(** Extract to F* *) open Errors open Pure open TranslateCore open PureToExtract open StringUtils module F = Format (** A qualifier for a type definition. Controls whether we should use `type ...` or `and ...` (for mutually recursive datatypes). *) type type_def_qualif = Type | And (** A qualifier for function definitions. Controls whether we should use `let ...`, `let rec ...` or `and ...` *) type fun_def_qualif = Let | LetRec | And (** A list of keywords/identifiers used in F* and with which we want to check collision. *) let fstar_keywords = [ "let"; "rec"; "in"; "fn"; "int"; "list"; "FStar"; "FStar.Mul"; "type"; "match"; "with"; "assert"; "Type0"; ] let fstar_int_name (int_ty : integer_type) = match int_ty with | Isize -> "isize" | I8 -> "i8" | I16 -> "i16" | I32 -> "i32" | I64 -> "i64" | I128 -> "i128" | Usize -> "usize" | U8 -> "u8" | U16 -> "u16" | U32 -> "u32" | U64 -> "u64" | U128 -> "u128" let fstar_assumed_adts : (assumed_ty * string) list = [ (Result, "result") ] let fstar_assumed_structs : (assumed_ty * string) list = [] let fstar_assumed_variants : (assumed_ty * VariantId.id * string) list = [ (Result, result_return_id, "Return"); (Result, result_fail_id, "Fail") ] let fstar_assumed_functions : (A.assumed_fun_id * T.RegionGroupId.id option * string) list = [] let fstar_names_map_init = { keywords = fstar_keywords; assumed_adts = fstar_assumed_adts; assumed_structs = fstar_assumed_structs; assumed_variants = fstar_assumed_variants; assumed_functions = fstar_assumed_functions; } let fstar_extract_unop (extract_expr : bool -> texpression -> unit) (fmt : F.formatter) (inside : bool) (unop : unop) (arg : texpression) : unit = let unop = match unop with | Not -> "not" | Neg int_ty -> fstar_int_name int_ty ^ "_neg" in if inside then F.pp_print_string fmt "("; F.pp_print_string fmt unop; F.pp_print_space fmt (); extract_expr true arg; if inside then F.pp_print_string fmt ")" let fstar_extract_binop (extract_expr : bool -> texpression -> unit) (fmt : F.formatter) (inside : bool) (binop : E.binop) (int_ty : integer_type) (arg0 : texpression) (arg1 : texpression) : unit = if inside then F.pp_print_string fmt "("; (match binop with | Eq -> extract_expr false arg0; F.pp_print_space fmt (); F.pp_print_string fmt "="; F.pp_print_space fmt (); extract_expr false arg1 | _ -> let binop = match binop with | Eq -> failwith "Unreachable" | Lt -> "lt" | Le -> "le" | Ne -> "ne" | Ge -> "ge" | Gt -> "gt" | Div -> "div" | Rem -> "rem" | Add -> "add" | Sub -> "sub" | Mul -> "mul" | BitXor | BitAnd | BitOr | Shl | Shr -> raise Unimplemented in F.pp_print_string fmt (fstar_int_name int_ty ^ "_" ^ binop); F.pp_print_space fmt (); extract_expr false arg0; F.pp_print_space fmt (); extract_expr false arg1); if inside then F.pp_print_string fmt ")" (** * [ctx]: we use the context to lookup type definitions, to retrieve type names. * This is used to compute variable names, when they have no basenames: in this * case we use the first letter of the type name. * * [variant_concatenate_type_name]: if true, add the type name as a prefix * to the variant names. * Ex.: * In Rust: * ``` * enum List = { * Cons(u32, Box),x * Nil, * } * ``` * * F*, if option activated: * ``` * type list = * | ListCons : u32 -> list -> list * | ListNil : list * ``` * * F*, if option not activated: * ``` * type list = * | Cons : u32 -> list -> list * | Nil : list * ``` * * Rk.: this should be true by default, because in Rust all the variant names * are actively uniquely identifier by the type name `List::Cons(...)`, while * in other languages it is not necessarily the case, and thus clashes can mess * up type checking. Note that some languages actually forbids the name clashes * (it is the case of F* ). *) let mk_formatter (ctx : trans_ctx) (variant_concatenate_type_name : bool) : formatter = let int_name = fstar_int_name in (* For now, we treat only the case where type names are of the * form: `Module::Type` *) let get_type_name (name : name) : string = match name with | [ _module; name ] -> name | _ -> failwith ("Unexpected name shape: " ^ Print.name_to_string name) in let type_name_to_camel_case name = let name = get_type_name name in to_camel_case name in let type_name_to_snake_case name = let name = get_type_name name in to_snake_case name in let type_name name = type_name_to_snake_case name ^ "_t" in let field_name (def_name : name) (field_id : FieldId.id) (field_name : string option) : string = let def_name = type_name_to_snake_case def_name ^ "_" in match field_name with | Some field_name -> def_name ^ field_name | None -> def_name ^ FieldId.to_string field_id in let variant_name (def_name : name) (variant : string) : string = let variant = to_camel_case variant in if variant_concatenate_type_name then type_name_to_camel_case def_name ^ variant else variant in let struct_constructor (basename : name) : string = let tname = type_name basename in "Mk" ^ tname in (* For now, we treat only the case where function names are of the * form: `function` (no module prefix) *) let get_fun_name (name : name) : string = match name with | [ name ] -> name | _ -> failwith ("Unexpected name shape: " ^ Print.name_to_string name) in let fun_name (_fid : A.fun_id) (fname : name) (num_rgs : int) (rg : region_group_info option) : string = let fname = get_fun_name fname in (* Converting to snake case should be a no-op, but it doesn't cost much *) let fname = to_snake_case fname in (* Compute the suffix *) let suffix = default_fun_suffix num_rgs rg in (* Concatenate *) fname ^ suffix in let var_basename (_varset : StringSet.t) (basename : string option) (ty : ty) : string = (* If there is a basename, we use it *) match basename with | Some basename -> (* This should be a no-op *) to_snake_case basename | None -> ( (* No basename: we use the first letter of the type *) match ty with | Adt (type_id, tys) -> ( match type_id with | Tuple -> (* The "pair" case is frequent enough to have its special treatment *) if List.length tys = 2 then "p" else "t" | Assumed Result -> "r" | AdtId adt_id -> let def = TypeDefId.Map.find adt_id ctx.type_context.type_defs in let c = (get_type_name def.name).[0] in let c = StringUtils.lowercase_ascii c in String.make 1 c) | TypeVar _ -> "x" (* lacking imagination here... *) | Bool -> "b" | Char -> "c" | Integer _ -> "i" | Str -> "s" | Array _ | Slice _ -> raise Unimplemented) in let type_var_basename (_varset : StringSet.t) (basename : string) : string = (* This is *not* a no-op: type variables in Rust often start with * a capital letter *) to_snake_case basename in let append_index (basename : string) (i : int) : string = basename ^ string_of_int i in let extract_constant_value (fmt : F.formatter) (_inside : bool) (cv : constant_value) : unit = match cv with | Scalar sv -> F.pp_print_string fmt (Z.to_string sv.V.value) | Bool b -> let b = if b then "true" else "false" in F.pp_print_string fmt b | Char c -> F.pp_print_string fmt ("'" ^ String.make 1 c ^ "'") | String s -> (* We need to replace all the line breaks *) let s = StringUtils.map (fun c -> if c = '\n' then "\n" else String.make 1 c) s in F.pp_print_string fmt ("\"" ^ s ^ "\"") in { bool_name = "bool"; char_name = "char"; int_name; str_name = "string"; field_name; variant_name; struct_constructor; type_name; fun_name; var_basename; type_var_basename; append_index; extract_constant_value; extract_unop = fstar_extract_unop; extract_binop = fstar_extract_binop; } (** [inside] constrols whether we should add parentheses or not around type application (if `true` we add parentheses). *) let rec extract_ty (ctx : extraction_ctx) (fmt : F.formatter) (inside : bool) (ty : ty) : unit = match ty with | Adt (type_id, tys) -> ( match type_id with | Tuple -> F.pp_print_string fmt "("; Collections.List.iter_link (F.pp_print_space fmt) (extract_ty ctx fmt true) tys; F.pp_print_string fmt ")" | AdtId _ | Assumed _ -> if inside then F.pp_print_string fmt "("; F.pp_print_string fmt (ctx_get_type type_id ctx); if tys <> [] then F.pp_print_space fmt (); Collections.List.iter_link (F.pp_print_space fmt) (extract_ty ctx fmt true) tys; if inside then F.pp_print_string fmt ")") | TypeVar vid -> F.pp_print_string fmt (ctx_get_type_var vid ctx) | Bool -> F.pp_print_string fmt ctx.fmt.bool_name | Char -> F.pp_print_string fmt ctx.fmt.char_name | Integer int_ty -> F.pp_print_string fmt (ctx.fmt.int_name int_ty) | Str -> F.pp_print_string fmt ctx.fmt.str_name | Array _ | Slice _ -> raise Unimplemented (** Compute the names for all the top-level identifiers used in a type definition (type name, variant names, field names, etc. but not type parameters). We need to do this preemptively, beforce extracting any definition, because of recursive definitions. *) let extract_type_def_register_names (ctx : extraction_ctx) (def : type_def) : extraction_ctx = (* Compute and register the type def name *) let ctx = ctx_add_type_def def ctx in (* Compute and register: * - the variant names, if this is an enumeration * - the field names, if this is a structure *) let ctx = match def.kind with | Struct fields -> fst (ctx_add_fields def (FieldId.mapi (fun id f -> (id, f)) fields) ctx) | Enum variants -> fst (ctx_add_variants def (VariantId.mapi (fun id v -> (id, v)) variants) ctx) in (* Return *) ctx let extract_type_def_struct_body (ctx : extraction_ctx) (fmt : F.formatter) (def : type_def) (fields : field list) : unit = (* We want to generate a definition which looks like this: * ``` * type t = { x : int; y : bool; } * ``` * * If there isn't enough space on one line: * ``` * type t = * { * x : int; y : bool; * } * ``` * * And if there is even less space: * ``` * type t = * { * x : int; * y : bool; * } * ``` * * Also, in case there are no fields, we need to define the type as `unit` * (`type t = {}` doesn't work in F* ). *) (* Note that we already printed: `type t =` *) if fields = [] then ( F.pp_print_space fmt (); F.pp_print_string fmt "unit") else ( F.pp_print_space fmt (); F.pp_print_string fmt "{"; F.pp_print_break fmt 1 ctx.indent_incr; (* The body itself *) F.pp_open_hvbox fmt 0; (* Print the fields *) let print_field (field_id : FieldId.id) (f : field) : unit = let field_name = ctx_get_field (AdtId def.def_id) field_id ctx in F.pp_open_box fmt ctx.indent_incr; F.pp_print_string fmt field_name; F.pp_print_space fmt (); F.pp_print_string fmt ":"; F.pp_print_space fmt (); extract_ty ctx fmt false f.field_ty; F.pp_print_string fmt ";"; F.pp_close_box fmt () in let fields = FieldId.mapi (fun fid f -> (fid, f)) fields in Collections.List.iter_link (F.pp_print_space fmt) (fun (fid, f) -> print_field fid f) fields; (* Close *) F.pp_close_box fmt (); F.pp_print_space fmt (); F.pp_print_string fmt "}") let extract_type_def_enum_body (ctx : extraction_ctx) (fmt : F.formatter) (def : type_def) (def_name : string) (type_params : string list) (variants : variant list) : unit = (* We want to generate a definition which looks like this: * ``` * type list a = | Cons : a -> list a -> list a | Nil : list a * ``` * * If there isn't enough space on one line: * ``` * type s = * | Cons : a -> list a -> list a * | Nil : list a * ``` * * And if we need to write the type of a variant on several lines: * ``` * type s = * | Cons : * a -> * list a -> * list a * | Nil : list a * ``` * * Finally, it is possible to give names to the variant fields in Rust. * In this situation, we generate a definition like this: * ``` * type s = * | Cons : hd:a -> tl:list a -> list a * | Nil : list a * ``` * * Note that we already printed: `type s =` *) (* Print the variants *) let print_variant (variant_id : VariantId.id) (variant : variant) : unit = let variant_name = ctx_get_variant (AdtId def.def_id) variant_id ctx in F.pp_print_space fmt (); F.pp_open_hvbox fmt ctx.indent_incr; (* variant box *) (* `| Cons :` * Note that we really don't want any break above so we print everything * at once. *) F.pp_print_string fmt ("| " ^ variant_name ^ " :"); F.pp_print_space fmt (); let print_field (fid : FieldId.id) (f : field) (ctx : extraction_ctx) : extraction_ctx = (* Open the field box *) F.pp_open_box fmt ctx.indent_incr; (* Print the field names * ` x :` * Note that when printing fields, we register the field names as * *variables*: they don't need to be unique at the top level. *) let ctx = match f.field_name with | None -> ctx | Some field_name -> let var_id = VarId.of_int (FieldId.to_int fid) in let field_name = ctx.fmt.var_basename ctx.names_map.names_set (Some field_name) f.field_ty in let ctx, field_name = ctx_add_var field_name var_id ctx in F.pp_print_string fmt (field_name ^ " :"); F.pp_print_space fmt (); ctx in (* Print the field type *) extract_ty ctx fmt false f.field_ty; (* Print the arrow `->`*) F.pp_print_space fmt (); F.pp_print_string fmt "->"; (* Close the field box *) F.pp_close_box fmt (); F.pp_print_space fmt (); (* Return *) ctx in (* Print the fields *) let fields = FieldId.mapi (fun fid f -> (fid, f)) variant.fields in let _ = List.fold_left (fun ctx (fid, f) -> print_field fid f ctx) ctx fields in (* Print the final type *) F.pp_open_hovbox fmt 0; F.pp_print_string fmt def_name; List.iter (fun type_param -> F.pp_print_space fmt (); F.pp_print_string fmt type_param) type_params; F.pp_close_box fmt (); (* Close the variant box *) F.pp_close_box fmt () in (* Print the variants *) let variants = VariantId.mapi (fun vid v -> (vid, v)) variants in List.iter (fun (vid, v) -> print_variant vid v) variants (** Extract a type definition. Note that all the names used for extraction should already have been registered. *) let extract_type_def (ctx : extraction_ctx) (fmt : F.formatter) (qualif : type_def_qualif) (def : type_def) : unit = (* Retrieve the definition name *) let def_name = ctx_get_local_type def.def_id ctx in (* Add the type params - note that we need those bindings only for the * body translation (they are not top-level) *) let ctx_body, type_params = ctx_add_type_params def.type_params ctx in (* Add a break before *) F.pp_print_break fmt 0 0; (* Print a comment to link the extracted type to its original rust definition *) F.pp_print_string fmt ("(** [" ^ Print.name_to_string def.name ^ "] *)"); F.pp_print_space fmt (); (* Open a box for the definition, so that whenever possible it gets printed on * one line *) F.pp_open_hvbox fmt 0; (* Open a box for "type TYPE_NAME (TYPE_PARAMS) =" *) F.pp_open_hovbox fmt ctx.indent_incr; (* > "type TYPE_NAME" *) let qualif = match qualif with Type -> "type" | And -> "and" in F.pp_print_string fmt (qualif ^ " " ^ def_name); (* Print the type parameters *) if def.type_params <> [] then ( F.pp_print_space fmt (); F.pp_print_string fmt "("; List.iter (fun (p : type_var) -> let pname = ctx_get_type_var p.index ctx_body in F.pp_print_string fmt pname; F.pp_print_space fmt ()) def.type_params; F.pp_print_string fmt ":"; F.pp_print_space fmt (); F.pp_print_string fmt "Type0)"); (* Print the "=" *) F.pp_print_space fmt (); F.pp_print_string fmt "="; (* Close the box for "type TYPE_NAME (TYPE_PARAMS) =" *) F.pp_close_box fmt (); (match def.kind with | Struct fields -> extract_type_def_struct_body ctx_body fmt def fields | Enum variants -> extract_type_def_enum_body ctx_body fmt def def_name type_params variants); (* Close the box for the definition *) F.pp_close_box fmt (); (* Add breaks to insert new lines between definitions *) F.pp_print_break fmt 0 0 (** Compute the names for all the pure functions generated from a rust function (forward function and backward functions). *) let extract_fun_def_register_names (ctx : extraction_ctx) (def : pure_fun_translation) : extraction_ctx = let fwd, back_ls = def in (* Register the forward function name *) let ctx = ctx_add_fun_def fwd ctx in (* Register the backward functions' names *) let ctx = List.fold_left (fun ctx back -> ctx_add_fun_def back ctx) ctx back_ls in (* Return *) ctx (** The following function factorizes the extraction of ADT values. Note that lvalues can introduce new variables: we thus return an extraction context updated with new bindings. *) let extract_adt_g_value (extract_value : extraction_ctx -> bool -> 'v -> extraction_ctx) (fmt : F.formatter) (ctx : extraction_ctx) (inside : bool) (variant_id : VariantId.id option) (field_values : 'v list) (ty : ty) : extraction_ctx = match ty with | Adt (Tuple, _) -> (* Tuple *) F.pp_print_string fmt "("; let ctx = Collections.List.fold_left_link (fun () -> F.pp_print_string fmt ","; F.pp_print_space fmt ()) (fun ctx v -> extract_value ctx false v) ctx field_values in F.pp_print_string fmt ")"; ctx | Adt (adt_id, _) -> (* "Regular" ADT *) (* We print something of the form: `Cons field0 ... fieldn`. * We could update the code to print something of the form: * `{ field0=...; ...; fieldn=...; }` in case of structures. *) let cons = match variant_id with | Some vid -> ctx_get_variant adt_id vid ctx | None -> ctx_get_struct adt_id ctx in if inside && field_values <> [] then F.pp_print_string fmt "("; F.pp_print_string fmt cons; let ctx = Collections.List.fold_left (fun ctx v -> F.pp_print_space fmt (); extract_value ctx true v) ctx field_values in if inside && field_values <> [] then F.pp_print_string fmt ")"; ctx | _ -> failwith "Inconsistent typed value" (** [inside]: see [extract_ty]. As an lvalue can introduce new variables, we return an extraction context updated with new bindings. *) let rec extract_typed_lvalue (ctx : extraction_ctx) (fmt : F.formatter) (inside : bool) (v : typed_lvalue) : extraction_ctx = match v.value with | LvVar (Var (v, _)) -> let vname = ctx.fmt.var_basename ctx.names_map.names_set v.basename v.ty in let ctx, vname = ctx_add_var vname v.id ctx in F.pp_print_string fmt vname; ctx | LvVar Dummy -> F.pp_print_string fmt "_"; ctx | LvAdt av -> let extract_value ctx inside v = extract_typed_lvalue ctx fmt inside v in extract_adt_g_value extract_value fmt ctx inside av.variant_id av.field_values v.ty let extract_place (ctx : extraction_ctx) (fmt : F.formatter) (p : place) : unit = let rec extract_projection (pl : projection) : unit = match pl with | [] -> (* No projection element left: print the variable *) let var_name = ctx_get_var p.var ctx in F.pp_print_string fmt var_name | pe :: pl -> (* Extract the interior of the projection *) extract_projection pl; (* Match on the projection element *) let def_id = match pe.pkind with | E.ProjAdt (def_id, None) -> def_id | E.ProjAdt (_, Some _) | E.ProjTuple _ -> (* We can't have field accesses on enumerations (variables for * the fields are introduced upon the moment we match over the * enumeration). We also forbid field access on tuples, because * we don't have the syntax to translate that... We thus * deconstruct the tuples whenever we need to have access: * `let (x, y) = p in ...` *) failwith "Unreachable" in let field_name = ctx_get_field (AdtId def_id) pe.field_id ctx in (* We allow to break where the "." appears *) F.pp_print_break fmt 0 0; F.pp_print_string fmt "."; F.pp_print_string fmt field_name in extract_projection p.projection (** [inside]: see [extract_ty] *) let rec extract_typed_rvalue (ctx : extraction_ctx) (fmt : F.formatter) (inside : bool) (v : typed_rvalue) : extraction_ctx = match v.value with | RvConcrete cv -> ctx.fmt.extract_constant_value fmt inside cv; ctx | RvPlace p -> extract_place ctx fmt p; ctx | RvAdt av -> let extract_value ctx inside v = extract_typed_rvalue ctx fmt inside v in extract_adt_g_value extract_value fmt ctx inside av.variant_id av.field_values v.ty (** [inside]: see [extract_ty] *) let rec extract_texpression (ctx : extraction_ctx) (fmt : F.formatter) (inside : bool) (e : texpression) : unit = match e.e with | Value (rv, _) -> let _ = extract_typed_rvalue ctx fmt inside rv in () | Call call -> ( log#ldebug (lazy ("ctx_get_function: " ^ show_fun_id call.func)); match (call.func, call.args) with | Unop unop, [ arg ] -> ctx.fmt.extract_unop (extract_texpression ctx fmt) fmt inside unop arg | Binop (binop, int_ty), [ arg0; arg1 ] -> ctx.fmt.extract_binop (extract_texpression ctx fmt) fmt inside binop int_ty arg0 arg1 | Regular (fun_id, rg_id), _ -> if inside then F.pp_print_string fmt "("; (* Open a box for the function call *) F.pp_open_hovbox fmt ctx.indent_incr; (* Print the function name *) let fun_name = ctx_get_function fun_id rg_id ctx in F.pp_print_string fmt fun_name; (* Print the type parameters *) List.iter (fun ty -> F.pp_print_space fmt (); extract_ty ctx fmt true ty) call.type_params; (* Print the input values *) List.iter (fun ve -> F.pp_print_space fmt (); extract_texpression ctx fmt true ve) call.args; (* Close the box for the function call *) F.pp_close_box fmt (); (* Return *) if inside then F.pp_print_string fmt ")" | _ -> failwith "Unreachable") | Let (monadic, lv, re, next_e) -> (* Open a box for the let-binding *) F.pp_open_hovbox fmt ctx.indent_incr; let ctx = if monadic then ( (* Note that in F*, the left value of a monadic let-binding can only be * a variable *) let ctx = extract_typed_lvalue ctx fmt true lv in F.pp_print_space fmt (); F.pp_print_string fmt "<--"; F.pp_print_space fmt (); extract_texpression ctx fmt false re; F.pp_print_string fmt ";"; ctx) else ( F.pp_print_string fmt "let"; F.pp_print_space fmt (); let ctx = extract_typed_lvalue ctx fmt true lv in F.pp_print_space fmt (); F.pp_print_string fmt "="; F.pp_print_space fmt (); extract_texpression ctx fmt false re; F.pp_print_space fmt (); F.pp_print_string fmt "in"; ctx) in (* Close the box for the let-binding *) F.pp_close_box fmt (); (* Print the next expression *) F.pp_print_space fmt (); extract_texpression ctx fmt inside next_e | Switch (scrut, body) -> ( match body with | If (e_then, e_else) -> (* Open a box for the whole `if ... then ... else ...` *) F.pp_open_hvbox fmt 0; (* Open a box for the `if` *) F.pp_open_hovbox fmt ctx.indent_incr; F.pp_print_string fmt "if"; F.pp_print_space fmt (); extract_texpression ctx fmt false scrut; (* Close the box for the `if` *) F.pp_close_box fmt (); (* Extract the branches *) let extract_branch (is_then : bool) (e_branch : texpression) : unit = F.pp_print_space fmt (); (* Open a box for the branch *) F.pp_open_hovbox fmt ctx.indent_incr; let then_or_else = if is_then then "then" else "else" in F.pp_print_string fmt then_or_else; F.pp_print_space fmt (); let parenth = PureUtils.expression_requires_parentheses e_branch in if parenth then F.pp_print_string fmt "("; extract_texpression ctx fmt false e_branch; if parenth then F.pp_print_string fmt ")"; (* Close the box for the branch *) F.pp_close_box fmt () in extract_branch true e_then; extract_branch false e_else; (* Close the box for the whole `if ... then ... else ...` *) F.pp_close_box fmt () | SwitchInt (_, branches, otherwise) -> (* Open a box for the whole match *) F.pp_open_hvbox fmt 0; (* Open a box for the `match ... with` *) F.pp_open_hovbox fmt ctx.indent_incr; (* Print the `match ... with` *) F.pp_print_string fmt "begin match"; F.pp_print_space fmt (); extract_texpression ctx fmt false scrut; F.pp_print_space fmt (); F.pp_print_string fmt "with"; (* Close the box for the `match ... with` *) F.pp_close_box fmt (); (* Extract the branches *) let extract_branch (sv : scalar_value option) (e_branch : texpression) : unit = F.pp_print_space fmt (); (* Open a box for the pattern+branch *) F.pp_open_hovbox fmt ctx.indent_incr; F.pp_print_string fmt "|"; (* Print the pattern *) F.pp_print_space fmt (); (match sv with | Some sv -> ctx.fmt.extract_constant_value fmt false (V.Scalar sv) | None -> F.pp_print_string fmt "_"); F.pp_print_space fmt (); F.pp_print_string fmt "->"; F.pp_print_space fmt (); (* Open a box for the branch *) F.pp_open_hvbox fmt 0; (* Print the branch itself *) extract_texpression ctx fmt false e_branch; (* Close the box for the branch *) F.pp_close_box fmt (); (* Close the box for the pattern+branch *) F.pp_close_box fmt () in let all_branches = List.map (fun (sv, br) -> (Some sv, br)) branches in let all_branches = List.append all_branches [ (None, otherwise) ] in List.iter (fun (sv, br) -> extract_branch sv br) all_branches; (* End the match *) F.pp_print_space fmt (); F.pp_print_string fmt "end"; (* Close the box for the whole match *) F.pp_close_box fmt () | Match branches -> (* Open a box for the whole match *) F.pp_open_hvbox fmt 0; (* Open a box for the `match ... with` *) F.pp_open_hovbox fmt ctx.indent_incr; (* Print the `match ... with` *) F.pp_print_string fmt "begin match"; F.pp_print_space fmt (); extract_texpression ctx fmt false scrut; F.pp_print_space fmt (); F.pp_print_string fmt "with"; (* Close the box for the `match ... with` *) F.pp_close_box fmt (); (* Extract the branches *) let extract_branch (br : match_branch) : unit = F.pp_print_space fmt (); (* Open a box for the pattern+branch *) F.pp_open_hovbox fmt ctx.indent_incr; F.pp_print_string fmt "|"; (* Print the pattern *) F.pp_print_space fmt (); let ctx = extract_typed_lvalue ctx fmt false br.pat in F.pp_print_space fmt (); F.pp_print_string fmt "->"; F.pp_print_space fmt (); (* Open a box for the branch *) F.pp_open_hvbox fmt 0; (* Print the branch itself *) extract_texpression ctx fmt false br.branch; (* Close the box for the branch *) F.pp_close_box fmt (); (* Close the box for the pattern+branch *) F.pp_close_box fmt () in List.iter extract_branch branches; (* End the match *) F.pp_print_space fmt (); F.pp_print_string fmt "end"; (* Close the box for the whole match *) F.pp_close_box fmt ()) | Meta (_, e) -> extract_texpression ctx fmt inside e (** Extract a function definition. Note that all the names used for extraction should already have been registered. *) let extract_fun_def (ctx : extraction_ctx) (fmt : F.formatter) (qualif : fun_def_qualif) (def : fun_def) : unit = (* Retrieve the function name *) let def_name = ctx_get_local_function def.def_id def.back_id ctx in (* Add the type parameters - note that we need those bindings only for the * body translation (they are not top-level) *) let ctx, _ = ctx_add_type_params def.signature.type_params ctx in (* Add a break before *) F.pp_print_break fmt 0 0; (* Print a comment to link the extracted type to its original rust definition *) F.pp_print_string fmt ("(** [" ^ Print.name_to_string def.basename ^ "] *)"); F.pp_print_space fmt (); (* Open a box for the definition, so that whenever possible it gets printed on * one line *) F.pp_open_hvbox fmt 0; (* Open a box for "let FUN_NAME (PARAMS) =" *) F.pp_open_hovbox fmt ctx.indent_incr; (* > "let FUN_NAME" *) let qualif = match qualif with Let -> "let" | LetRec -> "let rec" | And -> "and" in F.pp_print_string fmt (qualif ^ " " ^ def_name); (* Print the parameters - rk.: we should have filtered the functions * with no input parameters *) (* The type parameters *) if def.signature.type_params <> [] then ( F.pp_print_space fmt (); F.pp_print_string fmt "("; List.iter (fun (p : type_var) -> let pname = ctx_get_type_var p.index ctx in F.pp_print_string fmt pname; F.pp_print_space fmt ()) def.signature.type_params; F.pp_print_string fmt ":"; F.pp_print_space fmt (); F.pp_print_string fmt "Type0)"); (* The input parameters - note that doing this adds bindings in the context *) let ctx = List.fold_left (fun ctx (lv : typed_lvalue) -> F.pp_print_space fmt (); F.pp_print_string fmt "("; let ctx = extract_typed_lvalue ctx fmt false lv in F.pp_print_space fmt (); F.pp_print_string fmt ":"; F.pp_print_space fmt (); extract_ty ctx fmt false lv.ty; F.pp_print_string fmt ")"; ctx) ctx def.inputs_lvs in (* Print the "=" *) F.pp_print_space fmt (); F.pp_print_string fmt "="; (* Close the box for "let FUN_NAME (PARAMS) =" *) F.pp_close_box fmt (); F.pp_print_break fmt 1 ctx.indent_incr; (* Open a box for the body *) F.pp_open_hvbox fmt 0; (* Extract the body *) let _ = extract_texpression ctx fmt false def.body in (* Close the box for the body *) F.pp_close_box fmt (); (* Close the box for the definition *) F.pp_close_box fmt (); (* Add breaks to insert new lines between definitions *) F.pp_print_break fmt 0 0