let name,ty =
match defs with
| (params,(N.Ident (name, None), ty),_,_) :: _ ->
- let ty = match ty with Some ty -> ty | None -> N.Implicit in
+ let ty = match ty with Some ty -> ty | None -> N.Implicit `JustOne in
let ty =
List.fold_right
(fun var ty -> N.Binder (`Pi,var,ty)
else
`MutualDefinition
in
- (loc, N.Theorem(flavour, name, ty, Some (N.LetRec (ind_kind, defs, body))))
+ (loc, N.Theorem(flavour, name, ty, Some (N.LetRec (ind_kind, defs, body)), `Regular))
let nmk_rec_corec ind_kind defs loc =
let loc,t = mk_rec_corec ind_kind defs loc in
let deannotate = function
| N.AttributedTerm (_,t) | t -> t
in match deannotate params with
- | N.Implicit -> [false]
+ | N.Implicit _ -> [false]
| N.UserInput -> [true]
| N.Appl l ->
List.map (fun x -> match deannotate x with
- | N.Implicit -> false
+ | N.Implicit _ -> false
| N.UserInput -> true
| _ -> raise (Invalid_argument "malformed target parameter list 1")) l
| _ -> raise (Invalid_argument ("malformed target parameter list 2\n" ^ CicNotationPp.pp_term params)) ]
using: [ [ using = OPT [ IDENT "using"; t = tactic_term -> t ] -> using ] ];
ntactic: [
[ IDENT "napply"; t = tactic_term -> G.NApply (loc, t)
+ | IDENT "napplyS"; t = tactic_term -> G.NSmartApply (loc, t)
| IDENT "nassert";
seqs = LIST0 [
hyps = LIST0
concl = tactic_term -> (List.rev hyps,concl) ] ->
G.NAssert (loc, seqs)
| IDENT "nauto"; params = auto_params -> G.NAuto (loc, params)
+ | SYMBOL "/"; num = OPT NUMBER ; SYMBOL "/" ->
+ let depth = match num with Some n -> n | None -> "1" in
+ G.NAuto (loc, ([],["slir","";"depth",depth]))
| IDENT "ncases"; what = tactic_term ; where = pattern_spec ->
G.NCases (loc, what, where)
| IDENT "nchange"; what = pattern_spec; "with"; with_what = tactic_term ->
G.NChange (loc, what, with_what)
+ | SYMBOL "@"; num = OPT NUMBER; l = LIST0 tactic_term ->
+ G.NConstructor (loc,
+ (match num with None -> None | Some x -> Some (int_of_string x)),l)
+ | IDENT "ncut"; t = tactic_term -> G.NCut (loc, t)
+(* | IDENT "ndiscriminate"; t = tactic_term -> G.NDiscriminate (loc, t)
+ | IDENT "nsubst"; t = tactic_term -> G.NSubst (loc, t) *)
+ | IDENT "ndestruct" -> G.NDestruct loc
| IDENT "nelim"; what = tactic_term ; where = pattern_spec ->
G.NElim (loc, what, where)
| IDENT "ngeneralize"; p=pattern_spec ->
G.NGeneralize (loc, p)
+ | IDENT "nlapply"; t = tactic_term -> G.NLApply (loc, t)
| IDENT "nletin"; name = IDENT ; SYMBOL <:unicode<def>> ; t = tactic_term;
where = pattern_spec ->
G.NLetIn (loc,where,t,name)
G.NReduce (loc, kind, p)
| IDENT "nrewrite"; dir = direction; what = tactic_term ; where = pattern_spec ->
G.NRewrite (loc, dir, what, where)
- | IDENT "ntry"; LPAREN ; tac = SELF ; RPAREN -> G.NTry (loc,tac)
+ | IDENT "ntry"; tac = SELF -> G.NTry (loc,tac)
+ | IDENT "nrepeat"; tac = SELF -> G.NRepeat (loc,tac)
+ | LPAREN; l = LIST1 SELF; RPAREN -> G.NBlock (loc,l)
| IDENT "nassumption" -> G.NAssumption loc
| SYMBOL "#"; n=IDENT -> G.NIntro (loc,n)
| SYMBOL "#"; SYMBOL "_" -> G.NIntro (loc,"_")
];
auto_fixed_param: [
[ IDENT "paramodulation"
+ | IDENT "fast_paramod"
+ | IDENT "paramod"
+ | IDENT "slir"
| IDENT "depth"
| IDENT "width"
| IDENT "size"
| SYMBOL "|" -> G.NShift loc
| i = LIST1 int SEP SYMBOL ","; SYMBOL ":" -> G.NPos (loc, i)
| SYMBOL "*"; SYMBOL ":" -> G.NWildcard loc
+ | name = IDENT; SYMBOL ":" -> G.NPosbyname (loc, name)
| SYMBOL "]" -> G.NMerge loc
| SYMBOL ";" -> G.NSemicolon loc
| SYMBOL "." -> G.NDot loc
in
(params,name,typ,fields)
] ];
+
+ nmacro: [
+ [ [ IDENT "ncheck" ]; t = term -> G.NCheck (loc,t)
+ | [ IDENT "screenshot"]; fname = QSTRING -> G.Screenshot (loc, fname)
+ ]
+ ];
macro: [
[ [ IDENT "check" ]; t = term ->
IDENT "nqed" -> G.NQed loc
| nflavour = ntheorem_flavour; name = IDENT; SYMBOL ":"; typ = term;
body = OPT [ SYMBOL <:unicode<def>> (* ≝ *); body = term -> body ] ->
- G.NObj (loc, N.Theorem (nflavour, name, typ, body))
+ G.NObj (loc, N.Theorem (nflavour, name, typ, body,`Regular))
| nflavour = ntheorem_flavour; name = IDENT; SYMBOL <:unicode<def>> (* ≝ *);
body = term ->
- G.NObj (loc, N.Theorem (nflavour, name, N.Implicit, Some body))
+ G.NObj (loc, N.Theorem (nflavour, name, N.Implicit `JustOne, Some body,`Regular))
| IDENT "naxiom"; name = IDENT; SYMBOL ":"; typ = term ->
- G.NObj (loc, N.Theorem (`Axiom, name, typ, None))
+ G.NObj (loc, N.Theorem (`Axiom, name, typ, None, `Regular))
+ | IDENT "ndiscriminator" ; indty = tactic_term -> G.NDiscriminator (loc,indty)
+ | IDENT "ninverter"; name = IDENT; IDENT "for" ; indty = tactic_term ;
+ paramspec = OPT inverter_param_list ;
+ outsort = OPT [ SYMBOL ":" ; outsort = term -> outsort ] ->
+ G.NInverter (loc,name,indty,paramspec,outsort)
| NLETCOREC ; defs = let_defs ->
nmk_rec_corec `CoInductive defs loc
| NLETREC ; defs = let_defs ->
in
G.NObj (loc, N.Inductive (params, ind_types))
| IDENT "universe"; IDENT "constraint"; u1 = tactic_term;
- strict = [ SYMBOL <:unicode<lt>> -> true
- | SYMBOL <:unicode<leq>> -> false ];
- u2 = tactic_term ->
- let u1 =
- match u1 with
- | CicNotationPt.AttributedTerm (_, CicNotationPt.Sort (`NType i)) ->
- NUri.uri_of_string ("cic:/matita/pts/Type"^i^".univ")
- | CicNotationPt.AttributedTerm (_, CicNotationPt.Sort (`NCProp i)) ->
- NUri.uri_of_string ("cic:/matita/pts/CProp"^i^".univ")
- | _ -> raise (Failure "only a sort can be constrained")
- in
- let u2 =
- match u2 with
+ SYMBOL <:unicode<lt>> ; u2 = tactic_term ->
+ let urify = function
| CicNotationPt.AttributedTerm (_, CicNotationPt.Sort (`NType i)) ->
NUri.uri_of_string ("cic:/matita/pts/Type"^i^".univ")
- | CicNotationPt.AttributedTerm (_, CicNotationPt.Sort (`NCProp i)) ->
- NUri.uri_of_string ("cic:/matita/pts/CProp"^i^".univ")
- | _ -> raise (Failure "only a sort can be constrained")
+ | _ -> raise (Failure "only a Type[…] sort can be constrained")
in
- G.NUnivConstraint (loc, strict,u1,u2)
+ let u1 = urify u1 in
+ let u2 = urify u2 in
+ G.NUnivConstraint (loc,u1,u2)
| IDENT "unification"; IDENT "hint"; n = int; t = tactic_term ->
G.UnificationHint (loc, t, n)
+ | IDENT "ncoercion"; name = IDENT; SYMBOL ":"; ty = term;
+ SYMBOL <:unicode<def>>; t = term; "on";
+ id = [ IDENT | PIDENT ]; SYMBOL ":"; source = term;
+ "to"; target = term ->
+ G.NCoercion(loc,name,t,ty,(id,source),target)
| IDENT "nrecord" ; (params,name,ty,fields) = record_spec ->
G.NObj (loc, N.Record (params,name,ty,fields))
+ | IDENT "ncopy" ; s = IDENT; IDENT "from"; u = URI; "with";
+ m = LIST0 [ u1 = URI; SYMBOL <:unicode<mapsto>>; u2 = URI -> u1,u2 ] ->
+ G.NCopy (loc,s,NUri.uri_of_string u,
+ List.map (fun a,b -> NUri.uri_of_string a, NUri.uri_of_string b) m)
]];
grafite_command: [ [
typ = term; SYMBOL <:unicode<def>> ; newname = IDENT ->
G.Obj (loc,
N.Theorem
- (`Variant,name,typ,Some (N.Ident (newname, None))))
+ (`Variant,name,typ,Some (N.Ident (newname, None)), `Regular))
| flavour = theorem_flavour; name = IDENT; SYMBOL ":"; typ = term;
body = OPT [ SYMBOL <:unicode<def>> (* ≝ *); body = term -> body ] ->
- G.Obj (loc, N.Theorem (flavour, name, typ, body))
+ G.Obj (loc, N.Theorem (flavour, name, typ, body,`Regular))
| flavour = theorem_flavour; name = IDENT; SYMBOL <:unicode<def>> (* ≝ *);
body = term ->
G.Obj (loc,
- N.Theorem (flavour, name, N.Implicit, Some body))
+ N.Theorem (flavour, name, N.Implicit `JustOne, Some body,`Regular))
| IDENT "axiom"; name = IDENT; SYMBOL ":"; typ = term ->
- G.Obj (loc, N.Theorem (`Axiom, name, typ, None))
+ G.Obj (loc, N.Theorem (`Axiom, name, typ, None, `Regular))
| LETCOREC ; defs = let_defs ->
mk_rec_corec `CoInductive defs loc
| LETREC ; defs = let_defs ->
punct = punctuation_tactical ->
G.NTactic (loc, [nnon_punct_of_punct tac; npunct_of_punct punct])
| mac = macro; SYMBOL "." -> G.Macro (loc, mac)
+ | mac = nmacro; SYMBOL "." -> G.NMacro (loc, mac)
]
];
comment: [
status, LSome stm
| (iloc,fname,normal,mode) = include_command ; SYMBOL "." ->
fun ?(never_include=false) ~include_paths status ->
+ let _root, buri, fullpath, _rrelpath =
+ Librarian.baseuri_of_script ~include_paths fname in
+ if never_include then raise (NoInclusionPerformed fullpath)
+ else
+ begin
let stm =
- G.Executable (loc, G.Command (loc, G.Include (iloc, normal, fname)))
- in
+ G.Executable
+ (loc, G.Command (loc, G.Include (iloc,normal,`OldAndNew,fname))) in
!grafite_callback stm;
- let _root, buri, fullpath, _rrelpath =
- Librarian.baseuri_of_script ~include_paths fname
- in
let status =
- if never_include then raise (NoInclusionPerformed fullpath)
- else LE.eval_command status (L.Include (iloc,buri,mode,fullpath))
- in
+ LE.eval_command status (L.Include (iloc,buri,mode,fullpath)) in
let stm =
- G.Executable (loc, G.Command (loc, G.Include (iloc, normal, buri)))
+ G.Executable
+ (loc,G.Command (loc,G.Include (iloc,normal,`OldAndNew,buri)))
in
- status, LSome stm
+ status, LSome stm
+ end
| scom = lexicon_command ; SYMBOL "." ->
fun ?(never_include=false) ~include_paths status ->
!lexicon_callback scom;