Using the context Go package

Traducciones al Español
Estamos traduciendo nuestros guías y tutoriales al Español. Es posible que usted esté viendo una traducción generada automáticamente. Estamos trabajando con traductores profesionales para verificar las traducciones de nuestro sitio web. Este proyecto es un trabajo en curso.
Create a Linode account to try this guide with a $ credit.
This credit will be applied to any valid services used during your first  days.

Go is a compiled, statically typed programming language developed by Google. Many modern applications, including Docker, Kubernetes, and Caddy, are written in Go.

Running a go command is as simple as:

go run [filename]

The context package provides contextual information that a goroutine may need such as how long it should run and how and when it should end. It can also pass informational key-value pairs for use down the call chain.

In this guide you will learn:

Before You Begin

You will need to install a recent version of Go on your computer in order to follow the presented commands. Any Go version newer than 1.8 will do but it is considered a good practice to have the latest version of Go installed. You can check your Go version by executing go version.

If you still need to install Go, you can follow our guide for Ubuntu installation here.

Note
This guide is written for a non-root user. Depending on your configuration, some commands might require the help of sudo in order to get property executed. If you are not familiar with the sudo command, see the Users and Groups guide.

About the context package

The context package supports both the handling of multiple concurrent operations and the passing of (typically request-scoped) contextual data in key-value pairs.

If you take a look at the source code of the context package, you will realize that its implementation is pretty simple. The context package defines the Context type, which is a Go interface with four methods, named Deadline(), Done(), Err(), and Value():

File: context.go
1
2
3
4
5
6
type Context interface {
    Deadline() (deadline time.Time, ok bool)
    Done() <-chan struct{}
    Err() error
    Value(key interface{}) interface{}
}
  • The developer will need to declare and modify a Context variable using functions such as context.WithCancel(), context.WithDeadline() and context.WithTimeout().

  • All three of these functions return a derived Context (the child) and a CancelFunc function. Calling the CancelFunc function removes the parent’s reference to the child and stops any associated timers. This means that the Go garbage collector is free to garbage collect the child goroutines that no longer have associated parent goroutines.

  • For garbage collection, the parent goroutine needs to keep a reference to each child goroutine. If a child goroutine ends without the parent knowing about it, then a memory leak occurs until the parent is canceled as well.

A simple example

This first code example is relatively simple and illustrates the use of the context.Context type with the help of simple.go.

Explaining the Go code of the Example

The code of simple.go is as follows:

File: ./simple.go
 1
 2
 3
 4
 5
 6
 7
 8
 9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
package main

import (
        "context"
        "fmt"
        "os"
        "strconv"
        "time"
)

// The f1 function creates and executes a goroutine
// The time.Sleep() call simulates the time it would take a real goroutine
// to do its job - in this case it is 4 seconds. If the c1 context calls
// the Done() function in less than 4 seconds, the goroutine will not have
// enough time to finish.
func f1(t int) {
        c1 := context.Background()
        // WithCancel returns a copy of parent context with a new Done channel
        c1, cancel := context.WithCancel(c1)
        defer cancel()

        go func() {
                time.Sleep(4 * time.Second)
                cancel()
        }()

        select {
        case <-c1.Done():
                fmt.Println("f1() Done:", c1.Err())
                return
        case r := <-time.After(time.Duration(t) * time.Second):
                fmt.Println("f1():", r)
        }
        return
}

func f2(t int) {
        c2 := context.Background()
        c2, cancel := context.WithTimeout(c2, time.Duration(t)*time.Second)
        defer cancel()

        go func() {
                time.Sleep(4 * time.Second)
                cancel()
        }()

        select {
        case <-c2.Done():
                fmt.Println("f2() Done:", c2.Err())
                return
        case r := <-time.After(time.Duration(t) * time.Second):
                fmt.Println("f2():", r)
        }
        return
}

func f3(t int) {
        c3 := context.Background()
        deadline := time.Now().Add(time.Duration(2*t) * time.Second)
        c3, cancel := context.WithDeadline(c3, deadline)
        defer cancel()

        go func() {
                time.Sleep(4 * time.Second)
                cancel()
        }()

        select {
        case <-c3.Done():
                fmt.Println("f3() Done:", c3.Err())
                return
        case r := <-time.After(time.Duration(t) * time.Second):
                fmt.Println("f3():", r)
        }
        return
}

func main() {
        if len(os.Args) != 2 {
                fmt.Println("Need a delay!")
                return
        }

        delay, err := strconv.Atoi(os.Args[1])
        if err != nil {
                fmt.Println(err)
                return
        }
        fmt.Println("Delay:", delay)

        f1(delay)
        f2(delay)
        f3(delay)
}
  • The program contains four functions including the main() function. Functions f1(), f2(), and f3() each require just one parameter, which is a time delay, because everything else they need is defined inside their functions.

  • In this example we call the context.Background() function to initialize an empty Context. The other function that can create an empty Context is context.TODO() which will be presented later in this guide.

  • Notice that the cancel variable, a function, in f1() is one of the return values of context.CancelFunc(). The context.WithCancel() function uses an existing Context and creates a child with cancellation. The context.WithCancel() function also returns a Done channel that can be closed, either when the cancel() function is called, as shown in the preceding code, or when the Done channel of the parent context is closed.

    Note
    One of the return values of Context.Done() is a Go channel, which means that you will have to use a select statement to work with. Although select looks like switch, select allows a goroutine to wait on multiple communications operations.
  • The cancel variable in f2() comes from context.WithTimeout(). context.WithTimeout() requires two parameters: a Context parameter and a time.Duration parameter. When the timeout period expires, the cancel() function is called automatically.

  • The cancel variable in f3() comes from context.WithDeadline(). context.WithDeadline() requires two parameters: a Context variable and a time in the future that signifies the deadline of the operation. When the deadline passes, the cancel() function is called automatically.

    Note
    Notice that contexts should not be stored in structures – they should be passed as separate parameters to functions. It is considered a good practice to pass them as the first parameter of a function.

Using simple.go

Execute simple.go with a delay period of 3 seconds:

go run simple.go 3

It will generate the following kind of output:

go run simple.go 3
Delay: 3
f1(): 2019-05-31 19:29:38.664568 +0300 EEST m=+3.004314767
f2(): 2019-05-31 19:29:41.664942 +0300 EEST m=+6.004810929
f3(): 2019-05-31 19:29:44.668795 +0300 EEST m=+9.008786881

The long lines of the output are the return values from the time.After() function. They denote normal operation of the program. The point here is that the operation of the program is canceled when there are delays in its execution.

If you use a bigger delay (10 seconds), which is executed as a call to time.Sleep():

go run simple.go 10

You will get the following kind of output:

Delay: 10
f1() Done: context canceled
f2() Done: context canceled
f3() Done: context canceled

The calls to time.Sleep() simulate a program that is slow or an operation that takes too much time to finish. Production code does not usually have such time.Sleep() function calls.

Using Context for HTTP

In this section of the guide you will learn how to timeout HTTP connections on the client side.

Note

This example makes a request to a local web server. A suitable, simple web server is available via Python and can be started with the following commands:

Python 3.X

python3 -m http.server

Python 2.X

python -m SimpleHTTPServer

The presented utility, which is called http.go, requires two command line arguments, which are the URL to connect to and the allowed delay value in seconds.

Explaining the Go Code of the Example

The Go code of the http.go utility is the following:

File: ./http.go
 1
 2
 3
 4
 5
 6
 7
 8
 9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
package main

import (
        "context"
        "fmt"
        "io/ioutil"
        "net/http"
        "os"
        "strconv"
        "sync"
        "time"
)

var (
        myUrl string
        delay int = 5
        w     sync.WaitGroup
)

type myData struct {
        r   *http.Response
        err error
}

// In packages that use contexts, convention is to pass them as
// the first argument to a function.
func connect(c context.Context) error {
        defer w.Done()
        data := make(chan myData, 1)
        tr := &http.Transport{}
        httpClient := &http.Client{Transport: tr}
        req, _ := http.NewRequest("GET", myUrl, nil)

        go func() {
                response, err := httpClient.Do(req)
                if err != nil {
                        fmt.Println(err)
                        data <- myData{nil, err}
                        return
                } else {
                        pack := myData{response, err}
                        data <- pack
                }
        }()

        select {
        case <-c.Done():
                tr.CancelRequest(req)
                <-data
                fmt.Println("The request was canceled!")
                return c.Err()
        case ok := <-data:
                err := ok.err
                resp := ok.r
                if err != nil {
                        fmt.Println("Error select:", err)
                        return err
                }
                defer resp.Body.Close()

                realHTTPData, err := ioutil.ReadAll(resp.Body)
                if err != nil {
                        fmt.Println("Error select:", err)
                        return err
                }
                // Although fmt.Printf() is used here, server processes
                // use the log.Printf() function instead.
                fmt.Printf("Server Response: %s\n", realHTTPData)
        }
        return nil
}

func main() {
        if len(os.Args) == 1 {
                fmt.Println("Need a URL and a delay!")
                return
        }

        myUrl = os.Args[1]
        if len(os.Args) == 3 {
                t, err := strconv.Atoi(os.Args[2])
                if err != nil {
                        fmt.Println(err)
                        return
                }
                delay = t
        }

        fmt.Println("Delay:", delay)
        c := context.Background()
        c, cancel := context.WithTimeout(c, time.Duration(delay)*time.Second)
        defer cancel()

        fmt.Printf("Connecting to %s \n", myUrl)
        w.Add(1)
        go connect(c)
        w.Wait()
        fmt.Println("Exiting...")
}
  • The timeout period is defined by the context.WithTimeout() method in main().

  • The connect() function that is executed as a goroutine will either terminate normally or when the cancel() function is executed.

    Note
    It is considered a good practice to use context.Background() in the main() function, the init() function of a package or at tests.
  • The connect() function is used for connecting to the desired URL. The connect() function also starts a goroutine before the select block takes control in order to either wait for web data as returned by the goroutine or for a timeout with the help of the Context variable.

Using http.go

If the desired delay is too small, then http.go will timeout. One such example is when you declare that you want a delay of 0 seconds, as in the following example:

go run http.go https://www.linode.com/ 0

The output is as follows:

Delay: 0
Connecting to https://www.linode.com/
The request was canceled!
Exiting...

If the timeout period is sufficient, say 10 seconds.

go run http.go http://localhost:8000 10

Then the output from http.go will be similar to the following:

Delay: 1
Connecting to http://localhost:8000
Server Response: Serving: <!DOCTYPE HTML PUBLIC "-//W3C//DTD HTML 4.01//EN" "http://www.w3.org/TR/html4/strict.dtd">
<html>
<head>
<meta http-equiv="Content-Type" content="text/html; charset=utf-8">
<title>Directory listing for /</title>
</head>
<body>
<h1>Directory listing for /</h1>
<hr>
<ul>
<li><a href="http.go">http.go</a></li>
<li><a href="more.go">more.go</a></li>
<li><a href="simple.go">simple.go</a></li>
</ul>
<hr>
</body>
</html>

Notice that http://localhost:8000 uses a custom made HTTP server that returns a small amount of data. However, nothing prohibits you from trying commands such as:

go run http.go https://www.linode.com/ 10

Using Contexts as key-value stores

In this section of the guide you will pass values in a Context and use it as a key-value store. This is a case where we do not pass values into contexts in order to provide further information about why they where canceled.

The more.go program illustrates the use of the context.TODO() function as well as the use of the context.WithValue() function.

Explaining the Go Code

The Go code of more.go is the following:

File: ./more.go
 1
 2
 3
 4
 5
 6
 7
 8
 9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
package main

import (
        "context"
        "fmt"
)

type aKey string

func searchKey(ctx context.Context, k aKey) {
        v := ctx.Value(k)
        if v != nil {
                fmt.Println("found value:", v)
                return
        } else {
                fmt.Println("key not found:", k)
        }
}

func main() {
        myKey := aKey("mySecretValue")
        ctx := context.WithValue(context.Background(), myKey, "mySecretValue")
        searchKey(ctx, myKey)

        searchKey(ctx, aKey("notThere"))
        emptyCtx := context.TODO()
        searchKey(emptyCtx, aKey("notThere"))
}
  • This time we create a context using context.TODO() instead of context.Background(). Although both functions return a non-nil, empty Context, their purposes differ. You should never pass a nil context –– use the context.TODO() function to create a suitable context. Use the context.TODO() function when you are not sure about the Context that you want to use.

  • The context.TODO() function signifies that we intend to use an operation context, without being sure about it yet. The good thing is that TODO() is recognized by static analysis tools, which allows them to determine whether a context.Context variable is propagated correctly in a program or not.

  • The context.WithValue() function that is used in main() offers a way to associate a value with a Context`.

  • The searchKey() function retrieves a value from a Context variable and checks whether that value exists or not.

Using more.go

Execute more.go with the following command:

go run more.go

It will generate the following output:

found value: mySecretValue
key not found: notThere
key not found: notThere

Propagation over HTTP

In order to share a common context among multiple processes, you will need to propagate that context on your own.

The logic of this technique is based on the Go code of more.go. First use the context.WithValue() function to add your data into a context, serialize and send over HTTP, decode the data, get the context, and finally use context.Value() to check whether the desired key and desired values are in place or not.

Note
The http.Request type has the Context() method that returns the context of the request and the WithContext() method that according to the Go documentation returns a shallow copy of r with its context changed to ctx. You can learn more about both methods at https://golang.org/pkg/net/http/.

More Information

You may wish to consult the following resources for additional information on this topic. While these are provided in the hope that they will be useful, please note that we cannot vouch for the accuracy or timeliness of externally hosted materials.

This page was originally published on


Your Feedback Is Important

Let us know if this guide was helpful to you.


Join the conversation.
Read other comments or post your own below. Comments must be respectful, constructive, and relevant to the topic of the guide. Do not post external links or advertisements. Before posting, consider if your comment would be better addressed by contacting our Support team or asking on our Community Site.