/usr/lib/ocaml/compiler-libs/parsing/parser.mly is in ocaml-compiler-libs 3.12.1-2ubuntu2.
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/* */
/* Objective Caml */
/* */
/* Xavier Leroy, projet Cristal, INRIA Rocquencourt */
/* */
/* Copyright 1996 Institut National de Recherche en Informatique et */
/* en Automatique. All rights reserved. This file is distributed */
/* under the terms of the Q Public License version 1.0. */
/* */
/***********************************************************************/
/* $Id: parser.mly 11016 2011-04-29 04:56:21Z furuse $ */
/* The parser definition */
%{
open Location
open Asttypes
open Longident
open Parsetree
let mktyp d =
{ ptyp_desc = d; ptyp_loc = symbol_rloc() }
let mkpat d =
{ ppat_desc = d; ppat_loc = symbol_rloc() }
let mkexp d =
{ pexp_desc = d; pexp_loc = symbol_rloc() }
let mkmty d =
{ pmty_desc = d; pmty_loc = symbol_rloc() }
let mksig d =
{ psig_desc = d; psig_loc = symbol_rloc() }
let mkmod d =
{ pmod_desc = d; pmod_loc = symbol_rloc() }
let mkstr d =
{ pstr_desc = d; pstr_loc = symbol_rloc() }
let mkfield d =
{ pfield_desc = d; pfield_loc = symbol_rloc() }
let mkclass d =
{ pcl_desc = d; pcl_loc = symbol_rloc() }
let mkcty d =
{ pcty_desc = d; pcty_loc = symbol_rloc() }
let reloc_pat x = { x with ppat_loc = symbol_rloc () };;
let reloc_exp x = { x with pexp_loc = symbol_rloc () };;
let mkoperator name pos =
{ pexp_desc = Pexp_ident(Lident name); pexp_loc = rhs_loc pos }
(*
Ghost expressions and patterns:
expressions and patterns that do not appear explicitely in the
source file they have the loc_ghost flag set to true.
Then the profiler will not try to instrument them and the
-stypes option will not try to display their type.
Every grammar rule that generates an element with a location must
make at most one non-ghost element, the topmost one.
How to tell whether your location must be ghost:
A location corresponds to a range of characters in the source file.
If the location contains a piece of code that is syntactically
valid (according to the documentation), and corresponds to the
AST node, then the location must be real; in all other cases,
it must be ghost.
*)
let ghexp d = { pexp_desc = d; pexp_loc = symbol_gloc () };;
let ghpat d = { ppat_desc = d; ppat_loc = symbol_gloc () };;
let ghtyp d = { ptyp_desc = d; ptyp_loc = symbol_gloc () };;
let mkassert e =
match e with
| {pexp_desc = Pexp_construct (Lident "false", None, false) } ->
mkexp (Pexp_assertfalse)
| _ -> mkexp (Pexp_assert (e))
;;
let mkinfix arg1 name arg2 =
mkexp(Pexp_apply(mkoperator name 2, ["", arg1; "", arg2]))
let neg_float_string f =
if String.length f > 0 && f.[0] = '-'
then String.sub f 1 (String.length f - 1)
else "-" ^ f
let mkuminus name arg =
match name, arg.pexp_desc with
| "-", Pexp_constant(Const_int n) ->
mkexp(Pexp_constant(Const_int(-n)))
| "-", Pexp_constant(Const_int32 n) ->
mkexp(Pexp_constant(Const_int32(Int32.neg n)))
| "-", Pexp_constant(Const_int64 n) ->
mkexp(Pexp_constant(Const_int64(Int64.neg n)))
| "-", Pexp_constant(Const_nativeint n) ->
mkexp(Pexp_constant(Const_nativeint(Nativeint.neg n)))
| ("-" | "-."), Pexp_constant(Const_float f) ->
mkexp(Pexp_constant(Const_float(neg_float_string f)))
| _ ->
mkexp(Pexp_apply(mkoperator ("~" ^ name) 1, ["", arg]))
let mkuplus name arg =
let desc = arg.pexp_desc in
match name, desc with
| "+", Pexp_constant(Const_int _)
| "+", Pexp_constant(Const_int32 _)
| "+", Pexp_constant(Const_int64 _)
| "+", Pexp_constant(Const_nativeint _)
| ("+" | "+."), Pexp_constant(Const_float _) -> mkexp desc
| _ ->
mkexp(Pexp_apply(mkoperator ("~" ^ name) 1, ["", arg]))
let rec mktailexp = function
[] ->
ghexp(Pexp_construct(Lident "[]", None, false))
| e1 :: el ->
let exp_el = mktailexp el in
let l = {loc_start = e1.pexp_loc.loc_start;
loc_end = exp_el.pexp_loc.loc_end;
loc_ghost = true}
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 = function
[] ->
ghpat(Ppat_construct(Lident "[]", None, false))
| p1 :: pl ->
let pat_pl = mktailpat pl in
let l = {loc_start = p1.ppat_loc.loc_start;
loc_end = pat_pl.ppat_loc.loc_end;
loc_ghost = true}
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 ghstrexp e =
{ pstr_desc = Pstr_eval e; pstr_loc = {e.pexp_loc with loc_ghost = true} }
let array_function str name =
Ldot(Lident str, (if !Clflags.fast then "unsafe_" ^ name else name))
let rec deep_mkrangepat c1 c2 =
if c1 = c2 then ghpat(Ppat_constant(Const_char c1)) else
ghpat(Ppat_or(ghpat(Ppat_constant(Const_char c1)),
deep_mkrangepat (Char.chr(Char.code c1 + 1)) c2))
let rec mkrangepat c1 c2 =
if c1 > c2 then mkrangepat c2 c1 else
if c1 = c2 then mkpat(Ppat_constant(Const_char c1)) else
reloc_pat (deep_mkrangepat c1 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)))
let bigarray_function str name =
Ldot(Ldot(Lident "Bigarray", str), name)
let bigarray_untuplify = function
{ pexp_desc = Pexp_tuple explist} -> explist
| exp -> [exp]
let bigarray_get arr arg =
let get = if !Clflags.fast then "unsafe_get" else "get" in
match bigarray_untuplify arg with
[c1] ->
mkexp(Pexp_apply(ghexp(Pexp_ident(bigarray_function "Array1" get)),
["", arr; "", c1]))
| [c1;c2] ->
mkexp(Pexp_apply(ghexp(Pexp_ident(bigarray_function "Array2" get)),
["", arr; "", c1; "", c2]))
| [c1;c2;c3] ->
mkexp(Pexp_apply(ghexp(Pexp_ident(bigarray_function "Array3" get)),
["", arr; "", c1; "", c2; "", c3]))
| coords ->
mkexp(Pexp_apply(ghexp(Pexp_ident(bigarray_function "Genarray" "get")),
["", arr; "", ghexp(Pexp_array coords)]))
let bigarray_set arr arg newval =
let set = if !Clflags.fast then "unsafe_set" else "set" in
match bigarray_untuplify arg with
[c1] ->
mkexp(Pexp_apply(ghexp(Pexp_ident(bigarray_function "Array1" set)),
["", arr; "", c1; "", newval]))
| [c1;c2] ->
mkexp(Pexp_apply(ghexp(Pexp_ident(bigarray_function "Array2" set)),
["", arr; "", c1; "", c2; "", newval]))
| [c1;c2;c3] ->
mkexp(Pexp_apply(ghexp(Pexp_ident(bigarray_function "Array3" set)),
["", arr; "", c1; "", c2; "", c3; "", newval]))
| coords ->
mkexp(Pexp_apply(ghexp(Pexp_ident(bigarray_function "Genarray" "set")),
["", arr;
"", ghexp(Pexp_array coords);
"", newval]))
let lapply p1 p2 =
if !Clflags.applicative_functors
then Lapply(p1, p2)
else raise (Syntaxerr.Error(Syntaxerr.Applicative_path (symbol_rloc())))
let exp_of_label lbl =
mkexp (Pexp_ident(Lident(Longident.last lbl)))
let pat_of_label lbl =
mkpat (Ppat_var(Longident.last lbl))
%}
/* Tokens */
%token AMPERAMPER
%token AMPERSAND
%token AND
%token AS
%token ASSERT
%token BACKQUOTE
%token BANG
%token BAR
%token BARBAR
%token BARRBRACKET
%token BEGIN
%token <char> 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 <string> FLOAT
%token FOR
%token FUN
%token FUNCTION
%token FUNCTOR
%token GREATER
%token GREATERRBRACE
%token GREATERRBRACKET
%token IF
%token IN
%token INCLUDE
%token <string> INFIXOP0
%token <string> INFIXOP1
%token <string> INFIXOP2
%token <string> INFIXOP3
%token <string> INFIXOP4
%token INHERIT
%token INITIALIZER
%token <int> INT
%token <int32> INT32
%token <int64> INT64
%token <string> LABEL
%token LAZY
%token LBRACE
%token LBRACELESS
%token LBRACKET
%token LBRACKETBAR
%token LBRACKETLESS
%token LBRACKETGREATER
%token LESS
%token LESSMINUS
%token LET
%token <string> LIDENT
%token LPAREN
%token MATCH
%token METHOD
%token MINUS
%token MINUSDOT
%token MINUSGREATER
%token MODULE
%token MUTABLE
%token <nativeint> NATIVEINT
%token NEW
%token OBJECT
%token OF
%token OPEN
%token <string> OPTLABEL
%token OR
/* %token PARSER */
%token PLUS
%token PLUSDOT
%token <string> PREFIXOP
%token PRIVATE
%token QUESTION
%token QUESTIONQUESTION
%token QUOTE
%token RBRACE
%token RBRACKET
%token REC
%token RPAREN
%token SEMI
%token SEMISEMI
%token SHARP
%token SIG
%token STAR
%token <string> STRING
%token STRUCT
%token THEN
%token TILDE
%token TO
%token TRUE
%token TRY
%token TYPE
%token <string> UIDENT
%token UNDERSCORE
%token VAL
%token VIRTUAL
%token WHEN
%token WHILE
%token WITH
/* Precedences and associativities.
Tokens and rules have precedences. A reduce/reduce conflict is resolved
in favor of the first rule (in source file order). A shift/reduce conflict
is resolved by comparing the precedence and associativity of the token to
be shifted with those of the rule to be reduced.
By default, a rule has the precedence of its rightmost terminal (if any).
When there is a shift/reduce conflict between a rule and a token that
have the same precedence, it is resolved using the associativity:
if the token is left-associative, the parser will reduce; if
right-associative, the parser will shift; if non-associative,
the parser will declare a syntax error.
We will only use associativities with operators of the kind x * x -> x
for example, in the rules of the form expr: expr BINOP expr
in all other cases, we define two precedences if needed to resolve
conflicts.
The precedences must be listed from low to high.
*/
%nonassoc IN
%nonassoc below_SEMI
%nonassoc SEMI /* below EQUAL ({lbl=...; lbl=...}) */
%nonassoc LET /* above SEMI ( ...; let ... in ...) */
%nonassoc below_WITH
%nonassoc FUNCTION WITH /* below BAR (match ... with ...) */
%nonassoc AND /* above WITH (module rec A: SIG with ... and ...) */
%nonassoc THEN /* below ELSE (if ... then ...) */
%nonassoc ELSE /* (if ... then ... else ...) */
%nonassoc LESSMINUS /* below COLONEQUAL (lbl <- x := e) */
%right COLONEQUAL /* expr (e := e := e) */
%nonassoc AS
%left BAR /* pattern (p|p|p) */
%nonassoc below_COMMA
%left COMMA /* expr/expr_comma_list (e,e,e) */
%right MINUSGREATER /* core_type2 (t -> t -> t) */
%right OR BARBAR /* expr (e || e || e) */
%right AMPERSAND AMPERAMPER /* expr (e && e && e) */
%nonassoc below_EQUAL
%left INFIXOP0 EQUAL LESS GREATER /* expr (e OP e OP e) */
%right INFIXOP1 /* expr (e OP e OP e) */
%right COLONCOLON /* expr (e :: e :: e) */
%left INFIXOP2 PLUS PLUSDOT MINUS MINUSDOT /* expr (e OP e OP e) */
%left INFIXOP3 STAR /* expr (e OP e OP e) */
%right INFIXOP4 /* expr (e OP e OP e) */
%nonassoc prec_unary_minus prec_unary_plus /* unary - */
%nonassoc prec_constant_constructor /* cf. simple_expr (C versus C x) */
%nonassoc prec_constr_appl /* above AS BAR COLONCOLON COMMA */
%nonassoc below_SHARP
%nonassoc SHARP /* simple_expr/toplevel_directive */
%nonassoc below_DOT
%nonassoc DOT
/* Finally, the first tokens of simple_expr are above everything else. */
%nonassoc BACKQUOTE BANG BEGIN CHAR FALSE FLOAT INT INT32 INT64
LBRACE LBRACELESS LBRACKET LBRACKETBAR LIDENT LPAREN
NEW NATIVEINT PREFIXOP STRING TRUE UIDENT
/* Entry points */
%start implementation /* for implementation files */
%type <Parsetree.structure> implementation
%start interface /* for interface files */
%type <Parsetree.signature> interface
%start toplevel_phrase /* for interactive use */
%type <Parsetree.toplevel_phrase> toplevel_phrase
%start use_file /* for the #use directive */
%type <Parsetree.toplevel_phrase list> 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[ghstrexp $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[ghstrexp $1] :: $2 }
;
use_file_tail:
EOF { [] }
| SEMISEMI EOF { [] }
| SEMISEMI seq_expr use_file_tail { Ptop_def[ghstrexp $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
{ 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 }
| LPAREN VAL expr COLON package_type RPAREN
{ mkmod(Pmod_unpack($3, $5)) }
| LPAREN VAL expr COLON error
{ unclosed "(" 1 ")" 5 }
;
structure:
structure_tail { $1 }
| seq_expr structure_tail { ghstrexp $1 :: $2 }
;
structure_tail:
/* empty */ { [] }
| SEMISEMI { [] }
| SEMISEMI seq_expr structure_tail { ghstrexp $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)) }
| EXCEPTION UIDENT EQUAL constr_longident
{ mkstr(Pstr_exn_rebind($2, $4)) }
| MODULE UIDENT module_binding
{ mkstr(Pstr_module($2, $3)) }
| MODULE REC module_rec_bindings
{ mkstr(Pstr_recmodule(List.rev $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)) }
| INCLUDE module_expr
{ mkstr(Pstr_include $2) }
;
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_rec_bindings:
module_rec_binding { [$1] }
| module_rec_bindings AND module_rec_binding { $3 :: $1 }
;
module_rec_binding:
UIDENT COLON module_type EQUAL module_expr { ($1, $3, $5) }
;
/* 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 below_WITH
{ mkmty(Pmty_functor($3, $5, $8)) }
| module_type WITH with_constraints
{ mkmty(Pmty_with($1, List.rev $3)) }
| MODULE TYPE OF module_expr
{ mkmty(Pmty_typeof $4) }
| 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 REC module_rec_declarations
{ mksig(Psig_recmodule(List.rev $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)) }
;
module_rec_declarations:
module_rec_declaration { [$1] }
| module_rec_declarations AND module_rec_declaration { $3 :: $1 }
;
module_rec_declaration:
UIDENT COLON module_type { ($1, $3) }
;
/* 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
{ let params, variance = List.split (fst $2) in
{pci_virt = $1; pci_params = params, snd $2;
pci_name = $3; pci_expr = $4; pci_variance = variance;
pci_loc = symbol_rloc ()} }
;
class_fun_binding:
EQUAL class_expr
{ $2 }
| COLON class_type EQUAL class_expr
{ mkclass(Pcl_constraint($4, $2)) }
| labeled_simple_pattern class_fun_binding
{ let (l,o,p) = $1 in mkclass(Pcl_fun(l, o, p, $2)) }
;
class_type_parameters:
/*empty*/ { [], symbol_gloc () }
| LBRACKET type_parameter_list RBRACKET { List.rev $2, symbol_rloc () }
;
class_fun_def:
labeled_simple_pattern MINUSGREATER class_expr
{ let (l,o,p) = $1 in mkclass(Pcl_fun(l, o, p, $3)) }
| labeled_simple_pattern class_fun_def
{ let (l,o,p) = $1 in mkclass(Pcl_fun(l, o, p, $2)) }
;
class_expr:
class_simple_expr
{ $1 }
| FUN class_fun_def
{ $2 }
| class_simple_expr simple_labeled_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)) }
| class_longident
{ mkclass(Pcl_constr($1, [])) }
| OBJECT class_structure END
{ mkclass(Pcl_structure($2)) }
| OBJECT class_structure error
{ unclosed "object" 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
{ reloc_pat $2 }
| LPAREN pattern COLON core_type RPAREN
{ mkpat(Ppat_constraint($2, $4)) }
| /* empty */
{ ghpat(Ppat_any) }
;
class_fields:
/* empty */
{ [] }
| class_fields INHERIT override_flag class_expr parent_binder
{ Pcf_inher ($3, $4, $5) :: $1 }
| class_fields VAL virtual_value
{ Pcf_valvirt $3 :: $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 INITIALIZER seq_expr
{ Pcf_init $3 :: $1 }
;
parent_binder:
AS LIDENT
{ Some $2 }
| /* empty */
{ None }
;
virtual_value:
override_flag MUTABLE VIRTUAL label COLON core_type
{ if $1 = Override then syntax_error ();
$4, Mutable, $6, symbol_rloc () }
| VIRTUAL mutable_flag label COLON core_type
{ $3, $2, $5, symbol_rloc () }
;
value:
override_flag mutable_flag label EQUAL seq_expr
{ $3, $2, $1, $5, symbol_rloc () }
| override_flag mutable_flag label type_constraint EQUAL seq_expr
{ $3, $2, $1, (let (t, t') = $4 in ghexp(Pexp_constraint($6, t, t'))),
symbol_rloc () }
;
virtual_method:
METHOD override_flag PRIVATE VIRTUAL label COLON poly_type
{ if $2 = Override then syntax_error ();
$5, Private, $7, symbol_rloc () }
| METHOD override_flag VIRTUAL private_flag label COLON poly_type
{ if $2 = Override then syntax_error ();
$5, $4, $7, symbol_rloc () }
;
concrete_method :
METHOD override_flag private_flag label strict_binding
{ $4, $3, $2, ghexp(Pexp_poly ($5, None)), symbol_rloc () }
| METHOD override_flag private_flag label COLON poly_type EQUAL seq_expr
{ $4, $3, $2, ghexp(Pexp_poly($8,Some $6)), symbol_rloc () }
;
/* Class types */
class_type:
class_signature
{ $1 }
| QUESTION LIDENT COLON simple_core_type_or_tuple MINUSGREATER class_type
{ mkcty(Pcty_fun("?" ^ $2 ,
{ptyp_desc =
Ptyp_constr(Ldot (Lident "*predef*", "option"), [$4]);
ptyp_loc = $4.ptyp_loc},
$6)) }
| OPTLABEL simple_core_type_or_tuple MINUSGREATER class_type
{ mkcty(Pcty_fun("?" ^ $1 ,
{ptyp_desc =
Ptyp_constr(Ldot (Lident "*predef*", "option"), [$2]);
ptyp_loc = $2.ptyp_loc},
$4)) }
| LIDENT COLON simple_core_type_or_tuple MINUSGREATER class_type
{ mkcty(Pcty_fun($1, $3, $5)) }
| simple_core_type_or_tuple MINUSGREATER class_type
{ mkcty(Pcty_fun("", $1, $3)) }
;
class_signature:
LBRACKET core_type_comma_list RBRACKET clty_longident
{ mkcty(Pcty_constr ($4, List.rev $2)) }
| clty_longident
{ mkcty(Pcty_constr ($1, [])) }
| OBJECT class_sig_body END
{ mkcty(Pcty_signature $2) }
| OBJECT class_sig_body error
{ unclosed "object" 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_type { Pctf_virt $2 :: $1 }
| class_sig_fields method_type { Pctf_meth $2 :: $1 }
| class_sig_fields CONSTRAINT constrain { Pctf_cstr $3 :: $1 }
;
value_type:
VIRTUAL mutable_flag label COLON core_type
{ $3, $2, Virtual, $5, symbol_rloc () }
| MUTABLE virtual_flag label COLON core_type
{ $3, Mutable, $2, $5, symbol_rloc () }
| label COLON core_type
{ $1, Immutable, Concrete, $3, symbol_rloc () }
;
method_type:
METHOD private_flag label COLON poly_type
{ $3, $2, $5, symbol_rloc () }
;
virtual_method_type:
METHOD PRIVATE VIRTUAL label COLON poly_type
{ $4, Private, $6, symbol_rloc () }
| METHOD VIRTUAL private_flag label COLON poly_type
{ $4, $3, $6, symbol_rloc () }
;
constrain:
core_type EQUAL core_type { $1, $3, symbol_rloc () }
;
class_descriptions:
class_descriptions AND class_description { $3 :: $1 }
| class_description { [$1] }
;
class_description:
virtual_flag class_type_parameters LIDENT COLON class_type
{ let params, variance = List.split (fst $2) in
{pci_virt = $1; pci_params = params, snd $2;
pci_name = $3; pci_expr = $5; pci_variance = variance;
pci_loc = symbol_rloc ()} }
;
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
{ let params, variance = List.split (fst $2) in
{pci_virt = $1; pci_params = params, snd $2;
pci_name = $3; pci_expr = $5; pci_variance = variance;
pci_loc = symbol_rloc ()} }
;
/* Core expressions */
seq_expr:
| expr %prec below_SEMI { $1 }
| expr SEMI { reloc_exp $1 }
| expr SEMI seq_expr { mkexp(Pexp_sequence($1, $3)) }
;
labeled_simple_pattern:
QUESTION LPAREN label_let_pattern opt_default RPAREN
{ ("?" ^ fst $3, $4, snd $3) }
| QUESTION label_var
{ ("?" ^ fst $2, None, snd $2) }
| OPTLABEL LPAREN let_pattern opt_default RPAREN
{ ("?" ^ $1, $4, $3) }
| OPTLABEL pattern_var
{ ("?" ^ $1, None, $2) }
| TILDE LPAREN label_let_pattern RPAREN
{ (fst $3, None, snd $3) }
| TILDE label_var
{ (fst $2, None, snd $2) }
| LABEL simple_pattern
{ ($1, None, $2) }
| simple_pattern
{ ("", None, $1) }
;
pattern_var:
LIDENT { mkpat(Ppat_var $1) }
| UNDERSCORE { mkpat Ppat_any }
;
opt_default:
/* empty */ { None }
| EQUAL seq_expr { Some $2 }
;
label_let_pattern:
label_var
{ $1 }
| label_var COLON core_type
{ let (lab, pat) = $1 in (lab, mkpat(Ppat_constraint(pat, $3))) }
;
label_var:
LIDENT { ($1, mkpat(Ppat_var $1)) }
;
let_pattern:
pattern
{ $1 }
| pattern COLON core_type
{ mkpat(Ppat_constraint($1, $3)) }
;
expr:
simple_expr %prec below_SHARP
{ $1 }
| simple_expr simple_labeled_expr_list
{ mkexp(Pexp_apply($1, List.rev $2)) }
| LET rec_flag let_bindings IN seq_expr
{ mkexp(Pexp_let($2, List.rev $3, $5)) }
| LET MODULE UIDENT module_binding IN seq_expr
{ mkexp(Pexp_letmodule($3, $4, $6)) }
| LET OPEN mod_longident IN seq_expr
{ mkexp(Pexp_open($3, $5)) }
| FUNCTION opt_bar match_cases
{ mkexp(Pexp_function("", None, List.rev $3)) }
| FUN labeled_simple_pattern fun_def
{ let (l,o,p) = $2 in mkexp(Pexp_function(l, o, [p, $3])) }
| FUN LPAREN TYPE LIDENT RPAREN fun_def
{ mkexp(Pexp_newtype($4, $6)) }
| MATCH seq_expr WITH opt_bar match_cases
{ mkexp(Pexp_match($2, List.rev $5)) }
| TRY seq_expr WITH opt_bar match_cases
{ mkexp(Pexp_try($2, List.rev $5)) }
| TRY seq_expr WITH error
{ syntax_error() }
| expr_comma_list %prec below_COMMA
{ mkexp(Pexp_tuple(List.rev $1)) }
| constr_longident simple_expr %prec below_SHARP
{ mkexp(Pexp_construct($1, Some $2, false)) }
| name_tag simple_expr %prec below_SHARP
{ mkexp(Pexp_variant($1, Some $2)) }
| IF seq_expr THEN expr ELSE expr
{ mkexp(Pexp_ifthenelse($2, $4, Some $6)) }
| IF seq_expr THEN expr
{ 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(ghexp(Pexp_tuple[$1;$3])),
false)) }
| LPAREN COLONCOLON RPAREN LPAREN expr COMMA expr RPAREN
{ mkexp(Pexp_construct(Lident "::",
Some(ghexp(Pexp_tuple[$5;$7])),
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 PLUS expr
{ mkinfix $1 "+" $3 }
| expr PLUSDOT expr
{ mkinfix $1 "+." $3 }
| expr MINUS expr
{ mkinfix $1 "-" $3 }
| expr MINUSDOT expr
{ mkinfix $1 "-." $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 }
| additive expr %prec prec_unary_plus
{ mkuplus $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(ghexp(Pexp_ident(array_function "Array" "set")),
["",$1; "",$4; "",$7])) }
| simple_expr DOT LBRACKET seq_expr RBRACKET LESSMINUS expr
{ mkexp(Pexp_apply(ghexp(Pexp_ident(array_function "String" "set")),
["",$1; "",$4; "",$7])) }
| simple_expr DOT LBRACE expr RBRACE LESSMINUS expr
{ bigarray_set $1 $4 $7 }
| label LESSMINUS expr
{ mkexp(Pexp_setinstvar($1, $3)) }
| ASSERT simple_expr %prec below_SHARP
{ mkassert $2 }
| LAZY simple_expr %prec below_SHARP
{ mkexp (Pexp_lazy ($2)) }
| OBJECT class_structure END
{ mkexp (Pexp_object($2)) }
| OBJECT class_structure error
{ unclosed "object" 1 "end" 3 }
;
simple_expr:
val_longident
{ mkexp(Pexp_ident $1) }
| constant
{ mkexp(Pexp_constant $1) }
| constr_longident %prec prec_constant_constructor
{ mkexp(Pexp_construct($1, None, false)) }
| name_tag %prec prec_constant_constructor
{ mkexp(Pexp_variant($1, None)) }
| LPAREN seq_expr RPAREN
{ reloc_exp $2 }
| LPAREN seq_expr error
{ unclosed "(" 1 ")" 3 }
| BEGIN seq_expr END
{ reloc_exp $2 }
| BEGIN END
{ mkexp (Pexp_construct (Lident "()", None, false)) }
| 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)) }
| mod_longident DOT LPAREN seq_expr RPAREN
{ mkexp(Pexp_open($1, $4)) }
| mod_longident DOT LPAREN seq_expr error
{ unclosed "(" 3 ")" 5 }
| simple_expr DOT LPAREN seq_expr RPAREN
{ mkexp(Pexp_apply(ghexp(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(ghexp(Pexp_ident(array_function "String" "get")),
["",$1; "",$4])) }
| simple_expr DOT LBRACKET seq_expr error
{ unclosed "[" 3 "]" 5 }
| simple_expr DOT LBRACE expr RBRACE
{ bigarray_get $1 $4 }
| simple_expr DOT LBRACE expr_comma_list error
{ unclosed "{" 3 "}" 5 }
| LBRACE record_expr RBRACE
{ let (exten, fields) = $2 in mkexp(Pexp_record(fields, exten)) }
| LBRACE record_expr error
{ unclosed "{" 1 "}" 3 }
| 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
{ reloc_exp (mktailexp (List.rev $2)) }
| LBRACKET expr_semi_list opt_semi error
{ unclosed "[" 1 "]" 4 }
| PREFIXOP simple_expr
{ mkexp(Pexp_apply(mkoperator $1 1, ["",$2])) }
| BANG simple_expr
{ mkexp(Pexp_apply(mkoperator "!" 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)) }
| LPAREN MODULE module_expr COLON package_type RPAREN
{ mkexp (Pexp_pack ($3, $5)) }
| LPAREN MODULE module_expr COLON error
{ unclosed "(" 1 ")" 5 }
;
simple_labeled_expr_list:
labeled_simple_expr
{ [$1] }
| simple_labeled_expr_list labeled_simple_expr
{ $2 :: $1 }
;
labeled_simple_expr:
simple_expr %prec below_SHARP
{ ("", $1) }
| label_expr
{ $1 }
;
label_expr:
LABEL simple_expr %prec below_SHARP
{ ($1, $2) }
| TILDE label_ident
{ $2 }
| QUESTION label_ident
{ ("?" ^ fst $2, snd $2) }
| OPTLABEL simple_expr %prec below_SHARP
{ ("?" ^ $1, $2) }
;
label_ident:
LIDENT { ($1, mkexp(Pexp_ident(Lident $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) }
| val_ident COLON typevar_list DOT core_type EQUAL seq_expr
{ (ghpat(Ppat_constraint({ppat_desc = Ppat_var $1; ppat_loc = rhs_loc 1},
ghtyp(Ptyp_poly($3,$5)))),
$7) }
| pattern EQUAL seq_expr
{ ($1, $3) }
;
fun_binding:
strict_binding
{ $1 }
| type_constraint EQUAL seq_expr
{ let (t, t') = $1 in ghexp(Pexp_constraint($3, t, t')) }
;
strict_binding:
EQUAL seq_expr
{ $2 }
| labeled_simple_pattern fun_binding
{ let (l, o, p) = $1 in ghexp(Pexp_function(l, o, [p, $2])) }
| LPAREN TYPE LIDENT RPAREN fun_binding
{ mkexp(Pexp_newtype($3, $5)) }
;
match_cases:
pattern match_action { [$1, $2] }
| match_cases BAR pattern match_action { ($3, $4) :: $1 }
;
fun_def:
match_action { $1 }
| labeled_simple_pattern fun_def
{ let (l,o,p) = $1 in ghexp(Pexp_function(l, o, [p, $2])) }
| LPAREN TYPE LIDENT RPAREN fun_def
{ mkexp(Pexp_newtype($3, $5)) }
;
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
{ [$1,$3] }
| label_longident
{ [$1, exp_of_label $1] }
| lbl_expr_list SEMI label_longident EQUAL expr
{ ($3, $5) :: $1 }
| lbl_expr_list SEMI label_longident
{ ($3, exp_of_label $3) :: $1 }
;
field_expr_list:
label EQUAL expr
{ [$1,$3] }
| field_expr_list SEMI label EQUAL expr
{ ($3, $5) :: $1 }
;
expr_semi_list:
expr { [$1] }
| expr_semi_list SEMI expr { $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 %prec below_COMMA
{ mkpat(Ppat_tuple(List.rev $1)) }
| constr_longident pattern %prec prec_constr_appl
{ mkpat(Ppat_construct($1, Some $2, false)) }
| name_tag pattern %prec prec_constr_appl
{ mkpat(Ppat_variant($1, Some $2)) }
| pattern COLONCOLON pattern
{ mkpat(Ppat_construct(Lident "::", Some(ghpat(Ppat_tuple[$1;$3])),
false)) }
| LPAREN COLONCOLON RPAREN LPAREN pattern COMMA pattern RPAREN
{ mkpat(Ppat_construct(Lident "::", Some(ghpat(Ppat_tuple[$5;$7])),
false)) }
| pattern BAR pattern
{ mkpat(Ppat_or($1, $3)) }
| LAZY simple_pattern
{ mkpat(Ppat_lazy $2) }
;
simple_pattern:
val_ident %prec below_EQUAL
{ 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)) }
| name_tag
{ mkpat(Ppat_variant($1, None)) }
| SHARP type_longident
{ mkpat(Ppat_type $2) }
| LBRACE lbl_pattern_list record_pattern_end RBRACE
{ mkpat(Ppat_record(List.rev $2, $3)) }
| LBRACE lbl_pattern_list opt_semi error
{ unclosed "{" 1 "}" 4 }
| LBRACKET pattern_semi_list opt_semi RBRACKET
{ reloc_pat (mktailpat (List.rev $2)) }
| 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
{ reloc_pat $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)] }
| label_longident { [($1, pat_of_label $1)] }
| lbl_pattern_list SEMI label_longident EQUAL pattern { ($3, $5) :: $1 }
| lbl_pattern_list SEMI label_longident { ($3, pat_of_label $3) :: $1 }
;
record_pattern_end:
opt_semi { Closed }
| SEMI UNDERSCORE opt_semi { Open }
;
/* 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 (params, variance) = List.split $1 in
let (kind, private_flag, manifest) = $3 in
($2, {ptype_params = params;
ptype_cstrs = List.rev $4;
ptype_kind = kind;
ptype_private = private_flag;
ptype_manifest = manifest;
ptype_variance = variance;
ptype_loc = symbol_rloc()}) }
;
constraints:
constraints CONSTRAINT constrain { $3 :: $1 }
| /* empty */ { [] }
;
type_kind:
/*empty*/
{ (Ptype_abstract, Public, None) }
| EQUAL core_type
{ (Ptype_abstract, Public, Some $2) }
| EQUAL PRIVATE core_type
{ (Ptype_abstract, Private, Some $3) }
| EQUAL constructor_declarations
{ (Ptype_variant(List.rev $2), Public, None) }
| EQUAL PRIVATE constructor_declarations
{ (Ptype_variant(List.rev $3), Private, None) }
| EQUAL private_flag BAR constructor_declarations
{ (Ptype_variant(List.rev $4), $2, None) }
| EQUAL private_flag LBRACE label_declarations opt_semi RBRACE
{ (Ptype_record(List.rev $4), $2, None) }
| EQUAL core_type EQUAL private_flag opt_bar constructor_declarations
{ (Ptype_variant(List.rev $6), $4, Some $2) }
| EQUAL core_type EQUAL private_flag LBRACE label_declarations opt_semi RBRACE
{ (Ptype_record(List.rev $6), $4, Some $2) }
;
type_parameters:
/*empty*/ { [] }
| type_parameter { [$1] }
| LPAREN type_parameter_list RPAREN { List.rev $2 }
;
type_parameter:
type_variance QUOTE ident { $3, $1 }
;
type_variance:
/* empty */ { false, false }
| PLUS { true, false }
| MINUS { false, true }
;
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, symbol_rloc()) }
;
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 label COLON poly_type { ($2, $1, $4, symbol_rloc()) }
;
/* "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 with_type_binder core_type constraints
{ let params, variance = List.split $2 in
($3, Pwith_type {ptype_params = params;
ptype_cstrs = List.rev $6;
ptype_kind = Ptype_abstract;
ptype_manifest = Some $5;
ptype_private = $4;
ptype_variance = variance;
ptype_loc = symbol_rloc()}) }
/* used label_longident instead of type_longident to disallow
functor applications in type path */
| TYPE type_parameters label_longident COLONEQUAL core_type
{ let params, variance = List.split $2 in
($3, Pwith_typesubst {ptype_params = params;
ptype_cstrs = [];
ptype_kind = Ptype_abstract;
ptype_manifest = Some $5;
ptype_private = Public;
ptype_variance = variance;
ptype_loc = symbol_rloc()}) }
| MODULE mod_longident EQUAL mod_ext_longident
{ ($2, Pwith_module $4) }
| MODULE mod_longident COLONEQUAL mod_ext_longident
{ ($2, Pwith_modsubst $4) }
;
with_type_binder:
EQUAL { Public }
| EQUAL PRIVATE { Private }
;
/* Polymorphic types */
typevar_list:
QUOTE ident { [$2] }
| typevar_list QUOTE ident { $3 :: $1 }
;
poly_type:
core_type
{ mktyp(Ptyp_poly([], $1)) }
| typevar_list DOT core_type
{ mktyp(Ptyp_poly(List.rev $1, $3)) }
;
/* Core types */
core_type:
core_type2
{ $1 }
| core_type2 AS QUOTE ident
{ mktyp(Ptyp_alias($1, $4)) }
;
core_type2:
simple_core_type_or_tuple
{ $1 }
| QUESTION LIDENT COLON core_type2 MINUSGREATER core_type2
{ mktyp(Ptyp_arrow("?" ^ $2 ,
{ptyp_desc = Ptyp_constr(Ldot (Lident "*predef*", "option"), [$4]);
ptyp_loc = $4.ptyp_loc}, $6)) }
| OPTLABEL core_type2 MINUSGREATER core_type2
{ mktyp(Ptyp_arrow("?" ^ $1 ,
{ptyp_desc = Ptyp_constr(Ldot (Lident "*predef*", "option"), [$2]);
ptyp_loc = $2.ptyp_loc}, $4)) }
| LIDENT COLON core_type2 MINUSGREATER core_type2
{ mktyp(Ptyp_arrow($1, $3, $5)) }
| core_type2 MINUSGREATER core_type2
{ mktyp(Ptyp_arrow("", $1, $3)) }
;
simple_core_type:
simple_core_type2 %prec below_SHARP
{ $1 }
| LPAREN core_type_comma_list RPAREN %prec below_SHARP
{ match $2 with [sty] -> sty | _ -> raise Parse_error }
;
simple_core_type2:
QUOTE ident
{ mktyp(Ptyp_var $2) }
| UNDERSCORE
{ mktyp(Ptyp_any) }
| type_longident
{ mktyp(Ptyp_constr($1, [])) }
| simple_core_type2 type_longident
{ mktyp(Ptyp_constr($2, [$1])) }
| LPAREN core_type_comma_list RPAREN type_longident
{ mktyp(Ptyp_constr($4, List.rev $2)) }
| LESS meth_list GREATER
{ mktyp(Ptyp_object $2) }
| LESS GREATER
{ mktyp(Ptyp_object []) }
| SHARP class_longident opt_present
{ mktyp(Ptyp_class($2, [], $3)) }
| simple_core_type2 SHARP class_longident opt_present
{ mktyp(Ptyp_class($3, [$1], $4)) }
| LPAREN core_type_comma_list RPAREN SHARP class_longident opt_present
{ mktyp(Ptyp_class($5, List.rev $2, $6)) }
| LBRACKET tag_field RBRACKET
{ mktyp(Ptyp_variant([$2], true, None)) }
/* PR#3835: this is not LR(1), would need lookahead=2
| LBRACKET simple_core_type2 RBRACKET
{ mktyp(Ptyp_variant([$2], true, None)) }
*/
| LBRACKET BAR row_field_list RBRACKET
{ mktyp(Ptyp_variant(List.rev $3, true, None)) }
| LBRACKET row_field BAR row_field_list RBRACKET
{ mktyp(Ptyp_variant($2 :: List.rev $4, true, None)) }
| LBRACKETGREATER opt_bar row_field_list RBRACKET
{ mktyp(Ptyp_variant(List.rev $3, false, None)) }
| LBRACKETGREATER RBRACKET
{ mktyp(Ptyp_variant([], false, None)) }
| LBRACKETLESS opt_bar row_field_list RBRACKET
{ mktyp(Ptyp_variant(List.rev $3, true, Some [])) }
| LBRACKETLESS opt_bar row_field_list GREATER name_tag_list RBRACKET
{ mktyp(Ptyp_variant(List.rev $3, true, Some (List.rev $5))) }
| LPAREN MODULE package_type RPAREN
{ mktyp(Ptyp_package $3) }
;
package_type:
mty_longident { ($1, []) }
| mty_longident WITH package_type_cstrs { ($1, $3) }
;
package_type_cstr:
TYPE LIDENT EQUAL core_type { ($2, $4) }
;
package_type_cstrs:
package_type_cstr { [$1] }
| package_type_cstr AND package_type_cstrs { $1::$3 }
;
row_field_list:
row_field { [$1] }
| row_field_list BAR row_field { $3 :: $1 }
;
row_field:
tag_field { $1 }
| simple_core_type2 { Rinherit $1 }
;
tag_field:
name_tag OF opt_ampersand amper_type_list
{ Rtag ($1, $3, List.rev $4) }
| name_tag
{ Rtag ($1, true, []) }
;
opt_ampersand:
AMPERSAND { true }
| /* empty */ { false }
;
amper_type_list:
core_type { [$1] }
| amper_type_list AMPERSAND core_type { $3 :: $1 }
;
opt_present:
LBRACKETGREATER name_tag_list RBRACKET { List.rev $2 }
| /* empty */ { [] }
;
name_tag_list:
name_tag { [$1] }
| name_tag_list name_tag { $2 :: $1 }
;
simple_core_type_or_tuple:
simple_core_type { $1 }
| simple_core_type STAR core_type_list
{ mktyp(Ptyp_tuple($1 :: List.rev $3)) }
;
core_type_comma_list:
core_type { [$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 poly_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 }
| INT32 { Const_int32 $1 }
| INT64 { Const_int64 $1 }
| NATIVEINT { Const_nativeint $1 }
;
signed_constant:
constant { $1 }
| MINUS INT { Const_int(- $2) }
| MINUS FLOAT { Const_float("-" ^ $2) }
| MINUS INT32 { Const_int32(Int32.neg $2) }
| MINUS INT64 { Const_int64(Int64.neg $2) }
| MINUS NATIVEINT { Const_nativeint(Nativeint.neg $2) }
| PLUS INT { Const_int $2 }
| PLUS FLOAT { Const_float $2 }
| PLUS INT32 { Const_int32 $2 }
| PLUS INT64 { Const_int64 $2 }
| PLUS NATIVEINT { Const_nativeint $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 }
| BANG { "!" }
| PLUS { "+" }
| PLUSDOT { "+." }
| MINUS { "-" }
| MINUSDOT { "-." }
| STAR { "*" }
| EQUAL { "=" }
| LESS { "<" }
| GREATER { ">" }
| OR { "or" }
| BARBAR { "||" }
| AMPERSAND { "&" }
| AMPERAMPER { "&&" }
| COLONEQUAL { ":=" }
;
constr_ident:
UIDENT { $1 }
/* | LBRACKET RBRACKET { "[]" } */
| LPAREN RPAREN { "()" }
| COLONCOLON { "::" }
/* | LPAREN COLONCOLON RPAREN { "::" } */
| FALSE { "false" }
| TRUE { "true" }
;
val_longident:
val_ident { Lident $1 }
| mod_longident DOT val_ident { Ldot($1, $3) }
;
constr_longident:
mod_longident %prec below_DOT { $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) }
| SHARP ident FALSE { Ptop_dir($2, Pdir_bool false) }
| SHARP ident TRUE { Ptop_dir($2, Pdir_bool true) }
;
/* Miscellaneous */
name_tag:
BACKQUOTE ident { $2 }
;
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 }
;
override_flag:
/* empty */ { Fresh }
| BANG { Override }
;
opt_bar:
/* empty */ { () }
| BAR { () }
;
opt_semi:
| /* empty */ { () }
| SEMI { () }
;
subtractive:
| MINUS { "-" }
| MINUSDOT { "-." }
;
additive:
| PLUS { "+" }
| PLUSDOT { "+." }
;
%%
|