%{ (* START HEADER *) [@@@warning "-42"] open Region open AST (* END HEADER *) %} (* See [ParToken.mly] for the definition of tokens. *) (* Entry points *) %start program interactive_expr %type program %type interactive_expr %% (* RULES *) (* The rule [series(Item)] parses a list of [Item] separated by semi-colons and optionally terminated by a semi-colon, then the keyword [End]. *) series(Item): Item after_item(Item) { $1,$2 } after_item(Item): SEMI item_or_end(Item) { match $2 with `Some (item, items, term, close) -> ($1, item)::items, term, close | `End close -> [], Some $1, close } | End { [], None, $1 } item_or_end(Item): End { `End $1 } | series(Item) { let item, (items, term, close) = $1 in `Some (item, items, term, close) } (* Compound constructs *) par(X): LPAR X RPAR { let region = cover $1 $3 and value = { lpar = $1; inside = $2; rpar = $3} in {region; value} } braces(X): LBRACE X RBRACE { let region = cover $1 $3 and value = { lbrace = $1; inside = $2; rbrace = $3} in {region; value} } brackets(X): LBRACKET X RBRACKET { let region = cover $1 $3 and value = { lbracket = $1; inside = $2; rbracket = $3} in {region; value} } (* Sequences Series of instances of the same syntactical category have often to be parsed, like lists of expressions, patterns etc. The simplest of all is the possibly empty sequence (series), parsed below by [seq]. The non-empty sequence is parsed by [nseq]. Note that the latter returns a pair made of the first parsed item (the parameter [X]) and the rest of the sequence (possibly empty). This way, the OCaml typechecker can keep track of this information along the static control-flow graph. The rule [sepseq] parses possibly empty sequences of items separated by some token (e.g., a comma), and rule [nsepseq] is for non-empty such sequences. See module [Utils] for the types corresponding to the semantic actions of those rules. *) (* Possibly empty sequence of items *) seq(X): (**) { [] } | X seq(X) { $1::$2 } (* Non-empty sequence of items *) nseq(X): X seq(X) { $1,$2 } (* Non-empty separated sequence of items *) nsepseq(X,Sep): X { $1, [] } | X Sep nsepseq(X,Sep) { let h,t = $3 in $1, ($2,h)::t } (* Possibly empy separated sequence of items *) sepseq(X,Sep): (**) { None } | nsepseq(X,Sep) { Some $1 } (* Inlines *) %inline var : Ident { $1 } %inline type_name : Ident { $1 } %inline fun_name : Ident { $1 } %inline field_name : Ident { $1 } %inline record_name : Ident { $1 } %inline map_name : Ident { $1 } (* Main *) program: nseq(declaration) EOF { {decl = $1; eof = $2} } declaration: type_decl { TypeDecl $1 } | const_decl { ConstDecl $1 } | lambda_decl { LambdaDecl $1 } (* Type declarations *) type_decl: Type type_name Is type_expr option(SEMI) { let stop = match $5 with Some region -> region | None -> type_expr_to_region $4 in let region = cover $1 stop in let value = { kwd_type = $1; name = $2; kwd_is = $3; type_expr = $4; terminator = $5} in {region; value}} type_expr: cartesian { Prod $1 } | sum_type { Sum $1 } | record_type { Record $1 } cartesian: nsepseq(core_type,TIMES) { let region = nsepseq_to_region type_expr_to_region $1 in {region; value=$1} } core_type: type_name { TAlias $1 } | type_name type_tuple { let region = cover $1.region $2.region in TypeApp {region; value = $1,$2} } | Map type_tuple { let region = cover $1 $2.region in let value = {value="map"; region=$1} in TypeApp {region; value = value, $2} } | par(type_expr) { ParType $1 } type_tuple: par(nsepseq(type_expr,COMMA)) { $1 } sum_type: nsepseq(variant,VBAR) { let region = nsepseq_to_region (fun x -> x.region) $1 in {region; value = $1} } variant: Constr Of cartesian { let region = cover $1.region $3.region and value = {constr = $1; kwd_of = $2; product = $3} in {region; value} } record_type: Record nsepseq(field_decl,SEMI) End { let region = cover $1 $3 and value = {kwd_record = $1; fields = $2; kwd_end = $3} in {region; value} } field_decl: field_name COLON type_expr { let stop = type_expr_to_region $3 in let region = cover $1.region stop and value = {field_name = $1; colon = $2; field_type = $3} in {region; value} } (* Function and procedure declarations *) lambda_decl: fun_decl { FunDecl $1 } | proc_decl { ProcDecl $1 } | entry_decl { EntryDecl $1 } fun_decl: Function fun_name parameters COLON type_expr Is seq(local_decl) block With expr option(SEMI) { let stop = match $11 with Some region -> region | None -> expr_to_region $10 in let region = cover $1 stop in let value = { kwd_function = $1; name = $2; param = $3; colon = $4; ret_type = $5; kwd_is = $6; local_decls = $7; block = $8; kwd_with = $9; return = $10; terminator = $11} in {region; value} } entry_decl: Entrypoint fun_name entry_params COLON type_expr Is seq(local_decl) block With expr option(SEMI) { let stop = match $11 with Some region -> region | None -> expr_to_region $10 in let region = cover $1 stop in let value = { kwd_entrypoint = $1; name = $2; param = $3; colon = $4; ret_type = $5; kwd_is = $6; local_decls = $7; block = $8; kwd_with = $9; return = $10; terminator = $11} in {region; value} } entry_params: par(nsepseq(entry_param_decl,SEMI)) { $1 } proc_decl: Procedure fun_name parameters Is seq(local_decl) block option(SEMI) { let stop = match $7 with Some region -> region | None -> $6.region in let region = cover $1 stop in let value = { kwd_procedure = $1; name = $2; param = $3; kwd_is = $4; local_decls = $5; block = $6; terminator = $7} in {region; value} } parameters: par(nsepseq(param_decl,SEMI)) { $1 } param_decl: Var var COLON type_expr { let stop = type_expr_to_region $4 in let region = cover $1 stop and value = { kwd_var = $1; var = $2; colon = $3; param_type = $4} in ParamVar {region; value} } | Const var COLON type_expr { let stop = type_expr_to_region $4 in let region = cover $1 stop and value = { kwd_const = $1; var = $2; colon = $3; param_type = $4} in ParamConst {region; value} } entry_param_decl: param_decl { match $1 with ParamConst const -> EntryConst const | ParamVar var -> EntryVar var } | Storage var COLON type_expr { let stop = type_expr_to_region $4 in let region = cover $1 stop and value = { kwd_storage = $1; var = $2; colon = $3; storage_type = $4} in EntryStore {region; value} } block: Begin series(instruction) { let first, (others, terminator, close) = $2 in let region = cover $1 close and value = { opening = $1; instr = first, others; terminator; close} in {region; value} } local_decl: lambda_decl { LocalLam $1 } | const_decl { LocalConst $1 } | var_decl { LocalVar $1 } const_decl: Const var COLON type_expr EQUAL expr option(SEMI) { let stop = match $7 with Some region -> region | None -> expr_to_region $6 in let region = cover $1 stop in let value = { kwd_const = $1; name = $2; colon = $3; const_type = $4; equal = $5; init = $6; terminator = $7} in {region; value} } var_decl: Var var COLON type_expr ASS extended_expr option(SEMI) { let stop = match $7 with Some region -> region | None -> $6.region in let region = cover $1 stop in let init = match $6.value with `Expr e -> e | `EList (lbracket, rbracket) -> let region = $6.region and value = { lbracket; rbracket; colon = Region.ghost; list_type = $4} in let value = { lpar = Region.ghost; inside = value; rpar = Region.ghost} in ListExpr (EmptyList {region; value}) | `ENone region -> let value = { lpar = Region.ghost; inside = { c_None = region; colon = Region.ghost; opt_type = $4}; rpar = Region.ghost} in ConstrExpr (NoneExpr {region; value}) in (* | `EMap inj ->*) let value = { kwd_var = $1; name = $2; colon = $3; var_type = $4; assign = $5; init; terminator = $7} in {region; value} } extended_expr: expr { {region = expr_to_region $1; value = `Expr $1} } | LBRACKET RBRACKET { {region = cover $1 $2; value = `EList ($1,$2)} } | C_None { {region = $1; value = `ENone $1} } (* | map_injection { {region = $1.region; value = `EMap $1} } *) instruction: single_instr { Single $1 } | block { Block $1 } single_instr: conditional { Cond $1 } | case_instr { Case $1 } | assignment { Assign $1 } | loop { Loop $1 } | proc_call { ProcCall $1 } | fail_instr { Fail $1 } | Skip { Skip $1 } | record_patch { RecordPatch $1 } | map_patch { MapPatch $1 } map_patch: Map map_name With map_injection { let region = cover $1 $4.region in let value = { kwd_patch = $1; map_name = $2; kwd_with = $3; delta = $4} in {region; value} } map_injection: Map series(binding) { let first, (others, terminator, close) = $2 in let region = cover $1 close and value = { opening = $1; bindings = first, others; terminator; close} in {region; value} } binding: expr ARROW expr { let start = expr_to_region $1 and stop = expr_to_region $3 in let region = cover start stop and value = { source = $1; arrow = $2; image = $3} in {region; value} } record_patch: Patch record_name With record_injection { let region = cover $1 $4.region in let value = { kwd_patch = $1; record_name = $2; kwd_with = $3; delta = $4} in {region; value} } fail_instr: Fail expr { let region = cover $1 (expr_to_region $2) and value = {kwd_fail = $1; fail_expr = $2} in {region; value}} proc_call: fun_call { $1 } conditional: If expr Then instruction Else instruction { let region = cover $1 (instr_to_region $6) in let value = { kwd_if = $1; test = $2; kwd_then = $3; ifso = $4; kwd_else = $5; ifnot = $6} in {region; value} } case_instr: Case expr Of option(VBAR) cases End { let region = cover $1 $6 in let value = { kwd_case = $1; expr = $2; kwd_of = $3; lead_vbar = $4; cases = $5; kwd_end = $6} in {region; value} } cases: nsepseq(case,VBAR) { let region = nsepseq_to_region (fun x -> x.region) $1 in {region; value = $1} } case: pattern ARROW instruction { let region = cover (pattern_to_region $1) (instr_to_region $3) and value = {pattern = $1; arrow = $2; instr = $3} in {region; value} } assignment: var ASS expr { let region = cover $1.region (expr_to_region $3) and value = {var = $1; assign = $2; expr = $3} in {region; value} } loop: while_loop { $1 } | for_loop { $1 } while_loop: While expr block { let region = cover $1 $3.region and value = { kwd_while = $1; cond = $2; block = $3} in While {region; value} } for_loop: For assignment Down? To expr option(step_clause) block { let region = cover $1 $7.region in let value = { kwd_for = $1; assign = $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 = {arg1 = $1; op = $2; arg2 = $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 = {arg1 = $1; op = $2; arg2 = $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 = {arg1 = $1; op = $2; arg2 = $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 = {arg1 = $1; op = $2; arg2 = $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 = {arg1 = $1; op = $2; arg2 = $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 = {arg1 = $1; op = $2; arg2 = $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 = {arg1 = $1; op = $2; arg2 = $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 = {arg1 = $1; op = $2; arg2 = $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 = {arg1 = $1; op = $2; arg2 = $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 = {arg1 = $1; op = $2; arg2 = $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 = {arg1 = $1; op = $2; arg2 = $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 = {arg1 = $1; op = $2; arg2 = $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 = {arg1 = $1; op = $2; arg2 = $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 = {arg1 = $1; op = $2; arg2 = $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 = {arg1 = $1; op = $2; arg2 = $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; arg = $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; arg = $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 } | map_expr { MapExpr $1 } | record_expr { RecordExpr $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_expr: map_selection { MapLookUp $1 } map_selection: map_name brackets(expr) { let region = cover $1.region $2.region in let value = { path = Name $1; index = $2} in {region; value} } | record_projection brackets(expr) { let region = cover $1.region $2.region in let value = { path = RecordPath $1; index = $2} in {region; value} } record_expr: record_injection { RecordInj $1 } | record_projection { RecordProj $1 } record_injection: Record series(field_assignment) { let first, (others, terminator, close) = $2 in let region = cover $1 close and value = { opening = $1; fields = first, others; terminator; close} in {region; value} } 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 nsepseq(field_name,DOT) { let stop = nsepseq_to_region (fun x -> x.region) $3 in let region = cover $1.region stop and value = { record_name = $1; selector = $2; field_path = $3} 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 }