package yaml

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Parse and generate YAML 1.1 files

Install

Dune Dependency

Authors

Maintainers

Sources

yaml-0.2.0.tbz
sha256=7f5bc9352b5d18671281986a72f74be29c9397a2411917ce3cbf5959888a4815
md5=97f4d85f56eb21fabc210b6ff009a771

Description

This is an OCaml library to parse and generate the YAML file format. It is intended to interoperable with the Ezjsonm JSON handling library, if the simple common subset of Yaml is used. Anchors and other advanced Yaml features are not implemented in the JSON compatibility layer.

The Yaml module docs are browseable online.

Tags

org:mirage org:ocamllabs

Published: 17 May 2018

README

ocaml-yaml -- parse and generate YAML 1.1 files

This is an OCaml library to parse and generate the YAML file format. It is intended to interoperable with the Ezjsonm JSON handling library, if the simple common subset of Yaml is used. Anchors and other advanced Yaml features are not implemented in the JSON compatibility layer.

The Yaml module docs are browseable online.

Example of use

Install the library via opam install yaml, and then execute a toplevel via utop. You can also build and execute the toplevel locally:

$ jbuilder exec utop
# #require "yaml";;
# Yaml.of_string "foo";;
- : Yaml.value Yaml.res = Result.Ok (`String "foo")
# Yaml.of_string "- foo";;
- : Yaml.value Yaml.res = Result.Ok (`A [`String "foo"])
# Yaml.to_string (`O ["foo1", `String "bar1"; "foo2", `Float 1.0]);;
- : string Yaml.res = Result.Ok "foo1: bar1\nfoo2: 1.\n"
# #require "yaml.unix" ;;
# Yaml_unix.to_file Fpath.(v "my.yml") (`String "bar") ;;
- : (unit, Rresult.R.msg) result = Result.Ok ()
# Yaml_unix.of_file Fpath.(v "my.yml");;
- : (Yaml.value, Rresult.R.msg) result = Result.Ok (`String "bar")
# Yaml_unix.of_file_exn Fpath.(v "my.yml");;
- : Yaml.value = `String "bar"

Repository Structure

ocaml-yaml is based around a binding to the C libyaml library to do the majority of the low-level parsing and serialisation, with a higher-level OCaml module that provids a simple interface for the majority of common uses.

We use the following major OCaml tools and libraries:

  • build: jbuilder is the build tool used.

  • ffi: ctypes is the library to interface with the C FFI exposed by libYaml.

  • preprocessor: ppx_sexp_conv generates s-expression serialises and deserialisers for the types exposed by the library.

  • error handling: rresult is a set of combinators for returning errors as values, instead of raising OCaml exceptions.

  • tests: alcotest specifies conventional unit tests, and crowbar is used to drive property-based fuzz-testing of the library.

Library Architecture

The following layers are present to make the high-level library work, contained within the following directories in the repository:

  • vendor/ contains the C sources for libyaml, with some minor modifications. to the header files to make them easier to use with Ctypes.

  • types/ has OCaml definitions for the C types defined in yaml.h.

  • ffi/ has OCaml definitions for the C functions defined in yaml.h.

  • lib/ contains the high-level OCaml interface for Yaml manipulation, using the FFI definitions above.

  • unix/ contains OS-specific bindings with file-handling.

  • tests/ has unit tests for the library functionality.

  • fuzz/ contains exploratory fuzz testing that randomises inputs to find bugs.

C library: A copy of the libyaml C library is included into vendor/ to eliminate the need for a third-party dependency. The C code is built directly into a yaml.a static library, and linked in with the OCaml bindings.

Bindings to C types: We then need to generate OCaml type definitions that correspond to the C header definitions in libyaml. This is all done without writing a single line of C code, via the stub generation support in ocaml-ctypes. We define an OCaml library that describes the C enumerations or structs that we need a corresponding definition for (see yaml_bindings_types.ml). This code is also exported in the yaml.bindings.types ocamlfind library.

These binding descriptions are then then compiled into an executable (see ffi_types_stubgen.ml). When run, this calls the C compiler and generating a compatible OCaml module with the results of probing the C library and statically determining values for (e.g.) struct offsets or macros. The resulting OCaml library is expored in the yaml.types ocamlfind library.

Bindings to C functions: Once we have the C type definitions bound into OCaml, we then need to bind the corresponding C library functions that use them. We do exactly the same approach as we did for probing types earlier, but define an OCaml descriptions of the functions that we want to bind instead (see yaml_bindings.ml). The ffi_stubgen executable then takes these descriptions and generates two source code files: an OCaml module containing the typed function calls, and the corresponding C bindings that link those typed function calls to the C library. Again, this is all done automatically via Ctypes functions, and we never had to write any manual C code. As an additional layer of safety, mistakes when writing the Ctypes bindings will also result in a compile-time error, since the generated C code will fail to compile with the C header files for the yaml library. The resulting OCaml functions are exported in the yaml.ffi ocamlfind library.

OCaml API: Finally, we define the OCaml API that uses the low-level FFI to expose a well-typed OCaml interface. We adopt a convention of using the Rresult library to return explicit errors instead of raising OCaml exceptions. We also define some polymorphic variant types to represent various configuration options (such as the printing style of different Yaml values).

Since the most common use of Yaml is for relatively simple key-value stores, the OCaml API by default exposes polymorphic variant types that are completely compatible with the Ezjsonm library, meaning that you can print JSON or Yaml back and forth very easily. However, if you do need the advanced Yaml functions like anchors and aliases, then there are definitions that expose them too.

Testing: There are two test suites included with the repository. The first is a conventional unit test infrastructure that uses the Alcotest framework from MirageOS. The second is a property-based fuzz testing framework via Crowbar, which tries to find unexpected issues by exploring the library with randomised inputs that are guided by the control flow of the execution.

Docs: Documentation can be locally generated by running make doc, and looking in _build/default/_doc/index.html with a web browser. The URL for online docs is listed below.

Further Information

Contributions are very welcome. Please see the overall TODO list below, or please get in touch with any particular comments you might have.

TODO

  • Warnings: handle the unsigned char yaml_char_t in the Ctypes bindings.

  • Warnings: const needs to be specified in the Ctypes binding.

  • The pkg/pkg.ml file can be removed once topkg has jbuilder autodetection. dbuenzli/topkg#123

  • Send upstream PR for forked header file (due to removal of anonymous structs).

  • Use Configurator for C build rules in vendor/ (e.g. no -fPIC on arm32?)

Dependencies (10)

  1. bos
  2. logs
  3. fmt
  4. rresult < "0.7.0"
  5. sexplib
  6. ocaml-migrate-parsetree < "2.0.0"
  7. ppx_sexp_conv >= "v0.9.0"
  8. ctypes >= "0.13.0"
  9. jbuilder >= "1.0+beta17"
  10. ocaml >= "4.03.0"

Dev Dependencies (2)

  1. ezjsonm with-test
  2. alcotest with-test

Used by (7)

  1. finch
  2. irmin-unix >= "2.0.0" & < "3.0.0"
  3. lustre-v6 >= "6.107.1"
  4. obi
  5. ppx_deriving_yaml >= "0.1.1"
  6. ppx_protocol_conv = "2.0.0"
  7. ppx_protocol_conv_yaml < "5.0.0"

Conflicts

None

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