In the context of programming, a service refers to a reusable component or functionality that can be used by different parts of an application. Services are designed to provide specific capabilities and can be shared across multiple modules or components.

Services often encapsulate common tasks or operations that are needed by different parts of an application. They can handle complex operations, interact with external systems or APIs, manage data, or perform other specialized tasks.

Services are typically designed to be modular and decoupled from the rest of the application. This allows them to be easily maintained, tested, and replaced without affecting the overall functionality of the application.

When working with services in Effect, it is important to understand the concept of context: in the type Effect<A, E, R>, the parameter R represents the contextual data required by the effect to be executed. This contextual data is stored in a collection called Context.

#Managing Services with Effects

So far, we have been working with effects that don't require any specific context. In those cases, the R parameter in the Effect<A, E, R> type has always been of type never. However, there are situations where we need to work with effects that depend on specific services or contextual data.

In this guide, we will learn how to:

• Create Effects that depend on a specific context.
• Work with Effects that require a context or service dependencies.
• Provide the required context to the Effect.

Understanding how to manage services and provide the necessary context to effects is essential for building more complex and customizable programs. Let's dive in and explore these concepts in detail.

#Creating a Simple Service

Let's start by creating a service for a random number generator.

To create a new service, three things are needed:

• A unique identifier at the runtime level (the "Random" string).
• A unique identifier at the type level (the Random class type).
• A type describing the possible operations of the service .

ts
import { Effect, Context } from "effect"
 
export class Random extends Context.Tag("Random")<
  Random,
  { readonly next: Effect.Effect<number> }
>() {}

ts
import { Effect, Context } from "effect"
 
export class Random extends Context.Tag("Random")<
  Random,
  { readonly next: Effect.Effect<number> }
>() {}

The code above defines a type which represents our service. It has a single operation called next that returns a random number.

The Random value is what is referred to as a "Tag" in Effect. It serves as a representation of the service and allows Effect to locate and use this service at runtime.

To understand this better, let's think of the context of an effect as a Map:

ts
Map<Tag, ServiceImpl>

ts
Map<Tag, ServiceImpl>

Here, the Tag acts like the "key" to the service implementation within the context.

Additionally, you need to specify an identifier (in this case, the string "Random") to make the Tag global. This means that two tags with the same identifier must refer to the same instance.

This feature comes in handy in scenarios where live reloads can occur, and you want to preserve the instance across reloads. It ensures that there is no duplication of instances (although it should not happen in the first place, some bundlers and frameworks can behave strangely, and we don't have control over them). Additionally, using a unique identifier allows for better printing of a tag. If you ever face "Service Not Found" or "Service Not Found: Random," the second is better and provides more helpful information to identify the issue.

#Using the Service

Now that we have our service tag defined, let's see how we can use it by building a pipeline.

ts
import { Effect } from "effect"
import { Random } from "./service"
 
const program = Effect.gen(function* (_) {
  const random = yield* _(Random)
  const randomNumber = yield* _(random.next)
  console.log(`random number: ${randomNumber}`)
})

ts
import { Effect } from "effect"
import { Random } from "./service"
 
const program = Effect.gen(function* (_) {
  const random = yield* _(Random)
  const randomNumber = yield* _(random.next)
  console.log(`random number: ${randomNumber}`)
})

It's worth noting that the type of the program variable includes Random in the R type parameter:

ts
Effect<void, never, Random>

ts
Effect<void, never, Random>

This indicates that our program requires the Random service to be provided in order to execute successfully.

If we attempt to execute the effect without providing the necessary service we will encounter a type-checking error:

ts
Effect.runSync(program)
Argument of type 'Effect<void, never, Random>' is not assignable to parameter of type 'Effect<void, never, never>'.
  Type 'Random' is not assignable to type 'never'.2345Argument of type 'Effect<void, never, Random>' is not assignable to parameter of type 'Effect<void, never, never>'.
  Type 'Random' is not assignable to type 'never'.

ts
Effect.runSync(program)
Argument of type 'Effect<void, never, Random>' is not assignable to parameter of type 'Effect<void, never, never>'.
  Type 'Random' is not assignable to type 'never'.2345Argument of type 'Effect<void, never, Random>' is not assignable to parameter of type 'Effect<void, never, never>'.
  Type 'Random' is not assignable to type 'never'.

To resolve this error and successfully execute the program, we need to provide an actual implementation of the Random service.

In the next section, we will explore how to implement and provide the Random service to our program, enabling us to run it successfully.

#Providing a Service implementation

In order to provide an actual implementation of the Random service, we can utilize the Effect.provideService function.

ts
const runnable = Effect.provideService(program, Random, {
  next: Effect.sync(() => Math.random())
})
 
Effect.runPromise(runnable)
/*
Output:
random number: 0.8241872233134417
*/

ts
const runnable = Effect.provideService(program, Random, {
  next: Effect.sync(() => Math.random())
})
 
Effect.runPromise(runnable)
/*
Output:
random number: 0.8241872233134417
*/

In the code snippet above, we call the program that we defined earlier and provide it with an implementation of the Random service. We use the Effect.provideService(effect, tag, implementation) function to associate the Random tag with its implementation, an object with a next operation that generates a random number.

Notice that the R type parameter of the runnable effect is now never. This indicates that the effect no longer requires any context to be provided. With the implementation of the Random service in place, we are able to run the program without any further dependencies.

By calling Effect.runPromise(runnable), the program is executed, and the resulting output can be observed on the console.

#Using Multiple Services

When we require the usage of more than one service, the process remains similar to what we've learned in defining a service, repeated for each service needed. Let's examine an example where we need two services, namely Random and Logger:

ts
import { Effect, Context } from "effect"
 
// Create a 'Tag' for the 'Random' service
class Random extends Context.Tag("Random")<
  Random,
  {
    readonly next: Effect.Effect<number>
  }
>() {}
 
// Create a 'Tag' for the 'Logger' service
class Logger extends Context.Tag("Logger")<
  Logger,
  {
    readonly log: (message: string) => Effect.Effect<void>
  }
>() {}
 
const program = Effect.gen(function* (_) {
  // Acquire instances of the 'Random' and 'Logger' services
  const random = yield* _(Random)
  const logger = yield* _(Logger)
 
  // Generate a random number using the 'Random' service
  const randomNumber = yield* _(random.next)
 
  // Log the random number using the 'Logger' service
  return yield* _(logger.log(String(randomNumber)))
})

ts
import { Effect, Context } from "effect"
 
// Create a 'Tag' for the 'Random' service
class Random extends Context.Tag("Random")<
  Random,
  {
    readonly next: Effect.Effect<number>
  }
>() {}
 
// Create a 'Tag' for the 'Logger' service
class Logger extends Context.Tag("Logger")<
  Logger,
  {
    readonly log: (message: string) => Effect.Effect<void>
  }
>() {}
 
const program = Effect.gen(function* (_) {
  // Acquire instances of the 'Random' and 'Logger' services
  const random = yield* _(Random)
  const logger = yield* _(Logger)
 
  // Generate a random number using the 'Random' service
  const randomNumber = yield* _(random.next)
 
  // Log the random number using the 'Logger' service
  return yield* _(logger.log(String(randomNumber)))
})

The program effect now has an R type parameter of Random | Logger, indicating that it requires both the Random and Logger services to be provided.

ts
Effect<void, never, Random | Logger>

ts
Effect<void, never, Random | Logger>

To execute the program, we need to provide implementations for both services:

ts
import { Console } from "effect"
 
// Provide service implementations for 'Random' and 'Logger'
const runnable1 = program.pipe(
  Effect.provideService(Random, {
    next: Effect.sync(() => Math.random())
  }),
  Effect.provideService(Logger, {
    log: Console.log
  })
)

ts
import { Console } from "effect"
 
// Provide service implementations for 'Random' and 'Logger'
const runnable1 = program.pipe(
  Effect.provideService(Random, {
    next: Effect.sync(() => Math.random())
  }),
  Effect.provideService(Logger, {
    log: Console.log
  })
)

Alternatively, instead of calling provideService multiple times, we can combine the service implementations into a single Context and then provide the entire context using the Effect.provide function:

ts
import { Console } from "effect"
 
// Combine service implementations into a single 'Context'
const context = Context.empty().pipe(
  Context.add(Random, { next: Effect.sync(() => Math.random()) }),
  Context.add(Logger, { log: Console.log })
)
 
// Provide the entire context to the 'program'
const runnable2 = Effect.provide(program, context)

ts
import { Console } from "effect"
 
// Combine service implementations into a single 'Context'
const context = Context.empty().pipe(
  Context.add(Random, { next: Effect.sync(() => Math.random()) }),
  Context.add(Logger, { log: Console.log })
)
 
// Provide the entire context to the 'program'
const runnable2 = Effect.provide(program, context)

By providing the necessary implementations for each service, we ensure that the runnable effect can access and utilize both services when it is executed.

#Optional Services

There are situations where we may want to access a service implementation only if it is available. In such cases, we can use the Effect.serviceOption(tag) function to handle this scenario.

The serviceOption function returns an implementation that can is available only if it is actually provided before executing this effect. To represent this optionality it returns an Option of the implementation:

ts
Effect<Option<Random>>

ts
Effect<Option<Random>>

Let's take a look at an example that demonstrates the usage of optional services:

ts
import { Effect, Option } from "effect"
import { Random } from "./service"
 
const program = Effect.gen(function* (_) {
  const maybeRandom = yield* _(Effect.serviceOption(Random))
  const randomNumber = Option.isNone(maybeRandom)
    ? // the service is not available, return a default value
      -1
    : // the service is available
      yield* _(maybeRandom.value.next)
  console.log(randomNumber)
})

ts
import { Effect, Option } from "effect"
import { Random } from "./service"
 
const program = Effect.gen(function* (_) {
  const maybeRandom = yield* _(Effect.serviceOption(Random))
  const randomNumber = Option.isNone(maybeRandom)
    ? // the service is not available, return a default value
      -1
    : // the service is available
      yield* _(maybeRandom.value.next)
  console.log(randomNumber)
})

In the code above, we can observe that the R type parameter of the program effect is never, even though we are working with a service. This allows us to access something from the context only if it is actually provided before executing this effect.

When we run the program effect without providing the Random service:

ts
Effect.runPromise(program).then(console.log)
// Output: -1

ts
Effect.runPromise(program).then(console.log)
// Output: -1

We see that the log message contains -1, which is the default value we provided when the service was not available.

However, if we provide the Random service implementation:

ts
Effect.runPromise(
  Effect.provideService(program, Random, {
    next: Effect.sync(() => Math.random())
  })
).then(console.log)
// Output: 0.9957979486841035

ts
Effect.runPromise(
  Effect.provideService(program, Random, {
    next: Effect.sync(() => Math.random())
  })
).then(console.log)
// Output: 0.9957979486841035

We can observe that the log message now contains a random number generated by the next operation of the Random service.

By using the Effect.serviceOption function, we can gracefully handle scenarios where a service may or may not be available, providing flexibility in our programs.

In the upcoming section, we will delve into the topic of Layers. Layers are powerful constructs for creating services and composing them together, enabling us to build complex dependency graphs that can be seamlessly provided to Effects.