package ppx_jsonaf_conv
[@@deriving] plugin to generate Jsonaf conversion functions
Install
Dune Dependency
Authors
Maintainers
Sources
ppx_jsonaf_conv-v0.16.0.tar.gz
sha256=b9e7e6fb74e673d79429c980d03aef6cf581ce792708007ed8929842776efc5b
README.org.html
README.org
#+TITLE: ppx_jsonaf_conv * [@@deriving jsonaf] =ppx_jsonaf_conv= is a PPX syntax extension that generates code for converting OCaml types to and from [Jsonaf_kernel.t], as defined in the [[https://github.com/inhabitedtype/jsonaf][=jsonaf=]] library. [Jsonaf_kernel.t] is defined by the following type: #+begin_src ocaml type t = [ `Null | `True | `False | `Number of string | `String of string | `Object of (string * t) list | `Array of t list ] #+end_src =ppx_jsonaf_conv= fits into the [[https://github.com/whitequark/ppx_deriving][=ppx_deriving=]] framework, so you can invoke it the same way you invoke any other deriving plug-in. Thus, we can write #+begin_src ocaml type int_pair = (int * int) [@@deriving jsonaf] #+end_src to get two values defined automatically, =jsonaf_of_int_pair= and =int_pair_of_jsonaf=. If we only want one direction, we can write one of the following. #+begin_src ocaml type int_pair = (int * int) [@@deriving jsonaf_of] type int_pair = (int * int) [@@deriving of_jsonaf] #+end_src Note that Jsonaf_kernel-converters for primitive types like =int= need to be brought into scope in order for the ppx to use them, for example by adding =open Jsonaf.Export= or =open Jsonaf_kernel.Jsonaf_conv.Primitives= at the beginning of the file. It's also possible to construct converters based on type expressions, /i.e./: #+begin_src ocaml [%jsonaf_of: (int * string) list] [1,"one"; 2,"two"] |> Jsonaf_kernel.to_string;; => {|[[1,"one"],[2,"two"]]|} [%jsonaf_of: (int * string) list] [1,"one"; 2,"two"] |> [%of_jsonaf: (int * string) list];; => [1,"one"; 2,"two"] #+end_src For =%jsonaf_of=, we can also omit the conversion of some types by putting underscores for that type name. #+begin_src ocaml [%jsonaf_of: (int * _) list] [1,"one"; 2,"two"] |> Jsonaf_kernel.to_string;; => {|[[1,"_"],[2,"_"]]|} #+end_src ** Conversion rules In the following, we'll review the serialization rules for different OCaml types. *** Basic types For numbers like =int=, =int32=, =int64=, =float=, the value is stored as =`Number str= where =str= is the string representing the number in decimal. For the types =char= or =string=, the value is stored as =`String str= where =str= is respectively a one character string or the string itself. *** Lists and arrays OCaml-lists and arrays are represented as json lists (=`Array=). *** Tuples and unit OCaml tuples are treated as lists of values in the same order as in the tuple. The type =unit= is treated as Jsonaf_kernel =`Null=. /e.g./: #+begin_src ocaml (3.14, "foo", "bar bla", 27) => [3.14, "foo", "bar bla", 27] #+end_src *** Options With options, =None= is treated as Jsonaf_kernel =`Null=, and =Some= is treated as the value contained, as shown below. #+begin_src ocaml None => `Null Some value => value #+end_src The rules for variants are described below. *** Records Records are represented as Jsonaf_kernel =`Object of (string * t) list=, where item of the list is a key-value pair. Each pair consists of the name of the record field (first element), and its value (second element). /e.g./: #+begin_src ocaml { foo = (3,4); bar = "some string"; } => {"foo":[3,4],"bar":"some string"} #+end_src Type specifications of records allow the use of several attributes. The attribute =jsonaf.option= indicates that a record field should be optional. /e.g./: #+begin_src ocaml type t = { x : int option; y : int option [@jsonaf.option]; } [@@deriving jsonaf] #+end_src The following examples show how this works. #+begin_src ocaml { x = Some 1; y = Some 2; } => {"x":1,"y":2} { x = None ; y = None; } => {"x":null} #+end_src When the JSON object keys differ from the ocaml field names, users can specify the corresponding JSON key implicitly using =[@key "field"]=, for example: #+begin_src ocaml type t = { typ : float [@key "type"]; class_ : float [@key "CLASS"]; } [@@deriving jsonaf, jsonaf_fields] #+end_src The =jsonaf_fields= attribute generates the list of JSON keys from a record type, for example: #+begin_src ocaml type ty = { x : float [@key "a"]; y : float [@key "b"]; z : float } [@@deriving jsonaf_fields] #+end_src generates the list below, and the list will not be generated for the signature. #+begin_src ocaml jsonaf_fields_of_ty = ["a"; "b"; "z"] #+end_src **** Defaults More complex default values can be specified explicitly using several constructs, /e.g./: #+begin_src ocaml type t = { a : int [@default 42]; b : int [@default 3] [@jsonaf_drop_default (=)]; c : int [@default 3] [@jsonaf_drop_if fun x -> x = 3]; d : int list } [@@deriving jsonaf] #+end_src The =@default= annotation lets one specify a default value to be selected if the field is not specified, when converting from Jsonaf_kernel. The =@jsonaf_drop_default= annotation implies that the field will be dropped when generating the =Jsonaf_kernel.t= if the value being serialized is equal to the default according to the specified equality function. =@jsonaf_drop_if= is like =@jsonaf_drop_default=, except that it lets you specify the condition under which the field is dropped. ***** Specifying equality for [@jsonaf_drop_default] The equality used by [@jsonaf_drop_default] is customizable. There are several ways to specify the equality function: #+begin_src ocaml type t = { a : u [@default u0] [@jsonaf_drop_default (=)]; (* explicit user-provided function *) b : u [@default u0] [@jsonaf_drop_default.compare]; (* uses [%compare.equal: u] *) c : u [@default u0] [@jsonaf_drop_default.equal]; (* uses [%equal: u] *) d : u [@default u0] [@jsonaf_drop_default.jsonaf]; (* compares jsonaf representations *) e : u [@default u0] [@jsonaf_drop_default]; (* deprecated. uses polymorphic equality. *) } [@@deriving jsonaf] #+end_src **** Allowing extra fields The =@jsonaf.allow_extra_fields= annotation lets one specify that the jsonaf-converters should silently ignore extra fields, instead of raising. This applies only to the record to which the annotation is attached, and not to deeper jsonaf converters that may be called during conversion of a jsonaf to the record. #+begin_src ocaml type t = { a: int } [@@deriving jsonaf] {"a":1,"b":2} => exception type t = { a: int } [@@deriving jsonaf] [@@jsonaf.allow_extra_fields] {"a":1,"b":2} => {a = 1} type t = A of { a : int } [@jsonaf.allow_extra_fields] [@@deriving jsonaf] ["A", {"a":1,"b":2}] => A {a = 1} #+end_src *** Variants Constant constructors in variants are represented as a list with one string, which is the name of the contructor. Constructors with arguments are represented as lists, the first element being the constructor name, the rest being its arguments. For example: #+begin_src ocaml type t = A | B of int * float * t [@@deriving jsonaf] B (42, 3.14, B (-1, 2.72, A)) => ["B",42,3.14,["B",-1,2.72,["A"]]] #+end_src The above example also demonstrates recursion in data structures. if the JSON variant names differ from OCaml conventions, users can specify the corresponding JSON string explicitly using =[@name "constr"]=, for example: #+begin_src ocaml type t = | Typ [@name "type"] | Class [@name "class"] [@@deriving jsonaf] #+end_src *** Polymorphic variants Polymorphic variants behave almost the same as ordinary variants. The notable difference is that polymorphic variant constructors must always start with an either lower- or uppercase character, matching the way it was specified in the type definition. This is because OCaml distinguishes between upper and lowercase variant constructors. Note that type specifications containing unions of variant types are also supported by the Jsonaf_kernel converter, for example as in: #+begin_src ocaml type ab = [ `A | `B ] [@@deriving jsonaf] type cd = [ `C | `D ] [@@deriving jsonaf] type abcd = [ ab | cd ] [@@deriving jsonaf] #+end_src However, because `ppx_jsonaf_conv` needs to generate additional code to support inclusions of polymorphic variants, `ppx_jsonaf_conv` needs to know when processing a type definition whether it might be included in a polymorphic variant. `ppx_jsonaf_conv` will only generate the extra code automatically in the common case where the type definition is syntactically a polymorphic variant like in the example above. Otherwise, you will need to indicate it by using `[@@deriving jsonaf_poly]` (resp `of_yosjon_poly`) instead of `[@@deriving jsonaf]` (resp `of_jsonaf`): #+begin_src ocaml type ab = [ `A | `B ] [@@deriving jsonaf] type alias_of_ab = ab [@@deriving jsonaf_poly] type abcd = [ ab | `C | `D ] [@@deriving jsonaf] #+end_src *** Polymorphic values There is nothing special about polymorphic values as long as there are conversion functions for the type parameters. /e.g./: #+begin_src ocaml type 'a t = A | B of 'a [@@deriving jsonaf] type foo = int t [@@deriving jsonaf] #+end_src In the above case the conversion functions will behave as if =foo= had been defined as a monomorphic version of =t= with ='a= replaced by =int= on the right hand side. If a data structure is indeed polymorphic and you want to convert it, you will have to supply the conversion functions for the type parameters at runtime. If you wanted to convert a value of type ='a t= as in the above example, you would have to write something like this: #+begin_src ocaml jsonaf_of_t jsonaf_of_a v #+end_src where =jsonaf_of_a=, which may also be named differently in this particular case, is a function that converts values of type ='a= to a Jsonaf_kernel. Types with more than one parameter require passing conversion functions for those parameters in the order of their appearance on the left hand side of the type definition. *** Opaque values Opaque values are ones for which we do not want to perform conversions. This may be, because we do not have Jsonaf_kernel converters for them, or because we do not want to apply them in a particular type context. /e.g./ to hide large, unimportant parts of configurations. To prevent the preprocessor from generating calls to converters, simply apply the attribute =jsonaf.opaque= to the type, /e.g./: #+begin_src ocaml type foo = int * (stuff [@jsonaf.opaque]) [@@deriving jsonaf] #+end_src Thus, there is no need to specify converters for type =stuff=, and if there are any, they will not be used in this particular context. Needless to say, it is not possible to convert such a Jsonaf_kernel back to the original value. Here is an example conversion: #+begin_src ocaml (42, some_stuff) => [42,"<opaque>"] #+end_src *** Exceptions Unlike Sexp deriver, we are not handling exceptions in the jsonaf deriver. *** Hash tables The Stdlib's Hash tables, which are abstract values in OCaml, are represented as association lists, /i.e./ lists of key-value pairs, /e.g./: #+begin_src scheme [["foo",3],["bar",4]] #+end_src Reading in the above Jsonaf_kernel as hash table mapping strings to integers (=(string, int) Hashtbl.t=) will map =foo= to =3= and =bar= to =4=. Note that the order of elements in the list may matter, because the OCaml-implementation of hash tables keeps duplicates. Bindings will be inserted into the hash table in the order of appearance. Therefore, the last binding of a key will be the "visible" one, the others are "hidden". See the OCaml documentation on hash tables for details. ** A note about signatures In signatures, =ppx_jsonaf_conv= tries to generate an include of a named interface, instead of a list of value bindings. That is: #+begin_src ocaml type 'a t [@@deriving jsonaf] #+end_src will generate: #+begin_src ocaml include Jsonafable.S1 with type 'a t := 'a t #+end_src instead of: #+begin_src ocaml val t_of_jsonaf : (Jsonaf_kernel.t -> 'a) -> Jsonaf_kernel.t -> 'a t val jsonaf_of_t : ('a -> Jsonaf_kernel.t) -> 'a t -> Jsonaf_kernel.t #+end_src There are however a number of limitations: - the type has to be named t - the type can only have up to 3 parameters - there shouldn't be any constraint on the type parameters If these aren't met, then =ppx_jsonaf_conv= will simply generate a list of value bindings.
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