This project is a NPM module that generates model interfaces and web service clients from an OpenApi 3 specification. The generated classes follow the principles of Angular. The generated code is compatible with Angular 12+.
For a generator for Swagger 2.0, use ng-swagger-gen instead.
- It should be easy to use and to integrate with Angular CLI;
- It should support
OpenAPI
specifications in bothJSON
andYAML
formats; - Each tag in the OpenAPI specification generates an Angular
@Injectable()
service; - An Angular
@NgModule()
is generated, which provides all services; - It should be easy to access the original
HttpResponse
, for example, to read headers. This is achieved by generating a variant suffixed with$Response
for each generated method; OpenAPI
supports combinations of request body and response content types. For each combination, a distinct method is generated;- It should be possible to specify a subset of services to generate. Only the models actually used by that subset should be generated;
- It should be easy to specify a root URL for the web service endpoints;
- Generated files should compile using strict
TypeScript
compiler flags, such asnoUnusedLocals
andnoUnusedParameters
.
- Only standard OpenAPI 3 descriptions will be generated.
ng-swagger-gen
allows several extensions, specially types from JSON schema, but they are out of scope forng-openapi-gen
. There is, however, support for a few vendor extensions; - Servers per operation are not supported;
- Only the first server is used as a default root URL in the configuration;
- No data transformation is ever performed before sending / after returning data.
This means that a property of type
string
and formatdate-time
will always be generated asstring
, notDate
. Otherwise every API call would need to have a processing that would traverse the returned object graph before sending the request to replace all date properties byDate
. The same applies to sent requests. Such operations are out of scope forng-openapi-gen
;
This project uses the same philosophy as ng-swagger-gen, and was built by the same team.
We've learned a lot with ng-swagger-gen
and have applied all the acquired knowledge to build ng-openapi-gen
.
There were several reasons to not build a new major version of ng-swagger-gen
that supports OpenAPI 3
, but instead, to create a new project.
The main differences between ng-openapi-gen
and ng-swagger-gen
are:
- The first, more obvious and more important is the specification version,
OpenAPI 3
vsSwagger 2
; - The generator itself is written in
TypeScript
, which should be easier to maintain; - There is an extensive test suite for the generator;
- The command-line arguments are more robust, derived directly from the
JSON schema
definition for the configuration file, easily allowing to override any specific configuration on CLI. - Root enumerations (schemas of
type
=string
|number
|integer
) can be generated as TypeScript'senum
's. This is enabled by default. Inline enums are not, because it would require another type to be exported in the container type.
You may want to install ng-openapi-gen
globally or just on your project. Here is an example for a global setup:
$ npm install -g ng-openapi-gen
$ ng-openapi-gen --input my-api.yaml --output my-app/src/app/api
Alternativly you can use the generator directly from within your build-script:
import $RefParser from 'json-schema-ref-parser';
import { NgOpenApiGen } from 'ng-openapi-gen';
const options = {
input: "my-api.json",
output: "my-app/src/app/api",
}
// load the openapi-spec and resolve all $refs
const RefParser = new $RefParser();
const openApi = await RefParser.bundle(options.input, {
dereference: { circular: false }
});
const ngOpenGen = new NgOpenApiGen(openApi, options);
ngOpenGen.generate();
This will expect the file my-api.yaml
(or my-api.json
) to be in the current directory, and will generate the files on my-app/src/app/api
.
If the file ng-openapi-gen.json
exists in the current directory, it will be read. Alternatively, you can run ng-openapi-gen --config my-config.json
(could also be -c
) to specify a different configuration file, or even specify the input / output as ng-openapi-gen -i input.yaml
or ng-openapi-gen -i input.yaml -o /tmp/generation
.
The only required configuration property is input
, which specified the OpenAPI
specification file. The default output
is src/app/api
.
For a list with all possible configuration options, see the JSON schema file.
You can also run ng-openapi-gen --help
to see all available options.
Each option in the JSON schema can be passed in as a CLI argument, both in camel case, like --includeTags tag1,tag2,tag3
, or in kebab case, like --exclude-tags tag1,tag2,tag3
.
Here is an example of a configuration file:
{
"$schema": "node_modules/ng-openapi-gen/ng-openapi-gen-schema.json",
"input": "my-file.json",
"output": "out/person-place",
"ignoreUnusedModels": false
}
The easiest way to specify a custom root URL (web service endpoint URL) is to
use forRoot
method of ApiModule
and set the rootUrl
property from there.
@NgModule({
declarations: [
AppComponent
],
imports: [
HttpClientModule
ApiModule.forRoot({ rootUrl: 'https://www.example.com/api' }),
],
bootstrap: [
AppComponent
]
})
export class AppModule { }
Alternatively, you can inject the ApiConfiguration
instance in some service
or component, such as the AppComponent
and set the rootUrl
property there.
To pass request headers, such as authorization or API keys, as well as having a
centralized error handling, a standard
HttpInterceptor should
be used. It is basically an @Injectable
that is called before each request,
and can customize both requests and responses.
Here is an example:
@Injectable()
export class ApiInterceptor implements HttpInterceptor {
intercept(req: HttpRequest<any>, next: HttpHandler): Observable<HttpEvent<any>> {
// Apply the headers
req = req.clone({
setHeaders: {
'ApiToken': '1234567890'
}
});
// Also handle errors globally
return next.handle(req).pipe(
tap(x => x, err => {
// Handle this err
console.error(`Error performing request, status code = ${err.status}`);
})
);
}
}
Then, both the HttpInterceptor
implementation and the injection token
HTTP_INTERCEPTORS
pointing to it must be provided in your application module,
like this:
import { NgModule, Provider, forwardRef } from '@angular/core';
import { HTTP_INTERCEPTORS } from '@angular/common/http';
import { ApiInterceptor } from './api.interceptor';
export const API_INTERCEPTOR_PROVIDER: Provider = {
provide: HTTP_INTERCEPTORS,
useExisting: forwardRef(() => ApiInterceptor),
multi: true
};
@NgModule({
providers: [
ApiInterceptor,
API_INTERCEPTOR_PROVIDER
]
})
export class AppModule {}
Finer control over specific requests can also be achieved, such as:
- Set the immediate next request to use a BASIC authentication for login, and the subsequent ones to use a session key in another request header;
- Set the next request to not use the default error handling, and handle errors directly in the calling code.
To do so, just create another shared @Injectable()
, for example, called
ApiRequestConfiguration
, which has state for such special cases. Then inject
it on both the HttpInterceptor
and in the client code that makes requests.
Here is an example for such class for controlling the authentication:
import { Injectable } from '@angular/core';
import { HttpRequest } from '@angular/common/http';
/**
* Configuration for the performed HTTP requests
*/
@Injectable()
export class ApiRequestConfiguration {
private nextAuthHeader: string;
private nextAuthValue: string;
/** Set to basic authentication */
basic(user: string, password: string): void {
this.nextAuthHeader = 'Authorization';
this.nextAuthValue = 'Basic ' + btoa(user + ':' + password);
}
/** Set to session key */
session(sessionKey: string): void {
this.nextAuthHeader = 'Session';
this.nextAuthValue = sessionKey;
}
/** Clear any authentication headers (to be called after logout) */
clear(): void {
this.nextAuthHeader = null;
this.nextAuthValue = null;
}
/** Apply the current authorization headers to the given request */
apply(req: HttpRequest<any>): HttpRequest<any> {
const headers = {};
if (this.nextAuthHeader) {
headers[this.nextAuthHeader] = this.nextAuthValue;
}
// Apply the headers to the request
return req.clone({
setHeaders: headers
});
}
}
Then change the ApiInterceptor
class to call the apply
method.
And, of course, add ApiRequestConfiguration
to your module providers
and
inject it on your components or services.
Regardless If your Angular project was generated or is managed by Angular CLI, or you have started your project with some other seed (for example, using webpack directly), you can setup a script to make sure the generated API classes are consistent with the swagger descriptor.
To do so, create the ng-openapi-gen.json
configuration file and add the
following scripts
to your package.json
:
{
"scripts": {
"ng-openapi-gen": "ng-openapi-gen",
"start": "npm run ng-openapi-gen && npm run ng -- serve",
"build": "npm run ng-openapi-gen && npm run ng -- build -prod"
}
}
This way whenever you run npm start
or npm run build
, the API classes
will be generated before actually serving / building your application.
Also, if you use several configuration files, you can specify multiple times
the call to ng-openapi-gen
, like:
{
"scripts": {
"ng-openapi-gen": "ng-openapi-gen",
"generate.api1": "npm run ng-openapi-gen -c api1.json",
"generate.api2": "npm run ng-openapi-gen -c api2.json",
"generate": "npm run generate.api1 && npm run generate.api2",
"start": "npm run generate && npm run ng -- serve",
"build": "npm run generate && npm run ng -- build -prod"
}
}
Besides the OpenAPI 3 specification, the following vendor extensions are supported:
x-operation-name
: Defined in LoopBack, this extension can be used in operations to specify the actual method name. TheoperationId
is required to be unique among all tags, but with this extension, a shorter method name can be used per tag (service). Example:
paths:
/users:
get:
tags:
- Users
operationId: listUsers
x-operation-name: list
# ...
/places:
get:
tags:
- Places
operationId: listPlaces
x-operation-name: list
# ...
x-enumNames
: Generated by NSwag, this extension allows schemas which are enumerations to customize the enum names. It must be an array with the same length as the actual enum values. Example:
components:
schemas:
HttpStatusCode:
type: integer
enum:
- 200
- 404
- 500
x-enumNames:
- OK
- NOT_FOUND
- INTERNAL_SERVER_ERROR
You can customize the Handlebars templates by copying the desired files from the templates folder (only the ones you need to customize) to some folder in your project, and then reference it in the configuration file.
For example, to make objects extend a base interface, copy the
object.handlebars file to your src/templates
folder.
Then, in ng-openapi-gen.json
file, set the following: "templates": "src/templates"
.
Finally, the customized src/templates/object.handlebars
would look like the following (based on the 0.17.2 version, subject to change in the future):
You can integrate your own Handlebar helpers for custom templates. To do so simply provide a handlebars.js
file in the same directory as your templates that exports a function that recieves the Handlebars instance that will be used when generating the code from your templates.
module.exports = function(handlebars) {
// Adding a custom handlebars helper: loud
handlebars.registerHelper('loud', function (aString) {
return aString.toUpperCase()
});
};
The generator itself is written in TypeScript. When building, the code is transpiled to JavaScript in the dist
folder. And the dist
folder is the one that gets published to NPM. Even to prevent publishing from the wrong path, the package.json
file has "private": true
, which gets replaced by false
in the build process.
On the other hand, for developing / running tests, jasmine-ts
is used, so the tests run directly from TypeScript. There's even a committed VisualStudio Code debug configuration for tests.
After developing the changes, to link
the module and test it with other node projects, run the following:
npm run build
cd dist
npm link
At that point, the globally available ng-openapi-gen will be the one compiled to the dist
folder.