package melange-json
Compositional JSON encode/decode library and PPX for Melange, with native compatibility
Install
Dune Dependency
Authors
Maintainers
Sources
melange-json-1.2.0.tbz
sha256=080f34a2d6ce9c75ead1ba28264a102fe5326d09cb5347774d917bc52613b5f7
sha512=9308b09562eba762e3f61f82fcdaa49ca726868e3f411c2b944d35f1d9476584a7f3e0b60d7b1a5d2a53c66a39468a663ae410d93151c02d944dcea27eb12054
doc/src/ppx_deriving_json_native/ppx_deriving_tools.ml.html
Source file ppx_deriving_tools.ml
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txt = id } in let expr = pexp_ident ~loc { loc; txt = lident id } in patt, expr)) let gen_tuple ~loc prefix n = let ps, es = gen_bindings ~loc prefix n in ps, pexp_tuple ~loc es let gen_record ~loc prefix fs = let ps, es = List.split (List.map fs ~f:(fun (n, _attrs, _t) -> let id = sprintf "%s_%s" prefix n.txt in let patt = ppat_var ~loc { loc = n.loc; txt = id } in let expr = pexp_ident ~loc { loc = n.loc; txt = lident id } in (map_loc lident n, patt), expr)) in let ns, ps = List.split ps in ps, pexp_record ~loc (List.combine ns es) None let gen_pat_tuple ~loc prefix n = let patts, exprs = gen_bindings ~loc prefix n in ppat_tuple ~loc patts, exprs let gen_pat_list ~loc prefix n = let patts, exprs = gen_bindings ~loc prefix n in let patt = List.fold_left (List.rev patts) ~init:[%pat? []] ~f:(fun prev patt -> [%pat? [%p patt] :: [%p prev]]) in patt, exprs let gen_pat_record ~loc prefix ns = let xs = List.map ns ~f:(fun n -> let id = sprintf "%s_%s" prefix n.txt in let patt = ppat_var ~loc { loc = n.loc; txt = id } in let expr = pexp_ident ~loc { loc = n.loc; txt = lident id } in (map_loc lident n, patt), expr) in ppat_record ~loc (List.map xs ~f:fst) Closed, List.map xs ~f:snd let ( --> ) pc_lhs pc_rhs = { pc_lhs; pc_rhs; pc_guard = None } let derive_of_label name = mangle (Suffix name) let derive_of_longident name = mangle_lid (Suffix name) let ederiver name (lid : Longident.t loc) = pexp_ident ~loc:lid.loc (map_loc (derive_of_longident name) lid) type deriver = | As_fun of (expression -> expression) | As_val of expression let as_val ~loc deriver x = match deriver with As_fun f -> f x | As_val f -> [%expr [%e f] [%e x]] let as_fun ~loc deriver = match deriver with | As_fun f -> [%expr fun x -> [%e f [%expr x]]] | As_val f -> f class virtual deriving = object method virtual name : label method virtual extension : loc:location -> path:label -> core_type -> expression method virtual generator : ctxt:Expansion_context.Deriver.t -> rec_flag * type_declaration list -> structure end let register ?deps deriving = Deriving.add deriving#name ~str_type_decl: (Deriving.Generator.V2.make ?deps Deriving.Args.empty deriving#generator) ~extension:deriving#extension let register_combined ?deps name derivings = let generator ~ctxt bindings = List.fold_left derivings ~init:[] ~f:(fun str d -> d#generator ~ctxt bindings @ str) in Deriving.add name ~str_type_decl: (Deriving.Generator.V2.make ?deps Deriving.Args.empty generator) module Schema = struct let repr_row_field field = match field.prf_desc with | Rtag (id, _, ts) -> `Rtag (id, ts) | Rinherit { ptyp_desc = Ptyp_constr (id, ts); _ } -> `Rinherit (id, ts) | Rinherit _ -> not_supported ~loc:field.prf_loc "this polyvariant inherit" let repr_core_type ty = let loc = ty.ptyp_loc in match ty.ptyp_desc with | Ptyp_tuple ts -> `Ptyp_tuple ts | Ptyp_constr (id, ts) -> `Ptyp_constr (id, ts) | Ptyp_var txt -> `Ptyp_var { txt; loc = ty.ptyp_loc } | Ptyp_variant (fs, Closed, None) -> `Ptyp_variant fs | Ptyp_variant _ -> not_supported ~loc "non closed polyvariants" | Ptyp_arrow _ -> not_supported ~loc "function types" | Ptyp_any -> not_supported ~loc "type placeholders" | Ptyp_object _ -> not_supported ~loc "object types" | Ptyp_class _ -> not_supported ~loc "class types" | Ptyp_poly _ -> not_supported ~loc "polymorphic type expressions" | Ptyp_package _ -> not_supported ~loc "packaged module types" | Ptyp_extension _ -> not_supported ~loc "extension nodes" | Ptyp_alias _ -> not_supported ~loc "type aliases" let repr_type_declaration td = let loc = td.ptype_loc in match td.ptype_kind, td.ptype_manifest with | Ptype_abstract, None -> not_supported ~loc "abstract types" | Ptype_abstract, Some t -> `Ptype_core_type t | Ptype_variant ctors, _ -> `Ptype_variant ctors | Ptype_record fs, _ -> `Ptype_record fs | Ptype_open, _ -> not_supported ~loc "open types" let repr_type_declaration_is_poly td = match repr_type_declaration td with | `Ptype_core_type ({ ptyp_desc = Ptyp_variant _; _ } as t) -> `Ptyp_variant t | _ -> `Other let gen_type_ascription (td : type_declaration) = let loc = td.ptype_loc in ptyp_constr ~loc { loc; txt = lident td.ptype_name.txt } (List.map td.ptype_params ~f:(fun (p, _) -> match p.ptyp_desc with | Ptyp_var name -> ptyp_var ~loc name | _ -> failwith "this cannot be a type parameter")) class virtual deriving0 = object (self) inherit deriving method virtual t : loc:location -> label loc -> core_type -> core_type method derive_of_tuple : loc:location -> core_type list -> expression = not_supported "tuple types" method derive_of_record : loc:location -> label_declaration list -> expression = not_supported "record types" method derive_of_variant : loc:location -> constructor_declaration list -> expression = not_supported "variant types" method derive_of_polyvariant : loc:location -> row_field list -> expression = not_supported "polyvariant types" method private derive_type_ref_name : label -> longident loc -> expression = fun name n -> ederiver name n method derive_type_ref ~loc name n ts = let f = self#derive_type_ref_name name n in let args = List.fold_left (List.rev ts) ~init:[] ~f:(fun args a -> let a = self#derive_of_core_type a in (Nolabel, a) :: args) in pexp_apply ~loc f args method derive_of_core_type ty = let loc = ty.ptyp_loc in match repr_core_type ty with | `Ptyp_tuple ts -> self#derive_of_tuple ~loc ts | `Ptyp_constr (id, ts) -> self#derive_type_ref self#name ~loc id ts | `Ptyp_var label -> ederiver self#name (map_loc lident label) | `Ptyp_variant fs -> self#derive_of_polyvariant ~loc fs method derive_of_type_declaration td = let loc = td.ptype_loc in let name = td.ptype_name in let params = List.map td.ptype_params ~f:(fun (t, _) -> match t.ptyp_desc with | Ptyp_var txt -> { txt; loc = t.ptyp_loc } | _ -> failwith "type variable is not a variable") in let expr = match repr_type_declaration td with | `Ptype_core_type t -> self#derive_of_core_type t | `Ptype_variant ctors -> self#derive_of_variant ~loc ctors | `Ptype_record fs -> self#derive_of_record ~loc fs in let t = gen_type_ascription td in let expr = [%expr ([%e expr] : [%t self#t ~loc name t])] in let expr = List.fold_left params ~init:expr ~f:(fun body name -> pexp_fun ~loc Nolabel None (ppat_var ~loc (map_loc (derive_of_label self#name) name)) body) in [ value_binding ~loc ~pat:(ppat_var ~loc (self#derive_type_decl_label name)) ~expr; ] method private derive_type_decl_label name = map_loc (derive_of_label self#name) name method extension : loc:location -> path:label -> core_type -> expression = fun ~loc:_ ~path:_ ty -> self#derive_of_core_type ty method generator : ctxt:Expansion_context.Deriver.t -> rec_flag * type_declaration list -> structure = fun ~ctxt (_rec_flag, type_decls) -> let loc = Expansion_context.Deriver.derived_item_loc ctxt in let bindings = List.concat_map type_decls ~f:(fun decl -> self#derive_of_type_declaration decl) in [%str [@@@ocaml.warning "-39-11-27"] [%%i pstr_value ~loc Recursive bindings]] end class virtual deriving1 = object (self) inherit deriving method virtual t : loc:location -> label loc -> core_type -> core_type method derive_of_tuple : core_type -> core_type list -> expression -> expression = fun t _ _ -> let loc = t.ptyp_loc in not_supported "tuple types" ~loc method derive_of_record : type_declaration -> label_declaration list -> expression -> expression = fun td _ _ -> let loc = td.ptype_loc in not_supported "record types" ~loc method derive_of_variant : type_declaration -> constructor_declaration list -> expression -> expression = fun td _ _ -> let loc = td.ptype_loc in not_supported "variant types" ~loc method derive_of_polyvariant : core_type -> row_field list -> expression -> expression = fun t _ _ -> let loc = t.ptyp_loc in not_supported "polyvariant types" ~loc method private derive_type_ref_name : label -> longident loc -> expression = fun name n -> ederiver name n method private derive_type_ref' ~loc name n ts = let f = self#derive_type_ref_name name n in let args = List.fold_left (List.rev ts) ~init:[] ~f:(fun args a -> let a = as_fun ~loc (self#derive_of_core_type' a) in (Nolabel, a) :: args) in As_val (pexp_apply ~loc f args) method derive_type_ref ~loc name n ts x = as_val ~loc (self#derive_type_ref' ~loc name n ts) x method private derive_of_core_type' t = let loc = t.ptyp_loc in match repr_core_type t with | `Ptyp_tuple ts -> As_fun (self#derive_of_tuple t ts) | `Ptyp_var label -> As_val (ederiver self#name (map_loc lident label)) | `Ptyp_constr (id, ts) -> self#derive_type_ref' self#name ~loc id ts | `Ptyp_variant fs -> As_fun (self#derive_of_polyvariant t fs) method derive_of_core_type t x = let loc = x.pexp_loc in as_val ~loc (self#derive_of_core_type' t) x method private derive_type_decl_label name = map_loc (derive_of_label self#name) name method derive_of_type_declaration td = let loc = td.ptype_loc in let name = td.ptype_name in let rev_params = List.rev_map td.ptype_params ~f:(fun (t, _) -> match t.ptyp_desc with | Ptyp_var txt -> { txt; loc = t.ptyp_loc } | _ -> failwith "type variable is not a variable") in let x = [%expr x] in let expr = match repr_type_declaration td with | `Ptype_core_type t -> self#derive_of_core_type t x | `Ptype_variant ctors -> self#derive_of_variant td ctors x | `Ptype_record fs -> self#derive_of_record td fs x in let expr = [%expr (fun x -> [%e expr] : [%t self#t ~loc name (gen_type_ascription td)])] in let expr = List.fold_left rev_params ~init:expr ~f:(fun body param -> pexp_fun ~loc Nolabel None (ppat_var ~loc (map_loc (derive_of_label self#name) param)) body) in [ value_binding ~loc ~pat:(ppat_var ~loc (self#derive_type_decl_label name)) ~expr; ] method extension : loc:location -> path:label -> core_type -> expression = fun ~loc:_ ~path:_ ty -> let loc = ty.ptyp_loc in as_fun ~loc (self#derive_of_core_type' ty) method generator : ctxt:Expansion_context.Deriver.t -> rec_flag * type_declaration list -> structure = fun ~ctxt (_rec_flag, tds) -> let loc = Expansion_context.Deriver.derived_item_loc ctxt in let bindings = List.concat_map tds ~f:self#derive_of_type_declaration in [%str [@@@ocaml.warning "-39-11-27"] [%%i pstr_value ~loc Recursive bindings]] end end module Conv = struct type 'ctx tuple = { tpl_loc : location; tpl_types : core_type list; tpl_ctx : 'ctx; } type 'ctx record = { rcd_loc : location; rcd_fields : label_declaration list; rcd_ctx : 'ctx; } type variant_case = | Vcs_tuple of label loc * variant_case_ctx tuple | Vcs_record of label loc * variant_case_ctx record | Vcs_enum of label loc * variant_case_ctx and variant_case_ctx = | Vcs_ctx_variant of constructor_declaration | Vcs_ctx_polyvariant of row_field type variant = { vrt_loc : location; vrt_cases : variant_case list; vrt_ctx : variant_ctx; } and variant_ctx = | Vrt_ctx_variant of type_declaration | Vrt_ctx_polyvariant of core_type let repr_polyvariant_cases cs = let cases = List.rev cs |> List.map ~f:(fun c -> c, Schema.repr_row_field c) in let is_enum = List.for_all cases ~f:(fun (_, r) -> match r with | `Rtag (_, ts) -> ( match ts with [] -> true | _ :: _ -> false) | `Rinherit _ -> false) in is_enum, cases let repr_variant_cases cs = let cs = List.rev cs in let is_enum = List.for_all cs ~f:(fun (c : constructor_declaration) -> match c.pcd_args with | Pcstr_record [] -> true | Pcstr_tuple [] -> true | Pcstr_record _ | Pcstr_tuple _ -> false) in is_enum, cs let deriving_of ~name ~of_t ~error ~derive_of_tuple ~derive_of_record ~derive_of_variant ~derive_of_variant_case () = let poly_name = sprintf "%s_poly" name in let poly = object (self) inherit Schema.deriving1 method name = name method t ~loc _name t = [%type: [%t of_t ~loc] -> [%t t] option] method! derive_type_decl_label name = map_loc (derive_of_label poly_name) name method! derive_of_tuple t ts x = let t = { tpl_loc = t.ptyp_loc; tpl_types = ts; tpl_ctx = t } in derive_of_tuple self#derive_of_core_type t x method! derive_of_record _ _ _ = assert false method! derive_of_variant _ _ _ = assert false method! derive_of_polyvariant t (cs : row_field list) x = let loc = t.ptyp_loc in let is_enum, cases = repr_polyvariant_cases cs in let body, cases = List.fold_left cases ~init:([%expr None], []) ~f:(fun (next, cases) (c, r) -> match r with | `Rtag (n, ts) -> let make arg = [%expr Some [%e pexp_variant ~loc:n.loc n.txt arg]] in let ctx = Vcs_ctx_polyvariant c in let case = if is_enum then Vcs_enum (n, ctx) else let t = { tpl_loc = loc; tpl_types = ts; tpl_ctx = ctx } in Vcs_tuple (n, t) in let next = derive_of_variant_case self#derive_of_core_type make case next in next, case :: cases | `Rinherit (id, ts) -> let x = self#derive_type_ref ~loc poly_name id ts x in let t = ptyp_variant ~loc cs Closed None in let next = [%expr match [%e x] with | Some x -> (Some x :> [%t t] option) | None -> [%e next]] in next, cases) in let t = { vrt_loc = loc; vrt_cases = cases; vrt_ctx = Vrt_ctx_polyvariant t; } in derive_of_variant self#derive_of_core_type t body x end in (object (self) inherit Schema.deriving1 as super method name = name method t ~loc _name t = [%type: [%t of_t ~loc] -> [%t t]] method! derive_of_tuple t ts x = let t = { tpl_loc = t.ptyp_loc; tpl_types = ts; tpl_ctx = t } in derive_of_tuple self#derive_of_core_type t x method! derive_of_record td fs x = let t = { rcd_loc = td.ptype_loc; rcd_fields = fs; rcd_ctx = td } in derive_of_record self#derive_of_core_type t x method! derive_of_variant td cs x = let loc = td.ptype_loc in let is_enum, cs = repr_variant_cases cs in let body, cases = List.fold_left cs ~init:(error ~loc, []) ~f:(fun (next, cases) c -> let make (n : label loc) arg = pexp_construct (map_loc lident n) ~loc:n.loc arg in let ctx = Vcs_ctx_variant c in let n = c.pcd_name in match c.pcd_args with | Pcstr_record fs -> let t = if is_enum then Vcs_enum (n, ctx) else let t = { rcd_loc = loc; rcd_fields = fs; rcd_ctx = ctx } in Vcs_record (n, t) in let next = derive_of_variant_case self#derive_of_core_type (make n) t next in next, t :: cases | Pcstr_tuple ts -> let case = if is_enum then Vcs_enum (n, ctx) else let t = { tpl_loc = loc; tpl_types = ts; tpl_ctx = ctx } in Vcs_tuple (n, t) in let next = derive_of_variant_case self#derive_of_core_type (make n) case next in next, case :: cases) in let t = { vrt_loc = loc; vrt_cases = cases; vrt_ctx = Vrt_ctx_variant td; } in derive_of_variant self#derive_of_core_type t body x method! derive_of_polyvariant t (cs : row_field list) x = let loc = t.ptyp_loc in let is_enum, cases = repr_polyvariant_cases cs in let body, cases = List.fold_left cases ~init:(error ~loc, []) ~f:(fun (next, cases) (c, r) -> let ctx = Vcs_ctx_polyvariant c in match r with | `Rtag (n, ts) -> let make arg = pexp_variant ~loc:n.loc n.txt arg in let case = if is_enum then Vcs_enum (n, ctx) else let t = { tpl_loc = loc; tpl_types = ts; tpl_ctx = ctx } in Vcs_tuple (n, t) in let next = derive_of_variant_case self#derive_of_core_type make case next in next, case :: cases | `Rinherit (n, ts) -> let maybe_e = poly#derive_type_ref ~loc poly_name n ts x in let t = ptyp_variant ~loc cs Closed None in let next = [%expr match [%e maybe_e] with | Some e -> (e :> [%t t]) | None -> [%e next]] in next, cases) in let t = { vrt_loc = loc; vrt_cases = cases; vrt_ctx = Vrt_ctx_polyvariant t; } in derive_of_variant self#derive_of_core_type t body x method! derive_of_type_declaration td = match Schema.repr_type_declaration_is_poly td with | `Ptyp_variant _ -> let str = let loc = td.ptype_loc in let decl_name = td.ptype_name in let params = List.map td.ptype_params ~f:(fun (t, _) -> match t.ptyp_desc with | Ptyp_var txt -> t, { txt; loc = t.ptyp_loc } | _ -> assert false) in let expr = let x = [%expr x] in let init = poly#derive_type_ref ~loc poly_name (map_loc lident decl_name) (List.map params ~f:fst) x in let init = [%expr (fun x -> match [%e init] with | Some x -> x | None -> [%e error ~loc] : [%t self#t ~loc decl_name (Schema.gen_type_ascription td)])] in List.fold_left params ~init ~f:(fun body (_, param) -> pexp_fun ~loc Nolabel None (ppat_var ~loc (map_loc (derive_of_label name) param)) body) in [ value_binding ~loc ~pat: (ppat_var ~loc (map_loc (derive_of_label self#name) decl_name)) ~expr; ] in poly#derive_of_type_declaration td @ str | `Other -> super#derive_of_type_declaration td end :> deriving) let deriving_of_match ~name ~of_t ~error ~derive_of_tuple ~derive_of_record ~derive_of_variant_case () = let poly_name = sprintf "%s_poly" name in let poly = object (self) inherit Schema.deriving1 method name = name method t ~loc _name t = [%type: [%t of_t ~loc] -> [%t t] option] method! derive_type_decl_label name = map_loc (derive_of_label poly_name) name method! derive_of_tuple t ts x = let t = { tpl_loc = t.ptyp_loc; tpl_types = ts; tpl_ctx = t } in derive_of_tuple self#derive_of_core_type t x method! derive_of_record _ _ _ = assert false method! derive_of_variant _ _ _ = assert false method! derive_of_polyvariant t (cs : row_field list) x = let loc = t.ptyp_loc in let is_enum, cases = repr_polyvariant_cases cs in let ctors, inherits = List.partition_map cases ~f:(fun (c, r) -> let ctx = Vcs_ctx_polyvariant c in match r with | `Rtag (n, ts) -> if is_enum then Left (n, Vcs_enum (n, ctx)) else let t = { tpl_loc = loc; tpl_types = ts; tpl_ctx = ctx } in Left (n, Vcs_tuple (n, t)) | `Rinherit (n, ts) -> Right (n, ts)) in let catch_all = [%pat? x] --> List.fold_left (List.rev inherits) ~init:[%expr None] ~f:(fun next (n, ts) -> let maybe = self#derive_type_ref ~loc poly_name n ts [%expr x] in let t = ptyp_variant ~loc cs Closed None in [%expr match [%e maybe] with | Some x -> (Some x :> [%t t] option) | None -> [%e next]]) in let cases = List.fold_left ctors ~init:[ catch_all ] ~f:(fun next (n, case) -> let make arg = [%expr Some [%e pexp_variant ~loc:n.loc n.txt arg]] in derive_of_variant_case self#derive_of_core_type make case :: next) in pexp_match ~loc x cases end in (object (self) inherit Schema.deriving1 as super method name = name method t ~loc _name t = [%type: [%t of_t ~loc] -> [%t t]] method! derive_of_tuple t ts x = let t = { tpl_loc = t.ptyp_loc; tpl_types = ts; tpl_ctx = t } in derive_of_tuple self#derive_of_core_type t x method! derive_of_record td fs x = let t = { rcd_loc = td.ptype_loc; rcd_fields = fs; rcd_ctx = td } in derive_of_record self#derive_of_core_type t x method! derive_of_variant td cs x = let loc = td.ptype_loc in let is_enum, cs = repr_variant_cases cs in let cases = List.fold_left cs ~init:[ [%pat? _] --> error ~loc ] ~f:(fun next (c : constructor_declaration) -> let ctx = Vcs_ctx_variant c in let make (n : label loc) arg = pexp_construct (map_loc lident n) ~loc:n.loc arg in let n = c.pcd_name in match c.pcd_args with | Pcstr_record fs -> let t = if is_enum then Vcs_enum (n, ctx) else let r = { rcd_loc = loc; rcd_fields = fs; rcd_ctx = ctx } in Vcs_record (n, r) in derive_of_variant_case self#derive_of_core_type (make n) t :: next | Pcstr_tuple ts -> let t = if is_enum then Vcs_enum (n, ctx) else let t = { tpl_loc = loc; tpl_types = ts; tpl_ctx = ctx } in Vcs_tuple (n, t) in derive_of_variant_case self#derive_of_core_type (make n) t :: next) in pexp_match ~loc x cases method! derive_of_polyvariant t (cs : row_field list) x = let loc = t.ptyp_loc in let is_enum, cases = repr_polyvariant_cases cs in let ctors, inherits = List.partition_map cases ~f:(fun (c, r) -> let ctx = Vcs_ctx_polyvariant c in match r with | `Rtag (n, ts) -> if is_enum then Left (n, Vcs_enum (n, ctx)) else let t = { tpl_loc = loc; tpl_types = ts; tpl_ctx = ctx } in Left (n, Vcs_tuple (n, t)) | `Rinherit (n, ts) -> Right (n, ts)) in let catch_all = [%pat? x] --> List.fold_left (List.rev inherits) ~init:(error ~loc) ~f:(fun next (n, ts) -> let maybe = poly#derive_type_ref ~loc poly_name n ts x in let t = ptyp_variant ~loc cs Closed None in [%expr match [%e maybe] with | Some x -> (x :> [%t t]) | None -> [%e next]]) in let cases = List.fold_left ctors ~init:[ catch_all ] ~f:(fun next ((n : label loc), t) -> let make arg = pexp_variant ~loc:n.loc n.txt arg in derive_of_variant_case self#derive_of_core_type make t :: next) in pexp_match ~loc x cases method! derive_of_type_declaration td = match Schema.repr_type_declaration_is_poly td with | `Ptyp_variant _ -> let str = let loc = td.ptype_loc in let decl_name = td.ptype_name in let params = List.map td.ptype_params ~f:(fun (t, _) -> match t.ptyp_desc with | Ptyp_var txt -> t, { txt; loc = t.ptyp_loc } | _ -> assert false) in let expr = let x = [%expr x] in let init = poly#derive_type_ref ~loc poly_name (map_loc lident decl_name) (List.map params ~f:fst) x in let init = [%expr (fun x -> match [%e init] with | Some x -> x | None -> [%e error ~loc] : [%t self#t ~loc decl_name (Schema.gen_type_ascription td)])] in List.fold_left params ~init ~f:(fun body (_, param) -> pexp_fun ~loc Nolabel None (ppat_var ~loc (map_loc (derive_of_label name) param)) body) in [ value_binding ~loc ~pat: (ppat_var ~loc (map_loc (derive_of_label self#name) decl_name)) ~expr; ] in poly#derive_of_type_declaration td @ str | `Other -> super#derive_of_type_declaration td end :> deriving) let deriving_to ~name ~t_to ~derive_of_tuple ~derive_of_record ~derive_of_variant_case () = (object (self) inherit Schema.deriving1 method name = name method t ~loc _name t = [%type: [%t t] -> [%t t_to ~loc]] method! derive_of_tuple t ts x = let loc = t.ptyp_loc in let t = { tpl_loc = loc; tpl_types = ts; tpl_ctx = t } in let n = List.length ts in let p, es = gen_pat_tuple ~loc "x" n in pexp_match ~loc x [ p --> derive_of_tuple self#derive_of_core_type t es ] method! derive_of_record td fs x = let t = { rcd_loc = td.ptype_loc; rcd_fields = fs; rcd_ctx = td } in let loc = td.ptype_loc in let p, es = gen_pat_record ~loc "x" (List.map fs ~f:(fun f -> f.pld_name)) in pexp_match ~loc x [ p --> derive_of_record self#derive_of_core_type t es ] method! derive_of_variant td cs x = let loc = td.ptype_loc in let ctor_pat (n : label loc) pat = ppat_construct ~loc:n.loc (map_loc lident n) pat in let is_enum, cs = repr_variant_cases cs in pexp_match ~loc x (List.rev_map cs ~f:(fun c -> let n = c.pcd_name in let ctx = Vcs_ctx_variant c in match c.pcd_args with | Pcstr_record fs -> let p, es = gen_pat_record ~loc "x" (List.map fs ~f:(fun f -> f.pld_name)) in let t = if is_enum then Vcs_enum (n, ctx) else let t = { rcd_loc = loc; rcd_fields = fs; rcd_ctx = ctx; } in Vcs_record (n, t) in ctor_pat n (Some p) --> derive_of_variant_case self#derive_of_core_type t es | Pcstr_tuple ts -> let arity = List.length ts in let t = if is_enum then Vcs_enum (n, ctx) else let t = { tpl_loc = loc; tpl_types = ts; tpl_ctx = ctx } in Vcs_tuple (n, t) in let p, es = gen_pat_tuple ~loc "x" arity in ctor_pat n (if arity = 0 then None else Some p) --> derive_of_variant_case self#derive_of_core_type t es)) method! derive_of_polyvariant t (cs : row_field list) x = let loc = t.ptyp_loc in let is_enum, cases = repr_polyvariant_cases cs in let cases = List.rev_map cases ~f:(fun (c, r) -> let ctx = Vcs_ctx_polyvariant c in match r with | `Rtag (n, []) -> let t = if is_enum then Vcs_enum (n, ctx) else let t = { tpl_loc = loc; tpl_types = []; tpl_ctx = ctx } in Vcs_tuple (n, t) in ppat_variant ~loc n.txt None --> derive_of_variant_case self#derive_of_core_type t [] | `Rtag (n, ts) -> assert (not is_enum); let t = { tpl_loc = loc; tpl_types = ts; tpl_ctx = ctx } in let ps, es = gen_pat_tuple ~loc "x" (List.length ts) in ppat_variant ~loc n.txt (Some ps) --> derive_of_variant_case self#derive_of_core_type (Vcs_tuple (n, t)) es | `Rinherit (n, ts) -> assert (not is_enum); [%pat? [%p ppat_type ~loc n] as x] --> self#derive_of_core_type (ptyp_constr ~loc:n.loc n ts) [%expr x]) in pexp_match ~loc x cases end :> deriving) end include Schema