c0e6843240
and functional update (copy). The only creative piece of concrete syntax is that of the expression for functional updates: copy foo with record field = value end where "copy", "with", "record" and "end" are keywords.
845 lines
19 KiB
OCaml
845 lines
19 KiB
OCaml
%{
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(* START HEADER *)
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[@@@warning "-42"]
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open Region
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open AST
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(* END HEADER *)
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%}
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(* See [ParToken.mly] for the definition of tokens. *)
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(* Entry points *)
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%start program interactive_expr
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%type <AST.t> program
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%type <AST.expr> interactive_expr
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%%
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(* RULES *)
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(* Compound constructs *)
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par(X):
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LPAR X RPAR {
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let region = cover $1 $3
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and value = {
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lpar = $1;
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inside = $2;
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rpar = $3}
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in {region; value}
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}
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braces(X):
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LBRACE X RBRACE {
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let region = cover $1 $3
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and value = {
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lbrace = $1;
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inside = $2;
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rbrace = $3}
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in {region; value}
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}
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brackets(X):
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LBRACKET X RBRACKET {
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let region = cover $1 $3
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and value = {
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lbracket = $1;
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inside = $2;
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rbracket = $3}
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in {region; value}
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}
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(* Sequences
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Series of instances of the same syntactical category have often to
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be parsed, like lists of expressions, patterns etc. The simplest of
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all is the possibly empty sequence (series), parsed below by
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[seq]. The non-empty sequence is parsed by [nseq]. Note that the
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latter returns a pair made of the first parsed item (the parameter
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[X]) and the rest of the sequence (possibly empty). This way, the
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OCaml typechecker can keep track of this information along the
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static control-flow graph. The rule [sepseq] parses possibly empty
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sequences of items separated by some token (e.g., a comma), and
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rule [nsepseq] is for non-empty such sequences. See module [Utils]
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for the types corresponding to the semantic actions of those rules.
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*)
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(* Possibly empty sequence of items *)
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seq(X):
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(**) { [] }
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| X seq(X) { $1::$2 }
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(* Non-empty sequence of items *)
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nseq(X):
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X seq(X) { $1,$2 }
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(* Non-empty separated sequence of items *)
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nsepseq(X,Sep):
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X { $1, [] }
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| X Sep nsepseq(X,Sep) { let h,t = $3 in $1, ($2,h)::t }
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(* Possibly empy separated sequence of items *)
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sepseq(X,Sep):
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(**) { None }
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| nsepseq(X,Sep) { Some $1 }
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(* Inlines *)
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%inline var : Ident { $1 }
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%inline type_name : Ident { $1 }
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%inline fun_name : Ident { $1 }
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%inline field_name : Ident { $1 }
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%inline record_name : Ident { $1 }
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%inline map_name : Ident { $1 }
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(* Main *)
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program:
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nseq(declaration) EOF {
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{decl = $1; eof = $2}
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}
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declaration:
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type_decl { TypeDecl $1 }
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| const_decl { ConstDecl $1 }
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| storage_decl { StorageDecl $1 }
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| operations_decl { OpDecl $1 }
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| lambda_decl { LambdaDecl $1 }
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storage_decl:
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Storage var COLON type_expr option(SEMI) {
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let stop =
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match $5 with
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Some region -> region
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| None -> type_expr_to_region $4 in
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let region = cover $1 stop in
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let value = {
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kwd_storage = $1;
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name = $2;
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colon = $3;
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store_type = $4;
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terminator = $5}
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in {region; value}
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}
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operations_decl:
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Operations var COLON type_expr option(SEMI) {
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let stop =
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match $5 with
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Some region -> region
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| None -> type_expr_to_region $4 in
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let region = cover $1 stop in
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let value = {
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kwd_operations = $1;
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name = $2;
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colon = $3;
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op_type = $4;
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terminator = $5}
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in {region; value}
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}
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(* Type declarations *)
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type_decl:
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Type type_name Is type_expr option(SEMI) {
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let stop =
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match $5 with
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Some region -> region
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| None -> type_expr_to_region $4 in
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let region = cover $1 stop in
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let value = {
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kwd_type = $1;
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name = $2;
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kwd_is = $3;
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type_expr = $4;
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terminator = $5}
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in {region; value}}
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type_expr:
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cartesian { Prod $1 }
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| sum_type { Sum $1 }
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| record_type { Record $1 }
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cartesian:
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nsepseq(core_type,TIMES) {
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let region = nsepseq_to_region type_expr_to_region $1
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in {region; value=$1}
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}
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core_type:
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type_name {
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TAlias $1
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}
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| type_name type_tuple {
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let region = cover $1.region $2.region
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in TypeApp {region; value = $1,$2}
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}
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| par(type_expr) {
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ParType $1
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}
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type_tuple:
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par(nsepseq(type_name,COMMA)) { $1 }
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sum_type:
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nsepseq(variant,VBAR) {
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let region = nsepseq_to_region (fun x -> x.region) $1
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in {region; value = $1}
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}
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variant:
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Constr Of cartesian {
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let region = cover $1.region $3.region
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and value = {constr = $1; kwd_of = $2; product = $3}
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in {region; value}
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}
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record_type:
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Record
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nsepseq(field_decl,SEMI)
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End
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{
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let region = cover $1 $3
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and value = {kwd_record = $1; fields = $2; kwd_end = $3}
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in {region; value}
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}
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field_decl:
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field_name COLON type_expr {
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let stop = type_expr_to_region $3 in
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let region = cover $1.region stop
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and value = {field_name = $1; colon = $2; field_type = $3}
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in {region; value}
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}
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(* Function and procedure declarations *)
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lambda_decl:
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fun_decl { FunDecl $1 }
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| proc_decl { ProcDecl $1 }
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| entry_decl { EntryDecl $1 }
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fun_decl:
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Function fun_name parameters COLON type_expr Is
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seq(local_decl)
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block
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With expr option(SEMI) {
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let stop =
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match $11 with
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Some region -> region
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| None -> expr_to_region $10 in
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let region = cover $1 stop in
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let value = {
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kwd_function = $1;
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name = $2;
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param = $3;
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colon = $4;
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ret_type = $5;
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kwd_is = $6;
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local_decls = $7;
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block = $8;
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kwd_with = $9;
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return = $10;
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terminator = $11}
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in {region; value}
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}
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proc_decl:
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Procedure fun_name parameters Is
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seq(local_decl)
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block option(SEMI)
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{
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let stop =
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match $7 with
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Some region -> region
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| None -> $6.region in
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let region = cover $1 stop in
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let value = {
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kwd_procedure = $1;
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name = $2;
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param = $3;
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kwd_is = $4;
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local_decls = $5;
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block = $6;
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terminator = $7}
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in {region; value}
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}
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entry_decl:
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Entrypoint fun_name parameters Is
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seq(local_decl)
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block option(SEMI)
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{
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let stop =
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match $7 with
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Some region -> region
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| None -> $6.region in
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let region = cover $1 stop in
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let value = {
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kwd_entrypoint = $1;
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name = $2;
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param = $3;
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kwd_is = $4;
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local_decls = $5;
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block = $6;
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terminator = $7}
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in {region; value}
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}
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parameters:
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par(nsepseq(param_decl,SEMI)) { $1 }
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param_decl:
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Var var COLON type_expr {
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let stop = type_expr_to_region $4 in
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let region = cover $1 stop
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and value = {
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kwd_var = $1;
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var = $2;
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colon = $3;
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param_type = $4}
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in ParamVar {region; value}
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}
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| Const var COLON type_expr {
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let stop = type_expr_to_region $4 in
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let region = cover $1 stop
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and value = {
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kwd_const = $1;
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var = $2;
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colon = $3;
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param_type = $4}
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in ParamConst {region; value}
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}
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block:
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Begin
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instruction after_instr
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{
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let instrs, terminator, close = $3 in
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let region = cover $1 close
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and value = {
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opening = $1;
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instr = $2, instrs;
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terminator;
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close}
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in {region; value}
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}
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after_instr:
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SEMI instr_or_end {
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match $2 with
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`Some (instr, instrs, term, close) ->
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($1, instr)::instrs, term, close
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| `End close ->
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[], Some $1, close
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}
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| End {
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[], None, $1
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}
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instr_or_end:
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End {
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`End $1 }
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| instruction after_instr {
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let instrs, term, close = $2 in
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`Some ($1, instrs, term, close)
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}
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local_decl:
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lambda_decl { LocalLam $1 }
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| const_decl { LocalConst $1 }
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| var_decl { LocalVar $1 }
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const_decl:
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Const var COLON type_expr EQUAL expr option(SEMI) {
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let stop =
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match $7 with
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Some region -> region
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| None -> expr_to_region $6 in
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let region = cover $1 stop in
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let value = {
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kwd_const = $1;
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name = $2;
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colon = $3;
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const_type = $4;
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equal = $5;
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init = $6;
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terminator = $7}
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in {region; value}
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}
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var_decl:
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Var var COLON type_expr ASS expr option(SEMI) {
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let stop =
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match $7 with
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Some region -> region
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| None -> expr_to_region $6 in
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let region = cover $1 stop in
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let value = {
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kwd_var = $1;
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name = $2;
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colon = $3;
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var_type = $4;
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ass = $5;
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init = $6;
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terminator = $7}
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in {region; value}
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}
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instruction:
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single_instr { Single $1 }
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| block { Block $1 }
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single_instr:
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conditional { Cond $1 }
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| match_instr { Match $1 }
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| ass { Ass $1 }
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| loop { Loop $1 }
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| proc_call { ProcCall $1 }
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| Null { Null $1 }
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| fail_instr { Fail $1 }
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fail_instr:
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Fail expr {
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let region = cover $1 (expr_to_region $2)
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and value = {kwd_fail = $1; fail_expr = $2}
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in {region; value}}
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proc_call:
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fun_call { $1 }
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conditional:
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If expr Then instruction Else instruction {
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let region = cover $1 (instr_to_region $6) in
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let value = {
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kwd_if = $1;
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test = $2;
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kwd_then = $3;
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ifso = $4;
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kwd_else = $5;
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ifnot = $6}
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in {region; value}
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}
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match_instr:
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Match expr With option(VBAR) cases End {
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let region = cover $1 $6 in
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let value = {
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kwd_match = $1;
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expr = $2;
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kwd_with = $3;
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lead_vbar = $4;
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cases = $5;
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kwd_end = $6}
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in {region; value}
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}
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cases:
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nsepseq(case,VBAR) {
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let region = nsepseq_to_region (fun x -> x.region) $1
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in {region; value = $1}
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}
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case:
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pattern ARROW instruction {
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let region = cover (pattern_to_region $1) (instr_to_region $3)
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and value = {pattern = $1; arrow = $2; instr = $3}
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in {region; value}
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}
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|
ass:
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var ASS expr {
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let region = cover $1.region (expr_to_region $3)
|
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and value = {var = $1; ass = $2; expr = $3}
|
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in {region; value}
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}
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|
loop:
|
|
while_loop { $1 }
|
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| for_loop { $1 }
|
|
|
|
while_loop:
|
|
While expr block {
|
|
let region = cover $1 $3.region
|
|
and value = {
|
|
kwd_while = $1;
|
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cond = $2;
|
|
block = $3}
|
|
in While {region; value}
|
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}
|
|
|
|
for_loop:
|
|
For ass Down? To expr option(step_clause) block {
|
|
let region = cover $1 $7.region in
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let value =
|
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{
|
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kwd_for = $1;
|
|
ass = $2;
|
|
down = $3;
|
|
kwd_to = $4;
|
|
bound = $5;
|
|
step = $6;
|
|
block = $7;
|
|
}
|
|
in For (ForInt {region; value})
|
|
}
|
|
|
|
| For var option(arrow_clause) In expr block {
|
|
let region = cover $1 $6.region in
|
|
let value = {
|
|
kwd_for = $1;
|
|
var = $2;
|
|
bind_to = $3;
|
|
kwd_in = $4;
|
|
expr = $5;
|
|
block = $6}
|
|
in For (ForCollect {region; value})
|
|
}
|
|
|
|
step_clause:
|
|
Step expr { $1,$2 }
|
|
|
|
arrow_clause:
|
|
ARROW var { $1,$2 }
|
|
|
|
(* Expressions *)
|
|
|
|
interactive_expr:
|
|
expr EOF { $1 }
|
|
|
|
expr:
|
|
expr OR conj_expr {
|
|
let start = expr_to_region $1
|
|
and stop = expr_to_region $3 in
|
|
let region = cover start stop
|
|
and value = {op1 = $1; op = $2; op2 = $3} in
|
|
LogicExpr (BoolExpr (Or {region; value}))
|
|
}
|
|
| conj_expr { $1 }
|
|
|
|
conj_expr:
|
|
conj_expr AND comp_expr {
|
|
let start = expr_to_region $1
|
|
and stop = expr_to_region $3 in
|
|
let region = cover start stop
|
|
and value = {op1 = $1; op = $2; op2 = $3} in
|
|
LogicExpr (BoolExpr (And {region; value}))
|
|
}
|
|
| comp_expr { $1 }
|
|
|
|
comp_expr:
|
|
comp_expr LT cat_expr {
|
|
let start = expr_to_region $1
|
|
and stop = expr_to_region $3 in
|
|
let region = cover start stop
|
|
and value = {op1 = $1; op = $2; op2 = $3} in
|
|
LogicExpr (CompExpr (Lt {region; value}))
|
|
}
|
|
| comp_expr LEQ cat_expr {
|
|
let start = expr_to_region $1
|
|
and stop = expr_to_region $3 in
|
|
let region = cover start stop
|
|
and value = {op1 = $1; op = $2; op2 = $3}
|
|
in LogicExpr (CompExpr (Leq {region; value}))
|
|
}
|
|
| comp_expr GT cat_expr {
|
|
let start = expr_to_region $1
|
|
and stop = expr_to_region $3 in
|
|
let region = cover start stop
|
|
and value = {op1 = $1; op = $2; op2 = $3}
|
|
in LogicExpr (CompExpr (Gt {region; value}))
|
|
}
|
|
| comp_expr GEQ cat_expr {
|
|
let start = expr_to_region $1
|
|
and stop = expr_to_region $3 in
|
|
let region = cover start stop
|
|
and value = {op1 = $1; op = $2; op2 = $3}
|
|
in LogicExpr (CompExpr (Geq {region; value}))
|
|
}
|
|
| comp_expr EQUAL cat_expr {
|
|
let start = expr_to_region $1
|
|
and stop = expr_to_region $3 in
|
|
let region = cover start stop
|
|
and value = {op1 = $1; op = $2; op2 = $3}
|
|
in LogicExpr (CompExpr (Equal {region; value}))
|
|
}
|
|
| comp_expr NEQ cat_expr {
|
|
let start = expr_to_region $1
|
|
and stop = expr_to_region $3 in
|
|
let region = cover start stop
|
|
and value = {op1 = $1; op = $2; op2 = $3}
|
|
in LogicExpr (CompExpr (Neq {region; value}))
|
|
}
|
|
| cat_expr { $1 }
|
|
|
|
cat_expr:
|
|
cons_expr CAT cat_expr {
|
|
let start = expr_to_region $1
|
|
and stop = expr_to_region $3 in
|
|
let region = cover start stop
|
|
and value = {op1 = $1; op = $2; op2 = $3}
|
|
in StringExpr (Cat {region; value})
|
|
}
|
|
| cons_expr { $1 }
|
|
|
|
cons_expr:
|
|
add_expr CONS cons_expr {
|
|
let start = expr_to_region $1
|
|
and stop = expr_to_region $3 in
|
|
let region = cover start stop
|
|
and value = {op1 = $1; op = $2; op2 = $3}
|
|
in ListExpr (Cons {region; value})
|
|
}
|
|
| add_expr { $1 }
|
|
|
|
add_expr:
|
|
add_expr PLUS mult_expr {
|
|
let start = expr_to_region $1
|
|
and stop = expr_to_region $3 in
|
|
let region = cover start stop
|
|
and value = {op1 = $1; op = $2; op2 = $3}
|
|
in ArithExpr (Add {region; value})
|
|
}
|
|
| add_expr MINUS mult_expr {
|
|
let start = expr_to_region $1
|
|
and stop = expr_to_region $3 in
|
|
let region = cover start stop
|
|
and value = {op1 = $1; op = $2; op2 = $3}
|
|
in ArithExpr (Sub {region; value})
|
|
}
|
|
| mult_expr { $1 }
|
|
|
|
mult_expr:
|
|
mult_expr TIMES unary_expr {
|
|
let start = expr_to_region $1
|
|
and stop = expr_to_region $3 in
|
|
let region = cover start stop
|
|
and value = {op1 = $1; op = $2; op2 = $3}
|
|
in ArithExpr (Mult {region; value})
|
|
}
|
|
| mult_expr SLASH unary_expr {
|
|
let start = expr_to_region $1
|
|
and stop = expr_to_region $3 in
|
|
let region = cover start stop
|
|
and value = {op1 = $1; op = $2; op2 = $3}
|
|
in ArithExpr (Div {region; value})
|
|
}
|
|
| mult_expr Mod unary_expr {
|
|
let start = expr_to_region $1
|
|
and stop = expr_to_region $3 in
|
|
let region = cover start stop
|
|
and value = {op1 = $1; op = $2; op2 = $3}
|
|
in ArithExpr (Mod {region; value})
|
|
}
|
|
| unary_expr { $1 }
|
|
|
|
unary_expr:
|
|
MINUS core_expr {
|
|
let stop = expr_to_region $2 in
|
|
let region = cover $1 stop
|
|
and value = {op = $1; op1 = $2}
|
|
in ArithExpr (Neg {region; value})
|
|
}
|
|
| Not core_expr {
|
|
let stop = expr_to_region $2 in
|
|
let region = cover $1 stop
|
|
and value = {op = $1; op1 = $2} in
|
|
LogicExpr (BoolExpr (Not {region; value}))
|
|
}
|
|
| core_expr { $1 }
|
|
|
|
core_expr:
|
|
Int { ArithExpr (Int $1) }
|
|
| var { Var $1 }
|
|
| String { StringExpr (String $1) }
|
|
| Bytes { Bytes $1 }
|
|
| C_False { LogicExpr (BoolExpr (False $1)) }
|
|
| C_True { LogicExpr (BoolExpr (True $1)) }
|
|
| C_Unit { Unit $1 }
|
|
| tuple { Tuple $1 }
|
|
| list_expr { ListExpr (List $1) }
|
|
| empty_list { ListExpr (EmptyList $1) }
|
|
| set_expr { SetExpr (Set $1) }
|
|
| empty_set { SetExpr (EmptySet $1) }
|
|
| none_expr { ConstrExpr (NoneExpr $1) }
|
|
| fun_call { FunCall $1 }
|
|
| Constr arguments {
|
|
let region = cover $1.region $2.region in
|
|
ConstrExpr (ConstrApp {region; value = $1,$2})
|
|
}
|
|
| C_Some arguments {
|
|
let region = cover $1 $2.region in
|
|
ConstrExpr (SomeApp {region; value = $1,$2})
|
|
}
|
|
| map_name DOT brackets(expr) {
|
|
let region = cover $1.region $3.region in
|
|
let value = {
|
|
map_name = $1;
|
|
selector = $2;
|
|
index = $3}
|
|
in MapLookUp {region; value}
|
|
}
|
|
| record_expr { RecordExpr $1 }
|
|
|
|
record_expr:
|
|
record_injection { RecordInj $1 }
|
|
| record_projection { RecordProj $1 }
|
|
| record_copy { RecordCopy $1 }
|
|
|
|
record_injection:
|
|
Record
|
|
field_assignment after_field
|
|
{
|
|
let fields, terminator, close = $3 in
|
|
let region = cover $1 close
|
|
and value = {
|
|
opening = $1;
|
|
fields = $2, fields;
|
|
terminator;
|
|
close}
|
|
in {region; value}
|
|
}
|
|
|
|
after_field:
|
|
SEMI field_or_end {
|
|
match $2 with
|
|
`Some (field, fields, term, close) ->
|
|
($1, field)::fields, term, close
|
|
| `End close ->
|
|
[], Some $1, close
|
|
}
|
|
| End {
|
|
[], None, $1
|
|
}
|
|
|
|
field_or_end:
|
|
End {
|
|
`End $1 }
|
|
| field_assignment after_field {
|
|
let fields, term, close = $2 in
|
|
`Some ($1, fields, term, close)
|
|
}
|
|
|
|
field_assignment:
|
|
field_name EQUAL expr {
|
|
let region = cover $1.region (expr_to_region $3)
|
|
and value = {
|
|
field_name = $1;
|
|
equal = $2;
|
|
field_expr = $3}
|
|
in {region; value}
|
|
}
|
|
|
|
record_projection:
|
|
record_name DOT field_name {
|
|
let region = cover $1.region $3.region in
|
|
let value = {
|
|
record_name = $1;
|
|
selector = $2;
|
|
field_name = $3}
|
|
in {region; value}
|
|
}
|
|
|
|
record_copy:
|
|
Copy record_name With record_injection {
|
|
let region = cover $1 $4.region in
|
|
let value = {
|
|
kwd_copy = $1;
|
|
record_name = $2;
|
|
kwd_with = $3;
|
|
delta = $4}
|
|
in {region; value}
|
|
}
|
|
|
|
fun_call:
|
|
fun_name arguments {
|
|
let region = cover $1.region $2.region
|
|
in {region; value = $1,$2}
|
|
}
|
|
|
|
tuple:
|
|
par(nsepseq(expr,COMMA)) { $1 }
|
|
|
|
arguments:
|
|
tuple { $1 }
|
|
|
|
list_expr:
|
|
brackets(nsepseq(expr,COMMA)) { $1 }
|
|
|
|
empty_list:
|
|
par(typed_empty_list) { $1 }
|
|
|
|
typed_empty_list:
|
|
LBRACKET RBRACKET COLON type_expr {
|
|
{lbracket = $1;
|
|
rbracket = $2;
|
|
colon = $3;
|
|
list_type = $4}
|
|
}
|
|
|
|
set_expr:
|
|
braces(nsepseq(expr,COMMA)) { $1 }
|
|
|
|
empty_set:
|
|
par(typed_empty_set) { $1 }
|
|
|
|
typed_empty_set:
|
|
LBRACE RBRACE COLON type_expr {
|
|
{lbrace = $1;
|
|
rbrace = $2;
|
|
colon = $3;
|
|
set_type = $4}
|
|
}
|
|
|
|
none_expr:
|
|
par(typed_none_expr) { $1 }
|
|
|
|
typed_none_expr:
|
|
C_None COLON type_expr {
|
|
{c_None = $1;
|
|
colon = $2;
|
|
opt_type = $3}
|
|
}
|
|
|
|
(* Patterns *)
|
|
|
|
pattern:
|
|
nsepseq(core_pattern,CONS) {
|
|
let region = nsepseq_to_region pattern_to_region $1
|
|
in PCons {region; value=$1}
|
|
}
|
|
|
|
core_pattern:
|
|
var { PVar $1 }
|
|
| WILD { PWild $1 }
|
|
| Int { PInt $1 }
|
|
| String { PString $1 }
|
|
| C_Unit { PUnit $1 }
|
|
| C_False { PFalse $1 }
|
|
| C_True { PTrue $1 }
|
|
| C_None { PNone $1 }
|
|
| list_patt { PList $1 }
|
|
| tuple_patt { PTuple $1 }
|
|
| C_Some par(core_pattern) {
|
|
let region = cover $1 $2.region
|
|
in PSome {region; value = $1,$2}
|
|
}
|
|
|
|
list_patt:
|
|
brackets(sepseq(core_pattern,COMMA)) { Sugar $1 }
|
|
| par(cons_pattern) { Raw $1 }
|
|
|
|
cons_pattern:
|
|
core_pattern CONS pattern { $1,$2,$3 }
|
|
|
|
tuple_patt:
|
|
par(nsepseq(core_pattern,COMMA)) { $1 }
|