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FastHttpRouter

Build Status Coverage Status GoDoc

FastHttpRouter is forked from httprouter which is a lightweight high performance HTTP request router (also called multiplexer or just mux for short) for fasthttp.

In contrast to the RequestHandler functions of valyala's fasthttp package, this router supports variables in the routing pattern and matches against the request method. It also scales better.

The router is optimized for high performance and a small memory footprint. It scales well even with very long paths and a large number of routes. A compressing dynamic trie (radix tree) structure is used for efficient matching.

Features

Only explicit matches: With other routers, like http.ServeMux, a requested URL path could match multiple patterns. Therefore they have some awkward pattern priority rules, like longest match or first registered, first matched. By design of this router, a request can only match exactly one or no route. As a result, there are also no unintended matches, which makes it great for SEO and improves the user experience.

Stop caring about trailing slashes: Choose the URL style you like, the router automatically redirects the client if a trailing slash is missing or if there is one extra. Of course it only does so, if the new path has a handler. If you don't like it, you can turn off this behavior.

Path auto-correction: Besides detecting the missing or additional trailing slash at no extra cost, the router can also fix wrong cases and remove superfluous path elements (like ../ or //). Is CAPTAIN CAPS LOCK one of your users? FastHttpRouter can help him by making a case-insensitive look-up and redirecting him to the correct URL.

Parameters in your routing pattern: Stop parsing the requested URL path, just give the path segment a name and the router delivers the dynamic value to you. Because of the design of the router, path parameters are very cheap.

Zero Garbage: The matching and dispatching process generates zero bytes of garbage. In fact, the only heap allocations that are made, is by building the slice of the key-value pairs for path parameters. If the request path contains no parameters, not a single heap allocation is necessary.

Best Performance: Benchmarks speak for themselves. See below for technical details of the implementation.

No more server crashes: You can set a Panic handler to deal with panics occurring during handling a HTTP request. The router then recovers and lets the PanicHandler log what happened and deliver a nice error page.

Perfect for APIs: The router design encourages to build sensible, hierarchical RESTful APIs. Moreover it has builtin native support for OPTIONS requests and 405 Method Not Allowed replies.

Of course you can also set custom NotFound and MethodNotAllowed handlers and serve static files.

Usage

This is just a quick introduction, view the GoDoc for details.

Let's start with a trivial example:

package main

import (
	"fmt"
	"log"

	"github.com/buaazp/fasthttprouter"
	"github.com/valyala/fasthttp"
)

func Index(ctx *fasthttp.RequestCtx, _ fasthttprouter.Params) {
	fmt.Fprint(ctx, "Welcome!\n")
}

func Hello(ctx *fasthttp.RequestCtx, ps fasthttprouter.Params) {
	fmt.Fprintf(ctx, "hello, %s!\n", ps.ByName("name"))
}

func main() {
	router := fasthttprouter.New()
	router.GET("/", Index)
	router.GET("/hello/:name", Hello)

	log.Fatal(fasthttp.ListenAndServe(":8080", router.Handler))
}

Named parameters

As you can see, :name is a named parameter. The values are accessible via httprouter.Params, which is just a slice of httprouter.Params. You can get the value of a parameter either by its index in the slice, or by using the ByName(name) method: :name can be retrived by ByName("name").

Named parameters only match a single path segment:

Pattern: /user/:user

 /user/gordon              match
 /user/you                 match
 /user/gordon/profile      no match
 /user/                    no match

Note: Since this router has only explicit matches, you can not register static routes and parameters for the same path segment. For example you can not register the patterns /user/new and /user/:user for the same request method at the same time. The routing of different request methods is independent from each other.

Catch-All parameters

The second type are catch-all parameters and have the form *name. Like the name suggests, they match everything. Therefore they must always be at the end of the pattern:

Pattern: /src/*filepath

 /src/                     match
 /src/somefile.go          match
 /src/subdir/somefile.go   match

How does it work?

The router relies on a tree structure which makes heavy use of common prefixes, it is basically a compact prefix tree (or just Radix tree). Nodes with a common prefix also share a common parent. Here is a short example what the routing tree for the GET request method could look like:

Priority   Path             Handle
9          \                *<1>
3          ├s               nil
2          |├earch\         *<2>
1          |└upport\        *<3>
2          ├blog\           *<4>
1          |    └:post      nil
1          |         └\     *<5>
2          ├about-us\       *<6>
1          |        └team\  *<7>
1          └contact\        *<8>

Every *<num> represents the memory address of a handler function (a pointer). If you follow a path trough the tree from the root to the leaf, you get the complete route path, e.g \blog\:post\, where :post is just a placeholder (parameter) for an actual post name. Unlike hash-maps, a tree structure also allows us to use dynamic parts like the :post parameter, since we actually match against the routing patterns instead of just comparing hashes. [As benchmarks show][benchmark], this works very well and efficient.

Since URL paths have a hierarchical structure and make use only of a limited set of characters (byte values), it is very likely that there are a lot of common prefixes. This allows us to easily reduce the routing into ever smaller problems. Moreover the router manages a separate tree for every request method. For one thing it is more space efficient than holding a method->handle map in every single node, for another thing is also allows us to greatly reduce the routing problem before even starting the look-up in the prefix-tree.

For even better scalability, the child nodes on each tree level are ordered by priority, where the priority is just the number of handles registered in sub nodes (children, grandchildren, and so on..). This helps in two ways:

  1. Nodes which are part of the most routing paths are evaluated first. This helps to make as much routes as possible to be reachable as fast as possible.
  2. It is some sort of cost compensation. The longest reachable path (highest cost) can always be evaluated first. The following scheme visualizes the tree structure. Nodes are evaluated from top to bottom and from left to right.
├------------
├---------
├-----
├----
├--
├--
└-

Why doesn't this work with http.Handler?

Becasue fasthttp doesn't provide http.Handler. See this description.

Fasthttp works with RequestHandler functions instead of objects implementing Handler interface. So a FastHttpRouter provides a Handler interface to implement the fasthttp.ListenAndServe interface.

Just try it out for yourself, the usage of FastHttpRouter is very straightforward. The package is compact and minimalistic, but also probably one of the easiest routers to set up.

Just try it out for yourself, the usage of FastHttpRouter is very straightforward. The package is compact and minimalistic, but also probably one of the easiest routers to set up.

Where can I find Middleware X?

This package just provides a very efficient request router with a few extra features. The router is just a [http.Handler][http.Handler], you can chain any http.Handler compatible middleware before the router, for example the Gorilla handlers. Or you could just write your own, it's very easy!

Alternatively, you could try a web framework based on HttpRouter.

Multi-domain / Sub-domains

Here is a quick example: Does your server serve multiple domains / hosts? You want to use sub-domains? Define a router per host!

// We need an object that implements the fasthttp.RequestHandler interface.
// We just use a map here, in which we map host names (with port) to fasthttp.RequestHandlers
type HostSwitch map[string]fasthttp.RequestHandler

// Implement a CheckHost method on our new type
func (hs HostSwitch) CheckHost(ctx *fasthttp.RequestCtx) {
	// Check if a http.Handler is registered for the given host.
	// If yes, use it to handle the request.
	if handler := hs[string(ctx.Host())]; handler != nil {
		handler(ctx)
	} else {
		// Handle host names for wich no handler is registered
		ctx.Error("Forbidden", 403) // Or Redirect?
	}
}

func main() {
	// Initialize a router as usual
	router := fasthttprouter.New()
	router.GET("/", Index)
	router.GET("/hello/:name", Hello)

	// Make a new HostSwitch and insert the router (our http handler)
	// for example.com and port 12345
	hs := make(HostSwitch)
	hs["example.com:12345"] = router.Handler

	// Use the HostSwitch to listen and serve on port 12345
	log.Fatal(fasthttp.ListenAndServe(":12345", hs.CheckHost))
}

Basic Authentication

Another quick example: Basic Authentication (RFC 2617) for handles:

package main

import (
	"bytes"
	"encoding/base64"
	"fmt"
	"log"

	"github.com/buaazp/fasthttprouter"
	"github.com/valyala/fasthttp"
)

var basicAuthPrefix = []byte("Basic ")

func BasicAuth(h fasthttprouter.Handle, user, pass []byte) fasthttprouter.Handle {
	return fasthttprouter.Handle(func(ctx *fasthttp.RequestCtx, ps fasthttprouter.Params) {
		// Get the Basic Authentication credentials
		auth := ctx.Request.Header.Peek("Authorization")
		if bytes.HasPrefix(auth, basicAuthPrefix) {
			// Check credentials
			payload, err := base64.StdEncoding.DecodeString(string(auth[len(basicAuthPrefix):]))
			if err == nil {
				pair := bytes.SplitN(payload, []byte(":"), 2)
				if len(pair) == 2 &&
					bytes.Equal(pair[0], user) &&
					bytes.Equal(pair[1], pass) {
					// Delegate request to the given handle
					h(ctx, ps)
					return
				}
			}
		}

		// Request Basic Authentication otherwise
		ctx.Response.Header.Set("WWW-Authenticate", "Basic realm=Restricted")
		ctx.Error(fasthttp.StatusMessage(fasthttp.StatusUnauthorized), fasthttp.StatusUnauthorized)
	})
}

func Index(ctx *fasthttp.RequestCtx, _ fasthttprouter.Params) {
	fmt.Fprint(ctx, "Not protected!\n")
}

func Protected(ctx *fasthttp.RequestCtx, _ fasthttprouter.Params) {
	fmt.Fprint(ctx, "Protected!\n")
}

func main() {
	user := []byte("gordon")
	pass := []byte("secret!")

	router := fasthttprouter.New()
	router.GET("/", Index)
	router.GET("/protected/", BasicAuth(Protected, user, pass))

	log.Fatal(fasthttp.ListenAndServe(":8080", router.Handler))
}

Chaining with the NotFound handler

NOTE: It might be required to set Router.HandleMethodNotAllowed to false to avoid problems.

You can use another http.Handler, for example another router, to handle requests which could not be matched by this router by using the Router.NotFound handler. This allows chaining.

Static files

The NotFound handler can for example be used to serve static files from the root path / (like an index.html file along with other assets):

// Serve static files from the ./public directory
router.NotFound = fasthttp.FSHandler("./public", 0)

But this approach sidesteps the strict core rules of this router to avoid routing problems. A cleaner approach is to use a distinct sub-path for serving files, like /static/*filepath or /files/*filepath.

Web Frameworks based on FastHttpRouter

If the HttpRouter is a bit too minimalistic for you, you might try one of the following more high-level 3rd-party web frameworks building upon the HttpRouter package:

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