/***********************************************************************/ /* */ /* Objective Caml */ /* */ /* Xavier Leroy, projet Cristal, INRIA Rocquencourt */ /* */ /* Copyright 1996 Institut National de Recherche en Informatique et */ /* Automatique. Distributed only by permission. */ /* */ /***********************************************************************/ /* $Id$ */ /* The parser definition */ %{ open Location open Asttypes open Longident open Parsetree let mktyp d = { ptyp_desc = d; ptyp_loc = symbol_loc() } let mkpat d = { ppat_desc = d; ppat_loc = symbol_loc() } let mkexp d = { pexp_desc = d; pexp_loc = symbol_loc() } let mkmty d = { pmty_desc = d; pmty_loc = symbol_loc() } let mksig d = { psig_desc = d; psig_loc = symbol_loc() } let mkmod d = { pmod_desc = d; pmod_loc = symbol_loc() } let mkstr d = { pstr_desc = d; pstr_loc = symbol_loc() } let mkfield d = { pfield_desc = d; pfield_loc = symbol_loc() } let mkclass d = { pcl_desc = d; pcl_loc = symbol_loc() } let mkcty d = { pcty_desc = d; pcty_loc = symbol_loc() } let mkoperator name pos = { pexp_desc = Pexp_ident(Lident name); pexp_loc = rhs_loc pos } (* Ghost expressions and patterns: expressions and patterns added by the parser; their location is an empty range of characters. The profiler doesn't instrument such expressions. *) let ghexp d point = { pexp_desc = d; pexp_loc = {loc_start = point; loc_end = point} } ;; let ghpat d point = { ppat_desc = d; ppat_loc = {loc_start = point; loc_end = point} } ;; let mkassert e = let {loc_start = st; loc_end = en} = symbol_loc () in let triple = ghexp (Pexp_tuple [ghexp (Pexp_constant (Const_string !input_name)) en; ghexp (Pexp_constant (Const_int st)) en; ghexp (Pexp_constant (Const_int en)) en]) en in let ex = Ldot (Lident "Pervasives", "Assert_failure") in let bucket = ghexp (Pexp_construct (ex, Some triple, false)) en in let ra = Ldot (Lident "Pervasives", "raise") in let raiser = ghexp (Pexp_apply (ghexp (Pexp_ident ra) en, [bucket])) en in let un = ghexp (Pexp_construct (Lident "()", None, false)) en in match e with | {pexp_desc = Pexp_construct (Lident "false", None, false) } -> raiser | _ -> if !Clflags.noassert then mkexp (Pexp_construct (Lident "()", None, false)) else mkexp (Pexp_ifthenelse (e, un, Some raiser)) ;; let mklazy e = let {loc_start = st} = symbol_loc () in let void_pat = ghpat (Ppat_construct (Lident "()", None, false)) st in let f = mkexp (Pexp_function ([void_pat, e])) in let delayed = Ldot (Lident "Lazy", "Delayed") in let df = mkexp (Pexp_construct (delayed, Some f, false)) in let r = ghexp (Pexp_ident (Ldot (Lident "Pervasives", "ref"))) st in mkexp (Pexp_apply (r, [df])) ;; let mkinfix arg1 name arg2 = mkexp(Pexp_apply(mkoperator name 2, [arg1; arg2])) let mkuminus name arg = match arg.pexp_desc with Pexp_constant(Const_int n) -> mkexp(Pexp_constant(Const_int(-n))) | Pexp_constant(Const_float f) -> mkexp(Pexp_constant(Const_float("-" ^ f))) | _ -> mkexp(Pexp_apply(mkoperator ("~" ^ name) 1, [arg])) let rec mktailexp point = function [] -> ghexp(Pexp_construct(Lident "[]", None, false)) point | e1 :: el -> let exp_el = mktailexp point el in let l = {loc_start = e1.pexp_loc.loc_start; loc_end = exp_el.pexp_loc.loc_end} in let arg = {pexp_desc = Pexp_tuple [e1; exp_el]; pexp_loc = l} in {pexp_desc = Pexp_construct(Lident "::", Some arg, false); pexp_loc = l} let rec mktailpat point = function [] -> ghpat(Ppat_construct(Lident "[]", None, false)) point | p1 :: pl -> let pat_pl = mktailpat point pl in let l = {loc_start = p1.ppat_loc.loc_start; loc_end = pat_pl.ppat_loc.loc_end} in let arg = {ppat_desc = Ppat_tuple [p1; pat_pl]; ppat_loc = l} in {ppat_desc = Ppat_construct(Lident "::", Some arg, false); ppat_loc = l} let mkstrexp e = { pstr_desc = Pstr_eval e; pstr_loc = e.pexp_loc } let array_function str name = Ldot(Lident str, (if !Clflags.fast then "unsafe_" ^ name else name)) let rec mkrangepat c1 c2 = if c1 > c2 then mkrangepat c2 c1 else if c1 = c2 then mkpat(Ppat_constant(Const_char c1)) else mkpat(Ppat_or(mkpat(Ppat_constant(Const_char c1)), mkrangepat (Char.chr(Char.code c1 + 1)) c2)) let syntax_error () = raise Syntaxerr.Escape_error let unclosed opening_name opening_num closing_name closing_num = raise(Syntaxerr.Error(Syntaxerr.Unclosed(rhs_loc opening_num, opening_name, rhs_loc closing_num, closing_name))) %} /* Tokens */ %token AMPERAMPER %token AMPERSAND %token AND %token AS %token ASSERT %token BAR %token BARBAR %token BARRBRACKET %token BEGIN %token CHAR %token CLASS %token COLON %token COLONCOLON %token COLONEQUAL %token COLONGREATER %token COMMA %token CONSTRAINT %token DO %token DONE %token DOT %token DOTDOT %token DOWNTO %token ELSE %token END %token EOF %token EQUAL %token EXCEPTION %token EXTERNAL %token FALSE %token FLOAT %token FOR %token FUN %token FUNCTION %token FUNCTOR %token GREATER %token GREATERRBRACE %token GREATERRBRACKET %token IF %token IN %token INCLUDE %token INFIXOP0 %token INFIXOP1 %token INFIXOP2 %token INFIXOP3 %token INFIXOP4 %token INHERIT %token INITIALIZER %token INT %token LAZY %token LBRACE %token LBRACELESS %token LBRACKET %token LBRACKETBAR %token LBRACKETLESS %token LESS %token LESSMINUS %token LET %token LIDENT %token LPAREN %token MATCH %token METHOD %token MINUSGREATER %token MODULE %token MUTABLE %token NEW %token OBJECT %token OF %token OPEN %token OR %token PARSER %token PREFIXOP %token PRIVATE %token QUESTION %token QUOTE %token RBRACE %token RBRACKET %token REC %token RPAREN %token SEMI %token SEMISEMI %token SHARP %token SIG %token STAR %token STRING %token STRUCT %token SUBTRACTIVE %token THEN %token TO %token TRUE %token TRY %token TYPE %token UIDENT %token UNDERSCORE %token VAL %token VIRTUAL %token WHEN %token WHILE %token WITH /* Precedences and associativities. Lower precedences come first. */ %right prec_let /* let ... in ... */ %right prec_type_def /* = in type definitions */ %right SEMI /* e1; e2 (sequence) */ %right prec_fun prec_match prec_try /* match ... with ... */ %right prec_list /* e1; e2 (list, array, record) */ %right prec_if /* if ... then ... else ... */ %right COLONEQUAL LESSMINUS /* assignments */ %left AS /* as in patterns */ %left BAR /* | in patterns */ %left COMMA /* , in expressions, patterns, types */ %right prec_type_arrow /* -> in type expressions */ %right OR BARBAR /* or */ %right AMPERSAND AMPERAMPER /* & */ %left INFIXOP0 EQUAL LESS GREATER /* = < > etc */ %right INFIXOP1 /* @ ^ etc */ %right COLONCOLON /* :: */ %left INFIXOP2 SUBTRACTIVE /* + - */ %left INFIXOP3 STAR /* * / */ %right INFIXOP4 /* ** */ %right prec_unary_minus /* - unary */ %left prec_appl /* function application */ %right prec_constr_appl /* constructor application */ %left SHARP /* method call */ %left DOT /* record access, array access */ %right PREFIXOP /* ! */ /* Entry points */ %start implementation /* for implementation files */ %type implementation %start interface /* for interface files */ %type interface %start toplevel_phrase /* for interactive use */ %type toplevel_phrase %start use_file /* for the #use directive */ %type use_file %% /* Entry points */ implementation: structure EOF { $1 } ; interface: signature EOF { List.rev $1 } ; toplevel_phrase: top_structure SEMISEMI { Ptop_def $1 } | seq_expr SEMISEMI { Ptop_def[mkstrexp $1] } | toplevel_directive SEMISEMI { $1 } | EOF { raise End_of_file } ; top_structure: structure_item { [$1] } | structure_item top_structure { $1 :: $2 } ; use_file: use_file_tail { $1 } | seq_expr use_file_tail { Ptop_def[mkstrexp $1] :: $2 } ; use_file_tail: EOF { [] } | SEMISEMI EOF { [] } | SEMISEMI seq_expr use_file_tail { Ptop_def[mkstrexp $2] :: $3 } | SEMISEMI structure_item use_file_tail { Ptop_def[$2] :: $3 } | SEMISEMI toplevel_directive use_file_tail { $2 :: $3 } | structure_item use_file_tail { Ptop_def[$1] :: $2 } | toplevel_directive use_file_tail { $1 :: $2 } ; /* Module expressions */ module_expr: mod_longident { mkmod(Pmod_ident $1) } | STRUCT structure END { mkmod(Pmod_structure($2)) } | STRUCT structure error { unclosed "struct" 1 "end" 3 } | FUNCTOR LPAREN UIDENT COLON module_type RPAREN MINUSGREATER module_expr %prec prec_fun { mkmod(Pmod_functor($3, $5, $8)) } | module_expr LPAREN module_expr RPAREN { mkmod(Pmod_apply($1, $3)) } | module_expr LPAREN module_expr error { unclosed "(" 2 ")" 4 } | LPAREN module_expr COLON module_type RPAREN { mkmod(Pmod_constraint($2, $4)) } | LPAREN module_expr COLON module_type error { unclosed "(" 1 ")" 5 } | LPAREN module_expr RPAREN { $2 } | LPAREN module_expr error { unclosed "(" 1 ")" 3 } ; structure: structure_tail { $1 } | seq_expr structure_tail { mkstrexp $1 :: $2 } ; structure_tail: /* empty */ { [] } | SEMISEMI { [] } | SEMISEMI seq_expr structure_tail { mkstrexp $2 :: $3 } | SEMISEMI structure_item structure_tail { $2 :: $3 } | structure_item structure_tail { $1 :: $2 } ; structure_item: LET rec_flag let_bindings { match $3 with [{ppat_desc = Ppat_any}, exp] -> mkstr(Pstr_eval exp) | _ -> mkstr(Pstr_value($2, List.rev $3)) } | EXTERNAL val_ident COLON core_type EQUAL primitive_declaration { mkstr(Pstr_primitive($2, {pval_type = $4; pval_prim = $6})) } | TYPE type_declarations { mkstr(Pstr_type(List.rev $2)) } | EXCEPTION UIDENT constructor_arguments { mkstr(Pstr_exception($2, $3)) } | MODULE UIDENT module_binding { mkstr(Pstr_module($2, $3)) } | MODULE TYPE ident EQUAL module_type { mkstr(Pstr_modtype($3, $5)) } | OPEN mod_longident { mkstr(Pstr_open $2) } | CLASS class_declarations { mkstr(Pstr_class (List.rev $2)) } | CLASS TYPE class_type_declarations { mkstr(Pstr_class_type (List.rev $3)) } ; module_binding: EQUAL module_expr { $2 } | COLON module_type EQUAL module_expr { mkmod(Pmod_constraint($4, $2)) } | LPAREN UIDENT COLON module_type RPAREN module_binding { mkmod(Pmod_functor($2, $4, $6)) } ; /* Module types */ module_type: mty_longident { mkmty(Pmty_ident $1) } | SIG signature END { mkmty(Pmty_signature(List.rev $2)) } | SIG signature error { unclosed "sig" 1 "end" 3 } | FUNCTOR LPAREN UIDENT COLON module_type RPAREN MINUSGREATER module_type %prec prec_fun { mkmty(Pmty_functor($3, $5, $8)) } | module_type WITH with_constraints { mkmty(Pmty_with($1, List.rev $3)) } | LPAREN module_type RPAREN { $2 } | LPAREN module_type error { unclosed "(" 1 ")" 3 } ; signature: /* empty */ { [] } | signature signature_item { $2 :: $1 } | signature signature_item SEMISEMI { $2 :: $1 } ; signature_item: VAL val_ident COLON core_type { mksig(Psig_value($2, {pval_type = $4; pval_prim = []})) } | EXTERNAL val_ident COLON core_type EQUAL primitive_declaration { mksig(Psig_value($2, {pval_type = $4; pval_prim = $6})) } | TYPE type_declarations { mksig(Psig_type(List.rev $2)) } | EXCEPTION UIDENT constructor_arguments { mksig(Psig_exception($2, $3)) } | MODULE UIDENT module_declaration { mksig(Psig_module($2, $3)) } | MODULE TYPE ident { mksig(Psig_modtype($3, Pmodtype_abstract)) } | MODULE TYPE ident EQUAL module_type { mksig(Psig_modtype($3, Pmodtype_manifest $5)) } | OPEN mod_longident { mksig(Psig_open $2) } | INCLUDE module_type { mksig(Psig_include $2) } | CLASS class_descriptions { mksig(Psig_class (List.rev $2)) } | CLASS TYPE class_type_declarations { mksig(Psig_class_type (List.rev $3)) } ; module_declaration: COLON module_type { $2 } | LPAREN UIDENT COLON module_type RPAREN module_declaration { mkmty(Pmty_functor($2, $4, $6)) } ; /* Class expressions */ class_declarations: class_declarations AND class_declaration { $3 :: $1 } | class_declaration { [$1] } ; class_declaration: virtual_flag class_type_parameters LIDENT class_fun_binding { {pci_virt = $1; pci_params = $2; pci_name = $3; pci_expr = $4; pci_loc = symbol_loc ()} } ; class_fun_binding: EQUAL class_expr { $2 } /* | COLON class_type EQUAL class_expr { mkclass(Pcl_constraint($4, $2)) } */ | simple_pattern class_fun_binding { mkclass(Pcl_fun($1, $2)) } ; class_type_parameters: /*empty*/ { [], symbol_loc () } | LBRACKET type_parameter_list RBRACKET { List.rev $2, symbol_loc () } ; class_fun_def: simple_pattern MINUSGREATER class_expr { mkclass(Pcl_fun($1, $3)) } | simple_pattern class_fun_def { mkclass(Pcl_fun($1, $2)) } ; class_expr: class_simple_expr { $1 } | FUN class_fun_def { $2 } | class_simple_expr simple_expr_list { mkclass(Pcl_apply($1, List.rev $2)) } | LET rec_flag let_bindings IN class_expr { mkclass(Pcl_let ($2, List.rev $3, $5)) } ; class_simple_expr: LBRACKET core_type_comma_list RBRACKET class_longident { mkclass(Pcl_constr($4, List.rev $2)) } | LBRACKET core_type RBRACKET class_longident { mkclass(Pcl_constr($4, [$2])) } | class_longident { mkclass(Pcl_constr($1, [])) } | OBJECT class_structure END { mkclass(Pcl_structure($2)) } | OBJECT class_structure error { unclosed "class" 1 "end" 3 } /* | LPAREN class_expr COLON class_type RPAREN { mkclass(Pcl_constraint($2, $4)) } | LPAREN class_expr COLON class_type error { unclosed "(" 1 ")" 5 } */ | LPAREN class_expr RPAREN { $2 } | LPAREN class_expr error { unclosed "(" 1 ")" 3 } ; class_structure: class_self_pattern class_fields { $1, List.rev $2 } ; class_self_pattern: LPAREN pattern RPAREN { mkpat(Ppat_alias($2, "*self_pat*")) } | LPAREN pattern COLON core_type RPAREN { mkpat(Ppat_alias(mkpat(Ppat_constraint($2, $4)), "*self_pat*")) } | /* empty */ { mkpat(Ppat_var "*self_pat*") } ; class_fields: /* empty */ { [] } | class_fields INHERIT class_expr parent_binder { Pcf_inher ($3, $4) :: $1 } | class_fields VAL value { Pcf_val $3 :: $1 } | class_fields virtual_method { Pcf_virt $2 :: $1 } | class_fields concrete_method { Pcf_meth $2 :: $1 } | class_fields CONSTRAINT constrain { Pcf_cstr $3 :: $1 } /* | class_fields LET rec_flag class_let_bindings IN { let (bindings, loc) = $4 in Pcf_let ($3, List.rev bindings, loc) :: $1 } */ | class_fields INITIALIZER seq_expr { Pcf_init (mkexp(Pexp_function[mkpat(Ppat_var "*self*"), $3])) :: $1 } ; /* class_let_bindings: let_bindings { $1, symbol_loc () } ; */ parent_binder: AS LIDENT { Some $2 } | /* empty */ {None} ; value: mutable_flag label EQUAL seq_expr { $2, $1, $4, symbol_loc () } | mutable_flag label type_constraint EQUAL seq_expr { $2, $1, (let (t, t') = $3 in mkexp(Pexp_constraint($5, t, t'))), symbol_loc () } ; virtual_method: METHOD PRIVATE VIRTUAL label COLON core_type { $4, Private, $6, symbol_loc () } | METHOD VIRTUAL private_flag label COLON core_type { $4, $3, $6, symbol_loc () } ; concrete_method : METHOD private_flag label fun_binding { $3, $2, mkexp(Pexp_function[mkpat(Ppat_var "*self*"), $4]), symbol_loc () } ; /* Class types */ class_type: class_signature { $1 } | simple_core_type MINUSGREATER class_type { mkcty(Pcty_fun($1, $3)) } | core_type_tuple MINUSGREATER class_type { mkcty(Pcty_fun(mktyp(Ptyp_tuple(List.rev $1)), $3)) } ; class_signature: LBRACKET core_type_comma_list RBRACKET clty_longident { mkcty(Pcty_constr ($4, $2)) } | LBRACKET core_type RBRACKET clty_longident { mkcty(Pcty_constr ($4, [$2])) } | clty_longident { mkcty(Pcty_constr ($1, [])) } | OBJECT class_sig_body END { mkcty(Pcty_signature $2) } | OBJECT class_sig_body error { unclosed "sig" 1 "end" 3 } ; class_sig_body: class_self_type class_sig_fields { $1, List.rev $2 } ; class_self_type: LPAREN core_type RPAREN { $2 } | /* empty */ { mktyp(Ptyp_any) } ; class_sig_fields: /* empty */ { [] } | class_sig_fields INHERIT class_signature { Pctf_inher $3 :: $1 } | class_sig_fields VAL value_type { Pctf_val $3 :: $1 } | class_sig_fields virtual_method { Pctf_virt $2 :: $1 } | class_sig_fields method_type { Pctf_meth $2 :: $1 } | class_sig_fields CONSTRAINT constrain { Pctf_cstr $3 :: $1 } ; value_type: mutable_flag label COLON core_type { $2, $1, Some $4, symbol_loc () } /* XXX Should be removed | mutable_flag label { $2, $1, None, symbol_loc () } */ ; method_type: METHOD private_flag label COLON core_type { $3, $2, $5, symbol_loc () } ; constrain: core_type EQUAL core_type { $1, $3, symbol_loc () } ; class_descriptions: class_descriptions AND class_description { $3 :: $1 } | class_description { [$1] } ; class_description: virtual_flag class_type_parameters LIDENT COLON class_type { {pci_virt = $1; pci_params = $2; pci_name = $3; pci_expr = $5; pci_loc = symbol_loc ()} } ; class_type_declarations: class_type_declarations AND class_type_declaration { $3 :: $1 } | class_type_declaration { [$1] } ; class_type_declaration: virtual_flag class_type_parameters LIDENT EQUAL class_signature { {pci_virt = $1; pci_params = $2; pci_name = $3; pci_expr = $5; pci_loc = symbol_loc ()} } ; /* Core expressions */ seq_expr: | expr { $1 } | expr SEMI { $1 } | expr SEMI seq_expr { mkexp(Pexp_sequence($1, $3)) } ; expr: simple_expr { $1 } | simple_expr simple_expr_list %prec prec_appl { mkexp(Pexp_apply($1, List.rev $2)) } | LET rec_flag let_bindings IN seq_expr %prec prec_let { mkexp(Pexp_let($2, List.rev $3, $5)) } | LET MODULE UIDENT module_binding IN seq_expr %prec prec_let { mkexp(Pexp_letmodule($3, $4, $6)) } | PARSER opt_pat opt_bar parser_cases %prec prec_fun { Pstream.cparser ($2, List.rev $4) } | FUNCTION opt_bar match_cases %prec prec_fun { mkexp(Pexp_function(List.rev $3)) } | FUN simple_pattern fun_def %prec prec_fun { mkexp(Pexp_function([$2, $3])) } | MATCH seq_expr WITH opt_bar match_cases %prec prec_match { mkexp(Pexp_match($2, List.rev $5)) } | MATCH seq_expr WITH PARSER opt_pat opt_bar parser_cases %prec prec_match { mkexp(Pexp_apply(Pstream.cparser ($5, List.rev $7), [$2])) } | TRY seq_expr WITH opt_bar match_cases %prec prec_try { mkexp(Pexp_try($2, List.rev $5)) } | TRY seq_expr WITH error %prec prec_try { syntax_error() } | expr_comma_list { mkexp(Pexp_tuple(List.rev $1)) } | constr_longident simple_expr %prec prec_constr_appl { mkexp(Pexp_construct($1, Some $2, false)) } | IF seq_expr THEN expr ELSE expr %prec prec_if { mkexp(Pexp_ifthenelse($2, $4, Some $6)) } | IF seq_expr THEN expr %prec prec_if { mkexp(Pexp_ifthenelse($2, $4, None)) } | WHILE seq_expr DO seq_expr DONE { mkexp(Pexp_while($2, $4)) } | FOR val_ident EQUAL seq_expr direction_flag seq_expr DO seq_expr DONE { mkexp(Pexp_for($2, $4, $6, $5, $8)) } | expr COLONCOLON expr { mkexp(Pexp_construct(Lident "::", Some(mkexp(Pexp_tuple[$1;$3])), false)) } | expr INFIXOP0 expr { mkinfix $1 $2 $3 } | expr INFIXOP1 expr { mkinfix $1 $2 $3 } | expr INFIXOP2 expr { mkinfix $1 $2 $3 } | expr INFIXOP3 expr { mkinfix $1 $2 $3 } | expr INFIXOP4 expr { mkinfix $1 $2 $3 } | expr SUBTRACTIVE expr { mkinfix $1 $2 $3 } | expr STAR expr { mkinfix $1 "*" $3 } | expr EQUAL expr { mkinfix $1 "=" $3 } | expr LESS expr { mkinfix $1 "<" $3 } | expr GREATER expr { mkinfix $1 ">" $3 } | expr OR expr { mkinfix $1 "or" $3 } | expr BARBAR expr { mkinfix $1 "||" $3 } | expr AMPERSAND expr { mkinfix $1 "&" $3 } | expr AMPERAMPER expr { mkinfix $1 "&&" $3 } | expr COLONEQUAL expr { mkinfix $1 ":=" $3 } | SUBTRACTIVE expr %prec prec_unary_minus { mkuminus $1 $2 } | simple_expr DOT label_longident LESSMINUS expr { mkexp(Pexp_setfield($1, $3, $5)) } | simple_expr DOT LPAREN seq_expr RPAREN LESSMINUS expr { mkexp(Pexp_apply(mkexp(Pexp_ident(array_function "Array" "set")), [$1; $4; $7])) } | simple_expr DOT LBRACKET seq_expr RBRACKET LESSMINUS expr { mkexp(Pexp_apply(mkexp(Pexp_ident(array_function "String" "set")), [$1; $4; $7])) } | label LESSMINUS expr { mkexp(Pexp_setinstvar($1, $3)) } /* | expr SHARP label { mkexp(Pexp_send($1, $3)) } | expr SHARP label simple_expr_list { mkexp(Pexp_apply({ pexp_desc = Pexp_send($1, $3); pexp_loc = { loc_start = Parsing.symbol_start (); loc_end = Parsing.rhs_end 3 } }, List.rev $4)) } */ | ASSERT simple_expr %prec prec_appl { mkassert $2 } | LAZY simple_expr %prec prec_appl { mklazy $2 } ; simple_expr: val_longident { mkexp(Pexp_ident $1) } | constant { mkexp(Pexp_constant $1) } | constr_longident { mkexp(Pexp_construct($1, None, false)) } | LPAREN seq_expr RPAREN { $2 } | LPAREN seq_expr error { unclosed "(" 1 ")" 3 } | BEGIN seq_expr END { $2 } | BEGIN seq_expr error { unclosed "begin" 1 "end" 3 } | LPAREN seq_expr type_constraint RPAREN { let (t, t') = $3 in mkexp(Pexp_constraint($2, t, t')) } | simple_expr DOT label_longident { mkexp(Pexp_field($1, $3)) } | simple_expr DOT LPAREN seq_expr RPAREN { mkexp(Pexp_apply(mkexp(Pexp_ident(array_function "Array" "get")), [$1; $4])) } | simple_expr DOT LPAREN seq_expr error { unclosed "(" 3 ")" 5 } | simple_expr DOT LBRACKET seq_expr RBRACKET { mkexp(Pexp_apply(mkexp(Pexp_ident(array_function "String" "get")), [$1; $4])) } | simple_expr DOT LBRACKET seq_expr error { unclosed "[" 3 "]" 5 } | LBRACE record_expr RBRACE { let (exten, fields) = $2 in mkexp(Pexp_record(fields, exten)) } | LBRACE record_expr error { unclosed "{" 1 "}" 5 } | LBRACKETLESS stream_expr opt_semi GREATERRBRACKET { Pstream.cstream (List.rev $2) } | LBRACKETLESS stream_expr opt_semi error { unclosed "[<" 1 ">]" 4 } | LBRACKETLESS GREATERRBRACKET { Pstream.cstream [] } | LBRACKETBAR expr_semi_list opt_semi BARRBRACKET { mkexp(Pexp_array(List.rev $2)) } | LBRACKETBAR expr_semi_list opt_semi error { unclosed "[|" 1 "|]" 4 } | LBRACKETBAR BARRBRACKET { mkexp(Pexp_array []) } | LBRACKET expr_semi_list opt_semi RBRACKET { mkexp (mktailexp (rhs_loc 4).loc_end (List.rev $2)).pexp_desc } | LBRACKET expr_semi_list opt_semi error { unclosed "[" 1 "]" 4 } | PREFIXOP simple_expr { mkexp(Pexp_apply(mkoperator $1 1, [$2])) } | NEW class_longident { mkexp(Pexp_new($2)) } | LBRACELESS field_expr_list opt_semi GREATERRBRACE { mkexp(Pexp_override(List.rev $2)) } | LBRACELESS field_expr_list opt_semi error { unclosed "{<" 1 ">}" 4 } | LBRACELESS GREATERRBRACE { mkexp(Pexp_override []) } | simple_expr SHARP label { mkexp(Pexp_send($1, $3)) } ; simple_expr_list: simple_expr { [$1] } | simple_expr_list simple_expr { $2 :: $1 } ; let_bindings: let_binding { [$1] } | let_bindings AND let_binding { $3 :: $1 } ; let_binding: val_ident fun_binding { ({ppat_desc = Ppat_var $1; ppat_loc = rhs_loc 1}, $2) } | pattern EQUAL seq_expr %prec prec_let { ($1, $3) } ; fun_binding: EQUAL seq_expr %prec prec_let { $2 } | type_constraint EQUAL seq_expr %prec prec_let { let (t, t') = $1 in mkexp(Pexp_constraint($3, t, t')) } | simple_pattern fun_binding { mkexp(Pexp_function[$1,$2]) } ; parser_cases: parser_case { [$1] } | parser_cases BAR parser_case { $3 :: $1 } ; parser_case: LBRACKETLESS stream_pattern opt_semi GREATERRBRACKET opt_pat MINUSGREATER seq_expr { (List.rev $2, $5, $7) } | LBRACKETLESS stream_pattern opt_semi error { unclosed "[<" 1 ">]" 4 } | LBRACKETLESS GREATERRBRACKET opt_pat MINUSGREATER seq_expr { ([], $3, $5) } ; stream_pattern: stream_pattern_component opt_err { [($1, $2)] } | stream_pattern SEMI stream_pattern_component opt_err { ($3, $4) :: $1 } ; stream_pattern_component: QUOTE pattern { Pstream.Spat_term ($2, None) } | QUOTE pattern WHEN expr %prec prec_list { Pstream.Spat_term ($2, Some $4) } | pattern EQUAL expr { Pstream.Spat_nterm ($1, $3) } | pattern { Pstream.Spat_sterm $1 } ; opt_pat: /* empty */ { None } | simple_pattern { Some $1 } ; opt_err: /* empty */ { None } | QUESTION expr %prec prec_list { Some $2 } ; stream_expr: stream_expr_component { [$1] } | stream_expr SEMI stream_expr_component { $3 :: $1 } ; stream_expr_component: QUOTE expr %prec prec_list { Pstream.Sexp_term $2 } | expr %prec prec_list { Pstream.Sexp_nterm $1 } ; match_cases: pattern match_action { [$1, $2] } | match_cases BAR pattern match_action { ($3, $4) :: $1 } ; fun_def: match_action { $1 } | simple_pattern fun_def { mkexp(Pexp_function[$1,$2]) } ; match_action: MINUSGREATER seq_expr { $2 } | WHEN seq_expr MINUSGREATER seq_expr { mkexp(Pexp_when($2, $4)) } ; expr_comma_list: expr_comma_list COMMA expr { $3 :: $1 } | expr COMMA expr { [$3; $1] } ; record_expr: simple_expr WITH lbl_expr_list opt_semi { (Some $1, List.rev $3) } | lbl_expr_list opt_semi { (None, List.rev $1) } ; lbl_expr_list: label_longident EQUAL expr %prec prec_list { [$1,$3] } | lbl_expr_list SEMI label_longident EQUAL expr %prec prec_list { ($3, $5) :: $1 } ; field_expr_list: label EQUAL expr %prec prec_list { [$1,$3] } | field_expr_list SEMI label EQUAL expr %prec prec_list { ($3, $5) :: $1 } ; expr_semi_list: expr %prec prec_list { [$1] } | expr_semi_list SEMI expr %prec prec_list { $3 :: $1 } ; type_constraint: COLON core_type { (Some $2, None) } | COLON core_type COLONGREATER core_type { (Some $2, Some $4) } | COLONGREATER core_type { (None, Some $2) } | COLON error { syntax_error() } | COLONGREATER error { syntax_error() } ; /* Patterns */ pattern: simple_pattern { $1 } | pattern AS val_ident { mkpat(Ppat_alias($1, $3)) } | pattern_comma_list { mkpat(Ppat_tuple(List.rev $1)) } | constr_longident pattern %prec prec_constr_appl { mkpat(Ppat_construct($1, Some $2, false)) } | pattern COLONCOLON pattern { mkpat(Ppat_construct(Lident "::", Some(mkpat(Ppat_tuple[$1;$3])), false)) } | pattern BAR pattern { mkpat(Ppat_or($1, $3)) } ; simple_pattern: val_ident { mkpat(Ppat_var $1) } | UNDERSCORE { mkpat(Ppat_any) } | signed_constant { mkpat(Ppat_constant $1) } | CHAR DOTDOT CHAR { mkrangepat $1 $3 } | constr_longident { mkpat(Ppat_construct($1, None, false)) } | LBRACE lbl_pattern_list opt_semi RBRACE { mkpat(Ppat_record(List.rev $2)) } | LBRACE lbl_pattern_list opt_semi error { unclosed "{" 1 "}" 4 } | LBRACKET pattern_semi_list opt_semi RBRACKET { mkpat (mktailpat (rhs_loc 4).loc_end (List.rev $2)).ppat_desc } | LBRACKET pattern_semi_list opt_semi error { unclosed "[" 1 "]" 4 } | LBRACKETBAR pattern_semi_list opt_semi BARRBRACKET { mkpat(Ppat_array(List.rev $2)) } | LBRACKETBAR BARRBRACKET { mkpat(Ppat_array []) } | LBRACKETBAR pattern_semi_list opt_semi error { unclosed "[|" 1 "|]" 4 } | LPAREN pattern RPAREN { $2 } | LPAREN pattern error { unclosed "(" 1 ")" 3 } | LPAREN pattern COLON core_type RPAREN { mkpat(Ppat_constraint($2, $4)) } | LPAREN pattern COLON core_type error { unclosed "(" 1 ")" 5 } ; pattern_comma_list: pattern_comma_list COMMA pattern { $3 :: $1 } | pattern COMMA pattern { [$3; $1] } ; pattern_semi_list: pattern { [$1] } | pattern_semi_list SEMI pattern { $3 :: $1 } ; lbl_pattern_list: label_longident EQUAL pattern { [($1, $3)] } | lbl_pattern_list SEMI label_longident EQUAL pattern { ($3, $5) :: $1 } ; /* Primitive declarations */ primitive_declaration: STRING { [$1] } | STRING primitive_declaration { $1 :: $2 } ; /* Type declarations */ type_declarations: type_declaration { [$1] } | type_declarations AND type_declaration { $3 :: $1 } ; type_declaration: type_parameters LIDENT type_kind constraints { let (kind, manifest) = $3 in ($2, {ptype_params = $1; ptype_cstrs = List.rev $4; ptype_kind = kind; ptype_manifest = manifest; ptype_loc = symbol_loc()}) } ; constraints: constraints CONSTRAINT constrain { $3 :: $1 } | /* empty */ { [] } ; type_kind: /*empty*/ { (Ptype_abstract, None) } | EQUAL core_type %prec prec_type_def { (Ptype_abstract, Some $2) } | EQUAL constructor_declarations { (Ptype_variant(List.rev $2), None) } | EQUAL BAR constructor_declarations { (Ptype_variant(List.rev $3), None) } | EQUAL LBRACE label_declarations opt_semi RBRACE { (Ptype_record(List.rev $3), None) } | EQUAL core_type EQUAL opt_bar constructor_declarations %prec prec_type_def { (Ptype_variant(List.rev $5), Some $2) } | EQUAL core_type EQUAL LBRACE label_declarations opt_semi RBRACE %prec prec_type_def { (Ptype_record(List.rev $5), Some $2) } ; type_parameters: /*empty*/ { [] } | type_parameter { [$1] } | LPAREN type_parameter_list RPAREN { List.rev $2 } ; type_parameter: QUOTE ident { $2 } ; type_parameter_list: type_parameter { [$1] } | type_parameter_list COMMA type_parameter { $3 :: $1 } ; constructor_declarations: constructor_declaration { [$1] } | constructor_declarations BAR constructor_declaration { $3 :: $1 } ; constructor_declaration: constr_ident constructor_arguments { ($1, $2) } ; constructor_arguments: /*empty*/ { [] } | OF core_type_list { List.rev $2 } ; label_declarations: label_declaration { [$1] } | label_declarations SEMI label_declaration { $3 :: $1 } ; label_declaration: mutable_flag LIDENT COLON core_type { ($2, $1, $4) } ; /* "with" constraints (additional type equations over signature components) */ with_constraints: with_constraint { [$1] } | with_constraints AND with_constraint { $3 :: $1 } ; with_constraint: TYPE type_parameters label_longident EQUAL core_type constraints { ($3, Pwith_type {ptype_params = $2; ptype_cstrs = List.rev $6; ptype_kind = Ptype_abstract; ptype_manifest = Some $5; ptype_loc = symbol_loc()}) } /* used label_longident instead of type_longident to disallow functor applications in type path */ | MODULE mod_longident EQUAL mod_ext_longident { ($2, Pwith_module $4) } ; /* Core types */ core_type: simple_core_type { $1 } | core_type MINUSGREATER core_type %prec prec_type_arrow { mktyp(Ptyp_arrow($1, $3)) } | core_type_tuple { mktyp(Ptyp_tuple(List.rev $1)) } | core_type AS type_parameter { mktyp(Ptyp_alias($1, $3)) } ; simple_core_type: QUOTE ident { mktyp(Ptyp_var $2) } | UNDERSCORE { mktyp(Ptyp_any) } | type_longident { mktyp(Ptyp_constr($1, [])) } | simple_core_type type_longident %prec prec_constr_appl { mktyp(Ptyp_constr($2, [$1])) } | LPAREN core_type_comma_list RPAREN type_longident %prec prec_constr_appl { mktyp(Ptyp_constr($4, List.rev $2)) } | LPAREN core_type RPAREN { $2 } | LESS meth_list GREATER { mktyp(Ptyp_object $2) } | LESS GREATER { mktyp(Ptyp_object []) } | SHARP class_longident { mktyp(Ptyp_class($2, [])) } | simple_core_type SHARP class_longident %prec prec_constr_appl { mktyp(Ptyp_class($3, [$1])) } | LPAREN core_type_comma_list RPAREN SHARP class_longident %prec prec_constr_appl { mktyp(Ptyp_class($5, List.rev $2)) } ; core_type_tuple: simple_core_type STAR simple_core_type { [$3; $1] } | core_type_tuple STAR simple_core_type { $3 :: $1 } ; core_type_comma_list: core_type COMMA core_type { [$3; $1] } | core_type_comma_list COMMA core_type { $3 :: $1 } ; core_type_list: simple_core_type { [$1] } | core_type_list STAR simple_core_type { $3 :: $1 } ; meth_list: field SEMI meth_list { $1 :: $3 } | field opt_semi { [$1] } | DOTDOT { [mkfield Pfield_var] } ; field: label COLON core_type { mkfield(Pfield($1, $3)) } ; label: LIDENT { $1 } ; /* Constants */ constant: INT { Const_int $1 } | CHAR { Const_char $1 } | STRING { Const_string $1 } | FLOAT { Const_float $1 } ; signed_constant: constant { $1 } | SUBTRACTIVE INT { Const_int(- $2) } | SUBTRACTIVE FLOAT { Const_float("-" ^ $2) } ; /* Identifiers and long identifiers */ ident: UIDENT { $1 } | LIDENT { $1 } ; val_ident: LIDENT { $1 } | LPAREN operator RPAREN { $2 } ; operator: PREFIXOP { $1 } | INFIXOP0 { $1 } | INFIXOP1 { $1 } | INFIXOP2 { $1 } | INFIXOP3 { $1 } | INFIXOP4 { $1 } | SUBTRACTIVE { $1 } | STAR { "*" } | EQUAL { "=" } | LESS { "<" } | GREATER { ">" } | OR { "or" } | BARBAR { "||" } | AMPERSAND { "&" } | AMPERAMPER { "&&" } | COLONEQUAL { ":=" } ; constr_ident: UIDENT { $1 } | LBRACKET RBRACKET { "[]" } | LPAREN RPAREN { "()" } | COLONCOLON { "::" } | FALSE { "false" } | TRUE { "true" } ; val_longident: val_ident { Lident $1 } | mod_longident DOT val_ident { Ldot($1, $3) } ; constr_longident: mod_longident { $1 } | LBRACKET RBRACKET { Lident "[]" } | LPAREN RPAREN { Lident "()" } | FALSE { Lident "false" } | TRUE { Lident "true" } ; label_longident: LIDENT { Lident $1 } | mod_longident DOT LIDENT { Ldot($1, $3) } ; type_longident: LIDENT { Lident $1 } | mod_ext_longident DOT LIDENT { Ldot($1, $3) } ; mod_longident: UIDENT { Lident $1 } | mod_longident DOT UIDENT { Ldot($1, $3) } ; mod_ext_longident: UIDENT { Lident $1 } | mod_ext_longident DOT UIDENT { Ldot($1, $3) } | mod_ext_longident LPAREN mod_ext_longident RPAREN { Lapply($1, $3) } ; mty_longident: ident { Lident $1 } | mod_ext_longident DOT ident { Ldot($1, $3) } ; clty_longident: LIDENT { Lident $1 } | mod_ext_longident DOT LIDENT { Ldot($1, $3) } ; class_longident: LIDENT { Lident $1 } | mod_longident DOT LIDENT { Ldot($1, $3) } ; /* Toplevel directives */ toplevel_directive: SHARP ident { Ptop_dir($2, Pdir_none) } | SHARP ident STRING { Ptop_dir($2, Pdir_string $3) } | SHARP ident INT { Ptop_dir($2, Pdir_int $3) } | SHARP ident val_longident { Ptop_dir($2, Pdir_ident $3) } ; /* Miscellaneous */ rec_flag: /* empty */ { Nonrecursive } | REC { Recursive } ; direction_flag: TO { Upto } | DOWNTO { Downto } ; private_flag: /* empty */ { Public } | PRIVATE { Private } ; mutable_flag: /* empty */ { Immutable } | MUTABLE { Mutable } ; virtual_flag: /* empty */ { Concrete } | VIRTUAL { Virtual } ; opt_bar: /* empty */ { () } | BAR { () } ; opt_semi: | /* empty */ { () } | SEMI { () } ; %%