RxGo
Reactive Extensions for the Go Language
ReactiveX
ReactiveX, or Rx for short, is an API for programming with Observable streams. This is the official ReactiveX API for the Go language.
ReactiveX is a new, alternative way of asynchronous programming to callbacks, promises, and deferred. It is about processing streams of events or items, with events being any occurrences or changes within the system. A stream of events is called an Observable.
An operator is a function that defines an Observable, how and when it should emit data. The list of operators covered is available here.
RxGo
The RxGo implementation is based on the concept of pipelines. A pipeline is a series of stages connected by channels, where each stage is a group of goroutines running the same function.
Let's see a concrete example with each box being an operator:
- We create a static Observable based on a fixed list of items using the
Just
operator. - We define a transformation function (convert a circle into a square) using the
Map
operator. - We filter each yellow square using the
Filter
operator.
In this example, the final items are sent in a channel, available to a consumer. There are many ways to consume or to produce data using RxGo. Publishing the results in a channel is only one of them.
Each operator is a transformation stage. By default, everything is sequential. Yet, we can leverage modern CPU architectures by defining multiple instances of the same operator. Each operator instance being a goroutine connected to a common channel.
The philosophy of RxGo is to implement the ReactiveX concepts and leverage the main Go primitives (channels, goroutines, etc.) so that the integration between the two worlds is as smooth as possible.
Installation of RxGo v2
go get -u github.com/reactivex/rxgo/v2
Getting Started
Hello World
Let's create our first Observable and consume an item:
observable := rxgo.Just("Hello, World!")()
ch := observable.Observe()
item := <-ch
fmt.Println(item.V)
The Just
operator creates an Observable from a static list of items. Of(value)
creates an item from a given value. If we want to create an item from an error, we have to use Error(err)
. This is a difference with the v1 that was accepting a value or an error directly without having to wrap it. What's the rationale for this change? It is to prepare RxGo for the generics feature coming (hopefully) in Go 2.
By the way, the Just
operator uses currying as syntactic sugar. This way, it accepts multiple items in the first parameter list and multiple options in the second parameter list. We'll see below how to specify options.
Once the Observable is created, we can observe it using Observe()
. By default, an Observable is lazy in the sense that it emits items only once a subscription is made. Observe()
returns a <-chan rxgo.Item
.
We consumed an item from this channel and printed its value of the item using item.V
.
An item is a wrapper on top of a value or an error. We may want to check the type first like this:
item := <-ch
if item.Error() {
return item.E
}
fmt.Println(item.V)
item.Error()
returns a boolean indicating whether an item contains an error. Then, we use either item.E
to get the error or item.V
to get the value.
By default, an Observable is stopped once an error is produced. However, there are special operators to deal with errors (e.g., OnError
, Retry
, etc.)
It is also possible to consume items using callbacks:
observable.ForEach(func(v interface{}) {
fmt.Printf("received: %v\n", v)
}, func(err error) {
fmt.Printf("error: %e\n", err)
}, func() {
fmt.Println("observable is closed")
})
In this example, we passed three functions:
- A
NextFunc
triggered when a value item is emitted. - An
ErrFunc
triggered when an error item is emitted. - A
CompletedFunc
triggered once the Observable is completed.
ForEach
is non-blocking. Yet, it returns a notification channel that will be closed once the Observable completes. Hence, to make the previous code blocking, we simply need to use <-
:
<-observable.ForEach(...)
Real-World Example
Let's say we want to implement a stream that consumes the following Customer
structure:
type Customer struct {
ID int
Name, LastName string
Age int
TaxNumber string
}
We create a producer that will emit Customer
s to a given chan rxgo.Item
and create an Observable from it:
// Create the input channel
ch := make(chan rxgo.Item)
// Data producer
go producer(ch)
// Create an Observable
observable := rxgo.FromChannel(ch)
Then, we need to perform the two following operations:
- Filter the customers whose age is below 18.
- Enrich each customer with a tax number. Retrieving a tax number is done, for example, by an IO-bound function doing an external REST call.
As the enriching step is IO-bound, it might be interesting to parallelize it within a given pool of goroutines.
Yet, let's imagine that all the Customer
items need to be produced sequentially based on its ID
.
observable.
Filter(func(item interface{}) bool {
// Filter operation
customer := item.(Customer)
return customer.Age > 18
}).
Map(func(_ context.Context, item interface{}) (interface{}, error) {
// Enrich operation
customer := item.(Customer)
taxNumber, err := getTaxNumber(customer)
if err != nil {
return nil, err
}
customer.TaxNumber = taxNumber
return customer, nil
},
// Create multiple instances of the map operator
rxgo.WithPool(pool),
// Serialize the items emitted by their Customer.ID
rxgo.Serialize(func(item interface{}) int {
customer := item.(Customer)
return customer.ID
}), rxgo.WithBufferedChannel(1))
In the end, we consume the items using ForEach()
or Observe()
for example. Observe()
returns a <-chan Item
:
for customer := range observable.Observe() {
if customer.Error() {
return err
}
fmt.Println(customer)
}
Observable Types
Hot vs. Cold Observables
In the Rx world, there is a distinction between cold and hot Observables. When the data is produced by the Observable itself, it is a cold Observable. When the data is produced outside the Observable, it is a hot Observable. Usually, when we don't want to create a producer over and over again, we favour a hot Observable.
In RxGo, there is a similar concept.
First, let's create a hot Observable using FromChannel
operator and see the implications:
ch := make(chan rxgo.Item)
go func() {
for i := 0; i < 3; i++ {
ch <- rxgo.Of(i)
}
close(ch)
}()
observable := rxgo.FromChannel(ch)
// First Observer
for item := range observable.Observe() {
fmt.Println(item.V)
}
// Second Observer
for item := range observable.Observe() {
fmt.Println(item.V)
}
The result of this execution is:
0
1
2
It means the first Observer already consumed all items. And nothing left for others.
Though this behavior can be altered with Connectable Observables.
The main point here is the goroutine produced those items.
On the other hand, let's create a cold Observable using Defer
operator:
observable := rxgo.Defer([]rxgo.Producer{func(_ context.Context, ch chan<- rxgo.Item) {
for i := 0; i < 3; i++ {
ch <- rxgo.Of(i)
}
}})
// First Observer
for item := range observable.Observe() {
fmt.Println(item.V)
}
// Second Observer
for item := range observable.Observe() {
fmt.Println(item.V)
}
Now, the result is:
0
1
2
0
1
2
In the case of a cold observable, the stream was created independently for every Observer.
Again, hot vs cold Observables are not about how you consume items, it's about where data is produced.
Good example for hot Observable are price ticks from a trading exchange.
And if you teach an Observable to fetch products from a database, then yield them one by one, you will create the cold Observable.
Backpressure
There is another operator called FromEventSource
that creates an Observable from a channel. The difference between FromChannel
operator is that as soon as the Observable is created, it starts to emit items regardless if there is an Observer or not. Hence, the items emitted by an Observable without Observer(s) are lost (while they are buffered with FromChannel
operator).
A use case with FromEventSource
operator is, for example, telemetry. We may not be interested in all the data produced from the very beginning of a streamβonly the data since we started to observe it.
Once we start observing an Observable created with FromEventSource
, we can configure the backpressure strategy. By default, it is blocking (there is a guaranteed delivery for the items emitted after we observe it). We can override this strategy this way:
observable := rxgo.FromEventSource(input, rxgo.WithBackPressureStrategy(rxgo.Drop))
The Drop
strategy means that if the pipeline after FromEventSource
was not ready to consume an item, this item is dropped.
By default, a channel connecting operators is non-buffered. We can override this behaviour like this:
observable.Map(transform, rxgo.WithBufferedChannel(42))
Each operator has an opts ...Option
parameter allowing to pass such options.
Lazy vs. Eager Observation
The default observation strategy is lazy. It means an operator processes the items emitted by an Observable once we start observing it. We can change this behaviour this way:
observable := rxgo.FromChannel(ch).Map(transform, rxgo.WithObservationStrategy(rxgo.Eager))
In this case, the Map
operator is triggered whenever an item is produced, even without any Observer.
Sequential vs. Parallel Operators
By default, each operator is sequential. One operator being one goroutine instance. We can override it using the following option:
observable.Map(transform, rxgo.WithPool(32))
In this example, we create a pool of 32 goroutines that consume items concurrently from the same channel. If the operation is CPU-bound, we can use the WithCPUPool()
option that creates a pool based on the number of logical CPUs.
Connectable Observable
A Connectable Observable resembles an ordinary Observable, except that it does not begin emitting items when it is subscribed to, but only when its connect() method is called. In this way, you can wait for all intended Subscribers to subscribe to the Observable before the Observable begins emitting items.
Let's create a Connectable Observable using rxgo.WithPublishStrategy
:
ch := make(chan rxgo.Item)
go func() {
ch <- rxgo.Of(1)
ch <- rxgo.Of(2)
ch <- rxgo.Of(3)
close(ch)
}()
observable := rxgo.FromChannel(ch, rxgo.WithPublishStrategy())
Then, we create two Observers:
observable.Map(func(_ context.Context, i interface{}) (interface{}, error) {
return i.(int) + 1, nil
}).DoOnNext(func(i interface{}) {
fmt.Printf("First observer: %d\n", i)
})
observable.Map(func(_ context.Context, i interface{}) (interface{}, error) {
return i.(int) * 2, nil
}).DoOnNext(func(i interface{}) {
fmt.Printf("Second observer: %d\n", i)
})
If observable
was not a Connectable Observable, as DoOnNext
creates an Observer, the source Observable would have begun emitting items. Yet, in the case of a Connectable Observable, we have to call Connect()
:
observable.Connect()
Once Connect()
is called, the Connectable Observable begins to emit items.
There is another important change with a regular Observable. A Connectable Observable publishes its items. It means all the Observers receive a copy of the items.
Here is an example with a regular Observable:
ch := make(chan rxgo.Item)
go func() {
ch <- rxgo.Of(1)
ch <- rxgo.Of(2)
ch <- rxgo.Of(3)
close(ch)
}()
// Create a regular Observable
observable := rxgo.FromChannel(ch)
// Create the first Observer
observable.DoOnNext(func(i interface{}) {
fmt.Printf("First observer: %d\n", i)
})
// Create the second Observer
observable.DoOnNext(func(i interface{}) {
fmt.Printf("Second observer: %d\n", i)
})
First observer: 1
First observer: 2
First observer: 3
Now, with a Connectable Observable:
ch := make(chan rxgo.Item)
go func() {
ch <- rxgo.Of(1)
ch <- rxgo.Of(2)
ch <- rxgo.Of(3)
close(ch)
}()
// Create a Connectable Observable
observable := rxgo.FromChannel(ch, rxgo.WithPublishStrategy())
// Create the first Observer
observable.DoOnNext(func(i interface{}) {
fmt.Printf("First observer: %d\n", i)
})
// Create the second Observer
observable.DoOnNext(func(i interface{}) {
fmt.Printf("Second observer: %d\n", i)
})
disposed, cancel := observable.Connect()
go func() {
// Do something
time.Sleep(time.Second)
// Then cancel the subscription
cancel()
}()
// Wait for the subscription to be disposed
<-disposed
Second observer: 1
First observer: 1
First observer: 2
First observer: 3
Second observer: 2
Second observer: 3
Observable, Single, and Optional Single
An Iterable is an object that can be observed using Observe(opts ...Option) <-chan Item
.
An Iterable can be either:
- An Observable: emit 0 or multiple items
- A Single: emit 1 item
- An Optional Single: emit 0 or 1 item
Documentation
Package documentation: https://pkg.go.dev/github.com/reactivex/rxgo/v2
Assert API
How to use the assert API to write unit tests while using RxGo.
Operator Options
Creating Observables
- Create β create an Observable from scratch by calling Observer methods programmatically
- Defer β do not create the Observable until the Observer subscribes, and create a fresh Observable for each Observer
- Empty/Never/Thrown β create Observables that have very precise and limited behaviour
- FromChannel β create an Observable based on a lazy channel
- FromEventSource β create an Observable based on an eager channel
- Interval β create an Observable that emits a sequence of integers spaced by a particular time interval
- Just β convert a set of objects into an Observable that emits that or those objects
- JustItem β convert one object into a Single that emits this object
- Range β create an Observable that emits a range of sequential integers
- Repeat β create an Observable that emits a particular item or sequence of items repeatedly
- Start β create an Observable that emits the return value of a function
- Timer β create an Observable that completes after a specified delay
Transforming Observables
- Buffer β periodically gather items from an Observable into bundles and emit these bundles rather than emitting the items one at a time
- FlatMap β transform the items emitted by an Observable into Observables, then flatten the emissions from those into a single Observable
- GroupBy β divide an Observable into a set of Observables that each emit a different group of items from the original Observable, organized by key
- GroupByDynamic β divide an Observable into a dynamic set of Observables that each emit GroupedObservables from the original Observable, organized by key
- Map β transform the items emitted by an Observable by applying a function to each item
- Marshal β transform the items emitted by an Observable by applying a marshalling function to each item
- Scan β apply a function to each item emitted by an Observable, sequentially, and emit each successive value
- Unmarshal β transform the items emitted by an Observable by applying an unmarshalling function to each item
- Window β apply a function to each item emitted by an Observable, sequentially, and emit each successive value
Filtering Observables
- Debounce β only emit an item from an Observable if a particular timespan has passed without it emitting another item
- Distinct/DistinctUntilChanged β suppress duplicate items emitted by an Observable
- ElementAt β emit only item n emitted by an Observable
- Filter β emit only those items from an Observable that pass a predicate test
- Find β emit the first item passing a predicate, then complete
- First/FirstOrDefault β emit only the first item or the first item that meets a condition from an Observable
- IgnoreElements β do not emit any items from an Observable but mirror its termination notification
- Last/LastOrDefault β emit only the last item emitted by an Observable
- Sample β emit the most recent item emitted by an Observable within periodic time intervals
- Skip β suppress the first n items emitted by an Observable
- SkipLast β suppress the last n items emitted by an Observable
- Take β emit only the first n items emitted by an Observable
- TakeLast β emit only the last n items emitted by an Observable
Combining Observables
- CombineLatest β when an item is emitted by either of two Observables, combine the latest item emitted by each Observable via a specified function and emit items based on the results of this function
- Join β combine items emitted by two Observables whenever an item from one Observable is emitted during a time window defined according to an item emitted by the other Observable
- Merge β combine multiple Observables into one by merging their emissions
- StartWithIterable β emit a specified sequence of items before beginning to emit the items from the source Iterable
- ZipFromIterable β combine the emissions of multiple Observables together via a specified function and emit single items for each combination based on the results of this function
Error Handling Operators
- Catch β recover from an onError notification by continuing the sequence without error
- Retry/BackOffRetry β if a source Observable sends an onError notification, resubscribe to it in the hopes that it will complete without error
Observable Utility Operators
- Do - register an action to take upon a variety of Observable lifecycle events
- Run β create an Observer without consuming the emitted items
- Send β send the Observable items in a specific channel
- Serialize β force an Observable to make serialized calls and to be well-behaved
- TimeInterval β convert an Observable that emits items into one that emits indications of the amount of time elapsed between those emissions
- Timestamp β attach a timestamp to each item emitted by an Observable
Conditional and Boolean Operators
- All β determine whether all items emitted by an Observable meet some criteria
- Amb β given two or more source Observables, emit all of the items from only the first of these Observables to emit an item
- Contains β determine whether an Observable emits a particular item or not
- DefaultIfEmpty β emit items from the source Observable, or a default item if the source Observable emits nothing
- SequenceEqual β determine whether two Observables emit the same sequence of items
- SkipWhile β discard items emitted by an Observable until a specified condition becomes false
- TakeUntil β discard items emitted by an Observable after a second Observable emits an item or terminates
- TakeWhile β discard items emitted by an Observable after a specified condition becomes false
Mathematical and Aggregate Operators
- Average β calculates the average of numbers emitted by an Observable and emits this average
- Concat β emit the emissions from two or more Observables without interleaving them
- Count β count the number of items emitted by the source Observable and emit only this value
- Max β determine, and emit, the maximum-valued item emitted by an Observable
- Min β determine, and emit, the minimum-valued item emitted by an Observable
- Reduce β apply a function to each item emitted by an Observable, sequentially, and emit the final value
- Sum β calculate the sum of numbers emitted by an Observable and emit this sum
Operators to Convert Observables
- Error β return the first error thrown by an observable
- Errors β return all the errors thrown by an observable
- ToMap/ToMapWithValueSelector/ToSlice β convert an Observable into another object or data structure
Contributing
All contributions are very welcome! Be sure you check out the contributing guidelines first. Newcomers can take a look at ongoing issues and check for the help needed
label.
Also, if you publish a post about RxGo, please let us know. We would be glad to include it in the External Resources section.
Thanks to all the people who already contributed to RxGo!
External Resources
- Announcing RxGo v2
- Why YoMo (an open-source streaming serverless framework for building low-latency edge computing applications) uses RxGo
- Go Cookbook from Packt - Reactive programming with RxGo (based on v1)
- Writing PizzaScript Lexer with RxGo
- Writing PizzaScript Parser with RxGo
- Reactive programming in Go
- ProgramaciΓ³n reactiva en Go (Spanish)
- Go ζ―ζ₯δΈεΊδΉ RxGo (Chinese)
- RxGoε ₯ι¨ Β· θ―ι (Chinese)
Special Thanks
A big thanks to JetBrains for supporting the project.