========
Tutorial
========
What is atdgen?
---------------
Atdgen is a tool that derives OCaml boilerplate code from type definitions.
Currently it provides support for:
* `JSON `_ serialization and deserialization.
* `Biniou `_ serialization and deserialization.
Biniou is a binary format extensible like JSON but more compact
and faster to process.
* Convenience functions for creating and validating OCaml data.
What are the advantages of atdgen?
----------------------------------
Atdgen has a number of advantages over its predecessor json-static
which was based on Camlp4:
* produces explicit interfaces which describe what is available to
the user (`.mli` files).
* produces readable OCaml code that can be easily reviewed
(`.ml` files).
* produces fast code, 3x faster than json-static.
* runs fast, keeping build times low.
* same ATD definitions can be used to generate code other than
OCaml. See for instance
`atdj `_
which generates Java classes for JSON IO.
Auto-generating GUI widgets from type definitions is another
popular use of annotated type definitions. The implementation of
such code generators is facilitated by the
`atd `_ library.
Prerequisites
-------------
This tutorial assumes that you are using atdgen version 1.5.0 or above.
The following command tells you which version you are using:
::
$ atdgen -version
1.5.0
The recommended way of installing atdgen and all its dependencies is with
`opam `_:
::
$ opam install atdgen
Getting started
---------------
From now on we assume that atdgen 1.5.0 or above is installed properly.
::
$ atdgen -version
1.5.0
Type definitions are placed in a `.atd` file (`hello.atd`):
.. code-block:: ocaml
type date = {
year : int;
month : int;
day : int;
}
Our handwritten OCaml program is ``hello.ml``:
.. code-block:: ocaml
open Hello_t
let () =
let date = { year = 1970; month = 1; day = 1 } in
print_endline (Hello_j.string_of_date date)
We produce OCaml code from the type definitions using ``atdgen``:
::
$ atdgen -t hello.atd # produces OCaml type definitions
$ atdgen -j hello.atd # produces OCaml code dealing with JSON
We now have `_t` and `_j` files produced by `atdgen -t` and `atdgen -j`
respectively:
::
$ ls
hello.atd hello.ml hello_j.ml hello_j.mli hello_t.ml hello_t.mli
We compile all `.mli` and `.ml` files:
::
$ ocamlfind ocamlc -c hello_t.mli -package atdgen
$ ocamlfind ocamlc -c hello_j.mli -package atdgen
$ ocamlfind ocamlopt -c hello_t.ml -package atdgen
$ ocamlfind ocamlopt -c hello_j.ml -package atdgen
$ ocamlfind ocamlopt -c hello.ml -package atdgen
$ ocamlfind ocamlopt -o hello hello_t.cmx hello_j.cmx hello.cmx -package atdgen -linkpkg
And finally we run our `hello` program:
::
$ ./hello
{"year":1970,"month":1,"day":1}
`Source code for this section `_
Inspecting and pretty-printing JSON
-----------------------------------
Input JSON data:
::
$ cat single.json
[1234,"abcde",{"start_date":{"year":1970,"month":1,"day":1},
"end_date":{"year":1980,"month":1,"day":1}}]
Pretty-printed JSON can be produced with the ``ydump`` command:
::
$ ydump single.json
[
1234,
"abcde",
{
"start_date": { "year": 1970, "month": 1, "day": 1 },
"end_date": { "year": 1980, "month": 1, "day": 1 }
}
]
Multiple JSON objects separated by whitespace, typically one JSON object
per line, can also be pretty-printed with `ydump`. Input:
::
$ cat stream.json
[1234,"abcde",{"start_date":{"year":1970,"month":1,"day":1},
"end_date":{"year":1980,"month":1,"day":1}}]
[1,"a",{}]
In this case the `-s` option is required:
::
$ ydump -s stream.json
[
1234,
"abcde",
{
"start_date": { "year": 1970, "month": 1, "day": 1 },
"end_date": { "year": 1980, "month": 1, "day": 1 }
}
]
[ 1, "a", {} ]
From an OCaml program, pretty-printing can be done with `Yojson.Safe.prettify`
which has the following signature:
.. code-block:: ocaml
val prettify : string -> string
We wrote a tiny program that simply calls the `prettify` function on
some predefined JSON data (file `prettify.ml`):
.. code-block:: ocaml
let json =
"[1234,\"abcde\",{\"start_date\":{\"year\":1970,\"month\":1,\"day\":1},
\"end_date\":{\"year\":1980,\"month\":1,\"day\":1}}]"
let () = print_endline (Yojson.Safe.prettify json)
We now compile and run prettify.ml:
::
$ ocamlfind ocamlopt -o prettify prettify.ml -package atdgen -linkpkg
$ ./prettify
[
1234,
"abcde",
{
"start_date": { "year": 1970, "month": 1, "day": 1 },
"end_date": { "year": 1980, "month": 1, "day": 1 }
}
]
`Source code for this section `__
Inspecting biniou data
----------------------
Biniou is a binary format that can be displayed as text using a generic command
called ``bdump``. The only practical difficulty is to recover the original field
names and variant names which are stored as 31-bit hashes. Unhashing them is
done by consulting a dictionary (list of words) maintained by the user.
Let's first produce a sample data file ``tree.dat`` containing the
biniou representation of a binary tree. In the same program
we will also demonstrate how to render biniou data into text from an
OCaml program.
Here is the ATD file defining our tree type (file ``tree.atd``):
.. code-block:: ocaml
type tree = [
| Empty
| Node of (tree * int * tree)
]
This is our OCaml program (file ``tree.ml``):
.. code-block:: ocaml
open Printf
(* sample value *)
let tree : Tree_t.tree =
`Node (
`Node (`Empty, 1, `Empty),
2,
`Node (
`Node (`Empty, 3, `Empty),
4,
`Node (`Empty, 5, `Empty)
)
)
let () =
(* write sample value to file *)
let fname = "tree.dat" in
Atdgen_runtime.Util.Biniou.to_file Tree_b.write_tree fname tree;
(* write sample value to string *)
let s = Tree_b.string_of_tree tree in
printf "raw value (saved as %s):\n%S\n" fname s;
printf "length: %i\n" (String.length s);
printf "pretty-printed value (without dictionary):\n";
print_endline (Bi_io.view s);
printf "pretty-printed value (with dictionary):\n";
let unhash = Bi_io.make_unhash ["Empty"; "Node"; "foo"; "bar" ] in
print_endline (Bi_io.view ~unhash s)
Compilation:
::
$ atdgen -t tree.atd
$ atdgen -b tree.atd
$ ocamlfind ocamlopt -o tree \
tree_t.mli tree_t.ml tree_b.mli tree_b.ml tree.ml \
-package atdgen -linkpkg
Running the program:
::
$ ./tree
raw value (saved as tree.dat):
"\023\179\2276\"\020\003\023\179\2276\"\020\003\023\003\007\170m\017\002\023\003\007\170m\017\004\023\179\2276\"\020\003\023\179\2276\"\020\003\023\003\007\170m\017\006\023\003\007\170m\017\b\023\179\2276\"\020\003\023\003\007\170m\017\n\023\003\007\170m"
length: 75
pretty-printed value (without dictionary):
<#33e33622:
(<#33e33622: (<#0307aa6d>, 1, <#0307aa6d>)>,
2,
<#33e33622:
(<#33e33622: (<#0307aa6d>, 3, <#0307aa6d>)>,
4,
<#33e33622: (<#0307aa6d>, 5, <#0307aa6d>)>)>)>
pretty-printed value (with dictionary):
<"Node":
(<"Node": (<"Empty">, 1, <"Empty">)>,
2,
<"Node":
(<"Node": (<"Empty">, 3, <"Empty">)>,
4,
<"Node": (<"Empty">, 5, <"Empty">)>)>)>
Now let's see how to pretty-print any biniou data from the command line.
Our sample data are now in file `tree.dat`:
::
$ ls -l tree.dat
-rw-r--r-- 1 martin martin 75 Apr 17 01:46 tree.dat
We use the command ``bdump`` to render our sample biniou data as text:
::
$ bdump tree.dat
<#33e33622:
(<#33e33622: (<#0307aa6d>, 1, <#0307aa6d>)>,
2,
<#33e33622:
(<#33e33622: (<#0307aa6d>, 3, <#0307aa6d>)>,
4,
<#33e33622: (<#0307aa6d>, 5, <#0307aa6d>)>)>)>
We got hashes for the variant names ``Empty`` and ``Node``. Let's add them to the
dictionary:
::
$ bdump -w Empty,Node tree.dat
<"Node":
(<"Node": (<"Empty">, 1, <"Empty">)>,
2,
<"Node":
(<"Node": (<"Empty">, 3, <"Empty">)>,
4,
<"Node": (<"Empty">, 5, <"Empty">)>)>)>
``bdump`` remembers the dictionary so we don't have to pass the ``-w`` option
anymore (for this user on this machine). The following now works:
::
$ bdump tree.dat
<"Node":
(<"Node": (<"Empty">, 1, <"Empty">)>,
2,
<"Node":
(<"Node": (<"Empty">, 3, <"Empty">)>,
4,
<"Node": (<"Empty">, 5, <"Empty">)>)>)>
`Source code for this section `__
Optional fields and default values
----------------------------------
Although OCaml records do not support optional fields, both the JSON
and biniou formats make it possible to omit certain fields on a
per-record basis.
For example the JSON record `{ "x": 0, "y": 0 }` can be more
compactly written as `{}` if the reader knows the default values for
the missing fields `x` and `y`. Here is the corresponding type
definition:
.. code-block:: ocaml
type vector_v1 = { ~x: int; ~y: int }
``~x`` means that field ``x`` supports a default value. Since we do not specify
the default value ourselves, the built-in default is used, which is 0.
If we want the default to be something else than 0, we just have to specify it
as follows:
.. code-block:: ocaml
type vector_v2 = {
~x : int; (* default x is 1 *)
~y: int; (* default y is 0 *)
}
It is also possible to specify optional fields without a default value. For
example, let's add an optional ``z`` field:
.. code-block:: ocaml
type vector_v3 = {
~x: int;
~y: int;
?z: int option;
}
The following two examples are valid JSON representations of data of type
``vector_v3``:
::
{ "x": 2, "y": 2, "z": 3 } // OCaml: { x = 2; y = 2; z = Some 3 }
::
{ "x": 2, "y": 2 } // OCaml: { x = 2; y = 2; z = None }
By default, JSON fields whose value is ``null`` are treated
as missing fields. The following two JSON objects are therefore equivalent:
.. code-block:: json
{ "x": 2, "y": 2, "z": null }
{ "x": 2, "y": 2 }
Note also the difference between ``?z: int option`` and ``~z: int option``:
.. code-block:: ocaml
type vector_v4 = {
~x: int;
~y: int;
~z: int option; (* no unwrapping of the JSON field value! *)
}
Here are valid values of type ``vector_v4``, showing that it is usually not what
is intended:
.. code-block:: json
{ "x": 2, "y": 2, "z": [ "Some", 3 ] }
.. code-block:: json
{ "x": 2, "y": 2, "z": "None" }
.. code-block:: json
{ "x": 2, "y": 2 }
Smooth protocol upgrades
------------------------
Problem: you have a production system that uses a specific JSON or biniou
format. It may be data files or a client-server pair. You now want to add a
field to a record type or to add a case to a variant type.
Both JSON and biniou allow extra record fields. If the consumer does not know
how to deal with the extra field, the default behavior is to happily ignore it.
Adding or removing an optional record field
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
.. code-block:: ocaml
type t = {
x: int;
y: int;
}
Same ``.atd`` source file, edited:
.. code-block:: ocaml
type t = {
x: int;
y: int;
~z: int; (* new field *)
}
* Upgrade producers and consumers in any order
* Converting old data is not required nor useful
Adding a required record field
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
.. code-block:: ocaml
type t = {
x: int;
y: int;
}
Same ``.atd`` source file, edited:
.. code-block:: ocaml
type t = {
x: int;
y: int;
z: int; (* new field *)
}
* Upgrade all producers before the consumers
* Converting old data requires special-purpose hand-written code
Removing a required record field
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
* Upgrade all consumers before the producers
* Converting old data is not required but may save some storage space
(just read and re^write each record using the new type)
Adding a variant case
^^^^^^^^^^^^^^^^^^^^^
.. code-block:: ocaml
type t = [ A | B ]
Same ``.atd`` source file, edited:
.. code-block:: ocaml
type t = [ A | B | C ]
* Upgrade all consumers before the producers
* Converting old data is not required and would have no effect
Removing a variant case
^^^^^^^^^^^^^^^^^^^^^^^
* Upgrade all producers before the consumers
* Converting old data requires special^purpose hand^written code
Avoiding future problems
^^^^^^^^^^^^^^^^^^^^^^^^
* In doubt, use records rather than tuples because it makes it possible to add
or remove any field or to reorder them.
* Do not hesitate to create variant types with only one case or records with
only one field if you think they might be extended later.
Data validation
---------------
Atdgen can be used to produce data validators for all types defined in an ATD
file, based on user-given validators specified only for certain types. A simple
example is:
.. code-block:: ocaml
type t = string option
As we can see from this example, the validation function is specified using the
annotation ````, where ``p`` is a predicate ``p : t -> bool``,
returning ``true`` when the value of type ``t`` is valid and ``false``
otherwise.
Calling ``atdgen -v`` on a file containing this specification will produce
a validation function equivalent to the following implementation:
.. code-block:: ocaml
let validate_t path x =
match x with
| None -> None
| Some x ->
let msg = "Failed check by fun s -> String.length s >= 8" in
if (fun s -> String.length s >= 8) x
then None
else Some {error_path = path; error_msg = msg}
Let's consider this particular example as an illustration of the general shape
of generated validation functions.
The function takes two arguments: the first, ``path``, is a list indicating
where the second, ``x``, was encountered. As specified by our example ``.atd``
code above, ``x`` has type ``t option``.
The body of the validation function does two things:
1. it checks the value of ``x`` against the validation function specified in our
``.atd`` file, namely, checking whether there is ``Some s``, and verifying that
``s`` is at least 8 characters long if so
2. in the event that the validation check fails, it constructs an appropriate
error record.
In general, generated validation functions for a type ``t`` have a type
equivalent to ``validate_t : path -> t -> error option``, where the ``path``
gives the current location in a data structure and the ``error`` is a record of
the location of, and reason for, validation failure.
A return value of ``None`` indicates successful validation, while ``Some
{error_path; error_msg}`` tells us where and why validation failed.
Let's now consider a more realistic example with complex validators defined in a
separate ``.ml`` file. We will define a data structure representing a section of
a resume recording work experience. We will also define validation functions
that can enforce certain properties to protect against errors and junk data.
In the course of this example, we will manually create the following 3 source
files:
* ``resume.atd``: contains the type definitions with annotations
* ``resume_util.ml``: contains our handwritten validators
* ``resume.ml``: is our main program that creates data and checks it using our
generated validation functions.
After generating additional code with ``atdgen``, we will end up with the
following OCaml modules:
* ``Resume_t``: generated into ``resume_t.ml`` by ``atdgen -t resume.atd``, this
provides our OCaml type definitions
* ``Resume_util``: written manually in ``resume_util.ml``, this depends on
``Resume_t`` and provides validators we will use in ``resume.atd``
* ``Resume_v``: generated into ``resume_v.ml`` by ``atdgen -v resume.atd``, this
depends on ``Resume_util`` and ``Resume_t`` and provides a validation function
for each type
* ``Resume_j``: generated into ``resume_j.ml`` by ``atdgen -j resume.atd``, this
provides functions to serialize and deserialize data in and out of JSON.
* ``Resume``: written manually in ``resume.ml``, this depends on ``Resume_v``,
and ``Resume_t``, and makes use of the generated types and validation
functions.
To begin, we specify type definitions for a data structure representing a resume
in ``resume.atd``:
.. code-block:: ocaml
type text = string
type date = {
year : int;
month : int;
day : int;
}
type job = {
company : text;
title : text;
start_date : date;
?end_date : date option;
}
type work_experience = job list
We can now call ``atdgen -t resume.atd`` to generate our ``Resume_t`` module in
``resume_t.ml``, providing our data types. Using these data types, we'll define
the following handwritten validators in ``resume_util.ml`` (note that we've
already referred to these validators in ``resume.atd``):
.. code-block:: ocaml
open Resume_t
let ascii_printable c =
let n = Char.code c in
n >= 32 && n <= 127
(*
Check that string is not empty and contains only ASCII printable
characters (for the sake of the example; we use UTF-8 these days)
*)
let validate_some_text s =
s <> "" &&
try
String.iter (fun c -> if not (ascii_printable c) then raise Exit) s;
true
with Exit ->
false
(*
Check that the combination of year, month and day exists in the
Gregorian calendar.
*)
let validate_date x =
let y = x.year in
let m = x.month in
let d = x.day in
m >= 1 && m <= 12 && d >= 1 &&
(let dmax =
match m with
2 ->
if y mod 4 = 0 && not (y mod 100 = 0) || y mod 400 = 0 then 29
else 28
| 1 | 3 | 5 | 7 | 8 | 10 | 12 -> 31
| _ -> 30
in
d <= dmax)
(* Compare dates chronologically *)
let compare_date a b =
let c = compare a.year b.year in
if c <> 0 then c
else
let c = compare a.month b.month in
if c <> 0 then c
else compare a.day b.day
(* Check that the end_date, when defined, is not earlier than the start_date *)
let validate_job x =
match x.end_date with
None -> true
| Some end_date ->
compare_date x.start_date end_date <= 0
After we call ``atdgen -v resume.atd``, the module ``Resume_v`` will be
generated in ``resume_v.ml``, providing the function
``validate_work_experience`` . We can then use this function, along with the
generated ``Resume_j`` in the following program written in ``resume.ml``:
.. code-block:: ocaml
let check_experience x =
let is_valid = match Resume_v.validate_work_experience [] x with
| None -> true
| _ -> false
in
Printf.printf "%s:\n%s\n"
(if is_valid then "VALID" else "INVALID")
(Yojson.Safe.prettify (Resume_j.string_of_work_experience x))
let () =
(* one valid date *)
let valid = { Resume_t.year = 2000; month = 2; day = 29 } in
(* one invalid date *)
let invalid = { Resume_t.year = 1900; month = 0; day = 0 } in
(* two more valid dates, created with Resume_v.create_date *)
let date1 = { Resume_t.year = 2005; month = 8; day = 1 } in
let date2 = { Resume_t.year = 2006; month = 3; day = 22 } in
let job = {
Resume_t.company = "Acme Corp.";
title = "Tester";
start_date = date1;
end_date = Some date2;
}
in
let valid_job = { job with Resume_t.start_date = valid } in
let invalid_job = { job with Resume_t.end_date = Some invalid } in
let valid_experience = [ job; valid_job ] in
let invalid_experience = [ job; invalid_job ] in
check_experience valid_experience;
check_experience invalid_experience
Output:
::
VALID:
[
{
"company": "Acme Corp.",
"title": "Tester",
"start_date": { "year": 2005, "month": 8, "day": 1 },
"end_date": { "year": 2006, "month": 3, "day": 22 }
},
{
"company": "Acme Corp.",
"title": "Tester",
"start_date": { "year": 2000, "month": 2, "day": 29 },
"end_date": { "year": 2006, "month": 3, "day": 22 }
}
]
INVALID:
[
{
"company": "Acme Corp.",
"title": "Tester",
"start_date": { "year": 2005, "month": 8, "day": 1 },
"end_date": { "year": 2006, "month": 3, "day": 22 }
},
{
"company": "Acme Corp.",
"title": "Tester",
"start_date": { "year": 2005, "month": 8, "day": 1 },
"end_date": { "year": 1900, "month": 0, "day": 0 }
}
`Source code for this section `__
Modularity: referring to type definitions from another ATD file
---------------------------------------------------------------
It is possible to define types that depend on types defined in other ``.atd``
files. The example below is self-explanatory.
``part1.atd``:
.. code-block:: ocaml
type t = { x : int; y : int }
``part2.atd``:
.. code-block:: ocaml
type t1 = abstract
(*
Imports type t defined in file part1.atd.
The local name is t1. Because the local name (t1) is different from the
original name (t), we must specify the original name using t=.
*)
type t2 = t1 list
``part3.atd``:
.. code-block:: ocaml
type t2 = abstract
type t3 = {
name : string;
?data : t2 option;
}
``main.ml``:
.. code-block:: ocaml
let v = {
Part3_t.name = "foo";
data = Some [
{ Part1_t.x = 1; y = 2 };
{ Part1_t.x = 3; y = 4 };
]
}
let () =
Atdgen_runtime.Util.Json.to_channel Part3_j.write_t3 stdout v;
print_newline ()
Output:
.. code-block:: json
{"name":"foo","data":[{"x":1,"y":2},{"x":3,"y":4}]}
`Source code for this section `__
Managing JSON configuration files
---------------------------------
JSON makes a good format for configuration files because it is human-readable,
easy to modify programmatically and widespread. Here is an example of how to use
atdgen to manage config files.
* **Specifying defaults** is done in the .atd file. See section [Optional fields
and default values] for details on how to do that.
* **Auto-generating a template config file with default values**: a sample value
in the OCaml world needs to be created but only fields without default need to
be specified.
* **Describing the format** is achieved by embedding the .atd type definitions
in the OCaml program and printing it out on request.
* **Loading a config file and reporting illegal fields** is achieved using the
JSON deserializers produced by ``atdgen -j``. Option ``-j-strict-fields``
ensures the misspelled field names are not ignored but reported as errors.
* **Reindenting a config file** is achieved by the pretty-printing function
``Yojson.Safe.prettify`` that takes a JSON string and returns an equivalent
JSON string.
* **Showing implicit (default) settings** is achieved by passing the
``-j-defaults`` option to ``atdgen``. The OCaml config data is then serialized
into JSON containing all fields, including those whose value is the default.
The example uses the following type definitions:
.. code-block:: ocaml
type config = {
title : string;
?description : string option;
~timeout : int;
~credentials : param list
;
}
type param = {
name : string
;
key : string
;
}
Our program will perform the following actions:
::
$ ./config -template
{
"title": "",
"timeout": 10,
"credentials": [ { "name": "foo", "key": "0123456789abcdef" } ]
}
$ ./config -format
type config = {
title : string;
?description : string option;
~timeout : int;
~credentials : param list
;
}
type param = {
name : string
;
key : string
;
}
$ cat sample-config.json
{
"title": "Example",
"credentials": [
{
"name": "joeuser",
"key": "db7c0877bdef3016"
},
{
"name": "tester",
"key": "09871ff387ac2b10"
}
]
}
$ ./config -validate sample-config.json
{
"title": "Example",
"timeout": 10,
"credentials": [
{ "name": "joeuser", "key": "db7c0877bdef3016" },
{ "name": "tester", "key": "09871ff387ac2b10" }
]
}
This is our `demo.sh` script that builds and runs our example
program called `config`:
::
#! /bin/sh -e
set -x
# Embed the contents of the .atd file into our OCaml program
echo 'let contents = "\' > config_atd.ml
sed -e 's/\([\\"]\)/\\\1/g' config.atd >> config_atd.ml
echo '"' >> config_atd.ml
# Derive OCaml type definitions from .atd file
atdgen -t config.atd
# Derive JSON-related functions from .atd file
atdgen -j -j-defaults -j-strict-fields config.atd
# Derive validator from .atd file
atdgen -v config.atd
# Compile the OCaml program
ocamlfind ocamlopt -o config \
config_t.mli config_t.ml config_j.mli config_j.ml config_v.mli config_v.ml \
config_atd.ml config.ml -package atdgen -linkpkg
# Output a sample config
./config -template
# Print the original type definitions
./config -format
# Fail to validate an invalid config file
./config -validate bad-config1.json || :
# Fail to validate another invalid config file (using custom validators)
./config -validate bad-config3.json || :
# Validate, inject missing defaults and pretty-print
./config -validate sample-config.json
This is the hand-written OCaml program. It can be used as a start
point for a real-world program using a JSON config file:
.. code-block:: ocaml
open Printf
let param_template =
(* Sample item used to populate the template config file *)
{
Config_v.name = "foo";
key = "0123456789abcdef"
}
let config_template =
(*
Records can be conveniently created using functions generated by
"atdgen -v".
Here we use Config_v.create_config to create a record of type
Config_t.config. The big advantage over creating the record
directly using the record notation {...} is that we don't have to
specify default values (such as timeout in this example).
*)
Config_v.create_config ~title:"" ~credentials: [param_template] ()
let make_json_template () =
(* Thanks to the -j-defaults flag passed to atdgen, even default
fields will be printed out *)
let compact_json = Config_j.string_of_config config_template in
Yojson.Safe.prettify compact_json
let print_template () =
print_endline (make_json_template ())
let print_format () =
print_string Config_atd.contents
let validate fname =
let x =
try
(* Read config data structure from JSON file *)
let x = Atdgen_runtime.Util.Json.from_file Config_j.read_config fname in
(* Call the validators specified by *)
if not (Config_v.validate_config x) then
failwith "Some fields are invalid"
else
x
with e ->
(* Print decent error message and exit *)
let msg =
match e with
Failure s
| Yojson.Json_error s -> s
| e -> Printexc.to_string e
in
eprintf "Error: %s\n%!" msg;
exit 1
in
(* Convert config to compact JSON and pretty-print it.
~std:true means that the output will not use extended syntax for
variants and tuples but only standard JSON. *)
let json = Yojson.Safe.prettify ~std:true (Config_j.string_of_config x) in
print_endline json
type action = Template | Format | Validate of string
let main () =
let action = ref Template in
let options = [
"-template", Arg.Unit (fun () -> action := Template),
"
prints a sample configuration file";
"-format", Arg.Unit (fun () -> action := Format),
"
prints the format specification of the config files (atd format)";
"-validate", Arg.String (fun s -> action := Validate s),
"
reads a config file, validates it, adds default values
and prints the config nicely to stdout";
]
in
let usage_msg = sprintf "\
Usage: %s [-template|-format|-validate ...]
Demonstration of how to manage JSON configuration files with atdgen.
"
Sys.argv.(0)
in
let anon_fun s = eprintf "Invalid command parameter %S\n%!" s; exit 1 in
Arg.parse options anon_fun usage_msg;
match !action with
Template -> print_template ()
| Format -> print_format ()
| Validate s -> validate s
let () = main ()
The full source code for this section with examples can be inspected
and `downloaded here `__.
Integration with ocamldoc
-------------------------
Ocamldoc is a tool that comes with the core OCaml distribution.
It uses comments within `(**` and `*)` to produce
hyperlinked documentation (HTML) of module signatures.
Atdgen can produce `.mli` files with comments in the syntax supported by
ocamldoc but regular ATD comments within `(*` and `*)`
are always discarded
by atdgen. Instead, `` must be used and placed after the
element they describe. The contents of the text field must be UTF8-encoded.
.. code-block:: ocaml
type point = {
x : float;
y : float;
~z
: float;
}
is converted into the following `.mli` file with
ocamldoc-compatible comments:
.. code-block:: ocaml
(**
Point with optional 3rd dimension.
OCaml example:
{v
let p =
\{ x = 0.5; y = 1.0; z = 0. \}
v}
*)
type point = {
x: float;
y: float;
z: float (** Optional depth, its default value is [0.0]. *)
}
The only two forms of markup supported by ```` are ``{{`` ...
``}}`` for inline code and ``{{{`` ... ``}}}`` for a block of preformatted code.
Integration with build systems
------------------------------
OMake
^^^^^
We provide an `Atdgen plugin `__ for
`OMake `__. It simplifies the compilation rules to a
minimum.
The plugin consists of a self-documented file to copy into a project's root. The
following is a sample ``OMakefile`` for a project using JSON and five source
files (``foo.atd``, ``foo.ml``, ``bar.atd``, ``bar.ml`` and ``main.ml``):
::
# require file Atdgen.om
include Atdgen
# OCaml modules we want to build
OCAMLFILES = foo_t foo_j foo bar_t bar_j bar main
Atdgen(foo bar, )
OCamlProgram(foobar, $(OCAMLFILES))
.DEFAULT: foobar.opt
.PHONY: clean
clean:
rm -f *.cm[ioxa] *.cmx[as] *.[oa] *.opt *.run *~
rm -f $(ATDGEN_OUTFILES)
Running ``omake`` builds the native code executable ``foobar.opt``.
``omake clean`` removes all the products of compilation including the ``.mli``
and ``.ml`` produced by ``atdgen``.
GNU Make
^^^^^^^^
We provide `Atdgen.mk `__, a generic
makefile that defines the dependencies and rules for generating OCaml ``.mli`` and
``.ml`` files from ``.atd`` files containing type definitions. The ``Atdgen.mk`` file
contains its own documentation.
Here is a sample `Makefile` that takes advantage of
`OCamlMakefile `__:
.. code-block:: make
.PHONY: default
default: opt
ATDGEN_SOURCES = foo.atd bar.atd
ATDGEN_FLAGS =
include Atdgen.mk
SOURCES = \
foo_t.mli foo_t.ml foo_j.mli foo_j.ml \
bar_t.mli bar_t.ml bar_j.mli bar_j.ml \
hello.ml
RESULT = hello
PACKS = atdgen
# "include OCamlMakefile" must come after defs for SOURCES, RESULT, PACKS, etc.
include OCamlMakefile
.PHONY: sources opt all
sources: $(SOURCES)
opt: sources
$(MAKE) native-code
all: sources
$(MAKE) byte-code
``make`` alone builds a native code executable from source files ``foo.atd``,
``bar.atd`` and ``hello.ml``. ``make clean`` removes generated files. ``make
all`` builds a bytecode executable.
In addition to ``native-code``, ``byte-code`` and ``clean``, ``OCamlMakefile``
provides a number of other targets and options which are documented in
``OCamlMakefile``'s README.
Ocamlbuild
^^^^^^^^^^
There is an `atdgen plugin for ocamlbuild `__.
Dune (formerly jbuilder)
^^^^^^^^^^^^^^^^^^^^^^^^
Dune currently needs atdgen build rules specified manually. Given an ``example.atd``,
this will usually look like:
::
(rule
(targets example_j.ml
example_j.mli)
(deps example.atd)
(action (run atdgen -j %{deps})))
(rule
(targets example_t.ml
example_t.mli)
(deps example.atd)
(action (run atdgen -t %{deps})))
You can refer to ``example_t.ml`` and ``example_j.ml`` as usual (by default, they
will be automatically linked into the library being built in the same directory).
You will need to write rules for each .atd file individually until
`Dune supports wildcard rules `_.
Note that any options ``atdgen`` supports can be included in the ``run atdgen``
section (``-open``, ``-deriving-conv``, etc.).
Dealing with untypable JSON
---------------------------
Sometimes we have to deal with JSON data that cannot be described
using type definitions. In such case, we can represent the data as its
JSON abstract syntax tree (AST), which lets the user inspect it at runtime.
Let's consider a list of JSON objects for which we don't know the type
definitions, but somehow some other system knows how to deal with such
data. Here is such data:
.. code-block:: json
[
{
"label": "flower",
"value": {
"petals": [12, 45, 83.5555],
"water": "a340bcf02e"
}
},
{
"label": "flower",
"value": {
"petals": "undefined",
"fold": null,
"water": 0
}
},
{ "labels": ["fork", "scissors"],
"value": [ 8, 8 ]
}
]
Hopefully this means something for someone. We are going to assume that each
object has a ``value`` field of an unknown type, and may have a field ``label``
or a field ``labels`` of type ``string``:
.. code-block:: ocaml
(* File untypable.atd *)
type obj_list = obj list
type obj = {
?label: string option;
?labels: string list option;
value: abstract (* requires ATD >= 2.6.0 *)
}
Until ATD 2.5, ``abstract`` could not be used as freely and would not
stand for raw JSON by default. One had to write a dedicated type
definition as shown below:
.. code-block:: ocaml
(* File untypable.atd *)
(* deprecated since ATD 2.6 *)
type json = abstract
(* uses type Yojson.Safe.t,
with the functions Yojson.Safe.write_json
and Yojson.Safe.read_json *)
type obj_list = obj list
type obj = {
?label: string option;
?labels: string list option;
value: json
}
It is possible to give a different name than ``json`` to the type of the JSON
AST, but then the name of the type used in the original module must be provided
in the annotation, i.e.:
.. code-block:: ocaml
(* deprecated since ATD 2.6 *)
type raw_json = abstract
(* uses type Yojson.Safe.t,
with the functions Yojson.Safe.write_json
and Yojson.Safe.read_json *)
type obj_list = obj list
type obj = {
?label: string option;
?labels: string list option;
value: raw_json
}
Compile either example with:
::
$ atdgen -t untypable.atd
$ atdgen -j untypable.atd
$ ocamlfind ocamlc -a -o untypable.cma -package atdgen \
untypable_t.mli untypable_t.ml untypable_j.mli untypable_j.ml
Test the example with your favorite OCaml toplevel (``ocaml`` or ``utop``):
.. code-block:: ocaml
# #use "topfind";;
# #require "atdgen";;
# #load "untypable.cma";;
# Atdgen_runtime.Util.Json.from_channel Untypable_j.read_obj_list stdin;;
[
{
"label": "flower",
"value": {
"petals": [12, 45, 83.5555],
"water": "a340bcf02e"
}
},
{
"label": "flower",
"value": {
"petals": "undefined",
"fold": null,
"water": 0
}
},
{ "labels": ["fork", "scissors"],
"value": [ 8, 8 ]
}
]
- : Untypable_t.obj_list =
[{Untypable_t.label = Some "flower"; labels = None;
value =
`Assoc
[("petals", `List [`Int 12; `Int 45; `Float 83.5555]);
("water", `String "a340bcf02e")]};
{Untypable_t.label = Some "flower"; labels = None;
value =
`Assoc [("petals", `String "undefined");
("fold", `Null);
("water", `Int 0)]};
{Untypable_t.label = None; labels = Some ["fork"; "scissors"];
value = `List [`Int 8; `Int 8]}]