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Golang optimizes http requests

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Release: 2023-05-14 15:32:10
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With the development of web applications, the optimization of HTTP requests has become an important topic. Not only optimizes the performance of web applications, but also enhances user experience. In the Go language, we can use some techniques to optimize HTTP requests, including: concurrent requests and performance optimization.

  1. Concurrent requests

The Go language has built-in support for concurrent requests, which allows us to process multiple HTTP requests concurrently in one program, which can greatly improve the performance of the program. and response speed. We can use asynchronous requests and concurrent requests to achieve this function.

Asynchronous request:

Asynchronous request means that when processing a request, you do not wait for the response to return, but directly proceed to the next request. Asynchronous requests are usually implemented using goroutine. The sample code is as follows:

func request(url string) {
    resp, err := http.Get(url)
    if err != nil {
        // handle error
        return
    }
    defer resp.Body.Close()

    // handle response
    body, err := ioutil.ReadAll(resp.Body)
    if err != nil {
        // handle error
        return
    }

    fmt.Println(string(body))
}

func main() {
    urls := []string{"http://example.com", "http://example.net", "http://example.org"}

    for _, url := range urls {
        go request(url)
    }

    // Wait for all goroutines to finish
    time.Sleep(time.Second)
}
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In the above code, we define the request function to send HTTP requests and process responses, and then use a for loop to concurrently request multiple URL links. Each URL link is executed in a separate goroutine.

Concurrent requests:

Concurrent requests refer to processing multiple requests at the same time, but waiting for all requests to return before processing the results. In this case, you need to use goroutine and go channel to achieve the goal. The sample code is as follows:

func request(url string, ch chan<- string) {
    resp, err := http.Get(url)
    if err != nil {
        // handle error
        ch <- fmt.Sprintf("Error: %s", err)
        return
    }
    defer resp.Body.Close()

    body, err := ioutil.ReadAll(resp.Body)
    if err != nil {
        // handle error
        ch <- fmt.Sprintf("Error: %s", err)
        return
    }

    ch <- string(body)
}

func main() {
    urls := []string{"http://example.com", "http://example.net", "http://example.org"}

    ch := make(chan string)

    for _, url := range urls {
        go request(url, ch)
    }

    for range urls {
        fmt.Println(<-ch)
    }
}
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In the above code, we define the request function to send HTTP requests and process responses, and then use a for loop Multiple URL links are requested concurrently. Each URL link is executed in a separate goroutine, and the processing results are passed to the main function through the go channel. After the responses to all requests are received in the main function, the results are output.

  1. Performance Optimization

In addition to concurrent requests, we can also speed up the processing of HTTP requests through some performance optimization techniques.

Use connection pool:

In the Go language, each HTTP request needs to create a TCP connection, which will lead to too many connections when processing a large number of requests. If we use a connection pool, we can reuse these connections and reduce the consumption of system resources. The sample code is as follows:

// Create a new client with a connection pool
client := &http.Client{
    Transport: &http.Transport{
        MaxIdleConnsPerHost: 10,
    },
}

// Send a http request
resp, err := client.Get("http://example.com")
if err != nil {
    // handle error
    return
}
defer resp.Body.Close()

// handle response
body, err := ioutil.ReadAll(resp.Body)
if err != nil {
    // handle error
    return
}

fmt.Println(string(body))
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In the above code, we created an http.Client object and set the connection pool The size is 10 and then the HTTP request is sent using the client.Get method.

Use Keep-Alive:

In the HTTP/1.1 protocol, Keep-Alive is enabled by default, which allows the client and server to maintain the connection state after processing a request. Then use this connection status to handle subsequent requests. In the Go language, Keep-Alive is also turned on by default.

Use gzip compression:

When processing a large number of HTTP requests, if the data returned by the server is large, it may take a long time for the client to accept the data. In this case, we can request the server to use gzip compression when transmitting data, which can reduce the time of data transmission. In the Go language, you can enable gzip compression by setting the header of the request. The sample code is as follows:

// Create a new client with a gzip transport
client := &http.Client{
    Transport: &http.Transport{
        DisableCompression: false,
    },
}

// Create a new request with gzip header
req, err := http.NewRequest("GET", "http://example.com", nil)
if err != nil {
    // handle error
    return
}
req.Header.Add("Accept-Encoding", "gzip")

// Send a http request
resp, err := client.Do(req)
if err != nil {
    // handle error
    return
}
defer resp.Body.Close()

// handle response
if resp.Header.Get("Content-Encoding") == "gzip" {
    gzr, err := gzip.NewReader(resp.Body)
    if err != nil {
        // handle error
        return
    }
    defer gzr.Close()

    body, err := ioutil.ReadAll(gzr)
    if err != nil {
        // handle error
        return
    }

    fmt.Println(string(body))
} else {
    body, err := ioutil.ReadAll(resp.Body)
    if err != nil {
        // handle error
        return
    }

    fmt.Println(string(body))
}
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In the above code, we created an http.Client object and set the DisableCompression of the Transport attribute to false. , so that the Go language can automatically process gzip compressed data. We also created a new request object and added the gzip support tag in the request header, and then requested the data returned by the server to use judgment to handle the different situations of gzip compressed data and uncompressed data.

Summary:

The Go language has built-in support for concurrent requests and performance optimization. Using these technologies can greatly improve the performance and response speed of the program. We can use asynchronous requests and concurrent requests to implement concurrent requests, and use connection pooling, Keep-Alive, gzip compression and other technologies to optimize the performance of HTTP requests.

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