Crates.io | progenitor-impl |
lib.rs | progenitor-impl |
version | 0.8.0 |
source | src |
created_at | 2022-05-13 14:42:49.02903 |
updated_at | 2024-09-26 20:49:50.000994 |
description | An OpenAPI client generator - core implementation |
homepage | |
repository | https://github.com/oxidecomputer/progenitor.git |
max_upload_size | |
id | 585918 |
size | 231,760 |
Progenitor is a Rust crate for generating opinionated clients from API
descriptions in the OpenAPI 3.0.x specification. It makes use of Rust
futures for async
API calls and Streams
for paginated interfaces.
It generates a type called Client
with methods that correspond to the
operations specified in the OpenAPI document.
Progenitor can also generate a CLI to interact with an OpenAPI service
instance, and httpmock
helpers to
create a strongly typed mock of the OpenAPI service.
The primary target is OpenAPI documents emitted by Dropshot-generated APIs, but it can be used for many OpenAPI documents. As OpenAPI covers a wide range of APIs, Progenitor may fail for some OpenAPI documents. If you encounter a problem, you can help the project by filing an issue that includes the OpenAPI document that produced the problem.
There are three different ways of using the progenitor
crate. The one you
choose will depend on your use case and preferences.
The simplest way to use Progenitor is via its generate_api!
macro.
In a source file (often main.rs
, lib.rs
, or mod.rs
) simply invoke the
macro:
generate_api!("path/to/openapi_document.json");
You'll need to add the following to Cargo.toml
:
[dependencies]
futures = "0.3"
progenitor = { git = "https://github.com/oxidecomputer/progenitor" }
reqwest = { version = "0.12", features = ["json", "stream"] }
serde = { version = "1.0", features = ["derive"] }
In addition, if the OpenAPI document contains string types with the format
field set to date
or date-time
, include
[dependencies]
chrono = { version = "0.4", features = ["serde"] }
Similarly, if there is a format
field set to uuid
:
[dependencies]
uuid = { version = "1.0.0", features = ["serde", "v4"] }
And if there are any websocket channel endpoints:
[dependencies]
base64 = "0.21"
rand = "0.8"
If types include regular expression validation:
[dependencies]
regress = "0.4.1"
The macro has some additional fancy options to control the generated code:
generate_api!(
spec = "path/to/openapi_document.json", // The OpenAPI document
interface = Builder, // Choose positional (default) or builder style
tags = Separate, // Tags may be Merged or Separate (default)
inner_type = my_client::InnerType, // Client inner type available to pre and post hooks
pre_hook = closure::or::path::to::function, // Hook invoked before issuing the HTTP request
post_hook = closure::or::path::to::function, // Hook invoked prior to receiving the HTTP response
derives = [ schemars::JsonSchema ], // Additional derive macros applied to generated types
);
Note that the macro will be re-evaluated when the spec
OpenAPI document
changes (when its mtime is updated).
build.rs
Progenitor includes an interface appropriate for use in a
build.rs
file. While slightly more onerous than the macro, a builder has the advantage of making the generated code visible.
The capability of generating a CLI and httpmock
helpers is only available using build.rs
and the Generator
functions cli
and httpmock
respectively.
The build.rs
file should look something like this:
fn main() {
let src = "../sample_openapi/keeper.json";
println!("cargo:rerun-if-changed={}", src);
let file = std::fs::File::open(src).unwrap();
let spec = serde_json::from_reader(file).unwrap();
let mut generator = progenitor::Generator::default();
let tokens = generator.generate_tokens(&spec).unwrap();
let ast = syn::parse2(tokens).unwrap();
let content = prettyplease::unparse(&ast);
let mut out_file = std::path::Path::new(&std::env::var("OUT_DIR").unwrap()).to_path_buf();
out_file.push("codegen.rs");
std::fs::write(out_file, content).unwrap();
}
In a source file (often main.rs
, lib.rs
, or mod.rs
) include the generated
code:
include!(concat!(env!("OUT_DIR"), "/codegen.rs"));
You'll need to add the following to Cargo.toml
:
[dependencies]
futures = "0.3"
progenitor-client = { git = "https://github.com/oxidecomputer/progenitor" }
reqwest = { version = "0.12", features = ["json", "stream"] }
serde = { version = "1.0", features = ["derive"] }
[build-dependencies]
prettyplease = "0.1.25"
progenitor = { git = "https://github.com/oxidecomputer/progenitor" }
serde_json = "1.0"
syn = "1.0"
(chrono
, uuid
, base64
, and rand
as above)
Note that progenitor
is used by build.rs
, but the generated code required
progenitor-client
.
Progenitor can be run to emit a stand-alone crate for the generated client. This ensures no unexpected changes (e.g. from updates to progenitor). It is however, the most manual way to use Progenitor.
Usage:
cargo progenitor
Options:
-i INPUT OpenAPI definition document (JSON or YAML)
-o OUTPUT Generated Rust crate directory
-n CRATE Target Rust crate name
-v VERSION Target Rust crate version
For example:
cargo install cargo-progenitor
cargo progenitor -i sample_openapi/keeper.json -o keeper -n keeper -v 0.1.0
... or within the repo:
cargo run --bin cargo-progenitor -- progenitor -i sample_openapi/keeper.json -o keeper -n keeper -v 0.1.0
This will produce a package in the specified directory.
Options --license
and --registry-name
may also be used to improve metadata
before publishing the static crate.
The output will use the published progenitor-client
crate by default
if progenitor was built from a released version. However, when using progenitor
built from the repository, the progenitor-client
will be inlined into the
static crate by default. The command line flag --include-client
can be used
to override the default behaviour.
To ensure the output has no persistent dependency on Progenitor, enable --include-client
.
Here is an excerpt from the emitted Cargo.toml
:
[dependencies]
bytes = "1.3.0"
chrono = { version = "0.4.23", default-features=false, features = ["serde"] }
futures-core = "0.3.25"
percent-encoding = "2.2.0"
reqwest = { version = "0.12.4", default-features=false, features = ["json", "stream"] }
serde = { version = "1.0.152", features = ["derive"] }
serde_urlencoded = "0.7.1"
The dependency versions in the generated Cargo.toml
are the same as the
versions that were used when progenitor was built.
Note that there is a dependency on percent-encoding
which macro- and
build.rs-generated clients is included from progenitor-client
.
Progenitor can generate two distinct interface styles: positional and builder (described below). The choice is simply a matter of preference that many vary by API and taste.
The "positional" style generates Client
methods that accept parameters in
order, for example:
impl Client {
pub async fn instance_create<'a>(
&'a self,
organization_name: &'a types::Name,
project_name: &'a types::Name,
body: &'a types::InstanceCreate,
) -> Result<ResponseValue<types::Instance>, Error<types::Error>> {
// ...
}
}
A caller invokes this interface by specifying parameters by position:
let result = client.instance_create(org, proj, body).await?;
Note that the type of each parameter must match precisely--no conversion is done implicitly.
The "builder" style generates Client
methods that produce a builder struct.
API parameters are applied to that builder, and then the builder is executed
(via a send
method). The code is more extensive and more complex to enable
simpler and more legible consumers:
impl Client
pub fn instance_create(&self) -> builder::InstanceCreate {
builder::InstanceCreate::new(self)
}
}
mod builder {
pub struct InstanceCreate<'a> {
client: &'a super::Client,
organization_name: Result<types::Name, String>,
project_name: Result<types::Name, String>,
body: Result<types::InstanceCreate, String>,
}
impl<'a> InstanceCreate<'a> {
pub fn new(client: &'a super::Client) -> Self {
// ...
}
pub fn organization_name<V>(mut self, value: V) -> Self
where
V: TryInto<types::Name>,
{
// ...
}
pub fn project_name<V>(mut self, value: V) -> Self
where
V: TryInto<types::Name>,
{
// ...
}
pub fn body<V>(mut self, value: V) -> Self
where
V: TryInto<types::InstanceCreate>,
{
// ...
}
pub async fn send(self) ->
Result<ResponseValue<types::Instance>, Error<types::Error>>
{
// ...
}
}
}
Note that, unlike positional generation, consumers can supply compatible (rather than invariant) parameters:
let result = client
.instance_create()
.organization_name("org")
.project_name("proj")
.body(body)
.send()
.await?;
The string parameters will implicitly have TryFrom::try_from()
invoked on
them. Failed conversions or missing required parameters will result in an
Error
result from the send()
call.
Generated struct
types also have builders so that the body
parameter can be
constructed inline:
let result = client
.instance_create()
.organization_name("org")
.project_name("proj")
.body(types::InstanceCreate::builder()
.name("...")
.description("...")
.hostname("...")
.ncpus(types::InstanceCpuCount(4))
.memory(types::ByteCount(1024 * 1024 * 1024)),
)
.send()
.await?;
Consumers do not need to specify parameters and struct properties that are not required or for which the API specifies defaults. Neat!