exception Parse_error of string
exception Level_not_found of int
-let level1_pattern_grammar =
- Grammar.gcreate CicNotationLexer.level1_pattern_lexer
-let level2_ast_grammar = Grammar.gcreate CicNotationLexer.level2_ast_lexer
-let level2_meta_grammar = Grammar.gcreate CicNotationLexer.level2_meta_lexer
-
let min_precedence = 0
let max_precedence = 100
-let level1_pattern =
- Grammar.Entry.create level1_pattern_grammar "level1_pattern"
-let level2_ast = Grammar.Entry.create level2_ast_grammar "level2_ast"
-let term = Grammar.Entry.create level2_ast_grammar "term"
-let let_defs = Grammar.Entry.create level2_ast_grammar "let_defs"
-let protected_binder_vars = Grammar.Entry.create level2_ast_grammar "protected_binder_vars"
-let level2_meta = Grammar.Entry.create level2_meta_grammar "level2_meta"
+type ('a,'b,'c,'d) grammars = {
+ level1_pattern: 'a Grammar.Entry.e;
+ level2_ast: 'b Grammar.Entry.e;
+ level2_ast_grammar : Grammar.g;
+ term: 'b Grammar.Entry.e;
+ let_defs: 'c Grammar.Entry.e;
+ protected_binder_vars: 'd Grammar.Entry.e;
+ level2_meta: 'b Grammar.Entry.e;
+}
+
+let initial_grammars () =
+ let level1_pattern_grammar =
+ Grammar.gcreate (CicNotationLexer.level1_pattern_lexer ()) in
+ let level2_ast_grammar =
+ Grammar.gcreate (CicNotationLexer.level2_ast_lexer ()) in
+ let level2_meta_grammar =
+ Grammar.gcreate (CicNotationLexer.level2_meta_lexer ()) in
+ let level1_pattern =
+ Grammar.Entry.create level1_pattern_grammar "level1_pattern" in
+ let level2_ast = Grammar.Entry.create level2_ast_grammar "level2_ast" in
+ let term = Grammar.Entry.create level2_ast_grammar "term" in
+ let let_defs = Grammar.Entry.create level2_ast_grammar "let_defs" in
+ let protected_binder_vars =
+ Grammar.Entry.create level2_ast_grammar "protected_binder_vars" in
+ let level2_meta = Grammar.Entry.create level2_meta_grammar "level2_meta" in
+ { level1_pattern=level1_pattern;
+ level2_ast=level2_ast;
+ term=term;
+ let_defs=let_defs;
+ protected_binder_vars=protected_binder_vars;
+ level2_meta=level2_meta;
+ level2_ast_grammar=level2_ast_grammar;
+}
+;;
+
+let grammars = ref (initial_grammars ());;
let int_of_string s =
try
(** {2 Grammar extension} *)
+let level_of precedence =
+ if precedence < min_precedence || precedence > max_precedence then
+ raise (Level_not_found precedence);
+ string_of_int precedence
+
let gram_symbol s = Gramext.Stoken ("SYMBOL", s)
let gram_ident s = Gramext.Stoken ("IDENT", s)
let gram_number s = Gramext.Stoken ("NUMBER", s)
let gram_keyword s = Gramext.Stoken ("", s)
-let gram_term = Gramext.Sself
+let gram_term = function
+ | Ast.Self _ -> Gramext.Sself
+ | Ast.Level precedence ->
+ Gramext.Snterml
+ (Grammar.Entry.obj (!grammars.term: 'a Grammar.Entry.e),
+ level_of precedence)
+;;
let gram_of_literal =
function
[] -> Gramext.action (fun (loc: Ast.location) -> action vl loc)
| NoBinding :: tl -> Gramext.action (fun _ -> aux vl tl)
(* LUCA: DEFCON 3 BEGIN *)
- | Binding (name, Env.TermType) :: tl ->
+ | Binding (name, Env.TermType l) :: tl ->
Gramext.action
(fun (v:Ast.term) ->
- aux ((name, (Env.TermType, Env.TermValue v))::vl) tl)
+ aux ((name, (Env.TermType l, Env.TermValue v))::vl) tl)
| Binding (name, Env.StringType) :: tl ->
Gramext.action
(fun (v:string) ->
[NoBinding, gram_keyword s]
| `Number s -> [NoBinding, gram_number s]
and aux_layout = function
- | Ast.Sub (p1, p2) -> aux p1 @ [NoBinding, gram_symbol "\\sub"] @ aux p2
- | Ast.Sup (p1, p2) -> aux p1 @ [NoBinding, gram_symbol "\\sup"] @ aux p2
- | Ast.Below (p1, p2) -> aux p1 @ [NoBinding, gram_symbol "\\below"] @ aux p2
- | Ast.Above (p1, p2) -> aux p1 @ [NoBinding, gram_symbol "\\above"] @ aux p2
- | Ast.Frac (p1, p2) -> aux p1 @ [NoBinding, gram_symbol "\\frac"] @ aux p2
- | Ast.Atop (p1, p2) -> aux p1 @ [NoBinding, gram_symbol "\\atop"] @ aux p2
- | Ast.Over (p1, p2) -> aux p1 @ [NoBinding, gram_symbol "\\over"] @ aux p2
+ | Ast.Sub (p1, p2) -> aux p1 @ [NoBinding, gram_symbol "\\sub "] @ aux p2
+ | Ast.Sup (p1, p2) -> aux p1 @ [NoBinding, gram_symbol "\\sup "] @ aux p2
+ | Ast.Below (p1, p2) -> aux p1 @ [NoBinding, gram_symbol "\\below "] @ aux p2
+ | Ast.Above (p1, p2) -> aux p1 @ [NoBinding, gram_symbol "\\above "] @ aux p2
+ | Ast.Frac (p1, p2) -> aux p1 @ [NoBinding, gram_symbol "\\frac "] @ aux p2
+ | Ast.InfRule (p1, p2, p3) -> [NoBinding, gram_symbol "\\infrule "] @ aux p1 @ aux p2 @ aux p3
+ | Ast.Atop (p1, p2) -> aux p1 @ [NoBinding, gram_symbol "\\atop "] @ aux p2
+ | Ast.Over (p1, p2) -> aux p1 @ [NoBinding, gram_symbol "\\over "] @ aux p2
| Ast.Root (p1, p2) ->
- [NoBinding, gram_symbol "\\root"] @ aux p2
- @ [NoBinding, gram_symbol "\\of"] @ aux p1
- | Ast.Sqrt p -> [NoBinding, gram_symbol "\\sqrt"] @ aux p
+ [NoBinding, gram_symbol "\\root "] @ aux p2
+ @ [NoBinding, gram_symbol "\\of "] @ aux p1
+ | Ast.Sqrt p -> [NoBinding, gram_symbol "\\sqrt "] @ aux p
| Ast.Break -> []
| Ast.Box (_, pl) -> List.flatten (List.map aux pl)
| Ast.Group pl -> List.flatten (List.map aux pl)
+ | Ast.Mstyle (_,pl) -> List.flatten (List.map aux pl)
+ | Ast.Mpadded (_,pl) -> List.flatten (List.map aux pl)
+ | Ast.Maction l -> List.flatten (List.map aux l)
and aux_magic magic =
match magic with
| Ast.Opt p ->
| Ast.List0 (p, _)
| Ast.List1 (p, _) ->
let p_bindings, p_atoms, p_names, p_action = inner_pattern p in
-(* let env0 = List.map list_binding_of_name p_names in
- let grow_env_entry env n v =
- List.map
- (function
- | (n', (ty, ListValue vl)) as entry ->
- if n' = n then n', (ty, ListValue (v :: vl)) else entry
- | _ -> assert false)
- env
- in
- let grow_env env_i env =
- List.fold_left
- (fun env (n, (_, v)) -> grow_env_entry env n v)
- env env_i
- in *)
let action (env_list : CicNotationEnv.t list) (loc : Ast.location) =
CicNotationEnv.coalesce_env p_names env_list
in
match magic with
| Ast.List0 (_, None) -> Gramext.Slist0 s
| Ast.List1 (_, None) -> Gramext.Slist1 s
- | Ast.List0 (_, Some l) -> Gramext.Slist0sep (s, gram_of_literal l)
- | Ast.List1 (_, Some l) -> Gramext.Slist1sep (s, gram_of_literal l)
+ | Ast.List0 (_, Some l) -> Gramext.Slist0sep (s, gram_of_literal l, false)
+ | Ast.List1 (_, Some l) -> Gramext.Slist1sep (s, gram_of_literal l, false)
| _ -> assert false
in
[ Env (List.map Env.list_declaration p_names),
and aux_variable =
function
| Ast.NumVar s -> [Binding (s, Env.NumType), gram_number ""]
- | Ast.TermVar s -> [Binding (s, Env.TermType), gram_term]
+ | Ast.TermVar (s,(Ast.Self level|Ast.Level level as lv)) ->
+ [Binding (s, Env.TermType level), gram_term lv]
| Ast.IdentVar s -> [Binding (s, Env.StringType), gram_ident ""]
| Ast.Ascription (p, s) -> assert false (* TODO *)
| Ast.FreshVar _ -> assert false
in
aux pattern
-let level_of precedence associativity =
- if precedence < min_precedence || precedence > max_precedence then
- raise (Level_not_found precedence);
- let assoc_string =
- match associativity with
- | Gramext.NonA -> "N"
- | Gramext.LeftA -> "L"
- | Gramext.RightA -> "R"
- in
- string_of_int precedence ^ assoc_string
+type rule_id = Grammar.token Gramext.g_symbol list
-type rule_id = Token.t Gramext.g_symbol list
+let compare_rule_id x y =
+ let rec aux = function
+ | [],[] -> 0
+ | [],_ -> ~-1
+ | _,[] -> 1
+ | ((s1::tl1) ),((s2::tl2) ) ->
+ if Gramext.eq_symbol s1 s2 then aux (tl1,tl2)
+ else
+ let res =
+ try Pervasives.compare s1 s2
+ with Invalid_argument _ -> 0
+ in
+ if res = 0 then aux (tl1, tl2) else res
+ in
+ aux (x,y)
(* mapping: rule_id -> owned keywords. (rule_id, string list) Hashtbl.t *)
-let owned_keywords = Hashtbl.create 23
+let initial_owned_keywords () = Hashtbl.create 23
+let owned_keywords = ref (initial_owned_keywords ())
-let extend level1_pattern ~precedence ~associativity action =
+type checked_l1_pattern = CL1P of CicNotationPt.term * int
+
+let check_l1_pattern level1_pattern pponly level associativity =
+ let variables = ref 0 in
+ let symbols = ref 0 in
+ let rec aux = function
+ | Ast.AttributedTerm (att, t) -> Ast.AttributedTerm (att,aux t)
+ | Ast.Literal _ as l -> incr symbols; l
+ | Ast.Layout l -> Ast.Layout (aux_layout l)
+ | Ast.Magic m -> Ast.Magic (aux_magic m)
+ | Ast.Variable v -> (aux_variable v)
+ | t -> assert false
+ and aux_layout = function
+ | Ast.Sub (p1, p2) -> let p1 = aux p1 in let p2 = aux p2 in Ast.Sub (p1, p2)
+ | Ast.Sup (p1, p2) -> let p1 = aux p1 in let p2 = aux p2 in Ast.Sup (p1, p2)
+ | Ast.Below (p1, p2) -> let p1 = aux p1 in let p2 = aux p2 in Ast.Below (p1, p2)
+ | Ast.Above (p1, p2) -> let p1 = aux p1 in let p2 = aux p2 in Ast.Above (p1, p2)
+ | Ast.Frac (p1, p2) -> let p1 = aux p1 in let p2 = aux p2 in Ast.Frac (p1, p2)
+ | Ast.InfRule (p1, p2, p3) -> let p1 = aux p1 in let p2 = aux p2 in let p3 = aux p3 in Ast.InfRule (p1, p2, p3)
+ | Ast.Atop (p1, p2) -> let p1 = aux p1 in let p2 = aux p2 in Ast.Atop (p1, p2)
+ | Ast.Over (p1, p2) -> let p1 = aux p1 in let p2 = aux p2 in Ast.Over (p1, p2)
+ | Ast.Root (p1, p2) -> let p1 = aux p1 in let p2 = aux p2 in Ast.Root (p1, p2)
+ | Ast.Sqrt p -> Ast.Sqrt (aux p)
+ | Ast.Break as t -> t
+ | Ast.Box (b, pl) -> Ast.Box(b, List.map aux pl)
+ | Ast.Group pl -> Ast.Group (List.map aux pl)
+ | Ast.Mstyle (l,pl) -> Ast.Mstyle (l, List.map aux pl)
+ | Ast.Mpadded (l,pl) -> Ast.Mpadded (l, List.map aux pl)
+ | Ast.Maction l as t ->
+ if not pponly then
+ raise(Parse_error("Maction can be used only in output notations"))
+ else t
+ and aux_magic magic =
+ match magic with
+ | Ast.Opt p -> Ast.Opt (aux p)
+ | Ast.List0 (p, x) -> Ast.List0 (aux p, x)
+ | Ast.List1 (p, x) -> Ast.List1 (aux p, x)
+ | _ -> assert false
+ and aux_variable =
+ function
+ | Ast.NumVar _ as t -> Ast.Variable t
+ | Ast.TermVar (s,Ast.Self _) when associativity <> Gramext.NonA ->
+ incr variables;
+ if !variables > 2 then
+ raise (Parse_error ("Exactly 2 variables must be specified in an "^
+ "associative notation"));
+ (match !variables, associativity with
+ | 1,Gramext.LeftA ->
+ Ast.Variable (Ast.TermVar (s, Ast.Self level))
+ | 1,Gramext.RightA ->
+ Ast.Variable (Ast.TermVar (s, Ast.Self (level+1)))
+ | 2,Gramext.LeftA ->
+ Ast.Variable (Ast.TermVar (s, Ast.Self (level+1)))
+ | 2,Gramext.RightA ->
+ Ast.Variable (Ast.TermVar (s, Ast.Level (level-1)))
+ | _ -> assert false)
+ | Ast.TermVar (s,Ast.Level _) when associativity <> Gramext.NonA ->
+ raise (Parse_error ("Variables can not be declared with a " ^
+ "precedence in an associative notation"))
+ (*avoid camlp5 divergence due to non-Sself recursion at the same level *)
+ | Ast.TermVar (s,Ast.Level l) when l<=level && !variables=0 && !symbols=0->
+ raise(Parse_error("Left recursive rule with precedence not greater " ^
+ "than " ^ string_of_int level ^ " is not allowed to avoid divergence"))
+ | Ast.TermVar _ as t -> incr variables; Ast.Variable t
+ | Ast.IdentVar _ as t -> Ast.Variable t
+ | Ast.Ascription _ -> assert false (* TODO *)
+ | Ast.FreshVar _ -> assert false
+ in
+ if associativity <> Gramext.NonA && level = min_precedence then
+ raise (Parse_error ("You can not specify an associative notation " ^
+ "at level "^string_of_int min_precedence ^ "; increase it"));
+ let cp = aux level1_pattern in
+(* prerr_endline ("checked_pattern: " ^ CicNotationPp.pp_term cp); *)
+ if !variables <> 2 && associativity <> Gramext.NonA then
+ raise (Parse_error ("Exactly 2 variables must be specified in an "^
+ "associative notation"));
+ CL1P (cp,level)
+;;
+
+let extend (CL1P (level1_pattern,precedence)) action =
let p_bindings, p_atoms =
List.split (extract_term_production level1_pattern)
in
- let level = level_of precedence associativity in
-(* let p_names = flatten_opt p_bindings in *)
+ let level = level_of precedence in
let _ =
Grammar.extend
- [ Grammar.Entry.obj (term: 'a Grammar.Entry.e),
+ [ Grammar.Entry.obj (!grammars.term: 'a Grammar.Entry.e),
Some (Gramext.Level level),
[ None,
- Some associativity,
+ Some (*Gramext.NonA*) Gramext.NonA,
[ p_atoms,
(make_action
(fun (env: CicNotationEnv.t) (loc: Ast.location) ->
let keywords = CicNotationUtil.keywords_of_term level1_pattern in
let rule_id = p_atoms in
List.iter CicNotationLexer.add_level2_ast_keyword keywords;
- Hashtbl.add owned_keywords rule_id keywords; (* keywords may be [] *)
+ Hashtbl.add !owned_keywords rule_id keywords; (* keywords may be [] *)
rule_id
let delete rule_id =
let atoms = rule_id in
(try
- let keywords = Hashtbl.find owned_keywords rule_id in
+ let keywords = Hashtbl.find !owned_keywords rule_id in
List.iter CicNotationLexer.remove_level2_ast_keyword keywords
with Not_found -> assert false);
- Grammar.delete_rule term atoms
+ Grammar.delete_rule !grammars.term atoms
(** {2 Grammar} *)
-let parse_level1_pattern_ref = ref (fun _ -> assert false)
+let parse_level1_pattern_ref = ref (fun _ _ -> assert false)
let parse_level2_ast_ref = ref (fun _ -> assert false)
let parse_level2_meta_ref = ref (fun _ -> assert false)
pt_names body
let return_term loc term = Ast.AttributedTerm (`Loc loc, term)
+let return_term_of_level loc term l =
+ Ast.AttributedTerm (`Loc loc, term l)
(* create empty precedence level for "term" *)
-let _ =
+let initialize_grammars () =
let dummy_action =
Gramext.action (fun _ ->
failwith "internal error, lexer generated a dummy token")
| i when i < first -> acc
| i ->
aux
- ((Some (string_of_int i ^ "N"), Some Gramext.NonA, dummy_prod)
- :: (Some (string_of_int i ^ "L"), Some Gramext.LeftA, dummy_prod)
- :: (Some (string_of_int i ^ "R"), Some Gramext.RightA, dummy_prod)
+ ((Some (level_of i), Some Gramext.NonA, dummy_prod)
:: acc)
(i - 1)
in
aux [] last
in
Grammar.extend
- [ Grammar.Entry.obj (term: 'a Grammar.Entry.e),
+ [ Grammar.Entry.obj (!grammars.term: 'a Grammar.Entry.e),
None,
- mk_level_list min_precedence max_precedence ]
-
+ mk_level_list min_precedence max_precedence ];
(* {{{ Grammar for concrete syntax patterns, notation level 1 *)
+ begin
+ let level1_pattern = !grammars.level1_pattern in
EXTEND
GLOBAL: level1_pattern;
- level1_pattern: [ [ p = l1_pattern; EOI -> CicNotationUtil.boxify p ] ];
- l1_pattern: [ [ p = LIST1 l1_simple_pattern -> p ] ];
+ level1_pattern: [
+ [ p = l1_pattern; EOI -> fun l -> CicNotationUtil.boxify (p l) ]
+ ];
+ l1_pattern: [
+ [ p = LIST1 l1_simple_pattern ->
+ fun l -> List.map (fun x -> x l) p ]
+ ];
literal: [
[ s = SYMBOL -> `Symbol s
| k = QKEYWORD -> `Keyword k
]
];
sep: [ [ "sep"; sep = literal -> sep ] ];
-(* row_sep: [ [ "rowsep"; sep = literal -> sep ] ];
- field_sep: [ [ "fieldsep"; sep = literal -> sep ] ]; *)
l1_magic_pattern: [
- [ "list0"; p = l1_simple_pattern; sep = OPT sep -> Ast.List0 (p, sep)
- | "list1"; p = l1_simple_pattern; sep = OPT sep -> Ast.List1 (p, sep)
- | "opt"; p = l1_simple_pattern -> Ast.Opt p
+ [ "list0"; p = l1_simple_pattern; sep = OPT sep ->
+ fun l -> Ast.List0 (p l, sep)
+ | "list1"; p = l1_simple_pattern; sep = OPT sep ->
+ fun l -> Ast.List1 (p l, sep)
+ | "opt"; p = l1_simple_pattern -> fun l -> Ast.Opt (p l)
]
];
l1_pattern_variable: [
- [ "term"; id = IDENT -> Ast.TermVar id
+ [ "term"; precedence = NUMBER; id = IDENT ->
+ Ast.TermVar (id, Ast.Level (int_of_string precedence))
| "number"; id = IDENT -> Ast.NumVar id
| "ident"; id = IDENT -> Ast.IdentVar id
]
];
+ mstyle: [
+ [ id = IDENT;
+ v = [ IDENT | NUMBER | COLOR | FLOATWITHUNIT ] -> id, v]];
+ mpadded: [
+ [ id = IDENT;
+ v = [ PERCENTAGE ] -> id, v]];
l1_simple_pattern:
[ "layout" LEFTA
- [ p1 = SELF; SYMBOL "\\sub"; p2 = SELF ->
- return_term loc (Ast.Layout (Ast.Sub (p1, p2)))
- | p1 = SELF; SYMBOL "\\sup"; p2 = SELF ->
- return_term loc (Ast.Layout (Ast.Sup (p1, p2)))
- | p1 = SELF; SYMBOL "\\below"; p2 = SELF ->
- return_term loc (Ast.Layout (Ast.Below (p1, p2)))
- | p1 = SELF; SYMBOL "\\above"; p2 = SELF ->
- return_term loc (Ast.Layout (Ast.Above (p1, p2)))
- | p1 = SELF; SYMBOL "\\over"; p2 = SELF ->
- return_term loc (Ast.Layout (Ast.Over (p1, p2)))
- | p1 = SELF; SYMBOL "\\atop"; p2 = SELF ->
- return_term loc (Ast.Layout (Ast.Atop (p1, p2)))
-(* | "array"; p = SELF; csep = OPT field_sep; rsep = OPT row_sep ->
- return_term loc (Array (p, csep, rsep)) *)
- | SYMBOL "\\frac"; p1 = SELF; p2 = SELF ->
- return_term loc (Ast.Layout (Ast.Frac (p1, p2)))
- | SYMBOL "\\sqrt"; p = SELF -> return_term loc (Ast.Layout (Ast.Sqrt p))
- | SYMBOL "\\root"; index = SELF; SYMBOL "\\of"; arg = SELF ->
- return_term loc (Ast.Layout (Ast.Root (arg, index)))
+ [ p1 = SELF; SYMBOL "\\sub "; p2 = SELF ->
+ return_term_of_level loc
+ (fun l -> Ast.Layout (Ast.Sub (p1 l, p2 l)))
+ | p1 = SELF; SYMBOL "\\sup "; p2 = SELF ->
+ return_term_of_level loc
+ (fun l -> Ast.Layout (Ast.Sup (p1 l, p2 l)))
+ | p1 = SELF; SYMBOL "\\below "; p2 = SELF ->
+ return_term_of_level loc
+ (fun l -> Ast.Layout (Ast.Below (p1 l, p2 l)))
+ | p1 = SELF; SYMBOL "\\above "; p2 = SELF ->
+ return_term_of_level loc
+ (fun l -> Ast.Layout (Ast.Above (p1 l, p2 l)))
+ | p1 = SELF; SYMBOL "\\over "; p2 = SELF ->
+ return_term_of_level loc
+ (fun l -> Ast.Layout (Ast.Over (p1 l, p2 l)))
+ | p1 = SELF; SYMBOL "\\atop "; p2 = SELF ->
+ return_term_of_level loc
+ (fun l -> Ast.Layout (Ast.Atop (p1 l, p2 l)))
+ | p1 = SELF; SYMBOL "\\frac "; p2 = SELF ->
+ return_term_of_level loc
+ (fun l -> Ast.Layout (Ast.Frac (p1 l, p2 l)))
+ | SYMBOL "\\infrule "; p1 = SELF; p2 = SELF; p3 = SELF ->
+ return_term_of_level loc
+ (fun l -> Ast.Layout (Ast.InfRule (p1 l, p2 l, p3 l)))
+ | SYMBOL "\\sqrt "; p = SELF ->
+ return_term_of_level loc (fun l -> Ast.Layout (Ast.Sqrt p l))
+ | SYMBOL "\\root "; index = SELF; SYMBOL "\\of "; arg = SELF ->
+ return_term_of_level loc
+ (fun l -> Ast.Layout (Ast.Root (arg l, index l)))
| "hbox"; LPAREN; p = l1_pattern; RPAREN ->
- return_term loc (Ast.Layout (Ast.Box ((Ast.H, false, false), p)))
+ return_term_of_level loc
+ (fun l -> Ast.Layout (Ast.Box ((Ast.H, false, false), p l)))
| "vbox"; LPAREN; p = l1_pattern; RPAREN ->
- return_term loc (Ast.Layout (Ast.Box ((Ast.V, false, false), p)))
+ return_term_of_level loc
+ (fun l -> Ast.Layout (Ast.Box ((Ast.V, false, false), p l)))
| "hvbox"; LPAREN; p = l1_pattern; RPAREN ->
- return_term loc (Ast.Layout (Ast.Box ((Ast.HV, false, false), p)))
+ return_term_of_level loc
+ (fun l -> Ast.Layout (Ast.Box ((Ast.HV, false, false), p l)))
| "hovbox"; LPAREN; p = l1_pattern; RPAREN ->
- return_term loc (Ast.Layout (Ast.Box ((Ast.HOV, false, false), p)))
- | "break" -> return_term loc (Ast.Layout Ast.Break)
-(* | SYMBOL "\\SPACE" -> return_term loc (Layout Space) *)
+ return_term_of_level loc
+ (fun l -> Ast.Layout (Ast.Box ((Ast.HOV, false, false), p l)))
+ | "break" -> return_term_of_level loc (fun _ -> Ast.Layout Ast.Break)
+ | "mstyle"; m = LIST1 mstyle ; LPAREN; t = l1_pattern; RPAREN ->
+ return_term_of_level loc
+ (fun l ->
+ Ast.Layout (Ast.Mstyle (m, t l)))
+ | "mpadded"; m = LIST1 mpadded ; LPAREN; t = l1_pattern; RPAREN ->
+ return_term_of_level loc
+ (fun l ->
+ Ast.Layout (Ast.Mpadded (m, t l)))
+ | "maction"; m = LIST1 [ LPAREN; l = l1_pattern; RPAREN -> l ] ->
+ return_term_of_level loc
+ (fun l -> Ast.Layout (Ast.Maction (List.map (fun x ->
+ CicNotationUtil.group (x l)) m)))
| LPAREN; p = l1_pattern; RPAREN ->
- return_term loc (CicNotationUtil.group p)
+ return_term_of_level loc (fun l -> CicNotationUtil.group (p l))
]
| "simple" NONA
- [ i = IDENT -> return_term loc (Ast.Variable (Ast.TermVar i))
- | m = l1_magic_pattern -> return_term loc (Ast.Magic m)
- | v = l1_pattern_variable -> return_term loc (Ast.Variable v)
- | l = literal -> return_term loc (Ast.Literal l)
+ [ i = IDENT ->
+ return_term_of_level loc
+ (fun l -> Ast.Variable (Ast.TermVar (i,Ast.Self l)))
+ | m = l1_magic_pattern ->
+ return_term_of_level loc (fun l -> Ast.Magic (m l))
+ | v = l1_pattern_variable ->
+ return_term_of_level loc (fun _ -> Ast.Variable v)
+ | l = literal -> return_term_of_level loc (fun _ -> Ast.Literal l)
]
];
END
+ end;
(* }}} *)
-
(* {{{ Grammar for ast magics, notation level 2 *)
+ begin
+ let level2_meta = !grammars.level2_meta in
EXTEND
GLOBAL: level2_meta;
l2_variable: [
- [ "term"; id = IDENT -> Ast.TermVar id
+ [ "term"; precedence = NUMBER; id = IDENT ->
+ Ast.TermVar (id,Ast.Level (int_of_string precedence))
| "number"; id = IDENT -> Ast.NumVar id
| "ident"; id = IDENT -> Ast.IdentVar id
| "fresh"; id = IDENT -> Ast.FreshVar id
- | "anonymous" -> Ast.TermVar "_"
- | id = IDENT -> Ast.TermVar id
+ | "anonymous" -> Ast.TermVar ("_",Ast.Self 0) (* is the level relevant?*)
+ | id = IDENT -> Ast.TermVar (id,Ast.Self 0)
]
];
l2_magic: [
]
];
END
+ end;
(* }}} *)
-
(* {{{ Grammar for ast patterns, notation level 2 *)
+ begin
+ let level2_ast = !grammars.level2_ast in
+ let term = !grammars.term in
+ let let_defs = !grammars.let_defs in
+ let protected_binder_vars = !grammars.protected_binder_vars in
EXTEND
GLOBAL: level2_ast term let_defs protected_binder_vars;
level2_ast: [ [ p = term -> p ] ];
sort: [
[ "Prop" -> `Prop
| "Set" -> `Set
+ | "Type"; SYMBOL "["; n = [ NUMBER| IDENT ]; SYMBOL "]" -> `NType n
| "Type" -> `Type (CicUniv.fresh ())
- | "CProp" -> `CProp
+ | "CProp"; SYMBOL "["; n = [ NUMBER| IDENT ]; SYMBOL "]" -> `NCProp n
+ | "CProp" -> `CProp (CicUniv.fresh ())
]
];
explicit_subst: [
- [ SYMBOL "\\subst"; (* to avoid catching frequent "a [1]" cases *)
+ [ SYMBOL "\\subst "; (* to avoid catching frequent "a [1]" cases *)
SYMBOL "[";
substs = LIST1 [
i = IDENT; SYMBOL <:unicode<Assign>> (* ≔ *); t = term -> (i, t)
[ LPAREN; id = single_arg; SYMBOL ":"; typ = term; RPAREN ->
id, Some typ
| arg = single_arg -> arg, None
+ | id = PIDENT -> Ast.Ident (id, None), None
| SYMBOL "_" -> Ast.Ident ("_", None), None
+ | LPAREN; id = PIDENT; SYMBOL ":"; typ = term; RPAREN ->
+ Ast.Ident (id, None), Some typ
+ | LPAREN; SYMBOL "_"; SYMBOL ":"; typ = term; RPAREN ->
+ Ast.Ident ("_", None), Some typ
]
];
match_pattern: [
- [ id = IDENT -> id, None, []
+ [ SYMBOL "_" -> Ast.Wildcard
+ | id = IDENT -> Ast.Pattern (id, None, [])
| LPAREN; id = IDENT; vars = LIST1 possibly_typed_name; RPAREN ->
- id, None, vars
- | id = IDENT; vars = LIST1 possibly_typed_name -> id, None, vars
+ Ast.Pattern (id, None, vars)
+ | id = IDENT; vars = LIST1 possibly_typed_name ->
+ Ast.Pattern (id, None, vars)
]
];
binder: [
[ SYMBOL <:unicode<Pi>> (* Π *) -> `Pi
-(* | SYMBOL <:unicode<exists>> |+ ∃ +| -> `Exists *)
| SYMBOL <:unicode<forall>> (* ∀ *) -> `Forall
| SYMBOL <:unicode<lambda>> (* λ *) -> `Lambda
]
let meta = !parse_level2_meta_ref (Ulexing.from_utf8_string blob) in
match meta with
| Ast.Variable (Ast.FreshVar _) -> [meta], None
- | Ast.Variable (Ast.TermVar "_") -> [Ast.Ident ("_", None)], None
+ | Ast.Variable (Ast.TermVar ("_",_)) -> [Ast.Ident ("_", None)], None
| _ -> failwith "Invalid bound name."
]
];
match meta with
| Ast.Variable (Ast.FreshVar _)
| Ast.Variable (Ast.IdentVar _) -> meta
- | Ast.Variable (Ast.TermVar "_") -> Ast.Ident ("_", None)
+ | Ast.Variable (Ast.TermVar ("_",_)) -> Ast.Ident ("_", None)
| _ -> failwith "Invalid index name."
]
];
- induction_kind: [
- [ "rec" -> `Inductive
- | "corec" -> `CoInductive
- ]
- ];
let_defs: [
[ defs = LIST1 [
name = single_arg;
]
];
binder_vars: [
- [ vars = [
- l = LIST1 single_arg SEP SYMBOL "," -> l
- | SYMBOL "_" -> [Ast.Ident ("_", None)] ];
+ [ vars = [ l =
+ [ l = LIST1 single_arg SEP SYMBOL "," -> l
+ | l = LIST1 [ PIDENT | SYMBOL "_" ] SEP SYMBOL "," ->
+ List.map (fun x -> Ast.Ident(x,None)) l
+ ] -> l ];
typ = OPT [ SYMBOL ":"; t = term -> t ] -> (vars, typ)
]
];
| vars = protected_binder_vars -> vars
]
];
- term: LEVEL "10N" [ (* let in *)
- [ "let"; var = possibly_typed_name; SYMBOL <:unicode<def>> (* ≝ *);
+ term: LEVEL "10"
+ [
+ [ "let";
+ var =
+ [ LPAREN; id = single_arg; SYMBOL ":"; typ = term; RPAREN ->
+ id, Some typ
+ | id = IDENT; ty = OPT [ SYMBOL ":"; typ = term -> typ] ->
+ Ast.Ident(id,None), ty ];
+ SYMBOL <:unicode<def>> (* ≝ *);
p1 = term; "in"; p2 = term ->
return_term loc (Ast.LetIn (var, p1, p2))
- | "let"; k = induction_kind; defs = let_defs; "in";
+ | LETCOREC; defs = let_defs; "in";
body = term ->
- return_term loc (Ast.LetRec (k, defs, body))
+ return_term loc (Ast.LetRec (`CoInductive, defs, body))
+ | LETREC; defs = let_defs; "in";
+ body = term ->
+ return_term loc (Ast.LetRec (`Inductive, defs, body))
]
];
- term: LEVEL "20R" (* binder *)
+ term: LEVEL "20"
[
- [ b = binder; (vars, typ) = maybe_protected_binder_vars; SYMBOL "."; body = term ->
+ [ b = binder; (vars, typ) = maybe_protected_binder_vars; SYMBOL "."; body = term LEVEL "19" ->
return_term loc (fold_cluster b vars typ body)
- | SYMBOL <:unicode<exists>> (* ∃ *);
- (vars, typ) = maybe_protected_binder_vars; SYMBOL "."; body = term ->
- return_term loc (fold_exists vars typ body)
]
];
- term: LEVEL "70L" (* apply *)
+ term: LEVEL "70"
[
- [ p1 = term; p2 = term ->
+ [ p1 = term; p2 = term LEVEL "71" ->
let rec aux = function
| Ast.Appl (hd :: tl)
| Ast.AttributedTerm (_, Ast.Appl (hd :: tl)) ->
return_term loc (Ast.Appl (aux p1 @ [p2]))
]
];
- term: LEVEL "90N" (* simple *)
+ term: LEVEL "90"
[
[ id = IDENT -> return_term loc (Ast.Ident (id, None))
| id = IDENT; s = explicit_subst ->
return_term loc (Ast.Ident (id, Some s))
| s = CSYMBOL -> return_term loc (Ast.Symbol (s, 0))
| u = URI -> return_term loc (Ast.Uri (u, None))
+ | r = NREF -> return_term loc (Ast.NRef (NReference.reference_of_string r))
| n = NUMBER -> return_term loc (Ast.Num (n, 0))
- | IMPLICIT -> return_term loc (Ast.Implicit)
+ | IMPLICIT -> return_term loc (Ast.Implicit `JustOne)
+ | SYMBOL <:unicode<ldots>> -> return_term loc (Ast.Implicit `Vector)
| PLACEHOLDER -> return_term loc Ast.UserInput
| m = META -> return_term loc (Ast.Meta (int_of_string m, []))
| m = META; s = meta_substs ->
]
];
END
+ end
(* }}} *)
+;;
+
+let _ = initialize_grammars ();;
+
+let history = ref [];;
+
+let push () =
+ CicNotationLexer.push ();
+ history := (!owned_keywords,!grammars) :: !history;
+ owned_keywords := (initial_owned_keywords ());
+ grammars := initial_grammars ();
+ initialize_grammars ()
+;;
+
+let pop () =
+ CicNotationLexer.pop ();
+ match !history with
+ | [] -> assert false
+ | (kw,gram) :: old_history ->
+ owned_keywords := kw;
+ grammars := gram;
+ history := old_history
+;;
(** {2 API implementation} *)
try
f ()
with
- | Stdpp.Exc_located (floc, Stream.Error msg) ->
+ | Ploc.Exc (floc, Stream.Error msg) ->
raise (HExtlib.Localized (floc, Parse_error msg))
- | Stdpp.Exc_located (floc, exn) ->
+ | Ploc.Exc (floc, HExtlib.Localized (_,exn)) ->
+ raise (HExtlib.Localized (floc, (Parse_error (Printexc.to_string exn))))
+ | Ploc.Exc (floc, exn) ->
raise (HExtlib.Localized (floc, (Parse_error (Printexc.to_string exn))))
-let parse_level1_pattern lexbuf =
+let parse_level1_pattern precedence lexbuf =
exc_located_wrapper
- (fun () -> Grammar.Entry.parse level1_pattern (Obj.magic lexbuf))
+ (fun () -> Grammar.Entry.parse !grammars.level1_pattern (Obj.magic lexbuf) precedence)
let parse_level2_ast lexbuf =
exc_located_wrapper
- (fun () -> Grammar.Entry.parse level2_ast (Obj.magic lexbuf))
+ (fun () -> Grammar.Entry.parse !grammars.level2_ast (Obj.magic lexbuf))
let parse_level2_meta lexbuf =
exc_located_wrapper
- (fun () -> Grammar.Entry.parse level2_meta (Obj.magic lexbuf))
+ (fun () -> Grammar.Entry.parse !grammars.level2_meta (Obj.magic lexbuf))
let _ =
parse_level1_pattern_ref := parse_level1_pattern;
let parse_term lexbuf =
exc_located_wrapper
- (fun () -> (Grammar.Entry.parse term (Obj.magic lexbuf)))
+ (fun () -> (Grammar.Entry.parse !grammars.term (Obj.magic lexbuf)))
+
+let level2_ast_grammar () = !grammars.level2_ast_grammar
+let term () = !grammars.term
+let let_defs () = !grammars.let_defs
+let protected_binder_vars () = !grammars.protected_binder_vars
+
(** {2 Debugging} *)
let print_l2_pattern () =
- Grammar.print_entry Format.std_formatter (Grammar.Entry.obj term);
+ Grammar.print_entry Format.std_formatter (Grammar.Entry.obj !grammars.term);
Format.pp_print_flush Format.std_formatter ();
- flush stdout
+ flush stdout
(* vim:set encoding=utf8 foldmethod=marker: *)