Module Bin_prot.Shape

include Bin_shape_lib.Std.Shape
type t

Shape.t are constructed by the bin_shape syntax extension from Ocaml type definitions & expressions.

There is a direct mapping from ocaml type definition syntax to the corresponding Shape.group and from ocaml type expression syntax to the corresponding Shape.t.

val sexp_of_t : t -> Ppx_sexp_conv_lib.Sexp.t
module Location = Bin_shape_lib.Bin_shape.Location

Location.t is required when constructing shapes for which evaluation might fail.

module Uuid = Bin_shape_lib.Bin_shape.Uuid

Uuid.t is used by basetype and annotate.

type group

group of mutually recursive type definitions

val group : Location.t -> (Tid.t * Vid.t list * t) list -> group

This function is generative; repeated calls create distinct groups

val tuple : t list -> t
val record : (string * t) list -> t
val variant : (string * t list) list -> t
type poly_variant_row
val constr : string -> t option -> poly_variant_row
val inherit_ : Location.t -> t -> poly_variant_row
val poly_variant : Location.t -> poly_variant_row list -> t
val rec_app : Tid.t -> t list -> t

recursive apps within the current group

val top_app : group -> Tid.t -> t list -> t

apps from outside the group

val var : Location.t -> Vid.t -> t
val basetype : Uuid.t -> t list -> t

Built-in types and types with custom serialization: i.e. int,list,... To avoid accidental protocol compatibility, pass a UUID as the string argument

val annotate : Uuid.t -> t -> t
val eval : t -> Canonical.t

eval t returns the canonical-shape for a shape-expression Shape.t. Type aliases are expanded, so that no Tid.t or Vid.t have significance in the resulting canonical-shape. Type-recursion, including non-regular recursion, is translated to the de-bruijn representation used in canonical-shapes.

val eval_to_digest : t -> Digest.t

eval_to_digest t returns a hash-value direct from the Shape.t, potentially avoiding the intermediate Canonical.t from being constructed. This is important as the size of a canonical-shape might be exponential in terms of the size of the shape expression. The following holds: Digest.(eval_to_digest exp = Canonical.to_digest (eval exp))

val eval_to_digest_string : t -> string

eval_to_digest_string t == Digest.to_hex (eval_to_digest t) Convenience function useful for writing unit tests.

val bin_shape_unit : t
val bin_shape_bool : t
val bin_shape_string : t
val bin_shape_bytes : t
val bin_shape_char : t
val bin_shape_float : t
val bin_shape_int : t
val bin_shape_int32 : t
val bin_shape_int63 : t
val bin_shape_int64 : t
val bin_shape_nativeint : t
val bin_shape_nat0 : t
val bin_shape_digest : t
val bin_shape_float32_vec : t
val bin_shape_float64_vec : t
val bin_shape_vec : t
val bin_shape_float32_mat : t
val bin_shape_float64_mat : t
val bin_shape_mat : t
val bin_shape_bigstring : t
val bin_shape_variant_int : t
val bin_shape_int_8bit : t
val bin_shape_int_16bit : t
val bin_shape_int_32bit : t
val bin_shape_int_64bit : t
val bin_shape_int64_bits : t
val bin_shape_network16_int : t
val bin_shape_network32_int : t
val bin_shape_network32_int32 : t
val bin_shape_network64_int : t
val bin_shape_network64_int64 : t
val bin_shape_ref : t -> t
val bin_shape_option : t -> t
val bin_shape_list : t -> t
val bin_shape_array : t -> t
val bin_shape_hashtbl : t -> t -> t
val bin_shape_float_array : t
val bin_shape_lazy : 'a -> 'a
val bin_shape_pair : t -> t -> t
val bin_shape_triple : t -> t -> t -> t