SDK Extension Guide
This document will use the official SDK as an example to introduce the extension methods of the SDK, namely how to extend @plutolang/pluto
and @plutolang/pluto-infra
.
If you encounter any unclear concepts or unexplained terms in this document, please refer to the "How the SDK Works" for more information.
Overall Process
- Adding a new resource type
- Define two types of functional interfaces in the Client SDK:
- An interface for defining runtime functionality methods, called the Client Interface.
- An interface for defining infrastructure-related methods, called the Infra Interface.
- An interface that includes attributes generated at compile-time and accessed at runtime, referred to as a Prop Interface.
- Define a resource operation interface in the Client SDK to expose the functionality methods for the resource.
- Define two types of functional interfaces in the Client SDK:
- Adding a new implementation for the resource type
- Create a class implementation for the Client Interface in the Client SDK and bind it through the
buildClient
method of the resource type. - Create a class implementation for the Infra Interface and
base.ResourceInfra
interface in the Infra SDK, and register it to the registry using theRegistr.register
method.
- Create a class implementation for the Client Interface in the Client SDK and bind it through the
Next, we will use the Message Queue (Queue) as a new resource type and AWS SNS as the component used, to explain the complete extension process.
Adding a New Resource Type
Create a new file named queue.ts
in the src
directory of the @plutolang/pluto
dependency library, and complete the following steps in this new file.
Define the Client Interface
The methods defined in the Client Interface are the runtime functional methods that are dynamically called. As a message queue, the Queue currently includes a push
method for users to send messages to the corresponding queue.
// The client interface is used to define the methods for accessing resources that are used during runtime.
export interface IQueueClientApi extends base.IResourceClientApi {
push(msg: string): Promise<void>;
}
Define the Infra Interface
The methods defined in the Infra Interface are used to build resource associations between the invocation object and its parameters, typically used for consuming that invocation object.
As a message queue, the Queue usually allows creating a subscriber to consume the messages published in the Queue. The method for creating a subscriber is called subscribe
. The subscribe
method takes an EventHandler
type object as a parameter. The EventHandler
type is a function type interface that inherits the base.FnResource
interface, indicating that the EventHandler
type is a FaaS resource type.
// The infra interface is used to define the methods for accessing resources that are used during compilation.
export interface IQueueInfraApi extends base.IResourceInfraApi {
subscribe(fn: EventHandler): void;
}
export interface EventHandler extends base.FnResource {
(evt: CloudEvent): Promise<void>;
}
export interface CloudEvent {
timestamp: number;
data: string;
}
Define the Prop Interface
The property interface defines a set of getter methods. The values corresponding to these methods cannot be obtained solely based on the data provided by the user. For instance, the URL of a router in apigateway can only be known after deployment. Currently, Queue does not have such requirements, hence it is empty.
export interface IQueueCapturedProps extends base.IResourceCapturedProps {}
Define the Resource Operation Interface Exposed to Users
The resource operation interface exposed to users consists of a pair of classes and interfaces with the same name. The interface inherits both the client interface and the infrastructure interface, while the class only defines the constructor and a static buildClient
method. This leverages the TypeScript feature of type merging, allowing the class to provide sufficient hints to developers even though it does not implement the interface methods.
Here, the resource class should be treated as an equivalent of an abstract class, which will not be instantiated and used in the end. However, users will still instantiate this class for usage in development. It's not declared as an abstract class because if developers try to create an instance of an abstract class, it would cause an error.
import {
FnResource,
IResource,
IResourceCapturedProps,
IResourceClientApi,
IResourceInfraApi,
runtime,
simulator,
utils,
} from "@plutolang/base";
import { aws, k8s } from "./clients";
export interface CloudEvent {
timestamp: number;
data: string;
}
export interface EventHandler extends FnResource {
(evt: CloudEvent): Promise<void>;
}
/**
* The options for instantiating an infrastructure implementation class or a client implementation
* class.
*/
export interface QueueOptions {}
/**
* Define the access methods for Queue that operate during runtime.
*/
export interface IQueueClientApi extends IResourceClientApi {
push(msg: string): Promise<void>;
}
/**
* Define the methods for Queue, which operate during compilation.
*/
export interface IQueueInfraApi extends IResourceInfraApi {
subscribe(fn: EventHandler): void;
}
/**
* Define the properties for Queue that are captured at compile time and accessed during runtime.
*/
export interface IQueueCapturedProps extends IResourceCapturedProps {}
/**
* Construct a type that includes all the necessary methods required to be implemented within the
* client implementation class of a resource type.
*/
export type IQueueClient = IQueueClientApi & IQueueCapturedProps;
/**
* Construct a type that includes all the necessary methods required to be implemented within the
* infrastructure implementation class of a resource type.
*/
export type IQueueInfra = IQueueInfraApi & IQueueCapturedProps;
// TODO: abstract class
export class Queue implements IResource {
constructor(name: string, opts?: QueueOptions) {
name;
opts;
throw new Error(
"Cannot instantiate this class, instead of its subclass depending on the target runtime."
);
}
public static buildClient(name: string, opts?: QueueOptions): IQueueClient {
const platformType = utils.currentPlatformType();
switch (platformType) {
case PlatformType.AWS:
return new aws.SNSQueue(name, opts);
case PlatformType.K8s:
return new k8s.RedisQueue(name, opts);
case PlatformType.Simulator:
if (!process.env.PLUTO_SIMULATOR_URL) throw new Error("PLUTO_SIMULATOR_URL doesn't exist");
return simulator.makeSimulatorClient(process.env.PLUTO_SIMULATOR_URL!, name);
default:
throw new Error(`not support this runtime '${platformType}'`);
}
}
}
export interface Queue extends IResource, IQueueClient, IQueueInfra {}
Adding a New Implementation for the Resource Type
Create a Client Implementation Class
In the src/clients/aws
directory of @plutolang/pluto
, create an snsQueue.ts
file. The file and the class it contains are usually named after the component and the type.
In this file, the SNSQueue
class implements the IQueueClient
interface using the AWS SDK. When calling the PublishCommand
in the aws-sdk, the ARN of the SNS topic needs to be specified. Here, the ARN is constructed by concatenating the required parameters obtained from the environment variables, which are set in the queue.sns.ts
of @plutolang/pluto-infra
.
Currently, there is no effective solution on how to transfer the information generated during compilation to the runtime for effective use.
import { SNSClient, PublishCommand } from "@aws-sdk/client-sns";
import { CloudEvent, IQueueClient, QueueOptions } from "../../queue";
/**
* Implementation of Queue using AWS SNS.
*/
export class SNSQueue implements IQueueClient {
private topicName: string;
private client: SNSClient;
constructor(name: string, opts?: QueueOptions) {
this.topicName = name;
this.client = new SNSClient({});
opts;
}
public async push(msg: string): Promise<void> {
const evt: CloudEvent = {
timestamp: Date.now(),
data: msg,
};
await this.client.send(
new PublishCommand({
TopicArn: await this.buildARN(this.topicName),
Message: JSON.stringify(evt),
})
);
}
private async buildARN(topicName: string): Promise<string> {
const region = process.env.AWS_REGION;
if (!region) {
throw new Error("Missing AWS Region");
}
const accountId = await getAwsAccountId();
return `arn:aws:sns:${region}:${accountId}:${topicName}`;
}
}
After implementing the SNSQueue
class, it needs to be created at runtime based on the runtime type. Therefore, in the src/clients/aws/index.ts
of @plutolang/pluto
, export this class and, in the buildClient
method of the Queue
class under src
, instantiate the corresponding implementation class based on the runtime type.
...
public static buildClient(name: string, opts?: QueueOptions): IQueueClient {
const platformType = utils.currentPlatformType();
switch (platformType) {
case PlatformType.AWS:
return new aws.SNSQueue(name, opts);
case PlatformType.K8s:
return new k8s.RedisQueue(name, opts);
default:
throw new Error(`not support this runtime '${platformType}'`);
}
}
...
Create an Abstract Base Class for the Infrastructure Implementation Class
In the src/
directory of @plutolang/pluto-infra
, create a file named queue.ts
. In this file, define the interfaces that the base class needs to implement. Also, define an abstract class for instantiating specific implementation classes based on platform and engine. The example below uses lazy loading to import corresponding specific instances, reducing library load time.
When implementing, it's important to note that the parameters of the constructor for implementation classes and Queue's static method createInstance
should be consistent with those of Client's constructor.
import { ProvisionType, PlatformType, utils } from "@plutolang/base";
import { IQueueInfra QueueOptions } from "@plutolang/pluto";
import { ImplClassMap } from "./utils";
// Construct a type for a class constructor. The key point is that the parameters of the constructor
// must be consistent with the client class of this resource type. Use this type to ensure that
// all implementation classes have the correct and same constructor signature.
type QueueInfraImplClass = new (name: string, options?: QueueOptions) => IQueueInfra;
// Construct a map that contains all the implementation classes for this resource type.
// The final selection will be determined at runtime, and the class will be imported lazily.
const implClassMap = new ImplClassMap<IQueueInfra, QueueInfraImplClass>({
[ProvisionType.Pulumi]: {
[PlatformType.AWS]: async () => (await import("./aws")).SNSQueue,
[PlatformType.K8s]: async () => (await import("./k8s")).RedisQueue,
},
});
/**
* This is a factory class that provides an interface to create instances of this resource type
* based on the target platform and engine.
*/
export abstract class Queue {
/**
* Asynchronously creates an instance of the queue infrastructure class. The parameters of this function
* must be consistent with the constructor of both the client class and infrastructure class associated
* with this resource type.
*/
public static async createInstance(name: string, options?: QueueOptions): Promise<IQueueInfra> {
// TODO: ensure that the resource implementation class for the simulator has identical methods as those for the cloud.
if (
utils.currentPlatformType() === PlatformType.Simulator &&
utils.currentEngineType() === ProvisionType.Simulator
) {
return new (await import("./simulator")).SimQueue(name, options) as any;
}
return implClassMap.createInstanceOrThrow(
utils.currentPlatformType(),
utils.currentEngineType(),
name,
options
);
}
}
Create an Infrastructure Implementation Class
In the src/aws
directory of @plutolang/pluto-infra
, create an snsQueue.ts
file. The file and the class it contains are usually named after the component and the type. In this file, the SNSQueue
class needs to implement the ResourceInfra
and IQueueInfra
interfaces. Typically, the creation process of the main components is defined in the constructor, and the association with other resources is built in other methods. Note that the operation names in getPermission
should correspond to the functions in the client interface.
Currently, Pluto supports implementation based on Pulumi and will support more IaC tools in the future.
import * as aws from "@pulumi/aws";
import * as pulumi from "@pulumi/pulumi";
import { Resource, ResourceInfra } from "@plutolang/base";
import { IQueueInfra, QueueOptions } from "@plutolang/pluto";
import { Lambda } from "./lambda";
import { Permission } from "./permission";
export enum SNSOps {
PUSH = "push",
}
export class SNSQueue extends pulumi.ComponentResource implements ResourceInfra, IQueueInfra {
readonly name: string;
public readonly topic: aws.sns.Topic;
constructor(name: string, opts?: QueueOptions) {
super("pluto:queue:aws/SNS", name, opts);
this.name = name;
this.topic = new aws.sns.Topic(
name,
{
name: name,
tags: {
"dapr-topic-name": name,
},
},
{ parent: this }
);
}
public subscribe(fn: Resource): void {
if (!(fn instanceof Lambda)) throw new Error("Fn is not a subclass of LambdaDef.");
const lambda = fn as Lambda;
const resourceNamePrefix = `${this.name}-${lambda.name}`;
// create topic subscription
new aws.sns.TopicSubscription(
`${resourceNamePrefix}-subscription`,
{
endpoint: lambda.lambda.arn,
protocol: "lambda",
topic: this.topic.arn,
},
{ parent: this }
);
// create sns trigger
new aws.lambda.Permission(
`${resourceNamePrefix}-httpTrigger`,
{
action: "lambda:InvokeFunction",
function: lambda.lambda.name,
principal: "sns.amazonaws.com",
sourceArn: this.topic.arn,
},
{ parent: this }
);
}
public getPermission(op: string): Permission {
const actions = [];
switch (op) {
case SNSOps.PUSH:
actions.push("sns:Publish");
break;
default:
throw new Error(`Unknown operation: ${op}`);
}
return {
effect: "Allow",
actions: actions,
resources: [this.topic.arn],
};
}
public postProcess() {}
}
After implementing the SNSQueue
class, it needs to be registered to the abstract base class of Queue
. In the src/queue.ts
of @plutolang/pluto-infra
, add the following statement to the implClassMap
variable:
the registry in order to instantiate the corresponding implementation class for the target platform during deployment. In the src/aws/index.ts
of @plutolang/pluto-infra
, export this class and add the following statement in the register
method of src/index.ts
to register it:
const implClassMap = new ImplClassMap<IQueueInfra, QueueInfraImplClass>({
[ProvisionType.Pulumi]: {
[PlatformType.AWS]: async () => (await import("./aws")).SNSQueue,
[PlatformType.K8s]: async () => (await import("./k8s")).RedisQueue,
},
});
With this, the extension of the BaaS resource type is completed.
Note
Not all resources have both the Client Interface and the Infra Interface.
For example, the Router resource only has the Infra Interface and does not have the Client Interface, meaning the Router type does not have any functional methods for the compute module to call during runtime.
The KVStore resource only has the Client Interface and does not have the Infra Interface, indicating that the KVStore type currently does not have the need to establish triggering associations with other resources.
It is important to note that whether there is an Infra Interface or not, if it's a type of cloud resource, there needs to be an infrastructure implementation class that completes the resource creation in its constructor.