There are two ways to set up a development environment for Nickel: using Nix, or directly via your preferred system package manager. Nix is able to drop you in a development shell with everything needed (the Rust toolchain, mostly) to hack on Nickel in one command, without installing anything globally on your system. While Nix is also capable of building Nickel by itself, using cargo (either a system-wide installation or the one given by the Nix development shell) is the recommended way of building when working on the Nickel repository itself. The reason is that incremental compilation for Rust and Nix is not there yet, and incremental rebuilds using only Nix are going to be painfully long.
The Nickel repository consist of various crates:
nickel-lang-core
(path:core
). The main crate containing the interpreter as a library.nickel-lang-cli
(path:cli
). Thenickel
binary.nickel-lang-lsp
(path:lsp/nls/
). The Nickel Language Server (NLS), an LSP server for Nickel.nickel-lang-utils
: (path:utils/
). An auxiliary crate regrouping helpers for tests and benchmarks. Not required to buildnickel
itself.pyckel
(path:pyckel
). Python bindings tonickel-lang-core
.lsp-harness
(path:lsp/lsp-harness
). A testing harness for the Nickel Language Server.nickel-repl
(path:wasm-repl
). An auxiliary crate, re-exportingnickel-lang-core
with the right settings for building a WASM repl. Primarily used on nickel-lang.org.
Other noteworthy items:
- The user manual in
doc/manual/
, as a bunch of markdown files. - A VSCode extension for NLS in
lsp/client-extension/
.
To set up a development environment using a recent Nix (>= 2.4):
- Clone the repository:
git clone [email protected]:tweag/nickel.git
- At the root of the repository, run
nix develop
. You should now be dropped in a shell with all the required tool to hack on Nickel (rust
,cargo
, etc.)
Otherwise, you can install the Rust toolchain separately: follow the instructions of the Rust installation guide.
You can build all crates at once:
$ cargo build --all
$ ./target/debug/nickel --version
nickel-lang 0.1.0
$ ./target/debug/nls --version
nickel-lang-lsp 0.1.0
To only build the main crate nickel-lang-core
, run:
cargo build -p nickel-lang-core
To build the interpreter CLI, run:
$ cargo build -p nickel-lang-cli
$ ./target/debug/nickel --version
nickel-lang 0.1.0
To build NLS separately, the LSP server for Nickel, build the nickel-lang-lsp
crate:
$ cargo build -p nickel-lang-lsp
$ ./target/debug/nls --version
nickel-lang-lsp 0.1.0
(Alternatively, you can run cargo build
directly inside lsp/nls/
).
There is a WebAssembly (WASM) version of the REPL, which is used for the online
playground on nickel-lang.org. To ease the build, we use the
nickel-repl
located in wasm-repl
, which just wraps and re-export
the nickel-lang-core
crate with the right settings for building to WebAssembly.
The Nix flake has also an output to do the whole build, but incremental
compilation is not as good as with direct usage of cargo
.
Both methods are described below.
At the root of the repository:
$ nix build .#nickelWasm
$ ls result/nickel-repl
LICENSE package.json nickel_lang_bg.js nickel_lang_bg.wasm [..]
-
Run
wasm-pack
on thenickel-repl
crate:cd nickel-repl-wasm wasm-pack build -- --no-default-features --features repl-wasm
A
pkg
directory, containing the corresponding NPM package, should now be available.
Tests are run via cargo test
. They are two types of tests:
- Unit tests, located directly in the corresponding module.
- Integration tests, located in the dedicated crate
core/tests/integration
. - Snapshot tests, located in
cli/tests/smapshot
.
Tests are annotated with an expected result in a comment using TOML syntax that
must be located at the very beginning of the file. See the implementation in
utilities/src/annotated_test.rs
for details. These annotations are also used
to mark examples, in the top-level subdirectory examples
, with an expected
failure condition if necessary.
Tests for the happy path - i.e., valid Nickel programs which do not raise errors
are generally written in standalone Nickel files in the core/tests/integration/pass
directory. All .ncl
files in this directory are automatically converted into
Rust integration tests, which run the file and assert that no errors were
raised during evaluation.
Each of these .ncl
files is structured as an array of Bool
expressions, which
is ultimately passed to a check
function defined in
core/tests/integration/pass/lib/assert.ncl
.
This function applies an Assert
contract to each value in the array, which
checks that the value it is applied to evaluates to true
. The benefit of using
a contract for this is that if a test fails we can simply run the file directly
using Nickel, which gives better error messages than the ones we get by default
from cargo test
.
Tests which are expected to fail may be written in Rust in core/tests/integration
.
However, simple failure test cases can make use of the test annotation support
and are located in core/tests/integration/fail
.
The project also contains a suite of snapshot tests in the cli/tests/snapshot
directory. Here, .ncl
files written in the subdirectories of the input
directory are run against the last-built Nickel binary, and their output is
compared to the last-known output.
Failures of these tests do not necessarily mean that anything is wrong. Rather it should be seen as an opportunity to review the diffs and either accept any changes, or fix any issues introduced.
See README.md
in the snapshot testing crate for more detailed guides on
working with snapshot tests.
If your change is likely to impact performance, it is recommended to run the benchmark suite on master and on your branch to assess any performance changes. Please report your findings in the description of the PR.
The benchmark suite is located in the benches/
directory. To run it:
cargo bench
Note that a full run takes some time, up to a dozen of minutes. You can run
specific benchmarks instead of the full suite. Please refer to the documentation
of cargo bench
.