Crates.io | faux |
lib.rs | faux |
version | |
source | src |
created_at | 2020-01-06 22:03:18.26309 |
updated_at | 2024-12-02 08:21:35.368671 |
description | A library to mock structs |
homepage | https://github.com/nrxus/faux |
repository | https://github.com/nrxus/faux |
max_upload_size | |
id | 195952 |
Cargo.toml error: | TOML parse error at line 19, column 1 | 19 | autolib = false | ^^^^^^^ unknown field `autolib`, expected one of `name`, `version`, `edition`, `authors`, `description`, `readme`, `license`, `repository`, `homepage`, `documentation`, `build`, `resolver`, `links`, `default-run`, `default_dash_run`, `rust-version`, `rust_dash_version`, `rust_version`, `license-file`, `license_dash_file`, `license_file`, `licenseFile`, `license_capital_file`, `forced-target`, `forced_dash_target`, `autobins`, `autotests`, `autoexamples`, `autobenches`, `publish`, `metadata`, `keywords`, `categories`, `exclude`, `include` |
size | 0 |
A library to create mocks out of structs.
faux
allows you to mock the methods of structs for testing without
complicating or polluting your code.
See the API docs for more information.
faux
makes liberal use of unsafe Rust features, so it is only
recommended for use inside tests. To prevent faux
from leaking into
your production code, set it as a dev-dependency
in your
Cargo.toml
:
[dev-dependencies]
faux = "^0.1"
faux
provides two attributes:
#[create]
: transforms a struct into a mockable equivalent#[methods]
: transforms the methods in an impl
block into their
mockable equivalentUse Rust's #[cfg_attr(...)]
to gate these attributes to the test
config only.
#[cfg_attr(test, faux::create)]
pub struct MyStructToMock { /* fields */ }
#[cfg_attr(test, faux::methods)]
impl MyStructToMock { /* methods to mock */ }
mod client {
// #[faux::create] makes a struct mockable and
// generates an associated `faux` function
// e.g., `UserClient::faux()` will create a mock `UserClient` instance
#[faux::create]
pub struct UserClient { /* data of the client */ }
#[derive(Clone)]
pub struct User {
pub name: String
}
// #[faux::methods] makes every public method in the `impl` block mockable
#[faux::methods]
impl UserClient {
pub fn fetch(&self, id: usize) -> User {
// does some network calls that we rather not do in tests
User { name: "".into() }
}
}
}
use crate::client::UserClient;
pub struct Service {
client: UserClient,
}
#[derive(Debug, PartialEq)]
pub struct UserData {
pub id: usize,
pub name: String,
}
impl Service {
fn user_data(&self) -> UserData {
let id = 3;
let user = self.client.fetch(id);
UserData { id, name: user.name }
}
}
// A sample #[test] for Service that mocks the client::UserClient
fn main() {
// create a mock of client::UserClient using `faux`
let mut client = client::UserClient::faux();
// mock fetch but only if the argument is 3
// argument matchers are optional
faux::when!(client.fetch(3))
// stub the return value for this mock
.then_return(client::User { name: "my user name".into() });
// prepare the subject for your test using the mocked client
let subject = Service { client };
// assert that your subject returns the expected data
let expected = UserData { id: 3, name: String::from("my user name") };
assert_eq!(subject.user_data(), expected);
}
Due to constraints with rustdocs, the above example tests in
main()
rather than a #[test]
function. In real life, the faux
attributes should be gated to #[cfg(test)]
.
faux
lets you mock the return value or implementation of:
self: Rc<Self>
)faux
also provides easy-to-use argument matchers.
#[derive(...)]
and auto-traits.faux
mocks will auto implement Send
and Sync
if the real
instance also implements it. Using #[derive(...)]
for Clone
,
Debug
, and Default
will also work as expected. Other derivable
traits are not supported as they are about data (e.g., Eq
, or
Hash
) but faux
is about mocking behavior not data. Deriving traits
that are not part of the standard library is also not currently
supported. An escape hatch for this is to manually write the impl
for that trait. If you believe there is a derivable trait that faux
should support please file an issue explaining your use case.
Clone
is a bit of a special case in that it does not duplicate the
stubs but instead shares them with the cloned instance. If this is not
the desired behavior for cloning mocks you may instead implement
Clone
manually and do normal method stubbing
(faux::when!(my_struct.clone()).then_return(/* something */)
). Note
that for the cases of exhaustable stubs (e.g.,
faux::when!(my_struct.foo()).once()
) if either instance calls for
the stub that will count as exhausting the stub as they are shared.
While faux
makes no guarantees that it will work with other macro
libraries, it should "just" work. There are some caveats, however. For
a quick solution, try making the faux
attributes (e.g.
#[faux::methods]
) the first attribute.
If another proc-macro
modifies the signature of a method before
faux
does its macro expansion, then it could modify the signature
into something not supported by faux
. Unfortunately, the order of
proc macros is not specified. However, in practice it seems to
expand top-down (tested in Rust 1.42).
#[faux::create]
struct Foo { /*some items here */ }
#[faux::methods]
#[another_attribute]
impl Foo {
/* some methods here */
}
In the snippet above, #[faux::methods]
will expand first followed by
#[another_attribute]
.faux
is effectively ignoring the other macro
and expanding based on the code you wrote.
If #[faux::methods]
performs its expansion after another macro has
modified the impl
block, #[faux::methods]
receives the expanded
code. This code might contain different method signatures than what
you originally wrote. Note that the other proc macro's expansion may
create code that faux
cannot handle (e.g. explicit lifetimes).
For a concrete example, let's look at
async-trait
. async-trait
effectively converts:
async fn run(&self, arg: Arg) -> Out {
/* stuff inside */
}
fn run<'async>(&'async self, arg: Arg) -> Pin<Box<dyn std::future::Future<Output = Out> + Send + 'async>> {
/* crazier stuff inside */
}
Because async-trait
adds explicit lifetimes to the method signature,
which faux
cannot handle, having async-trait
do its expansion
first breaks faux
. Note that even if faux
could handle explicit
lifetimes, our signature is now so unwieldy that it would make mocks
hard to work with. Because async-trait
just wants an async
function signature, and faux
does not modify function signatures, it
is okay for faux
to expand first.
#[faux::methods]
#[async_trait]
impl MyStruct for MyTrait {
async fn run(&self, arg: Arg) -> Out {
/* stuff inside */
}
}
If you find a proc macro that faux
cannot handle, please open an
issue to see if faux
is doing something unexpected that conflicts
with that macro.
faux
was founded on the belief that traits with single
implementations are an undue burden and an unnecessary layer of
abstraction. Thus, faux
does not rely on trait definitions for every
mocked object, which would pollute their function signatures with
either generics or trait objects. faux
aims to create mocks out of
user-defined structs, avoiding extra production code that exists
solely for tests.
This library was inspired by mocktopus, a mocking library for
nightly Rust that lets you mock any function. Unlike mocktopus, faux
works on stable Rust and deliberately only allows for mocking public
methods in structs.