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catala/compiler/surface/desugaring.ml
Denis Merigoux a52cc0d881
Move fix to lexer as suggested by @altgr
2022-05-06 10:29:39 +02:00

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(* This file is part of the Catala compiler, a specification language for tax
and social benefits computation rules. Copyright (C) 2020 Inria, contributor:
Nicolas Chataing <nicolas.chataing@ens.fr> Denis Merigoux
<denis.merigoux@inria.fr>
Licensed under the Apache License, Version 2.0 (the "License"); you may not
use this file except in compliance with the License. You may obtain a copy of
the License at
http://www.apache.org/licenses/LICENSE-2.0
Unless required by applicable law or agreed to in writing, software
distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
License for the specific language governing permissions and limitations under
the License. *)
open Utils
(** Translation from {!module: Surface.Ast} to {!module: Desugaring.Ast}.
- Removes syntactic sugars
- Separate code from legislation *)
(** {1 Translating expressions} *)
let translate_op_kind (k : Ast.op_kind) : Dcalc.Ast.op_kind =
match k with
| KInt -> KInt
| KDec -> KRat
| KMoney -> KMoney
| KDate -> KDate
| KDuration -> KDuration
let translate_binop (op : Ast.binop) : Dcalc.Ast.binop =
match op with
| And -> And
| Or -> Or
| Xor -> Xor
| Add l -> Add (translate_op_kind l)
| Sub l -> Sub (translate_op_kind l)
| Mult l -> Mult (translate_op_kind l)
| Div l -> Div (translate_op_kind l)
| Lt l -> Lt (translate_op_kind l)
| Lte l -> Lte (translate_op_kind l)
| Gt l -> Gt (translate_op_kind l)
| Gte l -> Gte (translate_op_kind l)
| Eq -> Eq
| Neq -> Neq
| Concat -> Concat
let translate_unop (op : Ast.unop) : Dcalc.Ast.unop =
match op with Not -> Not | Minus l -> Minus (translate_op_kind l)
(** The two modules below help performing operations on map with the {!type:
Bindlib.box}. Indeed, Catala uses the {{:https://lepigre.fr/ocaml-bindlib/}
Bindlib} library to represent bound variables in the AST. In this
translation, bound variables are used to represent function parameters or
pattern macthing bindings. *)
module LiftStructFieldMap = Bindlib.Lift (Scopelang.Ast.StructFieldMap)
module LiftEnumConstructorMap = Bindlib.Lift (Scopelang.Ast.EnumConstructorMap)
let disambiguate_constructor
(ctxt : Name_resolution.context)
(constructor : (string Pos.marked option * string Pos.marked) list)
(pos : Pos.t) : Scopelang.Ast.EnumName.t * Scopelang.Ast.EnumConstructor.t =
let enum, constructor =
match constructor with
| [ c ] -> c
| _ ->
Errors.raise_spanned_error pos
"The deep pattern matching syntactic sugar is not yet supported"
in
let possible_c_uids =
try
Desugared.Ast.IdentMap.find (Pos.unmark constructor)
ctxt.constructor_idmap
with Not_found ->
Errors.raise_spanned_error
(Pos.get_position constructor)
"The name of this constructor has not been defined before, maybe it is \
a typo?"
in
match enum with
| None ->
if Scopelang.Ast.EnumMap.cardinal possible_c_uids > 1 then
Errors.raise_spanned_error
(Pos.get_position constructor)
"This constructor name is ambiguous, it can belong to %a. \
Disambiguate it by prefixing it with the enum name."
(Format.pp_print_list
~pp_sep:(fun fmt () -> Format.fprintf fmt " or ")
(fun fmt (s_name, _) ->
Format.fprintf fmt "%a" Scopelang.Ast.EnumName.format_t s_name))
(Scopelang.Ast.EnumMap.bindings possible_c_uids);
Scopelang.Ast.EnumMap.choose possible_c_uids
| Some enum -> (
try
(* The path is fully qualified *)
let e_uid =
Desugared.Ast.IdentMap.find (Pos.unmark enum) ctxt.enum_idmap
in
try
let c_uid = Scopelang.Ast.EnumMap.find e_uid possible_c_uids in
(e_uid, c_uid)
with Not_found ->
Errors.raise_spanned_error pos "Enum %s does not contain case %s"
(Pos.unmark enum) (Pos.unmark constructor)
with Not_found ->
Errors.raise_spanned_error (Pos.get_position enum)
"Enum %s has not been defined before" (Pos.unmark enum))
(** Usage: [translate_expr scope ctxt expr]
Translates [expr] into its desugared equivalent. [scope] is used to
disambiguate the scope and subscopes variables than occur in the expresion *)
let rec translate_expr
(scope : Scopelang.Ast.ScopeName.t)
(inside_definition_of : Desugared.Ast.ScopeDef.t Pos.marked option)
(ctxt : Name_resolution.context)
((expr, pos) : Ast.expression Pos.marked) :
Desugared.Ast.expr Pos.marked Bindlib.box =
let scope_ctxt = Scopelang.Ast.ScopeMap.find scope ctxt.scopes in
let rec_helper = translate_expr scope inside_definition_of ctxt in
match expr with
| Binop
( (Ast.And, _pos_op),
( TestMatchCase (e1_sub, ((constructors, Some binding), pos_pattern)),
_pos_e1 ),
e2 ) ->
(* This sugar corresponds to [e is P x && e'] and should desugar to [match
e with P x -> e' | _ -> false] *)
let enum_uid, c_uid =
disambiguate_constructor ctxt constructors pos_pattern
in
let cases =
Scopelang.Ast.EnumConstructorMap.mapi
(fun c_uid' tau ->
if Scopelang.Ast.EnumConstructor.compare c_uid c_uid' <> 0 then
let nop_var = Desugared.Ast.Var.make ("_", pos) in
Bindlib.unbox
(Desugared.Ast.make_abs [| nop_var |]
(Bindlib.box
(Desugared.Ast.ELit (Dcalc.Ast.LBool false), pos))
pos [ tau ] pos)
else
let ctxt, binding_var =
Name_resolution.add_def_local_var ctxt binding
in
let e2 = translate_expr scope inside_definition_of ctxt e2 in
Bindlib.unbox
(Desugared.Ast.make_abs [| binding_var |] e2 pos [ tau ] pos))
(Scopelang.Ast.EnumMap.find enum_uid ctxt.enums)
in
Bindlib.box_apply
(fun e1_sub -> (Desugared.Ast.EMatch (e1_sub, enum_uid, cases), pos))
(translate_expr scope inside_definition_of ctxt e1_sub)
| IfThenElse (e_if, e_then, e_else) ->
Bindlib.box_apply3
(fun e_if e_then e_else ->
(Desugared.Ast.EIfThenElse (e_if, e_then, e_else), pos))
(rec_helper e_if) (rec_helper e_then) (rec_helper e_else)
| Binop (op, e1, e2) ->
let op_term =
Pos.same_pos_as
(Desugared.Ast.EOp (Dcalc.Ast.Binop (translate_binop (Pos.unmark op))))
op
in
Bindlib.box_apply2
(fun e1 e2 -> (Desugared.Ast.EApp (op_term, [ e1; e2 ]), pos))
(rec_helper e1) (rec_helper e2)
| Unop (op, e) ->
let op_term =
Pos.same_pos_as
(Desugared.Ast.EOp (Dcalc.Ast.Unop (translate_unop (Pos.unmark op))))
op
in
Bindlib.box_apply
(fun e -> (Desugared.Ast.EApp (op_term, [ e ]), pos))
(rec_helper e)
| Literal l ->
let untyped_term =
match l with
| LNumber ((Int i, _), None) ->
Desugared.Ast.ELit (Dcalc.Ast.LInt (Runtime.integer_of_string i))
| LNumber ((Int i, _), Some (Percent, _)) ->
Desugared.Ast.ELit
(Dcalc.Ast.LRat
Runtime.(decimal_of_string i /& decimal_of_string "100"))
| LNumber ((Dec (i, f), _), None) ->
Desugared.Ast.ELit
(Dcalc.Ast.LRat Runtime.(decimal_of_string (i ^ "." ^ f)))
| LNumber ((Dec (i, f), _), Some (Percent, _)) ->
Desugared.Ast.ELit
(Dcalc.Ast.LRat
Runtime.(
decimal_of_string (i ^ "." ^ f) /& decimal_of_string "100"))
| LBool b -> Desugared.Ast.ELit (Dcalc.Ast.LBool b)
| LMoneyAmount i ->
Desugared.Ast.ELit
(Dcalc.Ast.LMoney
Runtime.(
money_of_cents_integer
(integer_of_string i.money_amount_units
*! integer_of_int 100
+! integer_of_string i.money_amount_cents)))
| LNumber ((Int i, _), Some (Year, _)) ->
Desugared.Ast.ELit
(Dcalc.Ast.LDuration
(Runtime.duration_of_numbers (int_of_string i) 0 0))
| LNumber ((Int i, _), Some (Month, _)) ->
Desugared.Ast.ELit
(Dcalc.Ast.LDuration
(Runtime.duration_of_numbers 0 (int_of_string i) 0))
| LNumber ((Int i, _), Some (Day, _)) ->
Desugared.Ast.ELit
(Dcalc.Ast.LDuration
(Runtime.duration_of_numbers 0 0 (int_of_string i)))
| LNumber ((Dec (_, _), _), Some ((Year | Month | Day), _)) ->
Errors.raise_spanned_error pos
"Impossible to specify decimal amounts of days, months or years"
| LDate date ->
if Pos.unmark date.literal_date_month > 12 then
Errors.raise_spanned_error
(Pos.get_position date.literal_date_month)
"There is an error in this date: the month number is bigger \
than 12";
if Pos.unmark date.literal_date_day > 31 then
Errors.raise_spanned_error
(Pos.get_position date.literal_date_day)
"There is an error in this date: the day number is bigger than \
31";
Desugared.Ast.ELit
(Dcalc.Ast.LDate
(try
Runtime.date_of_numbers
(Pos.unmark date.literal_date_year)
(Pos.unmark date.literal_date_month)
(Pos.unmark date.literal_date_day)
with Runtime.ImpossibleDate ->
Errors.raise_spanned_error pos
"There is an error in this date, it does not correspond \
to a correct calendar day"))
in
Bindlib.box (untyped_term, pos)
| Ident x -> (
(* first we check whether this is a local var, then we resort to
scope-wide variables *)
match Desugared.Ast.IdentMap.find_opt x ctxt.local_var_idmap with
| None -> (
match Desugared.Ast.IdentMap.find_opt x scope_ctxt.var_idmap with
| Some uid ->
(* If the referenced variable has states, then here are the rules
to desambiguate. In general, only the last state can be
referenced. Except if defining a state of the same variable,
then it references the previous state in the chain. *)
let x_sig = Desugared.Ast.ScopeVarMap.find uid ctxt.var_typs in
let x_state =
match x_sig.var_sig_states_list with
| [] -> None
| states -> (
match inside_definition_of with
| Some (Desugared.Ast.ScopeDef.Var (x'_uid, sx'), _)
when Desugared.Ast.ScopeVar.compare uid x'_uid = 0 -> (
match sx' with
| None ->
failwith
"inconsistent state: inside a definition of a \
variable with no state but variable has states"
| Some inside_def_state ->
if
Desugared.Ast.StateName.compare inside_def_state
(List.hd states)
= 0
then
Errors.raise_spanned_error pos
"It is impossible to refer to the variable you \
are defining when defining its first state."
else
(* Tricky: we have to retrieve in the list the
previous state with respect to the state that
we are defining. *)
let correct_state = ref None in
ignore
(List.fold_left
(fun previous_state state ->
if
Desugared.Ast.StateName.compare
inside_def_state state
= 0
then correct_state := previous_state;
Some state)
None states);
!correct_state)
| _ ->
(* we take the last state in the chain *)
Some (List.hd (List.rev states)))
in
Bindlib.box
(Desugared.Ast.ELocation (ScopeVar ((uid, pos), x_state)), pos)
| None ->
Name_resolution.raise_unknown_identifier
"for a local or scope-wide variable" (x, pos))
| Some uid ->
Desugared.Ast.make_var (uid, pos)
(* the whole box thing is to accomodate for this case *))
| Dotted (e, c, x) -> (
match Pos.unmark e with
| Ident y when Name_resolution.is_subscope_uid scope ctxt y ->
(* In this case, y.x is a subscope variable *)
let subscope_uid : Scopelang.Ast.SubScopeName.t =
Name_resolution.get_subscope_uid scope ctxt (Pos.same_pos_as y e)
in
let subscope_real_uid : Scopelang.Ast.ScopeName.t =
Scopelang.Ast.SubScopeMap.find subscope_uid scope_ctxt.sub_scopes
in
let subscope_var_uid =
Name_resolution.get_var_uid subscope_real_uid ctxt x
in
Bindlib.box
( Desugared.Ast.ELocation
(SubScopeVar
( subscope_real_uid,
(subscope_uid, pos),
(subscope_var_uid, pos) )),
pos )
| _ -> (
(* In this case e.x is the struct field x access of expression e *)
let e = translate_expr scope inside_definition_of ctxt e in
let x_possible_structs =
try Desugared.Ast.IdentMap.find (Pos.unmark x) ctxt.field_idmap
with Not_found ->
Errors.raise_spanned_error (Pos.get_position x)
"Unknown subscope or struct field name"
in
match c with
| None ->
(* No constructor name was specified *)
if Scopelang.Ast.StructMap.cardinal x_possible_structs > 1 then
Errors.raise_spanned_error (Pos.get_position x)
"This struct field name is ambiguous, it can belong to %a. \
Disambiguate it by prefixing it with the struct name."
(Format.pp_print_list
~pp_sep:(fun fmt () -> Format.fprintf fmt " or ")
(fun fmt (s_name, _) ->
Format.fprintf fmt "%a" Scopelang.Ast.StructName.format_t
s_name))
(Scopelang.Ast.StructMap.bindings x_possible_structs)
else
let s_uid, f_uid =
Scopelang.Ast.StructMap.choose x_possible_structs
in
Bindlib.box_apply
(fun e ->
(Desugared.Ast.EStructAccess (e, f_uid, s_uid), pos))
e
| Some c_name -> (
try
let c_uid =
Desugared.Ast.IdentMap.find (Pos.unmark c_name)
ctxt.struct_idmap
in
try
let f_uid =
Scopelang.Ast.StructMap.find c_uid x_possible_structs
in
Bindlib.box_apply
(fun e ->
(Desugared.Ast.EStructAccess (e, f_uid, c_uid), pos))
e
with Not_found ->
Errors.raise_spanned_error pos
"Struct %s does not contain field %s" (Pos.unmark c_name)
(Pos.unmark x)
with Not_found ->
Errors.raise_spanned_error (Pos.get_position c_name)
"Struct %s has not been defined before" (Pos.unmark c_name))))
| FunCall (f, arg) ->
Bindlib.box_apply2
(fun f arg -> (Desugared.Ast.EApp (f, [ arg ]), pos))
(rec_helper f) (rec_helper arg)
| StructLit (s_name, fields) ->
let s_uid =
try Desugared.Ast.IdentMap.find (Pos.unmark s_name) ctxt.struct_idmap
with Not_found ->
Errors.raise_spanned_error (Pos.get_position s_name)
"This identifier should refer to a struct name"
in
let s_fields =
List.fold_left
(fun s_fields (f_name, f_e) ->
let f_uid =
try
Scopelang.Ast.StructMap.find s_uid
(Desugared.Ast.IdentMap.find (Pos.unmark f_name)
ctxt.field_idmap)
with Not_found ->
Errors.raise_spanned_error (Pos.get_position f_name)
"This identifier should refer to a field of struct %s"
(Pos.unmark s_name)
in
(match Scopelang.Ast.StructFieldMap.find_opt f_uid s_fields with
| None -> ()
| Some e_field ->
Errors.raise_multispanned_error
[
(None, Pos.get_position f_e);
(None, Pos.get_position (Bindlib.unbox e_field));
]
"The field %a has been defined twice:"
Scopelang.Ast.StructFieldName.format_t f_uid);
let f_e = translate_expr scope inside_definition_of ctxt f_e in
Scopelang.Ast.StructFieldMap.add f_uid f_e s_fields)
Scopelang.Ast.StructFieldMap.empty fields
in
let expected_s_fields = Scopelang.Ast.StructMap.find s_uid ctxt.structs in
Scopelang.Ast.StructFieldMap.iter
(fun expected_f _ ->
if not (Scopelang.Ast.StructFieldMap.mem expected_f s_fields) then
Errors.raise_spanned_error pos
"Missing field for structure %a: \"%a\""
Scopelang.Ast.StructName.format_t s_uid
Scopelang.Ast.StructFieldName.format_t expected_f)
expected_s_fields;
Bindlib.box_apply
(fun s_fields -> (Desugared.Ast.EStruct (s_uid, s_fields), pos))
(LiftStructFieldMap.lift_box s_fields)
| EnumInject (enum, constructor, payload) -> (
let possible_c_uids =
try
Desugared.Ast.IdentMap.find (Pos.unmark constructor)
ctxt.constructor_idmap
with Not_found ->
Errors.raise_spanned_error
(Pos.get_position constructor)
"The name of this constructor has not been defined before, maybe \
it is a typo?"
in
match enum with
| None ->
if
(* No constructor name was specified *)
Scopelang.Ast.EnumMap.cardinal possible_c_uids > 1
then
Errors.raise_spanned_error
(Pos.get_position constructor)
"This constructor name is ambiguous, it can belong to %a. \
Desambiguate it by prefixing it with the enum name."
(Format.pp_print_list
~pp_sep:(fun fmt () -> Format.fprintf fmt " or ")
(fun fmt (s_name, _) ->
Format.fprintf fmt "%a" Scopelang.Ast.EnumName.format_t
s_name))
(Scopelang.Ast.EnumMap.bindings possible_c_uids)
else
let e_uid, c_uid = Scopelang.Ast.EnumMap.choose possible_c_uids in
let payload =
Option.map
(translate_expr scope inside_definition_of ctxt)
payload
in
Bindlib.box_apply
(fun payload ->
( Desugared.Ast.EEnumInj
( (match payload with
| Some e' -> e'
| None ->
( Desugared.Ast.ELit Dcalc.Ast.LUnit,
Pos.get_position constructor )),
c_uid,
e_uid ),
pos ))
(Bindlib.box_opt payload)
| Some enum -> (
try
(* The path has been fully qualified *)
let e_uid =
Desugared.Ast.IdentMap.find (Pos.unmark enum) ctxt.enum_idmap
in
try
let c_uid = Scopelang.Ast.EnumMap.find e_uid possible_c_uids in
let payload =
Option.map
(translate_expr scope inside_definition_of ctxt)
payload
in
Bindlib.box_apply
(fun payload ->
( Desugared.Ast.EEnumInj
( (match payload with
| Some e' -> e'
| None ->
( Desugared.Ast.ELit Dcalc.Ast.LUnit,
Pos.get_position constructor )),
c_uid,
e_uid ),
pos ))
(Bindlib.box_opt payload)
with Not_found ->
Errors.raise_spanned_error pos "Enum %s does not contain case %s"
(Pos.unmark enum) (Pos.unmark constructor)
with Not_found ->
Errors.raise_spanned_error (Pos.get_position enum)
"Enum %s has not been defined before" (Pos.unmark enum)))
| MatchWith (e1, (cases, _cases_pos)) ->
let e1 = translate_expr scope inside_definition_of ctxt e1 in
let cases_d, e_uid =
disambiguate_match_and_build_expression scope inside_definition_of ctxt
cases
in
Bindlib.box_apply2
(fun e1 cases_d -> (Desugared.Ast.EMatch (e1, e_uid, cases_d), pos))
e1
(LiftEnumConstructorMap.lift_box cases_d)
| TestMatchCase (e1, pattern) ->
(match snd (Pos.unmark pattern) with
| None -> ()
| Some binding ->
Errors.format_spanned_warning (Pos.get_position binding)
"This binding will be ignored (remove it to suppress warning)");
let enum_uid, c_uid =
disambiguate_constructor ctxt
(fst (Pos.unmark pattern))
(Pos.get_position pattern)
in
let cases =
Scopelang.Ast.EnumConstructorMap.mapi
(fun c_uid' tau ->
let nop_var = Desugared.Ast.Var.make ("_", pos) in
Bindlib.unbox
(Desugared.Ast.make_abs [| nop_var |]
(Bindlib.box
( Desugared.Ast.ELit
(Dcalc.Ast.LBool
(Scopelang.Ast.EnumConstructor.compare c_uid c_uid'
= 0)),
pos ))
pos [ tau ] pos))
(Scopelang.Ast.EnumMap.find enum_uid ctxt.enums)
in
Bindlib.box_apply
(fun e -> (Desugared.Ast.EMatch (e, enum_uid, cases), pos))
(translate_expr scope inside_definition_of ctxt e1)
| ArrayLit es ->
Bindlib.box_apply
(fun es -> (Desugared.Ast.EArray es, pos))
(Bindlib.box_list (List.map rec_helper es))
| CollectionOp
( (((Ast.Filter | Ast.Map) as op'), _pos_op'),
param',
collection,
predicate ) ->
let collection = rec_helper collection in
let ctxt, param = Name_resolution.add_def_local_var ctxt param' in
let f_pred =
Desugared.Ast.make_abs [| param |]
(translate_expr scope inside_definition_of ctxt predicate)
pos
[ (Scopelang.Ast.TAny, pos) ]
pos
in
Bindlib.box_apply2
(fun f_pred collection ->
( Desugared.Ast.EApp
( ( Desugared.Ast.EOp
(match op' with
| Ast.Map -> Dcalc.Ast.Binop Dcalc.Ast.Map
| Ast.Filter -> Dcalc.Ast.Binop Dcalc.Ast.Filter
| _ -> assert false (* should not happen *)),
pos ),
[ f_pred; collection ] ),
pos ))
f_pred collection
| CollectionOp
( ( Ast.Aggregate (Ast.AggregateArgExtremum (max_or_min, pred_typ, init)),
pos_op' ),
param',
collection,
predicate ) ->
let init = rec_helper init in
let collection = rec_helper collection in
let ctxt, param = Name_resolution.add_def_local_var ctxt param' in
let op_kind =
match pred_typ with
| Ast.Integer -> Dcalc.Ast.KInt
| Ast.Decimal -> Dcalc.Ast.KRat
| Ast.Money -> Dcalc.Ast.KMoney
| Ast.Duration -> Dcalc.Ast.KDuration
| Ast.Date -> Dcalc.Ast.KDate
| _ ->
Errors.raise_spanned_error pos
"It is impossible to compute the arg-%s of two values of type %a"
(if max_or_min then "max" else "min")
Print.format_primitive_typ pred_typ
in
let cmp_op =
if max_or_min then Dcalc.Ast.Gt op_kind else Dcalc.Ast.Lt op_kind
in
let f_pred =
Desugared.Ast.make_abs [| param |]
(translate_expr scope inside_definition_of ctxt predicate)
pos
[ (Scopelang.Ast.TAny, pos) ]
pos
in
let f_pred_var =
Desugared.Ast.Var.make ("predicate", Pos.get_position predicate)
in
let f_pred_var_e =
Desugared.Ast.make_var (f_pred_var, Pos.get_position predicate)
in
let acc_var = Desugared.Ast.Var.make ("acc", pos) in
let acc_var_e = Desugared.Ast.make_var (acc_var, pos) in
let item_var =
Desugared.Ast.Var.make
("item", Pos.get_position (Bindlib.unbox collection))
in
let item_var_e =
Desugared.Ast.make_var
(item_var, Pos.get_position (Bindlib.unbox collection))
in
let fold_body =
Bindlib.box_apply3
(fun acc_var_e item_var_e f_pred_var_e ->
( Desugared.Ast.EIfThenElse
( ( Desugared.Ast.EApp
( (Desugared.Ast.EOp (Dcalc.Ast.Binop cmp_op), pos_op'),
[
(Desugared.Ast.EApp (f_pred_var_e, [ acc_var_e ]), pos);
( Desugared.Ast.EApp (f_pred_var_e, [ item_var_e ]),
pos );
] ),
pos ),
acc_var_e,
item_var_e ),
pos ))
acc_var_e item_var_e f_pred_var_e
in
let fold_f =
Desugared.Ast.make_abs [| acc_var; item_var |] fold_body pos
[ (Scopelang.Ast.TAny, pos); (Scopelang.Ast.TAny, pos) ]
pos
in
let fold =
Bindlib.box_apply3
(fun fold_f collection init ->
( Desugared.Ast.EApp
( (Desugared.Ast.EOp (Dcalc.Ast.Ternop Dcalc.Ast.Fold), pos),
[ fold_f; init; collection ] ),
pos ))
fold_f collection init
in
Desugared.Ast.make_let_in f_pred_var (Scopelang.Ast.TAny, pos) f_pred fold
| CollectionOp (op', param', collection, predicate) ->
let ctxt, param = Name_resolution.add_def_local_var ctxt param' in
let collection = rec_helper collection in
let init =
match Pos.unmark op' with
| Ast.Map | Ast.Filter | Ast.Aggregate (Ast.AggregateArgExtremum _) ->
assert false (* should not happen *)
| Ast.Exists ->
Bindlib.box
(Desugared.Ast.ELit (Dcalc.Ast.LBool false), Pos.get_position op')
| Ast.Forall ->
Bindlib.box
(Desugared.Ast.ELit (Dcalc.Ast.LBool true), Pos.get_position op')
| Ast.Aggregate (Ast.AggregateSum Ast.Integer) ->
Bindlib.box
( Desugared.Ast.ELit (Dcalc.Ast.LInt (Runtime.integer_of_int 0)),
Pos.get_position op' )
| Ast.Aggregate (Ast.AggregateSum Ast.Decimal) ->
Bindlib.box
( Desugared.Ast.ELit
(Dcalc.Ast.LRat (Runtime.decimal_of_string "0")),
Pos.get_position op' )
| Ast.Aggregate (Ast.AggregateSum Ast.Money) ->
Bindlib.box
( Desugared.Ast.ELit
(Dcalc.Ast.LMoney
(Runtime.money_of_cents_integer (Runtime.integer_of_int 0))),
Pos.get_position op' )
| Ast.Aggregate (Ast.AggregateSum Ast.Duration) ->
Bindlib.box
( Desugared.Ast.ELit
(Dcalc.Ast.LDuration (Runtime.duration_of_numbers 0 0 0)),
Pos.get_position op' )
| Ast.Aggregate (Ast.AggregateSum t) ->
Errors.raise_spanned_error pos
"It is impossible to sum two values of type %a together"
Print.format_primitive_typ t
| Ast.Aggregate (Ast.AggregateExtremum (_, _, init)) -> rec_helper init
| Ast.Aggregate Ast.AggregateCount ->
Bindlib.box
( Desugared.Ast.ELit (Dcalc.Ast.LInt (Runtime.integer_of_int 0)),
Pos.get_position op' )
in
let acc_var = Desugared.Ast.Var.make ("acc", Pos.get_position param') in
let acc = Desugared.Ast.make_var (acc_var, Pos.get_position param') in
let f_body =
let make_body (op : Dcalc.Ast.binop) =
Bindlib.box_apply2
(fun predicate acc ->
( Desugared.Ast.EApp
( ( Desugared.Ast.EOp (Dcalc.Ast.Binop op),
Pos.get_position op' ),
[ acc; predicate ] ),
pos ))
(translate_expr scope inside_definition_of ctxt predicate)
acc
in
let make_extr_body
(cmp_op : Dcalc.Ast.binop) (t : Scopelang.Ast.typ Pos.marked) =
let tmp_var =
Desugared.Ast.Var.make ("tmp", Pos.get_position param')
in
let tmp = Desugared.Ast.make_var (tmp_var, Pos.get_position param') in
Desugared.Ast.make_let_in tmp_var t
(translate_expr scope inside_definition_of ctxt predicate)
(Bindlib.box_apply2
(fun acc tmp ->
( Desugared.Ast.EIfThenElse
( ( Desugared.Ast.EApp
( ( Desugared.Ast.EOp (Dcalc.Ast.Binop cmp_op),
Pos.get_position op' ),
[ acc; tmp ] ),
pos ),
acc,
tmp ),
pos ))
acc tmp)
in
match Pos.unmark op' with
| Ast.Map | Ast.Filter | Ast.Aggregate (Ast.AggregateArgExtremum _) ->
assert false (* should not happen *)
| Ast.Exists -> make_body Dcalc.Ast.Or
| Ast.Forall -> make_body Dcalc.Ast.And
| Ast.Aggregate (Ast.AggregateSum Ast.Integer) ->
make_body (Dcalc.Ast.Add Dcalc.Ast.KInt)
| Ast.Aggregate (Ast.AggregateSum Ast.Decimal) ->
make_body (Dcalc.Ast.Add Dcalc.Ast.KRat)
| Ast.Aggregate (Ast.AggregateSum Ast.Money) ->
make_body (Dcalc.Ast.Add Dcalc.Ast.KMoney)
| Ast.Aggregate (Ast.AggregateSum Ast.Duration) ->
make_body (Dcalc.Ast.Add Dcalc.Ast.KDuration)
| Ast.Aggregate (Ast.AggregateSum _) ->
assert false (* should not happen *)
| Ast.Aggregate (Ast.AggregateExtremum (max_or_min, t, _)) ->
let op_kind, typ =
match t with
| Ast.Integer -> (Dcalc.Ast.KInt, (Scopelang.Ast.TLit TInt, pos))
| Ast.Decimal -> (Dcalc.Ast.KRat, (Scopelang.Ast.TLit TRat, pos))
| Ast.Money -> (Dcalc.Ast.KMoney, (Scopelang.Ast.TLit TMoney, pos))
| Ast.Duration ->
(Dcalc.Ast.KDuration, (Scopelang.Ast.TLit TDuration, pos))
| Ast.Date -> (Dcalc.Ast.KDate, (Scopelang.Ast.TLit TDate, pos))
| _ ->
Errors.raise_spanned_error pos
"It is impossible to compute the %s of two values of type \
%a"
(if max_or_min then "max" else "min")
Print.format_primitive_typ t
in
let cmp_op =
if max_or_min then Dcalc.Ast.Gt op_kind else Dcalc.Ast.Lt op_kind
in
make_extr_body cmp_op typ
| Ast.Aggregate Ast.AggregateCount ->
Bindlib.box_apply2
(fun predicate acc ->
( Desugared.Ast.EIfThenElse
( predicate,
( Desugared.Ast.EApp
( ( Desugared.Ast.EOp
(Dcalc.Ast.Binop (Dcalc.Ast.Add Dcalc.Ast.KInt)),
Pos.get_position op' ),
[
acc;
( Desugared.Ast.ELit
(Dcalc.Ast.LInt (Runtime.integer_of_int 1)),
Pos.get_position predicate );
] ),
pos ),
acc ),
pos ))
(translate_expr scope inside_definition_of ctxt predicate)
acc
in
let f =
let make_f (t : Dcalc.Ast.typ_lit) =
Bindlib.box_apply
(fun binder ->
( Desugared.Ast.EAbs
( (binder, pos),
[
(Scopelang.Ast.TLit t, Pos.get_position op');
(Scopelang.Ast.TAny, pos)
(* we put any here because the type of the elements of the
arrays is not always the type of the accumulator; for
instance in AggregateCount. *);
] ),
pos ))
(Bindlib.bind_mvar [| acc_var; param |] f_body)
in
match Pos.unmark op' with
| Ast.Map | Ast.Filter | Ast.Aggregate (Ast.AggregateArgExtremum _) ->
assert false (* should not happen *)
| Ast.Exists -> make_f Dcalc.Ast.TBool
| Ast.Forall -> make_f Dcalc.Ast.TBool
| Ast.Aggregate (Ast.AggregateSum Ast.Integer)
| Ast.Aggregate (Ast.AggregateExtremum (_, Ast.Integer, _)) ->
make_f Dcalc.Ast.TInt
| Ast.Aggregate (Ast.AggregateSum Ast.Decimal)
| Ast.Aggregate (Ast.AggregateExtremum (_, Ast.Decimal, _)) ->
make_f Dcalc.Ast.TRat
| Ast.Aggregate (Ast.AggregateSum Ast.Money)
| Ast.Aggregate (Ast.AggregateExtremum (_, Ast.Money, _)) ->
make_f Dcalc.Ast.TMoney
| Ast.Aggregate (Ast.AggregateSum Ast.Duration)
| Ast.Aggregate (Ast.AggregateExtremum (_, Ast.Duration, _)) ->
make_f Dcalc.Ast.TDuration
| Ast.Aggregate (Ast.AggregateSum _)
| Ast.Aggregate (Ast.AggregateExtremum _) ->
assert false (* should not happen *)
| Ast.Aggregate Ast.AggregateCount -> make_f Dcalc.Ast.TInt
in
Bindlib.box_apply3
(fun f collection init ->
( Desugared.Ast.EApp
( (Desugared.Ast.EOp (Dcalc.Ast.Ternop Dcalc.Ast.Fold), pos),
[ f; init; collection ] ),
pos ))
f collection init
| MemCollection (member, collection) ->
let param_var = Desugared.Ast.Var.make ("collection_member", pos) in
let param = Desugared.Ast.make_var (param_var, pos) in
let collection = rec_helper collection in
let init =
Bindlib.box (Desugared.Ast.ELit (Dcalc.Ast.LBool false), pos)
in
let acc_var = Desugared.Ast.Var.make ("acc", pos) in
let acc = Desugared.Ast.make_var (acc_var, pos) in
let f_body =
Bindlib.box_apply3
(fun member acc param ->
( Desugared.Ast.EApp
( (Desugared.Ast.EOp (Dcalc.Ast.Binop Dcalc.Ast.Or), pos),
[
( Desugared.Ast.EApp
( (Desugared.Ast.EOp (Dcalc.Ast.Binop Dcalc.Ast.Eq), pos),
[ member; param ] ),
pos );
acc;
] ),
pos ))
(translate_expr scope inside_definition_of ctxt member)
acc param
in
let f =
Bindlib.box_apply
(fun binder ->
( Desugared.Ast.EAbs
( (binder, pos),
[
(Scopelang.Ast.TLit Dcalc.Ast.TBool, pos);
(Scopelang.Ast.TAny, pos);
] ),
pos ))
(Bindlib.bind_mvar [| acc_var; param_var |] f_body)
in
Bindlib.box_apply3
(fun f collection init ->
( Desugared.Ast.EApp
( (Desugared.Ast.EOp (Dcalc.Ast.Ternop Dcalc.Ast.Fold), pos),
[ f; init; collection ] ),
pos ))
f collection init
| Builtin IntToDec ->
Bindlib.box (Desugared.Ast.EOp (Dcalc.Ast.Unop Dcalc.Ast.IntToRat), pos)
| Builtin Cardinal ->
Bindlib.box (Desugared.Ast.EOp (Dcalc.Ast.Unop Dcalc.Ast.Length), pos)
| Builtin GetDay ->
Bindlib.box (Desugared.Ast.EOp (Dcalc.Ast.Unop Dcalc.Ast.GetDay), pos)
| Builtin GetMonth ->
Bindlib.box (Desugared.Ast.EOp (Dcalc.Ast.Unop Dcalc.Ast.GetMonth), pos)
| Builtin GetYear ->
Bindlib.box (Desugared.Ast.EOp (Dcalc.Ast.Unop Dcalc.Ast.GetYear), pos)
| Builtin RoundMoney ->
Bindlib.box (Desugared.Ast.EOp (Dcalc.Ast.Unop Dcalc.Ast.RoundMoney), pos)
| Builtin RoundDecimal ->
Bindlib.box
(Desugared.Ast.EOp (Dcalc.Ast.Unop Dcalc.Ast.RoundDecimal), pos)
and disambiguate_match_and_build_expression
(scope : Scopelang.Ast.ScopeName.t)
(inside_definition_of : Desugared.Ast.ScopeDef.t Pos.marked option)
(ctxt : Name_resolution.context)
(cases : Ast.match_case Pos.marked list) :
Desugared.Ast.expr Pos.marked Bindlib.box Scopelang.Ast.EnumConstructorMap.t
* Scopelang.Ast.EnumName.t =
let create_var = function
| None -> (ctxt, (Desugared.Ast.Var.make ("_", Pos.no_pos), Pos.no_pos))
| Some param ->
let ctxt, param_var = Name_resolution.add_def_local_var ctxt param in
(ctxt, (param_var, Pos.get_position param))
in
let bind_case_body
(c_uid : Dcalc.Ast.EnumConstructor.t)
(e_uid : Dcalc.Ast.EnumName.t)
(ctxt : Name_resolution.context)
(param_pos : Pos.t)
(case_body : ('a * Pos.t) Bindlib.box)
(e_binder :
(Desugared.Ast.expr, Desugared.Ast.expr * Pos.t) Bindlib.mbinder
Bindlib.box) : 'c Bindlib.box =
Bindlib.box_apply2
(fun e_binder case_body ->
Pos.same_pos_as
(Desugared.Ast.EAbs
( (e_binder, param_pos),
[
Scopelang.Ast.EnumConstructorMap.find c_uid
(Scopelang.Ast.EnumMap.find e_uid ctxt.Name_resolution.enums);
] ))
case_body)
e_binder case_body
in
let bind_match_cases (cases_d, e_uid, curr_index) (case, case_pos) =
match case with
| Ast.MatchCase case ->
let constructor, binding = Pos.unmark case.Ast.match_case_pattern in
let e_uid', c_uid =
disambiguate_constructor ctxt constructor
(Pos.get_position case.Ast.match_case_pattern)
in
let e_uid =
match e_uid with
| None -> e_uid'
| Some e_uid ->
if e_uid = e_uid' then e_uid
else
Errors.raise_spanned_error
(Pos.get_position case.Ast.match_case_pattern)
"This case matches a constructor of enumeration %a but \
previous case were matching constructors of enumeration %a"
Scopelang.Ast.EnumName.format_t e_uid
Scopelang.Ast.EnumName.format_t e_uid'
in
(match Scopelang.Ast.EnumConstructorMap.find_opt c_uid cases_d with
| None -> ()
| Some e_case ->
Errors.raise_multispanned_error
[
(None, Pos.get_position case.match_case_expr);
(None, Pos.get_position (Bindlib.unbox e_case));
]
"The constructor %a has been matched twice:"
Scopelang.Ast.EnumConstructor.format_t c_uid);
let ctxt, (param_var, param_pos) = create_var binding in
let case_body =
translate_expr scope inside_definition_of ctxt
case.Ast.match_case_expr
in
let e_binder =
Bindlib.bind_mvar (Array.of_list [ param_var ]) case_body
in
let case_expr =
bind_case_body c_uid e_uid ctxt param_pos case_body e_binder
in
( Scopelang.Ast.EnumConstructorMap.add c_uid case_expr cases_d,
Some e_uid,
curr_index + 1 )
| Ast.WildCard match_case_expr -> (
let nb_cases = List.length cases in
let raise_wildcard_not_last_case_err () =
Errors.raise_multispanned_error
[
(Some "Not ending wildcard:", case_pos);
( Some "Next reachable case:",
curr_index + 1 |> List.nth cases |> Pos.get_position );
]
"Wildcard must be the last match case"
in
match e_uid with
| None ->
if 1 = nb_cases then
Errors.raise_spanned_error case_pos
"Couldn't infer the enumeration name from lonely wildcard \
(wildcard cannot be used as single match case)"
else raise_wildcard_not_last_case_err ()
| Some e_uid ->
if curr_index < nb_cases - 1 then
raise_wildcard_not_last_case_err ();
let missing_constructors =
Scopelang.Ast.EnumMap.find e_uid ctxt.Name_resolution.enums
|> Scopelang.Ast.EnumConstructorMap.filter_map (fun c_uid _ ->
match
Scopelang.Ast.EnumConstructorMap.find_opt c_uid cases_d
with
| Some _ -> None
| None -> Some c_uid)
in
if Scopelang.Ast.EnumConstructorMap.is_empty missing_constructors
then
Errors.format_spanned_warning case_pos
"Unreachable match case, all constructors of the enumeration \
%a are already specified"
Scopelang.Ast.EnumName.format_t e_uid;
(* The current used strategy is to replace the wildcard branch:
match foo with
| Case1 x -> x
| _ -> 1
with:
let wildcard_payload = 1 in
match foo with
| Case1 x -> x
| Case2 -> wildcard_payload
...
| CaseN -> wildcard_payload *)
(* Creates the wildcard payload *)
let ctxt, (payload_var, var_pos) = create_var None in
let case_body =
translate_expr scope inside_definition_of ctxt match_case_expr
in
let e_binder =
Bindlib.bind_mvar (Array.of_list [ payload_var ]) case_body
in
(* For each missing cases, binds the wildcard payload. *)
Scopelang.Ast.EnumConstructorMap.fold
(fun c_uid _ (cases_d, e_uid_opt, curr_index) ->
let case_expr =
bind_case_body c_uid e_uid ctxt var_pos case_body e_binder
in
( Scopelang.Ast.EnumConstructorMap.add c_uid case_expr cases_d,
e_uid_opt,
curr_index + 1 ))
missing_constructors
(cases_d, Some e_uid, curr_index))
in
let expr, e_name, _ =
List.fold_left bind_match_cases
(Scopelang.Ast.EnumConstructorMap.empty, None, 0)
cases
in
(expr, Option.get e_name)
[@@ocamlformat "wrap-comments=false"]
(** {1 Translating scope definitions} *)
(** A scope use can be annotated with a pervasive precondition, in which case
this precondition has to be appended to the justifications of each
definition in the subscope use. This is what this function does. *)
let merge_conditions
(precond : Desugared.Ast.expr Pos.marked Bindlib.box option)
(cond : Desugared.Ast.expr Pos.marked Bindlib.box option)
(default_pos : Pos.t) : Desugared.Ast.expr Pos.marked Bindlib.box =
match (precond, cond) with
| Some precond, Some cond ->
let op_term =
( Desugared.Ast.EOp (Dcalc.Ast.Binop Dcalc.Ast.And),
Pos.get_position (Bindlib.unbox cond) )
in
Bindlib.box_apply2
(fun precond cond ->
( Desugared.Ast.EApp (op_term, [ precond; cond ]),
Pos.get_position cond ))
precond cond
| Some precond, None ->
Bindlib.box_apply
(fun precond -> (Pos.unmark precond, default_pos))
precond
| None, Some cond -> cond
| None, None ->
Bindlib.box (Desugared.Ast.ELit (Dcalc.Ast.LBool true), default_pos)
(** Translates a surface definition into condition into a desugared {!type:
Desugared.Ast.rule} *)
let process_default
(ctxt : Name_resolution.context)
(scope : Scopelang.Ast.ScopeName.t)
(def_key : Desugared.Ast.ScopeDef.t Pos.marked)
(rule_id : Desugared.Ast.RuleName.t)
(param_uid : Desugared.Ast.Var.t Pos.marked option)
(precond : Desugared.Ast.expr Pos.marked Bindlib.box option)
(exception_to_rules : Desugared.Ast.RuleSet.t Pos.marked)
(just : Ast.expression Pos.marked option)
(cons : Ast.expression Pos.marked) : Desugared.Ast.rule =
let just =
match just with
| Some just -> Some (translate_expr scope (Some def_key) ctxt just)
| None -> None
in
let just = merge_conditions precond just (Pos.get_position def_key) in
let cons = translate_expr scope (Some def_key) ctxt cons in
{
rule_just = just;
rule_cons = cons;
rule_parameter =
(let def_key_typ =
Name_resolution.get_def_typ ctxt (Pos.unmark def_key)
in
match (Pos.unmark def_key_typ, param_uid) with
| Scopelang.Ast.TArrow (t_in, _), Some param_uid ->
Some (Pos.unmark param_uid, t_in)
| Scopelang.Ast.TArrow _, None ->
Errors.raise_spanned_error
(Pos.get_position (Bindlib.unbox cons))
"This definition has a function type but the parameter is missing"
| _, Some _ ->
Errors.raise_spanned_error
(Pos.get_position (Bindlib.unbox cons))
"This definition has a parameter but its type is not a function"
| _ -> None);
rule_exception_to_rules = exception_to_rules;
rule_id;
}
(** Wrapper around {!val: process_default} that performs some name
disambiguation *)
let process_def
(precond : Desugared.Ast.expr Pos.marked Bindlib.box option)
(scope_uid : Scopelang.Ast.ScopeName.t)
(ctxt : Name_resolution.context)
(prgm : Desugared.Ast.program)
(def : Ast.definition) : Desugared.Ast.program =
let scope : Desugared.Ast.scope =
Scopelang.Ast.ScopeMap.find scope_uid prgm.program_scopes
in
let scope_ctxt = Scopelang.Ast.ScopeMap.find scope_uid ctxt.scopes in
let def_key =
Name_resolution.get_def_key
(Pos.unmark def.definition_name)
def.definition_state scope_uid ctxt
(Pos.get_position def.definition_expr)
in
let scope_def_ctxt =
Desugared.Ast.ScopeDefMap.find def_key scope_ctxt.scope_defs_contexts
in
(* We add to the name resolution context the name of the parameter variable *)
let param_uid, new_ctxt =
match def.definition_parameter with
| None -> (None, ctxt)
| Some param ->
let ctxt, param_var = Name_resolution.add_def_local_var ctxt param in
(Some (Pos.same_pos_as param_var param), ctxt)
in
let scope_updated =
let scope_def = Desugared.Ast.ScopeDefMap.find def_key scope.scope_defs in
let rule_name = def.definition_id in
let parent_rules =
match def.Ast.definition_exception_to with
| NotAnException ->
(Desugared.Ast.RuleSet.empty, Pos.get_position def.Ast.definition_name)
| UnlabeledException -> (
match scope_def_ctxt.default_exception_rulename with
(* This should have been caught previously by
check_unlabeled_exception *)
| None | Some (Name_resolution.Ambiguous _) ->
assert false (* should not happen *)
| Some (Name_resolution.Unique (name, pos)) ->
(Desugared.Ast.RuleSet.singleton name, pos))
| ExceptionToLabel label -> (
try
let label_id =
Desugared.Ast.IdentMap.find (Pos.unmark label)
scope_def_ctxt.label_idmap
in
( Desugared.Ast.LabelMap.find label_id
scope_def.scope_def_label_groups,
Pos.get_position def.Ast.definition_name )
with Not_found ->
Errors.raise_spanned_error (Pos.get_position label)
"Unknown label for the scope variable %a: \"%s\""
Desugared.Ast.ScopeDef.format_t def_key (Pos.unmark label))
in
let scope_def =
{
scope_def with
scope_def_rules =
Desugared.Ast.RuleMap.add rule_name
(process_default new_ctxt scope_uid
(def_key, Pos.get_position def.definition_name)
rule_name param_uid precond parent_rules def.definition_condition
def.definition_expr)
scope_def.scope_def_rules;
}
in
{
scope with
scope_defs =
Desugared.Ast.ScopeDefMap.add def_key scope_def scope.scope_defs;
}
in
{
prgm with
program_scopes =
Scopelang.Ast.ScopeMap.add scope_uid scope_updated prgm.program_scopes;
}
(** Translates a {!type: Surface.Ast.rule} from the surface language *)
let process_rule
(precond : Desugared.Ast.expr Pos.marked Bindlib.box option)
(scope : Scopelang.Ast.ScopeName.t)
(ctxt : Name_resolution.context)
(prgm : Desugared.Ast.program)
(rule : Ast.rule) : Desugared.Ast.program =
let def = Ast.rule_to_def rule in
process_def precond scope ctxt prgm def
(** Translates assertions *)
let process_assert
(precond : Desugared.Ast.expr Pos.marked Bindlib.box option)
(scope_uid : Scopelang.Ast.ScopeName.t)
(ctxt : Name_resolution.context)
(prgm : Desugared.Ast.program)
(ass : Ast.assertion) : Desugared.Ast.program =
let scope : Desugared.Ast.scope =
Scopelang.Ast.ScopeMap.find scope_uid prgm.program_scopes
in
let ass =
translate_expr scope_uid None ctxt
(match ass.Ast.assertion_condition with
| None -> ass.Ast.assertion_content
| Some cond ->
( Ast.IfThenElse
( cond,
ass.Ast.assertion_content,
Pos.same_pos_as (Ast.Literal (Ast.LBool true)) cond ),
Pos.get_position cond ))
in
let ass =
match precond with
| Some precond ->
Bindlib.box_apply2
(fun precond ass ->
( Desugared.Ast.EIfThenElse
( precond,
ass,
Pos.same_pos_as (Desugared.Ast.ELit (Dcalc.Ast.LBool true))
precond ),
Pos.get_position precond ))
precond ass
| None -> ass
in
let new_scope =
{ scope with scope_assertions = ass :: scope.scope_assertions }
in
{
prgm with
program_scopes =
Scopelang.Ast.ScopeMap.add scope_uid new_scope prgm.program_scopes;
}
(** Translates a surface definition, rule or assertion *)
let process_scope_use_item
(precond : Ast.expression Pos.marked option)
(scope : Scopelang.Ast.ScopeName.t)
(ctxt : Name_resolution.context)
(prgm : Desugared.Ast.program)
(item : Ast.scope_use_item Pos.marked) : Desugared.Ast.program =
let precond = Option.map (translate_expr scope None ctxt) precond in
match Pos.unmark item with
| Ast.Rule rule -> process_rule precond scope ctxt prgm rule
| Ast.Definition def -> process_def precond scope ctxt prgm def
| Ast.Assertion ass -> process_assert precond scope ctxt prgm ass
| _ -> prgm
(** {1 Translating top-level items} *)
(* If this is an unlabeled exception, ensures that it has a unique default
definition *)
let check_unlabeled_exception
(scope : Scopelang.Ast.ScopeName.t)
(ctxt : Name_resolution.context)
(item : Ast.scope_use_item Pos.marked) : unit =
let scope_ctxt = Scopelang.Ast.ScopeMap.find scope ctxt.scopes in
match Pos.unmark item with
| Ast.Rule _ | Ast.Definition _ -> (
let def_key, exception_to =
match Pos.unmark item with
| Ast.Rule rule ->
( Name_resolution.get_def_key
(Pos.unmark rule.rule_name)
rule.rule_state scope ctxt
(Pos.get_position rule.rule_name),
rule.rule_exception_to )
| Ast.Definition def ->
( Name_resolution.get_def_key
(Pos.unmark def.definition_name)
def.definition_state scope ctxt
(Pos.get_position def.definition_name),
def.definition_exception_to )
| _ -> assert false
(* should not happen *)
in
let scope_def_ctxt =
Desugared.Ast.ScopeDefMap.find def_key scope_ctxt.scope_defs_contexts
in
match exception_to with
| Ast.NotAnException | Ast.ExceptionToLabel _ -> ()
(* If this is an unlabeled exception, we check that it has a unique
default definition *)
| Ast.UnlabeledException -> (
match scope_def_ctxt.default_exception_rulename with
| None ->
Errors.raise_spanned_error (Pos.get_position item)
"This exception does not have a corresponding definition"
| Some (Ambiguous pos) ->
Errors.raise_multispanned_error
([ (Some "Ambiguous exception", Pos.get_position item) ]
@ List.map (fun p -> (Some "Candidate definition", p)) pos)
"This exception can refer to several definitions. Try using \
labels to disambiguate"
| Some (Unique _) -> ()))
| _ -> ()
(** Translates a surface scope use, which is a bunch of definitions *)
let process_scope_use
(ctxt : Name_resolution.context)
(prgm : Desugared.Ast.program)
(use : Ast.scope_use) : Desugared.Ast.program =
let name = fst use.scope_use_name in
let scope_uid = Desugared.Ast.IdentMap.find name ctxt.scope_idmap in
(* Make sure the scope exists *)
let prgm =
match Scopelang.Ast.ScopeMap.find_opt scope_uid prgm.program_scopes with
| Some _ -> prgm
| None -> assert false
(* should not happen *)
in
let precond = use.scope_use_condition in
List.iter (check_unlabeled_exception scope_uid ctxt) use.scope_use_items;
List.fold_left
(process_scope_use_item precond scope_uid ctxt)
prgm use.scope_use_items
let attribute_to_io (attr : Ast.scope_decl_context_io) : Scopelang.Ast.io =
{
Scopelang.Ast.io_output = attr.scope_decl_context_io_output;
Scopelang.Ast.io_input =
Pos.map_under_mark
(fun io ->
match io with
| Ast.Input -> Scopelang.Ast.OnlyInput
| Ast.Internal -> Scopelang.Ast.NoInput
| Ast.Context -> Scopelang.Ast.Reentrant)
attr.scope_decl_context_io_input;
}
(** Main function of this module *)
let desugar_program (ctxt : Name_resolution.context) (prgm : Ast.program) :
Desugared.Ast.program =
let empty_prgm =
{
Desugared.Ast.program_structs =
Scopelang.Ast.StructMap.map Scopelang.Ast.StructFieldMap.bindings
ctxt.Name_resolution.structs;
Desugared.Ast.program_enums =
Scopelang.Ast.EnumMap.map Scopelang.Ast.EnumConstructorMap.bindings
ctxt.Name_resolution.enums;
Desugared.Ast.program_scopes =
Scopelang.Ast.ScopeMap.mapi
(fun s_uid s_context ->
{
Desugared.Ast.scope_vars =
Desugared.Ast.IdentMap.fold
(fun _ v acc ->
let v_sig =
Desugared.Ast.ScopeVarMap.find v ctxt.var_typs
in
match v_sig.var_sig_states_list with
| [] ->
Desugared.Ast.ScopeVarMap.add v Desugared.Ast.WholeVar
acc
| states ->
Desugared.Ast.ScopeVarMap.add v
(Desugared.Ast.States states) acc)
s_context.Name_resolution.var_idmap
Desugared.Ast.ScopeVarMap.empty;
Desugared.Ast.scope_sub_scopes =
s_context.Name_resolution.sub_scopes;
Desugared.Ast.scope_defs =
(* Initializing the definitions of all scopes and subscope vars,
with no rules yet inside *)
(let scope_vars_defs =
Desugared.Ast.IdentMap.fold
(fun _ v acc ->
let v_sig =
Desugared.Ast.ScopeVarMap.find v
ctxt.Name_resolution.var_typs
in
match v_sig.var_sig_states_list with
| [] ->
let def_key = Desugared.Ast.ScopeDef.Var (v, None) in
Desugared.Ast.ScopeDefMap.add def_key
{
Desugared.Ast.scope_def_rules =
Desugared.Ast.RuleMap.empty;
Desugared.Ast.scope_def_typ = v_sig.var_sig_typ;
Desugared.Ast.scope_def_label_groups =
Name_resolution.label_groups ctxt s_uid def_key;
Desugared.Ast.scope_def_is_condition =
v_sig.var_sig_is_condition;
Desugared.Ast.scope_def_io =
attribute_to_io v_sig.var_sig_io;
}
acc
| states ->
fst
(List.fold_left
(fun (acc, i) state ->
let def_key =
Desugared.Ast.ScopeDef.Var (v, Some state)
in
( Desugared.Ast.ScopeDefMap.add def_key
{
Desugared.Ast.scope_def_rules =
Desugared.Ast.RuleMap.empty;
Desugared.Ast.scope_def_typ =
v_sig.var_sig_typ;
Desugared.Ast.scope_def_label_groups =
Name_resolution.label_groups ctxt
s_uid def_key;
Desugared.Ast.scope_def_is_condition =
v_sig.var_sig_is_condition;
Desugared.Ast.scope_def_io =
(* The first state should have the
input I/O of the original variable,
and the last state should have the
output I/O of the original
variable. All intermediate states
shall have "internal" I/O.*)
(let original_io =
attribute_to_io v_sig.var_sig_io
in
let io_input =
if i = 0 then original_io.io_input
else
( Scopelang.Ast.NoInput,
Pos.get_position
(Desugared.Ast.StateName
.get_info state) )
in
let io_output =
if i = List.length states - 1 then
original_io.io_output
else
( false,
Pos.get_position
(Desugared.Ast.StateName
.get_info state) )
in
{ io_input; io_output });
}
acc,
i + 1 ))
(acc, 0) states))
s_context.Name_resolution.var_idmap
Desugared.Ast.ScopeDefMap.empty
in
let scope_and_subscope_vars_defs =
Scopelang.Ast.SubScopeMap.fold
(fun subscope_name subscope_uid acc ->
Desugared.Ast.IdentMap.fold
(fun _ v acc ->
let v_sig =
Desugared.Ast.ScopeVarMap.find v
ctxt.Name_resolution.var_typs
in
let def_key =
Desugared.Ast.ScopeDef.SubScopeVar
(subscope_name, v)
in
Desugared.Ast.ScopeDefMap.add def_key
{
Desugared.Ast.scope_def_rules =
Desugared.Ast.RuleMap.empty;
Desugared.Ast.scope_def_typ = v_sig.var_sig_typ;
Desugared.Ast.scope_def_label_groups =
Name_resolution.label_groups ctxt subscope_uid
def_key;
Desugared.Ast.scope_def_is_condition =
v_sig.var_sig_is_condition;
Desugared.Ast.scope_def_io =
attribute_to_io v_sig.var_sig_io;
}
acc)
(Scopelang.Ast.ScopeMap.find subscope_uid
ctxt.Name_resolution.scopes)
.Name_resolution.var_idmap acc)
s_context.sub_scopes scope_vars_defs
in
scope_and_subscope_vars_defs);
Desugared.Ast.scope_assertions = [];
Desugared.Ast.scope_meta_assertions = [];
Desugared.Ast.scope_uid = s_uid;
})
ctxt.Name_resolution.scopes;
}
in
let rec processer_structure
(prgm : Desugared.Ast.program) (item : Ast.law_structure) :
Desugared.Ast.program =
match item with
| LawHeading (_, children) ->
List.fold_left
(fun prgm child -> processer_structure prgm child)
prgm children
| CodeBlock (block, _, _) ->
List.fold_left
(fun prgm item ->
match Pos.unmark item with
| Ast.ScopeUse use -> process_scope_use ctxt prgm use
| _ -> prgm)
prgm block
| LawInclude _ | LawText _ -> prgm
in
List.fold_left processer_structure empty_prgm prgm.program_items
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