Plugins
The heart of Vendure is its plugin system. Plugins not only allow you to instantly add new functionality to your Vendure server via third-part npm packages, they are also the means by which you build out the custom business logic of your application.
Plugins in Vendure allow one to:
- Modify the VendureConfig object, such as defining custom fields on existing entities.
- Extend the GraphQL APIs, including modifying existing types and adding completely new queries and mutations.
- Define new database entities and interact directly with the database.
- Interact with external systems that you need to integrate with.
- Respond to events such as new orders being placed.
- Trigger background tasks to run on the worker process.
… and more!
In a typical Vendure application, custom logic and functionality is implemented as a set of plugins which are usually independent of one another. For example, there could be a plugin for each of the following: wishlists, product reviews, loyalty points, gift cards, etc. This allows for a clean separation of concerns and makes it easy to add or remove functionality as needed.
Core Plugins
Vendure provides a set of core plugins covering common functionality such as assets handling, email sending, and search. For documentation on these, see the Core Plugins reference.
Plugin basics
Here's a bare-minimum example of a plugin:
import { LanguageCode, PluginCommonModule, VendurePlugin } from '@vendure/core';
@VendurePlugin({
imports: [PluginCommonModule],
configuration: config => {
config.customFields.Customer.push({
type: 'string',
name: 'avatarUrl',
label: [{ languageCode: LanguageCode.en, value: 'Avatar URL' }],
list: true,
});
return config;
},
})
export class AvatarPlugin {}
This plugin does one thing only: it adds a new custom field to the Customer
entity.
The plugin is then imported into the VendureConfig
:
import { VendureConfig } from '@vendure/core';
import { AvatarPlugin } from './plugins/avatar-plugin/avatar.plugin';
export const config: VendureConfig = {
// ...
plugins: [AvatarPlugin],
};
The key feature is the @VendurePlugin()
decorator, which marks the class as a Vendure plugin and accepts a configuration
object on the type VendurePluginMetadata
.
A VendurePlugin is actually an enhanced version of a NestJS Module, and supports all the metadata properties that NestJS modules support:
imports
: Allows importing other NestJS modules in order to make use of their exported providers.providers
: The providers (services) that will be instantiated by the Nest injector and that may be shared across this plugin.controllers
: Controllers allow the plugin to define REST-style endpoints.exports
: The providers which will be exported from this plugin and made available to other plugins.
Additionally, the VendurePlugin
decorator adds the following Vendure-specific properties:
configuration
: A function which can modify theVendureConfig
object before the server bootstraps.shopApiExtensions
: Allows the plugin to extend the GraphQL Shop API with new queries, mutations, resolvers & scalars.adminApiExtensions
: Allows the plugin to extend the GraphQL Admin API with new queries, mutations, resolvers & scalars.entities
: Allows the plugin to define new database entities.compatibility
: Allows the plugin to declare which versions of Vendure it is compatible with.
Since a Vendure plugin is a superset of a NestJS module, this means that many NestJS modules are actually valid Vendure plugins!
Plugin lifecycle
Since a VendurePlugin is built on top of the NestJS module system, any plugin (as well as any providers it defines) can make use of any of the NestJS lifecycle hooks:
- onModuleInit
- onApplicationBootstrap
- onModuleDestroy
- beforeApplicationShutdown
- onApplicationShutdown
Note that lifecycle hooks are run in both the server and worker contexts. If you have code that should only run either in the server context or worker context, you can inject the ProcessContext provider.
Configure
Another hook that is not strictly a lifecycle hook, but which can be useful to know is the configure
method which is
used by NestJS to apply middleware. This method is called only for the server and not for the worker, since middleware relates
to the network stack, and the worker has no network part.
import { MiddlewareConsumer, NestModule } from '@nestjs/common';
import { EventBus, PluginCommonModule, VendurePlugin } from '@vendure/core';
import { MyMiddleware } from './api/my-middleware';
@VendurePlugin({
imports: [PluginCommonModule]
})
export class MyPlugin implements NestModule {
configure(consumer: MiddlewareConsumer) {
consumer
.apply(MyMiddleware)
.forRoutes('my-custom-route');
}
}
Create a Plugin via CLI
Run the npx vendure add
command, and select "Create a new Vendure plugin".
This will guide you through the creation of a new plugin and automate all aspects of the process.
This is the recommended way of creating a new plugin.
Writing a plugin from scratch
Although the Vendure CLI is the recommended way to create a new plugin, it can be useful to understand the process of creating a plugin manually.
In Vendure plugins are used to extend the core functionality of the server. Plugins can be pre-made functionality that you can install via npm, or they can be custom plugins that you write yourself.
For any unit of functionality that you need to add to your project, you'll be creating a Vendure plugin. By convention, plugins are stored in the plugins
directory of your project. However, this is not a requirement, and you are free to arrange your plugin files in any way you like.
├──src
├── index.ts
├── vendure-config.ts
├── plugins
├── reviews-plugin
├── cms-plugin
├── wishlist-plugin
├── stock-sync-plugin
For a complete working example of a Vendure plugin, see the real-world-vendure Reviews plugin
You can also use the Vendure CLI to quickly scaffold a new plugin.
If you intend to write a shared plugin to be distributed as an npm package, see the vendure plugin-template repo
In this guide, we will implement a simple but fully-functional wishlist plugin step-by-step. The goal of this plugin is to allow signed-in customers to add products to a wishlist, and to view and manage their wishlist.
Step 1: Create the plugin file
We'll start by creating a new directory to house our plugin, add create the main plugin file:
├──src
├── index.ts
├── vendure-config.ts
├── plugins
├── wishlist-plugin
├── wishlist.plugin.ts
import { PluginCommonModule, VendurePlugin } from '@vendure/core';
@VendurePlugin({
imports: [PluginCommonModule],
})
export class WishlistPlugin {}
The PluginCommonModule
will be required in all plugins that you create. It contains the common services that are exposed by Vendure Core, allowing you to inject them into your plugin's services and resolvers.
Step 2: Define an entity
Next we will define a new database entity to store the wishlist items. Vendure uses TypeORM to manage the database schema, and an Entity corresponds to a database table.
First let's create the file to house the entity:
├── wishlist-plugin
├── wishlist.plugin.ts
├── entities
├── wishlist-item.entity.ts
By convention, we'll store the entity definitions in the entities
directory of the plugin. Again, this is not a requirement, but it is a good way to keep your plugin organized.
import { DeepPartial, ID, ProductVariant, VendureEntity, EntityId } from '@vendure/core';
import { Column, Entity, ManyToOne } from 'typeorm';
@Entity()
export class WishlistItem extends VendureEntity {
constructor(input?: DeepPartial<WishlistItem>) {
super(input);
}
@ManyToOne(type => ProductVariant)
productVariant: ProductVariant;
@EntityId()
productVariantId: ID;
}
Let's break down what's happening here:
- The
WishlistItem
entity extends theVendureEntity
class. This is a base class which provides theid
,createdAt
andupdatedAt
fields, and all custom entities should extend it. - The
@Entity()
decorator marks this class as a TypeORM entity. - The
@ManyToOne()
decorator defines a many-to-one relationship with theProductVariant
entity. This means that eachWishlistItem
will be associated with a singleProductVariant
. - The
productVariantId
column is not strictly necessary, but it allows us to always have access to the ID of the relatedProductVariant
without having to load the entireProductVariant
entity from the database. - The
constructor()
is used to create a new instance of the entity. This is not strictly necessary, but it is a good practice to define a constructor which takes aDeepPartial
of the entity as an argument. This allows us to create new instances of the entity using thenew
keyword, passing in a plain object with the desired properties.
Next we need to register this entity with our plugin:
import { PluginCommonModule, VendurePlugin } from '@vendure/core';
import { WishlistItem } from './entities/wishlist-item.entity';
@VendurePlugin({
imports: [PluginCommonModule],
entities: [WishlistItem],
})
export class WishlistPlugin {}
Step 3: Add a custom field to the Customer entity
We'll now define a new custom field on the Customer entity which will store a list of WishlistItems. This will allow us to easily query for all wishlist items associated with a particular customer.
Custom fields are defined in the VendureConfig object, and in a plugin we use the configuration
function to modify the config object:
import { PluginCommonModule, VendurePlugin } from '@vendure/core';
import { WishlistItem } from './entities/wishlist-item.entity';
@VendurePlugin({
imports: [PluginCommonModule],
entities: [WishlistItem],
configuration: config => {
config.customFields.Customer.push({
name: 'wishlistItems',
type: 'relation',
list: true,
entity: WishlistItem,
internal: true,
});
return config;
},
})
export class WishlistPlugin {}
In this snippet we are pushing a new custom field definition onto the Customer
entity's customFields
array, and defining this new field as a list (array) of WishlistItem
entities. Internally, this will tell TypeORM to update the database schema to store this new field. We set internal: true
to indicate that this field should not be directly exposed to the GraphQL API as Customer.customFields.wishlistItems
, but instead should be accessed via a custom resolver we will define later.
In order to make use of this custom field in a type-safe way, we can tell TypeScript about this field in a new file:
├── wishlist-plugin
├── wishlist.plugin.ts
├── types.ts
import { WishlistItem } from './entities/wishlist-item.entity';
declare module '@vendure/core/dist/entity/custom-entity-fields' {
interface CustomCustomerFields {
wishlistItems: WishlistItem[];
}
}
We can then import this types file in our plugin's main file:
import './types';
Step 4: Create a service
A "service" is a class which houses the bulk of the business logic of any plugin. A plugin can define multiple services if needed, but each service should be responsible for a single unit of functionality, such as dealing with a particular entity, or performing a particular task.
Let's create a service to handle the wishlist functionality:
├── wishlist-plugin
├── wishlist.plugin.ts
├── services
├── wishlist.service.ts
import { Injectable } from '@nestjs/common';
import {
Customer,
ForbiddenError,
ID,
InternalServerError,
ProductVariantService,
RequestContext,
TransactionalConnection,
UserInputError,
} from '@vendure/core';
import { WishlistItem } from '../entities/wishlist-item.entity';
@Injectable()
export class WishlistService {
constructor(
private connection: TransactionalConnection,
private productVariantService: ProductVariantService,
) {}
async getWishlistItems(ctx: RequestContext): Promise<WishlistItem[]> {
try {
const customer = await this.getCustomerWithWishlistItems(ctx);
return customer.customFields.wishlistItems;
} catch (err: any) {
return [];
}
}
/**
* Adds a new item to the active Customer's wishlist.
*/
async addItem(ctx: RequestContext, variantId: ID): Promise<WishlistItem[]> {
const customer = await this.getCustomerWithWishlistItems(ctx);
const variant = this.productVariantService.findOne(ctx, variantId);
if (!variant) {
throw new UserInputError(`No ProductVariant with the id ${variantId} could be found`);
}
const existingItem = customer.customFields.wishlistItems.find(i => i.productVariantId === variantId);
if (existingItem) {
// Item already exists in wishlist, do not
// add it again
return customer.customFields.wishlistItems;
}
const wishlistItem = await this.connection
.getRepository(ctx, WishlistItem)
.save(new WishlistItem({ productVariantId: variantId }));
customer.customFields.wishlistItems.push(wishlistItem);
await this.connection.getRepository(ctx, Customer).save(customer, { reload: false });
return this.getWishlistItems(ctx);
}
/**
* Removes an item from the active Customer's wishlist.
*/
async removeItem(ctx: RequestContext, itemId: ID): Promise<WishlistItem[]> {
const customer = await this.getCustomerWithWishlistItems(ctx);
const itemToRemove = customer.customFields.wishlistItems.find(i => i.id === itemId);
if (itemToRemove) {
await this.connection.getRepository(ctx, WishlistItem).remove(itemToRemove);
customer.customFields.wishlistItems = customer.customFields.wishlistItems.filter(
i => i.id !== itemId,
);
}
await this.connection.getRepository(ctx, Customer).save(customer);
return this.getWishlistItems(ctx);
}
/**
* Gets the active Customer from the context and loads the wishlist items.
*/
private async getCustomerWithWishlistItems(ctx: RequestContext): Promise<Customer> {
if (!ctx.activeUserId) {
throw new ForbiddenError();
}
const customer = await this.connection.getRepository(ctx, Customer).findOne({
where: { user: { id: ctx.activeUserId } },
relations: {
customFields: {
wishlistItems: {
productVariant: true,
},
},
},
});
if (!customer) {
throw new InternalServerError(`Customer was not found`);
}
return customer;
}
}
Let's break down what's happening here:
- The
WishlistService
class is decorated with the@Injectable()
decorator. This is a standard NestJS decorator which tells the NestJS dependency injection (DI) system that this class can be injected into other classes. All your services should be decorated with this decorator. - The arguments passed to the constructor will be injected by the NestJS DI system. The
connection
argument is a TransactionalConnection instance, which is used to access and manipulate data in the database. TheProductVariantService
argument is a built-in Vendure service which contains methods relating to ProductVariants. - The
RequestContext
object is usually the first argument to any service method, and contains information and context about the current request as well as any open database transactions. It should always be passed to the methods of theTransactionalConnection
.
The service is then registered with the plugin metadata as a provider:
import { PluginCommonModule, VendurePlugin } from '@vendure/core';
import { WishlistService } from './services/wishlist.service';
@VendurePlugin({
imports: [PluginCommonModule],
providers: [WishlistService],
entities: [WishlistItem],
configuration: config => {
// ...
},
})
export class WishlistPlugin {}
Step 5: Extend the GraphQL API
This plugin will need to extend the Shop API, adding new mutations and queries to enable the customer to view and manage their wishlist.
First we will create a new file to hold the GraphQL schema extensions:
├── wishlist-plugin
├── wishlist.plugin.ts
├── api
├── api-extensions.ts
import gql from 'graphql-tag';
export const shopApiExtensions = gql`
type WishlistItem implements Node {
id: ID!
createdAt: DateTime!
updatedAt: DateTime!
productVariant: ProductVariant!
productVariantId: ID!
}
extend type Query {
activeCustomerWishlist: [WishlistItem!]!
}
extend type Mutation {
addToWishlist(productVariantId: ID!): [WishlistItem!]!
removeFromWishlist(itemId: ID!): [WishlistItem!]!
}
`;
The graphql-tag
package is a dependency of the Vendure core package. Depending on the package manager you are using, you may need to install it separately with yarn add graphql-tag
or npm install graphql-tag
.
The api-extensions.ts
file is where we define the extensions we will be making to the Shop API GraphQL schema. We are defining a new WishlistItem
type; a new query: activeCustomerWishlist
; and two new mutations: addToWishlist
and removeFromWishlist
. This definition is written in schema definition language (SDL), a convenient syntax for defining GraphQL schemas.
Next we need to pass these extensions to our plugin's metadata:
import { PluginCommonModule, VendurePlugin } from '@vendure/core';
import { shopApiExtensions } from './api/api-extensions';
@VendurePlugin({
imports: [PluginCommonModule],
shopApiExtensions: {
schema: shopApiExtensions,
resolvers: [],
},
})
export class WishlistPlugin {}
Step 6: Create a resolver
Now that we have defined the GraphQL schema extensions, we need to create a resolver to handle the new queries and mutations. A resolver in GraphQL is a function which actually implements the query or mutation defined in the schema. This is done by creating a new file in the api
directory:
├── wishlist-plugin
├── wishlist.plugin.ts
├── api
├── api-extensions.ts
├── wishlist.resolver.ts
import { Args, Mutation, Query, Resolver } from '@nestjs/graphql';
import { Allow, Ctx, Permission, RequestContext, Transaction } from '@vendure/core';
import { WishlistItem } from '../entities/wishlist-item.entity';
import { WishlistService } from '../services/wishlist.service';
@Resolver()
export class WishlistShopResolver {
constructor(private wishlistService: WishlistService) {}
@Query()
@Allow(Permission.Owner)
activeCustomerWishlist(@Ctx() ctx: RequestContext) {
return this.wishlistService.getWishlistItems(ctx);
}
@Mutation()
@Transaction()
@Allow(Permission.Owner)
async addToWishlist(
@Ctx() ctx: RequestContext,
@Args() { productVariantId }: { productVariantId: string },
) {
return this.wishlistService.addItem(ctx, productVariantId);
}
@Mutation()
@Transaction()
@Allow(Permission.Owner)
async removeFromWishlist(@Ctx() ctx: RequestContext, @Args() { itemId }: { itemId: string }) {
return this.wishlistService.removeItem(ctx, itemId);
}
}
Resolvers are usually "thin" functions that delegate the actual work to a service. Vendure, like NestJS itself, makes heavy use of decorators at the API layer to define various aspects of the resolver. Let's break down what's happening here:
- The
@Resolver()
decorator tells the NestJS DI system that this class is a resolver. Since a Resolver is part of the NestJS DI system, we can also inject dependencies into its constructor. In this case we are injecting theWishlistService
which we created in the previous step. - The
@Mutation()
decorator tells Vendure that this is a mutation resolver. Similarly,@Query()
decorator defines a query resolver. The name of the method is the name of the query or mutation in the schema. - The
@Transaction()
decorator tells Vendure that this resolver method should be wrapped in a database transaction. This is important because we are performing multiple database operations in this method, and we want them to be atomic. - The
@Allow()
decorator tells Vendure that this mutation is only allowed for users with theOwner
permission. TheOwner
permission is a special permission which indicates that the active user should be the owner of this operation. - The
@Ctx()
decorator tells Vendure that this method requires access to theRequestContext
object. Every resolver should have this as the first argument, as it is required throughout the Vendure request lifecycle.
This resolver is then registered with the plugin metadata:
import { PluginCommonModule, VendurePlugin } from '@vendure/core';
import { shopApiExtensions } from './api/api-extensions';
import { WishlistShopResolver } from './api/wishlist.resolver';
@VendurePlugin({
imports: [PluginCommonModule],
shopApiExtensions: {
schema: shopApiExtensions,
resolvers: [WishlistShopResolver],
},
configuration: config => {
// ...
},
})
export class WishlistPlugin {}
More information about resolvers can be found in the NestJS docs.
Step 7: Specify compatibility
Since Vendure v2.0.0, it is possible for a plugin to specify which versions of Vendure core it is compatible with. This is especially important if the plugin is intended to be made publicly available via npm or another package registry.
The compatibility is specified via the compatibility
property in the plugin metadata:
@VendurePlugin({
// ...
compatibility: '^2.0.0',
})
export class WishlistPlugin {}
The value of this property is a semver range which specifies the range of compatible versions. In this case, we are saying that this plugin is compatible with any version of Vendure core which is >= 2.0.0 < 3.0.0
.
Step 8: Add the plugin to the VendureConfig
The final step is to add the plugin to the VendureConfig
object. This is done in the vendure-config.ts
file:
import { VendureConfig } from '@vendure/core';
import { WishlistPlugin } from './plugins/wishlist-plugin/wishlist.plugin';
export const config: VendureConfig = {
// ...
plugins: [
// ...
WishlistPlugin,
],
};
Test the plugin
Now that the plugin is installed, we can test it out. Since we have defined a custom field, we'll need to generate and run a migration to add the new column to the database:
npm run migration:generate wishlist-plugin
Then start the server:
npm run dev
Once the server is running, we should be able to log in as an existing Customer, and then add a product to the wishlist:
- Login mutation
- Response
mutation Login {
login(username: "alec.breitenberg@gmail.com", password: "test") {
... on CurrentUser {
id
identifier
}
... on ErrorResult {
errorCode
message
}
}
}
{
"data": {
"login": {
"id": "9",
"identifier": "alec.breitenberg@gmail.com"
}
}
}
- AddToWishlist mutation
- Response
mutation AddToWishlist {
addToWishlist(productVariantId: "7") {
id
productVariant {
id
name
}
}
}
{
"data": {
"addToWishlist": [
{
"id": "4",
"productVariant": {
"id": "7",
"name": "Wireless Optical Mouse"
}
}
]
}
}
We can then query the wishlist items:
- GetWishlist mutation
- Response
query GetWishlist {
activeCustomerWishlist {
id
productVariant {
id
name
}
}
}
{
"data": {
"activeCustomerWishlist": [
{
"id": "4",
"productVariant": {
"id": "7",
"name": "Wireless Optical Mouse"
}
}
]
}
}
And finally, we can test removing an item from the wishlist:
- RemoveFromWishlist mutation
- Response
mutation RemoveFromWishlist {
removeFromWishlist(itemId: "4") {
id
productVariant {
name
}
}
}
{
"data": {
"removeFromWishlist": []
}
}