Core application - Temporal Go SDK feature guide
The Foundations section of the Temporal Developer's guide covers the minimum set of concepts and implementation details needed to build and run a Temporal Application—that is, all the relevant steps to start a Workflow Execution that executes an Activity.
In this section you can find the following:
- Run a development Temporal Service
- Develop a Workflow
- Develop an Activity
- Start an Activity Execution
- Run a dev Worker
- Run a Temporal Cloud Worker
How to install the Temporal CLI and run a development server
This section describes how to install the Temporal CLI and run a development Temporal Service. The local development Temporal Service comes packaged with the Temporal Web UI.
For information on deploying and running a self-hosted production Temporal Service, see the Self-hosted guide, or sign up for Temporal Cloud and let us run your production Temporal Service for you.
The Temporal CLI is a tool for interacting with a Temporal Service from the command line and it includes a distribution of the Temporal Server and Web UI. This local development Temporal Service runs as a single process with zero runtime dependencies and it supports persistence to disk and in-memory mode through SQLite.
Install the Temporal CLI
Choose one of the following install methods to install the Temporal CLI.
- macOS
- Linux
- Windows
-
Install the Temporal CLI with Homebrew.
brew install temporal
-
Install the Temporal CLI with cURL.
curl -sSf https://temporal.download/cli.sh | sh
-
Install the Temporal CLI from CDN.
- Select the platform and architecture needed.
- Extract the downloaded archive.
- Add the
temporal
binary to your PATH.
-
Install the Temporal CLI with cURL.
curl -sSf https://temporal.download/cli.sh | sh
-
Install the Temporal CLI from CDN.
- Select the platform and architecture needed.
- Extract the downloaded archive.
- Add the
temporal
binary to your PATH.
- Install the Temporal CLI from CDN.
- Select the platform and architecture needed and download the binary.
- Extract the downloaded archive.
- Add the
temporal.exe
binary to your PATH.
Start the Temporal Development Server
Start the Temporal Development Server by using the server start-dev
command.
temporal server start-dev
This command automatically starts the Web UI, creates the default Namespace, and uses an in-memory database.
The Temporal Server should be available on localhost:7233
and the Temporal Web UI should be accessible at http://localhost:8233
.
The server's startup configuration can be customized using command line options. For a full list of options, run:
temporal server start-dev --help
How to install a Temporal SDK
A Temporal SDK provides a framework for Temporal Application development.
An SDK provides you with the following:
- A Temporal Client to communicate with a Temporal Service.
- APIs to develop Workflows.
- APIs to create and manage Worker Processes.
- APIs to author Activities.
Add the Temporal Go SDK to your project:
go get go.temporal.io/sdk
Or clone the Go SDK repo to your preferred location:
git clone git@github.com:temporalio/sdk-go.git
How to find the Go SDK API reference
The Temporal Go SDK API reference is published on pkg.go.dev.
- Short link:
t.mp/go-api
Where are SDK-specific code examples?
You can find a complete list of executable code samples in Temporal's GitHub repository.
Additionally, several of the Tutorials are backed by a fully executable template application.
- Go Samples repo
- Background Check application: Provides a non-trivial Temporal Application implementation in conjunction with application documentation.
- Hello world application template in Go: Provides a quick-start development app for users. This sample works in conjunction with the "Hello World!" from scratch tutorial in Go.
- Money transfer application template in Go: Provides a quick-start development app for users. It demonstrates a basic "money transfer" Workflow Definition and works in conjunction with the Run your first app tutorial in Go.
- Subscription-style Workflow Definition in Go: Demonstrates some of the patterns that could be implemented for a subscription-style business process.
- eCommerce application example in Go: Showcases a per-user shopping cart–style Workflow Definition that includes an API for adding and removing items from the cart as well as a web UI. This application sample works in conjunction with the eCommerce in Go tutorial.
How to develop a basic Workflow
Workflows are the fundamental unit of a Temporal Application, and it all starts with the development of a Workflow Definition.
In the Temporal Go SDK programming model, a Workflow Definition is an exportable function. Below is an example of a basic Workflow Definition.
View the source code
in the context of the rest of the application code.
package yourapp
import (
"time"
"go.temporal.io/sdk/workflow"
)
// ...
// YourSimpleWorkflowDefintiion is the most basic Workflow Defintion.
func YourSimpleWorkflowDefinition(ctx workflow.Context) error {
// ...
return nil
}
How to define Workflow parameters
Temporal Workflows may have any number of custom parameters. However, we strongly recommend that objects are used as parameters, so that the object's individual fields may be altered without breaking the signature of the Workflow. All Workflow Definition parameters must be serializable.
The first parameter of a Go-based Workflow Definition must be of the workflow.Context
type.
It is used by the Temporal Go SDK to pass around Workflow Execution context, and virtually all the Go SDK APIs that are callable from the Workflow require it.
It is acquired from the go.temporal.io/sdk/workflow
package.
The workflow.Context
entity operates similarly to the standard context.Context
entity provided by Go.
The only difference between workflow.Context
and context.Context
is that the Done()
function, provided by workflow.Context
, returns workflow.Channel
instead of the standard Go chan
.
Additional parameters can be passed to the Workflow when it is invoked.
A Workflow Definition may support multiple custom parameters, or none.
These parameters can be regular type variables or safe pointers.
However, the best practice is to pass a single parameter that is of a struct
type, so there can be some backward compatibility if new parameters are added.
All Workflow Definition parameters must be serializable and can't be channels, functions, variadic, or unsafe pointers.
View the source code
in the context of the rest of the application code.
package yourapp
import (
"time"
"go.temporal.io/sdk/workflow"
)
// YourWorkflowParam is the object passed to the Workflow.
type YourWorkflowParam struct {
WorkflowParamX string
WorkflowParamY int
}
// ...
// YourWorkflowDefinition is your custom Workflow Definition.
func YourWorkflowDefinition(ctx workflow.Context, param YourWorkflowParam) (*YourWorkflowResultObject, error) {
// ...
}
How to define Workflow return parameters
Workflow return values must also be serializable. Returning results, returning errors, or throwing exceptions is fairly idiomatic in each language that is supported. However, Temporal APIs that must be used to get the result of a Workflow Execution will only ever receive one of either the result or the error.
A Go-based Workflow Definition can return either just an error
or a customValue, error
combination.
Again, the best practice here is to use a struct
type to hold all custom values.
A Workflow Definition written in Go can return both a custom value and an error.
However, it's not possible to receive both a custom value and an error in the calling process, as is normal in Go.
The caller will receive either one or the other.
Returning a non-nil error
from a Workflow indicates that an error was encountered during its execution and the Workflow Execution should be terminated, and any custom return values will be ignored by the system.
View the source code
in the context of the rest of the application code.
package yourapp
import (
"time"
"go.temporal.io/sdk/workflow"
)
// ...
// YourWorkflowResultObject is the object returned by the Workflow.
type YourWorkflowResultObject struct {
WFResultFieldX string
WFResultFieldY int
}
// ...
// YourWorkflowDefinition is your custom Workflow Definition.
func YourWorkflowDefinition(ctx workflow.Context, param YourWorkflowParam) (*YourWorkflowResultObject, error) {
// ...
if err != nil {
return nil, err
}
// Make the results of the Workflow Execution available.
workflowResult := &YourWorkflowResultObject{
WFResultFieldX: activityResult.ResultFieldX,
WFResultFieldY: activityResult.ResultFieldY,
}
return workflowResult, nil
}
How to customize Workflow Type in Go
In Go, by default, the Workflow Type name is the same as the function name.
To customize the Workflow Type, set the Name
parameter with RegisterOptions
when registering your Workflow with a Worker.
View the source code
in the context of the rest of the application code.
package main
import (
"log"
"go.temporal.io/sdk/activity"
"go.temporal.io/sdk/client"
"go.temporal.io/sdk/worker"
"go.temporal.io/sdk/workflow"
"documentation-samples-go/yourapp"
)
// ...
func main() {
// ...
yourWorker := worker.New(temporalClient, "your-custom-task-queue-name", worker.Options{})
// ...
// Use RegisterOptions to set the name of the Workflow Type for example.
registerWFOptions := workflow.RegisterOptions{
Name: "JustAnotherWorkflow",
}
yourWorker.RegisterWorkflowWithOptions(yourapp.YourSimpleWorkflowDefinition, registerWFOptions)
// ...
}
How to develop Workflow logic
Workflow logic is constrained by deterministic execution requirements. Therefore, each language is limited to the use of certain idiomatic techniques. However, each Temporal SDK provides a set of APIs that can be used inside your Workflow to interact with external (to the Workflow) application code.
In Go, Workflow Definition code cannot directly do the following:
- Iterate over maps using
range
, because withrange
the order of the map's iteration is randomized. Instead you can collect the keys of the map, sort them, and then iterate over the sorted keys to access the map. This technique provides deterministic results. You can also use a Side Effect or an Activity to process the map instead. - Call an external API, conduct a file I/O operation, talk to another service, etc. (Use an Activity for these.)
The Temporal Go SDK has APIs to handle equivalent Go constructs:
workflow.Now()
This is a replacement fortime.Now()
.workflow.Sleep()
This is a replacement fortime.Sleep()
.workflow.GetLogger()
This ensures that the provided logger does not duplicate logs during a replay.workflow.Go()
This is a replacement for thego
statement.workflow.Channel
This is a replacement for the nativechan
type. Temporal provides support for both buffered and unbuffered channels.workflow.Selector
This is a replacement for theselect
statement. Learn more on the Go SDK Selectors page.workflow.Context
This is a replacement forcontext.Context
. See Tracing for more information about context propagation.
How to develop an Activity Definition in Go
In the Temporal Go SDK programming model, an Activity Definition is an exportable function or a struct
method.
Below is an example of both a basic Activity Definition and of an Activity defined as a Struct method.
An Activity struct can have more than one method, with each method acting as a separate Activity Type.
Activities written as struct methods can use shared struct variables, such as:
- an application level DB pool
- client connection to another service
- reusable utilities
- any other expensive resources that you only want to initialize once per process
Because this is such a common need, the rest of this guide shows Activities written as struct
methods.
View the source code
in the context of the rest of the application code.
package yourapp
import (
"context"
"go.temporal.io/sdk/activity"
)
// ...
// YourSimpleActivityDefinition is a basic Activity Definiton.
func YourSimpleActivityDefinition(ctx context.Context) error {
return nil
}
// YourActivityObject is the struct that maintains shared state across Activities.
// If the Worker crashes this Activity object loses its state.
type YourActivityObject struct {
Message *string
Number *int
}
// YourActivityDefinition is your custom Activity Definition.
// An Activity Definiton is an exportable function.
func (a *YourActivityObject) YourActivityDefinition(ctx context.Context, param YourActivityParam) (*YourActivityResultObject, error) {
// ...
}
How to develop Activity Parameters
There is no explicit limit to the total number of parameters that an Activity Definition may support. However, there is a limit to the total size of the data that ends up encoded into a gRPC message Payload.
A single argument is limited to a maximum size of 2 MB. And the total size of a gRPC message, which includes all the arguments, is limited to a maximum of 4 MB.
Also, keep in mind that all Payload data is recorded in the Workflow Execution Event History and large Event Histories can affect Worker performance. This is because the entire Event History could be transferred to a Worker Process with a Workflow Task.
Some SDKs require that you pass context objects, others do not. When it comes to your application data—that is, data that is serialized and encoded into a Payload—we recommend that you use a single object as an argument that wraps the application data passed to Activities. This is so that you can change what data is passed to the Activity without breaking a function or method signature.
The first parameter of an Activity Definition is context.Context
.
This parameter is optional for an Activity Definition, though it is recommended, especially if the Activity is expected to use other Go SDK APIs.
An Activity Definition can support as many other custom parameters as needed. However, all parameters must be serializable (parameters can't be channels, functions, variadic, or unsafe pointers), and it is recommended to pass a single struct that can be updated later.
View the source code
in the context of the rest of the application code.
// YourActivityParam is the struct passed to your Activity.
// Use a struct so that your function signature remains compatible if fields change.
type YourActivityParam struct {
ActivityParamX string
ActivityParamY int
}
// ...
func (a *YourActivityObject) YourActivityDefinition(ctx context.Context, param YourActivityParam) (*YourActivityResultObject, error) {
// ...
}
How to define Activity return values
All data returned from an Activity must be serializable.
There is no explicit limit to the amount of data that can be returned by an Activity, but keep in mind that all return values are recorded in a Workflow Execution Event History.
A Go-based Activity Definition can return either just an error
or a customValue, error
combination (same as a Workflow Definition).
You may wish to use a struct
type to hold all custom values, just keep in mind they must all be serializable.
View the source code
in the context of the rest of the application code.
// YourActivityResultObject is the struct returned from your Activity.
// Use a struct so that you can return multiple values of different types.
// Additionally, your function signature remains compatible if the fields change.
type YourActivityResultObject struct {
ResultFieldX string
ResultFieldY int
}
// ...
func (a *YourActivityObject) YourActivityDefinition(ctx context.Context, param YourActivityParam) (*YourActivityResultObject, error) {
// ...
result := &YourActivityResultObject{
ResultFieldX: "Success",
ResultFieldY: 1,
}
// Return the results back to the Workflow Execution.
// The results persist within the Event History of the Workflow Execution.
return result, nil
}
How to customize Activity Type in Go
To customize the Activity Type, set the Name
parameter with RegisterOptions
when registering your Activity with a Worker.
View the source code
in the context of the rest of the application code.
func main() {
// ...
yourWorker := worker.New(temporalClient, "your-custom-task-queue-name", worker.Options{})
// ...
// Use RegisterOptions to change the name of the Activity Type for example.
registerAOptions := activity.RegisterOptions{
Name: "JustAnotherActivity",
}
yourWorker.RegisterActivityWithOptions(yourapp.YourSimpleActivityDefinition, registerAOptions)
// Run the Worker
err = yourWorker.Run(worker.InterruptCh())
// ...
}
// ...
How to start an Activity Execution
Calls to spawn Activity Executions are written within a Workflow Definition. The call to spawn an Activity Execution generates the ScheduleActivityTask Command. This results in the set of three Activity Task related Events (ActivityTaskScheduled, ActivityTaskStarted, and ActivityTask[Closed])in your Workflow Execution Event History.
A single instance of the Activities implementation is shared across multiple simultaneous Activity invocations. Activity implementation code should be idempotent.
The values passed to Activities through invocation parameters or returned through a result value are recorded in the Execution history. The entire Execution history is transferred from the Temporal Service to Workflow Workers when a Workflow state needs to recover. A large Execution history can thus adversely impact the performance of your Workflow.
Therefore, be mindful of the amount of data you transfer through Activity invocation parameters or Return Values. Otherwise, no additional limitations exist on Activity implementations.
To spawn an Activity Execution, call ExecuteActivity()
inside your Workflow Definition.
The API is available from the go.temporal.io/sdk/workflow
package.
The ExecuteActivity()
API call requires an instance of workflow.Context
, the Activity function name, and any variables to be passed to the Activity Execution.
The Activity function name can be provided as a variable object (no quotations) or as a string.
The benefit of passing the actual function object is that the framework can validate the parameters against the Activity Definition.
The ExecuteActivity
call returns a Future, which can be used to get the result of the Activity Execution.
View the source code
in the context of the rest of the application code.
func YourWorkflowDefinition(ctx workflow.Context, param YourWorkflowParam) (*YourWorkflowResultObject, error) {
// Set the options for the Activity Execution.
// Either StartToClose Timeout OR ScheduleToClose is required.
// Not specifying a Task Queue will default to the parent Workflow Task Queue.
activityOptions := workflow.ActivityOptions{
StartToCloseTimeout: 10 * time.Second,
}
ctx = workflow.WithActivityOptions(ctx, activityOptions)
activityParam := YourActivityParam{
ActivityParamX: param.WorkflowParamX,
ActivityParamY: param.WorkflowParamY,
}
// Use a nil struct pointer to call Activities that are part of a struct.
var a *YourActivityObject
// Execute the Activity and wait for the result.
var activityResult YourActivityResultObject
err := workflow.ExecuteActivity(ctx, a.YourActivityDefinition, activityParam).Get(ctx, &activityResult)
if err != nil {
return nil, err
}
// ...
}
How to set the required Activity Timeouts
Activity Execution semantics rely on several parameters. The only required value that needs to be set is either a Schedule-To-Close Timeout or a Start-To-Close Timeout. These values are set in the Activity Options.
To set an Activity Timeout in Go, create an instance of ActivityOptions
from the go.temporal.io/sdk/workflow
package, set the Activity Timeout field, and then use the WithActivityOptions()
API to apply the options to the instance of workflow.Context
.
Available timeouts are:
StartToCloseTimeout
ScheduleToClose
ScheduleToStartTimeout
activityoptions := workflow.ActivityOptions{
// Set Activity Timeout duration
ScheduleToCloseTimeout: 10 * time.Second,
// StartToCloseTimeout: 10 * time.Second,
// ScheduleToStartTimeout: 10 * time.Second,
}
ctx = workflow.WithActivityOptions(ctx, activityoptions)
var yourActivityResult YourActivityResult
err = workflow.ExecuteActivity(ctx, YourActivityDefinition, yourActivityParam).Get(ctx, &yourActivityResult)
if err != nil {
// ...
}
Go ActivityOptions reference
Create an instance of ActivityOptions
from the go.temporal.io/sdk/workflow
package and use WithActivityOptions()
to apply it to the instance of workflow.Context
.
The instance of workflow.Context
is then passed to the ExecuteActivity()
call.
Field | Required | Type |
---|---|---|
ActivityID | No | string |
TaskQueueName | No | string |
ScheduleToCloseTimeout | Yes (or StartToCloseTimeout ) | time.Duration |
ScheduleToStartTimeout | No | time.Duration |
StartToCloseTimeout | Yes (or ScheduleToCloseTimeout ) | time.Duration |
HeartbeatTimeout | No | time.Duration |
WaitForCancellation | No | bool |
OriginalTaskQueueName | No | string |
RetryPolicy | No | RetryPolicy |
ActivityID
- Type:
string
- Default: None
activityoptions := workflow.ActivityOptions{
ActivityID: "your-activity-id",
}
ctx = workflow.WithActivityOptions(ctx, activityoptions)
var yourActivityResult YourActivityResult
err = workflow.ExecuteActivity(ctx, YourActivityDefinition, yourActivityParam).Get(ctx, &yourActivityResult)
if err != nil {
// ...
}
TaskQueueName
- Type:
string
- Default: Inherits the TaskQueue name from the Workflow.
activityoptions := workflow.ActivityOptions{
TaskQueueName: "your-task-queue-name",
}
ctx = workflow.WithActivityOptions(ctx, activityoptions)
var yourActivityResult YourActivityResult
err = workflow.ExecuteActivity(ctx, YourActivityDefinition, yourActivityParam).Get(ctx, &yourActivityResult)
if err != nil {
// ...
}
ScheduleToCloseTimeout
To set a Schedule-To-Close Timeout, create an instance of ActivityOptions
from the go.temporal.io/sdk/workflow
package, set the ScheduleToCloseTimeout
field, and then use the WithActivityOptions()
API to apply the options to the instance of workflow.Context
.
This or StartToCloseTimeout
must be set.
- Type:
time.Duration
- Default: ∞ (infinity - no limit)
activityoptions := workflow.ActivityOptions{
ScheduleToCloseTimeout: 10 * time.Second,
}
ctx = workflow.WithActivityOptions(ctx, activityoptions)
var yourActivityResult YourActivityResult
err = workflow.ExecuteActivity(ctx, YourActivityDefinition, yourActivityParam).Get(ctx, &yourActivityResult)
if err != nil {
// ...
}
ScheduleToStartTimeout
To set a Schedule-To-Start Timeout, create an instance of ActivityOptions
from the go.temporal.io/sdk/workflow
package, set the ScheduleToStartTimeout
field, and then use the WithActivityOptions()
API to apply the options to the instance of workflow.Context
.
- Type:
time.Duration
- Default: ∞ (infinity - no limit)
activityoptions := workflow.ActivityOptions{
ScheduleToStartTimeout: 10 * time.Second,
}
ctx = workflow.WithActivityOptions(ctx, activityoptions)
var yourActivityResult YourActivityResult
err = workflow.ExecuteActivity(ctx, YourActivityDefinition, yourActivityParam).Get(ctx, &yourActivityResult)
if err != nil {
// ...
}
StartToCloseTimeout
To set a Start-To-Close Timeout, create an instance of ActivityOptions
from the go.temporal.io/sdk/workflow
package, set the StartToCloseTimeout
field, and then use the WithActivityOptions()
API to apply the options to the instance of workflow.Context
.
This or ScheduleToCloseTimeout
must be set.
- Type:
time.Duration
- Default: Same as the
ScheduleToCloseTimeout
activityoptions := workflow.ActivityOptions{
StartToCloseTimeout: 10 * time.Second,
}
ctx = workflow.WithActivityOptions(ctx, activityoptions)
var yourActivityResult YourActivityResult
err = workflow.ExecuteActivity(ctx, YourActivityDefinition, yourActivityParam).Get(ctx, &yourActivityResult)
if err != nil {
// ...
}
HeartbeatTimeout
To set a Heartbeat Timeout, create an instance of ActivityOptions
from the go.temporal.io/sdk/workflow
package, set the RetryPolicy
field, and then use the WithActivityOptions()
API to apply the options to the instance of workflow.Context
.
activityoptions := workflow.ActivityOptions{
HeartbeatTimeout: 10 * time.Second,
}
ctx = workflow.WithActivityOptions(ctx, activityoptions)
var yourActivityResult YourActivityResult
err = workflow.ExecuteActivity(ctx, YourActivityDefinition, yourActivityParam).Get(ctx, &yourActivityResult)
if err != nil {
// ...
}
WaitForCancellation
If true
the Activity Execution will finish executing should there be a Cancellation request.
- Type:
bool
- Default:
false
activityoptions := workflow.ActivityOptions{
WaitForCancellation: false,
}
ctx = workflow.WithActivityOptions(ctx, activityoptions)
var yourActivityResult YourActivityResult
err = workflow.ExecuteActivity(ctx, YourActivityDefinition, yourActivityParam).Get(ctx, &yourActivityResult)
if err != nil {
// ...
}
OriginalTaskQueueName
activityoptions := workflow.ActivityOptions{
OriginalTaskQueueName: "your-original-task-queue-name",
}
ctx = workflow.WithActivityOptions(ctx, activityoptions)
var yourActivityResult YourActivityResult
err = workflow.ExecuteActivity(ctx, YourActivityDefinition, yourActivityParam).Get(ctx, &yourActivityResult)
if err != nil {
// ...
}
RetryPolicy
To set a RetryPolicy, create an instance of ActivityOptions
from the go.temporal.io/sdk/workflow
package, set the RetryPolicy
field, and then use the WithActivityOptions()
API to apply the options to the instance of workflow.Context
.
- Type:
RetryPolicy
- Default:
retrypolicy := &temporal.RetryPolicy{
InitialInterval: time.Second,
BackoffCoefficient: 2.0,
MaximumInterval: time.Second * 100, // 100 * InitialInterval
MaximumAttempts: 0, // Unlimited
NonRetryableErrorTypes: []string, // empty
}
Providing a Retry Policy here is a customization that overwrites individual Field defaults.
retrypolicy := &temporal.RetryPolicy{
InitialInterval: time.Second,
BackoffCoefficient: 2.0,
MaximumInterval: time.Second * 100,
}
activityoptions := workflow.ActivityOptions{
RetryPolicy: retrypolicy,
}
ctx = workflow.WithActivityOptions(ctx, activityoptions)
var yourActivityResult YourActivityResult
err = workflow.ExecuteActivity(ctx, YourActivityDefinition, yourActivityParam).Get(ctx, &yourActivityResult)
if err != nil {
// ...
}
How to get the results of an Activity Execution
The call to spawn an Activity Execution generates the ScheduleActivityTask Command and provides the Workflow with an Awaitable. Workflow Executions can either block progress until the result is available through the Awaitable or continue progressing, making use of the result when it becomes available.
The ExecuteActivity
API call returns an instance of workflow.Future
which has the following two methods:
Get()
: Takes an instance of theworkflow.Context
, that was passed to the Activity Execution, and a pointer as parameters. The variable associated with the pointer is populated with the Activity Execution result. This call blocks until the results are available.IsReady()
: Returnstrue
when the result of the Activity Execution is ready.
Call the Get()
method on the instance of workflow.Future
to get the result of the Activity Execution.
The type of the result parameter must match the type of the return value declared by the Activity function.
func YourWorkflowDefinition(ctx workflow.Context, param YourWorkflowParam) (YourWorkflowResponse, error) {
// ...
future := workflow.ExecuteActivity(ctx, YourActivityDefinition, yourActivityParam)
var yourActivityResult YourActivityResult
if err := future.Get(ctx, &yourActivityResult); err != nil {
// ...
}
// ...
}
Use the IsReady()
method first to make sure the Get()
call doesn't cause the Workflow Execution to wait on the result.
func YourWorkflowDefinition(ctx workflow.Context, param YourWorkflowParam) (YourWorkflowResponse, error) {
// ...
future := workflow.ExecuteActivity(ctx, YourActivityDefinition, yourActivityParam)
// ...
if(future.IsReady()) {
var yourActivityResult YourActivityResult
if err := future.Get(ctx, &yourActivityResult); err != nil {
// ...
}
}
// ...
}
It is idiomatic to invoke multiple Activity Executions from within a Workflow. Therefore, it is also idiomatic to either block on the results of the Activity Executions or continue on to execute additional logic, checking for the Activity Execution results at a later time.
How to develop a Worker in Go
Create an instance of Worker
by calling worker.New()
, available through the go.temporal.io/sdk/worker
package, and pass it the following parameters:
- An instance of the Temporal Go SDK
Client
. - The name of the Task Queue that it will poll.
- An instance of
worker.Options
, which can be empty.
Then, register the Workflow Types and the Activity Types that the Worker will be capable of executing.
Lastly, call either the Start()
or the Run()
method on the instance of the Worker.
Run accepts an interrupt channel as a parameter, so that the Worker can be stopped in the terminal.
Otherwise, the Stop()
method must be called to stop the Worker.
If you have gow
installed, the Worker Process automatically "reloads" when you update the Worker file:
go install github.com/mitranim/gow@latest
gow run worker/main.go # automatically reloads when file changes
View the source code
in the context of the rest of the application code.
package main
import (
"log"
"go.temporal.io/sdk/activity"
"go.temporal.io/sdk/client"
"go.temporal.io/sdk/worker"
"go.temporal.io/sdk/workflow"
"documentation-samples-go/yourapp"
)
func main() {
// Create a Temporal Client
// A Temporal Client is a heavyweight object that should be created just once per process.
temporalClient, err := client.Dial(client.Options{})
if err != nil {
log.Fatalln("Unable to create client", err)
}
defer temporalClient.Close()
// Create a new Worker.
yourWorker := worker.New(temporalClient, "your-custom-task-queue-name", worker.Options{})
// Register your Workflow Definitions with the Worker.
// Use the ReisterWorkflow or RegisterWorkflowWithOptions method for each Workflow registration.
yourWorker.RegisterWorkflow(yourapp.YourWorkflowDefinition)
// ...
// Register your Activity Definitons with the Worker.
// Use this technique for registering all Activities that are part of a struct and set the shared variable values.
message := "This could be a connection string or endpoint details"
number := 100
activities := &yourapp.YourActivityObject{
Message: &message,
Number: &number,
}
// Use the RegisterActivity or RegisterActivityWithOptions method for each Activity.
yourWorker.RegisterActivity(activities)
// ...
// Run the Worker
err = yourWorker.Run(worker.InterruptCh())
if err != nil {
log.Fatalln("Unable to start Worker", err)
}
}
// ...