kw() ++ pr_binder false pr_c (nal,k,t)
| LocalRawAssum _ :: _ as bdl ->
pr_com_at n ++ kw() ++ pr_undelimited_binders sep pr_c bdl
| _ -> assert false
let pr_binders_gen pr_c sep is_open =
if is_open then pr_delimited_binders mt sep pr_c
else pr_undelimited_binders sep pr_c
let rec extract_prod_binders = function
(* | CLetIn (loc,na,b,c) as x ->
let bl,c = extract_prod_binders c in
if bl = [] then [], x else LocalRawDef (na,b) :: bl, c*)
| CProdN (loc,[],c) ->
extract_prod_binders c
| CProdN (loc,(nal,bk,t)::bl,c) ->
let bl,c = extract_prod_binders (CProdN(loc,bl,c)) in
LocalRawAssum (nal,bk,t) :: bl, c
| c -> [], c
let rec extract_lam_binders = function
(* | CLetIn (loc,na,b,c) as x ->
let bl,c = extract_lam_binders c in
if bl = [] then [], x else LocalRawDef (na,b) :: bl, c*)
| CLambdaN (loc,[],c) ->
extract_lam_binders c
| CLambdaN (loc,(nal,bk,t)::bl,c) ->
let bl,c = extract_lam_binders (CLambdaN(loc,bl,c)) in
LocalRawAssum (nal,bk,t) :: bl, c
| c -> [], c
let split_lambda = function
| CLambdaN (loc,[[na],bk,t],c) -> (na,t,c)
| CLambdaN (loc,([na],bk,t)::bl,c) -> (na,t,CLambdaN(loc,bl,c))
| CLambdaN (loc,(na::nal,bk,t)::bl,c) -> (na,t,CLambdaN(loc,(nal,bk,t)::bl,c))
| _ -> anomaly (Pp.str "ill-formed fixpoint body")
let rename na na' t c =
match (na,na') with
| (_,Name id), (_,Name id') ->
(na',t,Topconstr.replace_vars_constr_expr (Id.Map.singleton id id') c)
| (_,Name id), (_,Anonymous) -> (na,t,c)
| _ -> (na',t,c)
let split_product na' = function
| CProdN (loc,[[na],bk,t],c) -> rename na na' t c
| CProdN (loc,([na],bk,t)::bl,c) -> rename na na' t (CProdN(loc,bl,c))
| CProdN (loc,(na::nal,bk,t)::bl,c) ->
rename na na' t (CProdN(loc,(nal,bk,t)::bl,c))
| _ -> anomaly (Pp.str "ill-formed fixpoint body")
let rec split_fix n typ def =
if Int.equal n 0 then ([],typ,def)
else
let (na,_,def) = split_lambda def in
let (na,t,typ) = split_product na typ in
let (bl,typ,def) = split_fix (n-1) typ def in
(LocalRawAssum ([na],default_binder_kind,t)::bl,typ,def)
let pr_recursive_decl pr pr_dangling dangling_with_for id bl annot t c =
let pr_body =
if dangling_with_for then pr_dangling else pr in
pr_id id ++ str" " ++
hov 0 (pr_undelimited_binders spc (pr ltop) bl ++ annot) ++
pr_opt_type_spc pr t ++ str " :=" ++
pr_sep_com (fun () -> brk(1,2)) (pr_body ltop) c
let pr_guard_annot pr_aux bl (n,ro) =
match n with
| None -> mt ()
| Some (loc, id) ->
match (ro : Constrexpr.recursion_order_expr) with
| CStructRec ->
let names_of_binder = function
| LocalRawAssum (nal,_,_) -> nal
| LocalRawDef (_,_) -> []
in let ids = List.flatten (List.map names_of_binder bl) in
if List.length ids > 1 then
spc() ++ str "{struct " ++ pr_id id ++ str"}"
else mt()
| CWfRec c ->
spc() ++ str "{wf " ++ pr_aux c ++ spc() ++ pr_id id ++ str"}"
| CMeasureRec (m,r) ->
spc() ++ str "{measure " ++ pr_aux m ++ spc() ++ pr_id id++
(match r with None -> mt() | Some r -> str" on " ++ pr_aux r) ++ str"}"
let pr_fixdecl pr prd dangling_with_for ((_,id),ro,bl,t,c) =
let annot = pr_guard_annot (pr lsimpleconstr) bl ro in
pr_recursive_decl pr prd dangling_with_for id bl annot t c
let pr_cofixdecl pr prd dangling_with_for ((_,id),bl,t,c) =
pr_recursive_decl pr prd dangling_with_for id bl (mt()) t c
let pr_recursive pr_decl id = function
| [] -> anomaly (Pp.str "(co)fixpoint with no definition")
| [d1] -> pr_decl false d1
| dl ->
prlist_with_sep (fun () -> fnl() ++ str "with ")
(pr_decl true) dl ++
fnl() ++ str "for " ++ pr_id id
let pr_asin pr (na,indnalopt) =
(match na with (* Decision of printing "_" or not moved to constrextern.ml *)
| Some na -> spc () ++ str "as " ++ pr_lname na
| None -> mt ()) ++
(match indnalopt with
| None -> mt ()
| Some t -> spc () ++ str "in " ++ pr_patt lsimplepatt t)
let pr_case_item pr (tm,asin) =
hov 0 (pr (lcast,E) tm ++ pr_asin pr asin)
let pr_case_type pr po =
match po with
| None | Some (CHole _) -> mt()
| Some p ->
spc() ++ hov 2 (str "return" ++ pr_sep_com spc (pr lsimpleconstr) p)
let pr_simple_return_type pr na po =
(match na with
| Some (_,Name id) ->
spc () ++ str "as " ++ pr_id id
| _ -> mt ()) ++
pr_case_type pr po
let pr_proj pr pr_app a f l =
hov 0 (pr (lproj,E) a ++ cut() ++ str ".(" ++ pr_app pr f l ++ str ")")
let pr_appexpl pr (f,us) l =
hov 2 (
str "@" ++ pr_reference f ++
pr_universe_instance us ++
prlist (pr_sep_com spc (pr (lapp,L))) l)
let pr_app pr a l =
hov 2 (
pr (lapp,L) a ++
prlist (fun a -> spc () ++ pr_expl_args pr a) l)
let pr_forall () = str"forall" ++ spc ()
let pr_fun () = str"fun" ++ spc ()
let pr_fun_sep = str " =>"
let pr_dangling_with_for sep pr inherited a =
match a with
| (CFix (_,_,[_])|CCoFix(_,_,[_])) -> pr sep (latom,E) a
| _ -> pr sep inherited a
let pr pr sep inherited a =
let (strm,prec) = match a with
| CRef (r,us) -> pr_cref r us, latom
| CFix (_,id,fix) ->
hov 0 (str"fix " ++
pr_recursive
(pr_fixdecl (pr mt) (pr_dangling_with_for mt pr)) (snd id) fix),
lfix
| CCoFix (_,id,cofix) ->
hov 0 (str "cofix " ++
pr_recursive
(pr_cofixdecl (pr mt) (pr_dangling_with_for mt pr)) (snd id) cofix),
lfix
| CProdN _ ->
let (bl,a) = extract_prod_binders a in
hov 0 (
hov 2 (pr_delimited_binders pr_forall spc
(pr mt ltop) bl) ++
str "," ++ pr spc ltop a),
lprod
| CLambdaN _ ->
let (bl,a) = extract_lam_binders a in
hov 0 (
hov 2 (pr_delimited_binders pr_fun spc
(pr mt ltop) bl) ++
pr_fun_sep ++ pr spc ltop a),
llambda
| CLetIn (_,(_,Name x),(CFix(_,(_,x'),[_])|CCoFix(_,(_,x'),[_]) as fx), b)
when Id.equal x x' ->
hv 0 (
hov 2 (str "let " ++ pr mt ltop fx ++ str " in") ++
pr spc ltop b),
lletin
| CLetIn (_,x,a,b) ->
hv 0 (
hov 2 (str "let " ++ pr_lname x ++ str " :=" ++
pr spc ltop a ++ str " in") ++
pr spc ltop b),
lletin
| CAppExpl (_,(Some i,f,us),l) ->
let l1,l2 = List.chop i l in
let c,l1 = List.sep_last l1 in
let p = pr_proj (pr mt) pr_appexpl c (f,us) l1 in
if not (List.is_empty l2) then
p ++ prlist (pr spc (lapp,L)) l2, lapp
else
p, lproj
| CAppExpl (_,(None,Ident (_,var),us),[t])
| CApp (_,(_,CRef(Ident(_,var),us)),[t,None])
when Id.equal var Notation_ops.ldots_var ->
hov 0 (str ".." ++ pr spc (latom,E) t ++ spc () ++ str ".."), larg
| CAppExpl (_,(None,f,us),l) -> pr_appexpl (pr mt) (f,us) l, lapp
| CApp (_,(Some i,f),l) ->
let l1,l2 = List.chop i l in
let c,l1 = List.sep_last l1 in
assert (Option.is_empty (snd c));
let p = pr_proj (pr mt) pr_app (fst c) f l1 in
if not (List.is_empty l2) then
p ++ prlist (fun a -> spc () ++ pr_expl_args (pr mt) a) l2, lapp
else
p, lproj
| CApp (_,(None,a),l) -> pr_app (pr mt) a l, lapp
| CRecord (_,w,l) ->
let beg =
match w with
| None -> spc ()
| Some t -> spc () ++ pr spc ltop t ++ spc () ++ str"with" ++ spc ()
in
hv 0 (str"{|" ++ beg ++
prlist_with_sep pr_semicolon
(fun (id, c) -> h 1 (pr_reference id ++ spc () ++ str":=" ++ pr spc ltop c)) l
++ str" |}"), latom
| CCases (_,LetPatternStyle,rtntypopt,[c,asin],[(_,[(loc,[p])],b)]) ->
hv 0 (
str "let '" ++
hov 0 (pr_patt ltop p ++
pr_asin (pr_dangling_with_for mt pr) asin ++
str " :=" ++ pr spc ltop c ++
pr_case_type (pr_dangling_with_for mt pr) rtntypopt ++
str " in" ++ pr spc ltop b)),
lletpattern
| CCases(_,_,rtntypopt,c,eqns) ->
v 0
(hv 0 (str "match" ++ brk (1,2) ++
hov 0 (
prlist_with_sep sep_v
(pr_case_item (pr_dangling_with_for mt pr)) c
++ pr_case_type (pr_dangling_with_for mt pr) rtntypopt) ++
spc () ++ str "with") ++
prlist (pr_eqn (pr mt)) eqns ++ spc() ++ str "end"),
latom
| CLetTuple (_,nal,(na,po),c,b) ->
hv 0 (
str "let " ++
hov 0 (str "(" ++
prlist_with_sep sep_v pr_lname nal ++
str ")" ++
pr_simple_return_type (pr mt) na po ++ str " :=" ++
pr spc ltop c ++ str " in") ++
pr spc ltop b),
lletin
| CIf (_,c,(na,po),b1,b2) ->
(* On force les parenthèses autour d'un "if" sous-terme (même si le
parsing est lui plus tolérant) *)
hv 0 (
hov 1 (str "if " ++ pr mt ltop c ++ pr_simple_return_type (pr mt) na po) ++
spc () ++
hov 0 (str "then" ++ pr (fun () -> brk (1,1)) ltop b1) ++ spc () ++
hov 0 (str "else" ++ pr (fun () -> brk (1,1)) ltop b2)),
lif
| CHole _ -> str "_", latom
| CEvar (_,n,l) -> pr_evar (pr mt) n l, latom
| CPatVar (_,(_,p)) -> str "?" ++ pr_patvar p, latom
| CSort (_,s) -> pr_glob_sort s, latom
| CCast (_,a,b) ->
hv 0 (pr mt (lcast,L) a ++ cut () ++
match b with
| CastConv b -> str ":" ++ pr mt (-lcast,E) b
| CastVM b -> str "<:" ++ pr mt (-lcast,E) b
| CastNative b -> str "<<:" ++ pr mt (-lcast,E) b
| CastCoerce -> str ":>"), lcast
| CNotation (_,"( _ )",([t],[],[])) ->
pr (fun()->str"(") (max_int,L) t ++ str")", latom
| CNotation (_,s,env) ->
pr_notation (pr mt) (pr_binders_gen (pr mt ltop)) s env
| CGeneralization (_,bk,ak,c) -> pr_generalization bk ak (pr mt ltop c), latom
| CPrim (_,p) -> pr_prim_token p, prec_of_prim_token p
| CDelimiters (_,sc,a) -> pr_delimiters sc (pr mt (ldelim,E) a), ldelim
in
let loc = constr_loc a in
pr_with_comments loc
(sep() ++ if prec_less prec inherited then strm else surround strm)
type term_pr = {
pr_constr_expr : constr_expr -> std_ppcmds;
pr_lconstr_expr : constr_expr -> std_ppcmds;
pr_constr_pattern_expr : constr_pattern_expr -> std_ppcmds;
pr_lconstr_pattern_expr : constr_pattern_expr -> std_ppcmds
}
type precedence = Ppextend.precedence * Ppextend.parenRelation
let modular_constr_pr = pr
let rec fix rf x =rf (fix rf) x
let pr = fix modular_constr_pr mt
let transf env c =
if !Flags.beautify_file then
let r = Constrintern.for_grammar (Constrintern.intern_constr env) c in
Constrextern.extern_glob_constr (Termops.vars_of_env env) r
else c
let pr prec c = pr prec (transf (Global.env()) c)
let pr_simpleconstr = function
| CAppExpl (_,(None,f,us),[]) -> str "@" ++ pr_cref f us
| c -> pr lsimpleconstr c
let default_term_pr = {
pr_constr_expr = pr_simpleconstr;
pr_lconstr_expr = pr ltop;
pr_constr_pattern_expr = pr_simpleconstr;
pr_lconstr_pattern_expr = pr ltop
}
let term_pr = ref default_term_pr
let set_term_pr = (:=) term_pr
let pr_constr_expr c = !term_pr.pr_constr_expr c
let pr_lconstr_expr c = !term_pr.pr_lconstr_expr c
let pr_constr_pattern_expr c = !term_pr.pr_constr_pattern_expr c
let pr_lconstr_pattern_expr c = !term_pr.pr_lconstr_pattern_expr c
let pr_cases_pattern_expr = pr_patt ltop
let pr_binders = pr_undelimited_binders spc (pr ltop)
let pr_with_occurrences pr (occs,c) =
match occs with
| AllOccurrences -> pr c
| NoOccurrences -> failwith "pr_with_occurrences: no occurrences"
| OnlyOccurrences nl ->
hov 1 (pr c ++ spc() ++ str"at " ++
hov 0 (prlist_with_sep spc (pr_or_var int) nl))
| AllOccurrencesBut nl ->
hov 1 (pr c ++ spc() ++ str"at - " ++
hov 0 (prlist_with_sep spc (pr_or_var int) nl))
let pr_red_flag pr r =
(if r.rBeta then pr_arg str "beta" else mt ()) ++
(if r.rIota then pr_arg str "iota" else mt ()) ++
(if r.rZeta then pr_arg str "zeta" else mt ()) ++
(if List.is_empty r.rConst then
if r.rDelta then pr_arg str "delta"
else mt ()
else
pr_arg str "delta " ++ (if r.rDelta then str "-" else mt ()) ++
hov 0 (str "[" ++ prlist_with_sep spc pr r.rConst ++ str "]"))
let pr_metaid id = str"?" ++ pr_id id
let pr_red_expr (pr_constr,pr_lconstr,pr_ref,pr_pattern) = function
| Red false -> str "red"
| Hnf -> str "hnf"
| Simpl o -> str "simpl" ++ pr_opt (pr_with_occurrences pr_pattern) o
| Cbv f ->
if f.rBeta && f.rIota && f.rZeta && f.rDelta && List.is_empty f.rConst then
str "compute"
else
hov 1 (str "cbv" ++ pr_red_flag pr_ref f)
| Lazy f ->
hov 1 (str "lazy" ++ pr_red_flag pr_ref f)
| Cbn f ->
hov 1 (str "cbn" ++ pr_red_flag pr_ref f)
| Unfold l ->
hov 1 (str "unfold" ++ spc() ++
prlist_with_sep pr_comma (pr_with_occurrences pr_ref) l)
| Fold l -> hov 1 (str "fold" ++ prlist (pr_arg pr_constr) l)
| Pattern l ->
hov 1 (str "pattern" ++
pr_arg (prlist_with_sep pr_comma (pr_with_occurrences pr_constr)) l)
| Red true -> error "Shouldn't be accessible from user."
| ExtraRedExpr s -> str s
| CbvVm o -> str "vm_compute" ++ pr_opt (pr_with_occurrences pr_pattern) o
| CbvNative o -> str "native_compute" ++ pr_opt (pr_with_occurrences pr_pattern) o
let pr_may_eval test prc prlc pr2 pr3 = function
| ConstrEval (r,c) ->
hov 0
(str "eval" ++ brk (1,1) ++
pr_red_expr (prc,prlc,pr2,pr3) r ++
str " in" ++ spc() ++ prc c)
| ConstrContext ((_,id),c) ->
hov 0
(str "context " ++ pr_id id ++ spc () ++
str "[" ++ prlc c ++ str "]")
| ConstrTypeOf c -> hov 1 (str "type of" ++ spc() ++ prc c)
| ConstrTerm c when test c -> h 0 (str "(" ++ prc c ++ str ")")
| ConstrTerm c -> prc c
let pr_may_eval a = pr_may_eval (fun _ -> false) a
|