.. | ||
fasthttputil | ||
stackless | ||
args.go | ||
bytebuffer.go | ||
bytesconv_32.go | ||
bytesconv_64.go | ||
bytesconv.go | ||
client.go | ||
compress.go | ||
cookie.go | ||
doc.go | ||
fs.go | ||
header.go | ||
http.go | ||
lbclient.go | ||
LICENSE | ||
nocopy.go | ||
peripconn.go | ||
README.md | ||
server.go | ||
ssl-cert-snakeoil.key | ||
ssl-cert-snakeoil.pem | ||
status.go | ||
stream.go | ||
strings.go | ||
tcpdialer.go | ||
timer.go | ||
TODO | ||
uri_unix.go | ||
uri_windows.go | ||
uri.go | ||
userdata.go | ||
workerpool.go |
fasthttp
Fast HTTP implementation for Go.
Currently fasthttp is successfully used by VertaMedia in a production serving up to 200K rps from more than 1.5M concurrent keep-alive connections per physical server.
TechEmpower Benchmark round 12 results
Switching from net/http to fasthttp
HTTP server performance comparison with net/http
In short, fasthttp server is up to 10 times faster than net/http. Below are benchmark results.
GOMAXPROCS=1
net/http server:
$ GOMAXPROCS=1 go test -bench=NetHTTPServerGet -benchmem -benchtime=10s
BenchmarkNetHTTPServerGet1ReqPerConn 1000000 12052 ns/op 2297 B/op 29 allocs/op
BenchmarkNetHTTPServerGet2ReqPerConn 1000000 12278 ns/op 2327 B/op 24 allocs/op
BenchmarkNetHTTPServerGet10ReqPerConn 2000000 8903 ns/op 2112 B/op 19 allocs/op
BenchmarkNetHTTPServerGet10KReqPerConn 2000000 8451 ns/op 2058 B/op 18 allocs/op
BenchmarkNetHTTPServerGet1ReqPerConn10KClients 500000 26733 ns/op 3229 B/op 29 allocs/op
BenchmarkNetHTTPServerGet2ReqPerConn10KClients 1000000 23351 ns/op 3211 B/op 24 allocs/op
BenchmarkNetHTTPServerGet10ReqPerConn10KClients 1000000 13390 ns/op 2483 B/op 19 allocs/op
BenchmarkNetHTTPServerGet100ReqPerConn10KClients 1000000 13484 ns/op 2171 B/op 18 allocs/op
fasthttp server:
$ GOMAXPROCS=1 go test -bench=kServerGet -benchmem -benchtime=10s
BenchmarkServerGet1ReqPerConn 10000000 1559 ns/op 0 B/op 0 allocs/op
BenchmarkServerGet2ReqPerConn 10000000 1248 ns/op 0 B/op 0 allocs/op
BenchmarkServerGet10ReqPerConn 20000000 797 ns/op 0 B/op 0 allocs/op
BenchmarkServerGet10KReqPerConn 20000000 716 ns/op 0 B/op 0 allocs/op
BenchmarkServerGet1ReqPerConn10KClients 10000000 1974 ns/op 0 B/op 0 allocs/op
BenchmarkServerGet2ReqPerConn10KClients 10000000 1352 ns/op 0 B/op 0 allocs/op
BenchmarkServerGet10ReqPerConn10KClients 20000000 789 ns/op 2 B/op 0 allocs/op
BenchmarkServerGet100ReqPerConn10KClients 20000000 604 ns/op 0 B/op 0 allocs/op
GOMAXPROCS=4
net/http server:
$ GOMAXPROCS=4 go test -bench=NetHTTPServerGet -benchmem -benchtime=10s
BenchmarkNetHTTPServerGet1ReqPerConn-4 3000000 4529 ns/op 2389 B/op 29 allocs/op
BenchmarkNetHTTPServerGet2ReqPerConn-4 5000000 3896 ns/op 2418 B/op 24 allocs/op
BenchmarkNetHTTPServerGet10ReqPerConn-4 5000000 3145 ns/op 2160 B/op 19 allocs/op
BenchmarkNetHTTPServerGet10KReqPerConn-4 5000000 3054 ns/op 2065 B/op 18 allocs/op
BenchmarkNetHTTPServerGet1ReqPerConn10KClients-4 1000000 10321 ns/op 3710 B/op 30 allocs/op
BenchmarkNetHTTPServerGet2ReqPerConn10KClients-4 2000000 7556 ns/op 3296 B/op 24 allocs/op
BenchmarkNetHTTPServerGet10ReqPerConn10KClients-4 5000000 3905 ns/op 2349 B/op 19 allocs/op
BenchmarkNetHTTPServerGet100ReqPerConn10KClients-4 5000000 3435 ns/op 2130 B/op 18 allocs/op
fasthttp server:
$ GOMAXPROCS=4 go test -bench=kServerGet -benchmem -benchtime=10s
BenchmarkServerGet1ReqPerConn-4 10000000 1141 ns/op 0 B/op 0 allocs/op
BenchmarkServerGet2ReqPerConn-4 20000000 707 ns/op 0 B/op 0 allocs/op
BenchmarkServerGet10ReqPerConn-4 30000000 341 ns/op 0 B/op 0 allocs/op
BenchmarkServerGet10KReqPerConn-4 50000000 310 ns/op 0 B/op 0 allocs/op
BenchmarkServerGet1ReqPerConn10KClients-4 10000000 1119 ns/op 0 B/op 0 allocs/op
BenchmarkServerGet2ReqPerConn10KClients-4 20000000 644 ns/op 0 B/op 0 allocs/op
BenchmarkServerGet10ReqPerConn10KClients-4 30000000 346 ns/op 0 B/op 0 allocs/op
BenchmarkServerGet100ReqPerConn10KClients-4 50000000 282 ns/op 0 B/op 0 allocs/op
HTTP client comparison with net/http
In short, fasthttp client is up to 10 times faster than net/http. Below are benchmark results.
GOMAXPROCS=1
net/http client:
$ GOMAXPROCS=1 go test -bench='HTTPClient(Do|GetEndToEnd)' -benchmem -benchtime=10s
BenchmarkNetHTTPClientDoFastServer 1000000 12567 ns/op 2616 B/op 35 allocs/op
BenchmarkNetHTTPClientGetEndToEnd1TCP 200000 67030 ns/op 5028 B/op 56 allocs/op
BenchmarkNetHTTPClientGetEndToEnd10TCP 300000 51098 ns/op 5031 B/op 56 allocs/op
BenchmarkNetHTTPClientGetEndToEnd100TCP 300000 45096 ns/op 5026 B/op 55 allocs/op
BenchmarkNetHTTPClientGetEndToEnd1Inmemory 500000 24779 ns/op 5035 B/op 57 allocs/op
BenchmarkNetHTTPClientGetEndToEnd10Inmemory 1000000 26425 ns/op 5035 B/op 57 allocs/op
BenchmarkNetHTTPClientGetEndToEnd100Inmemory 500000 28515 ns/op 5045 B/op 57 allocs/op
BenchmarkNetHTTPClientGetEndToEnd1000Inmemory 500000 39511 ns/op 5096 B/op 56 allocs/op
fasthttp client:
$ GOMAXPROCS=1 go test -bench='kClient(Do|GetEndToEnd)' -benchmem -benchtime=10s
BenchmarkClientDoFastServer 20000000 865 ns/op 0 B/op 0 allocs/op
BenchmarkClientGetEndToEnd1TCP 1000000 18711 ns/op 0 B/op 0 allocs/op
BenchmarkClientGetEndToEnd10TCP 1000000 14664 ns/op 0 B/op 0 allocs/op
BenchmarkClientGetEndToEnd100TCP 1000000 14043 ns/op 1 B/op 0 allocs/op
BenchmarkClientGetEndToEnd1Inmemory 5000000 3965 ns/op 0 B/op 0 allocs/op
BenchmarkClientGetEndToEnd10Inmemory 3000000 4060 ns/op 0 B/op 0 allocs/op
BenchmarkClientGetEndToEnd100Inmemory 5000000 3396 ns/op 0 B/op 0 allocs/op
BenchmarkClientGetEndToEnd1000Inmemory 5000000 3306 ns/op 2 B/op 0 allocs/op
GOMAXPROCS=4
net/http client:
$ GOMAXPROCS=4 go test -bench='HTTPClient(Do|GetEndToEnd)' -benchmem -benchtime=10s
BenchmarkNetHTTPClientDoFastServer-4 2000000 8774 ns/op 2619 B/op 35 allocs/op
BenchmarkNetHTTPClientGetEndToEnd1TCP-4 500000 22951 ns/op 5047 B/op 56 allocs/op
BenchmarkNetHTTPClientGetEndToEnd10TCP-4 1000000 19182 ns/op 5037 B/op 55 allocs/op
BenchmarkNetHTTPClientGetEndToEnd100TCP-4 1000000 16535 ns/op 5031 B/op 55 allocs/op
BenchmarkNetHTTPClientGetEndToEnd1Inmemory-4 1000000 14495 ns/op 5038 B/op 56 allocs/op
BenchmarkNetHTTPClientGetEndToEnd10Inmemory-4 1000000 10237 ns/op 5034 B/op 56 allocs/op
BenchmarkNetHTTPClientGetEndToEnd100Inmemory-4 1000000 10125 ns/op 5045 B/op 56 allocs/op
BenchmarkNetHTTPClientGetEndToEnd1000Inmemory-4 1000000 11132 ns/op 5136 B/op 56 allocs/op
fasthttp client:
$ GOMAXPROCS=4 go test -bench='kClient(Do|GetEndToEnd)' -benchmem -benchtime=10s
BenchmarkClientDoFastServer-4 50000000 397 ns/op 0 B/op 0 allocs/op
BenchmarkClientGetEndToEnd1TCP-4 2000000 7388 ns/op 0 B/op 0 allocs/op
BenchmarkClientGetEndToEnd10TCP-4 2000000 6689 ns/op 0 B/op 0 allocs/op
BenchmarkClientGetEndToEnd100TCP-4 3000000 4927 ns/op 1 B/op 0 allocs/op
BenchmarkClientGetEndToEnd1Inmemory-4 10000000 1604 ns/op 0 B/op 0 allocs/op
BenchmarkClientGetEndToEnd10Inmemory-4 10000000 1458 ns/op 0 B/op 0 allocs/op
BenchmarkClientGetEndToEnd100Inmemory-4 10000000 1329 ns/op 0 B/op 0 allocs/op
BenchmarkClientGetEndToEnd1000Inmemory-4 10000000 1316 ns/op 5 B/op 0 allocs/op
Install
go get -u github.com/valyala/fasthttp
Switching from net/http to fasthttp
Unfortunately, fasthttp doesn't provide API identical to net/http. See the FAQ for details. There is net/http -> fasthttp handler converter, but it is better to write fasthttp request handlers by hand in order to use all of the fasthttp advantages (especially high performance :) ).
Important points:
-
Fasthttp works with RequestHandler functions instead of objects implementing Handler interface. Fortunately, it is easy to pass bound struct methods to fasthttp:
type MyHandler struct { foobar string } // request handler in net/http style, i.e. method bound to MyHandler struct. func (h *MyHandler) HandleFastHTTP(ctx *fasthttp.RequestCtx) { // notice that we may access MyHandler properties here - see h.foobar. fmt.Fprintf(ctx, "Hello, world! Requested path is %q. Foobar is %q", ctx.Path(), h.foobar) } // request handler in fasthttp style, i.e. just plain function. func fastHTTPHandler(ctx *fasthttp.RequestCtx) { fmt.Fprintf(ctx, "Hi there! RequestURI is %q", ctx.RequestURI()) } // pass bound struct method to fasthttp myHandler := &MyHandler{ foobar: "foobar", } fasthttp.ListenAndServe(":8080", myHandler.HandleFastHTTP) // pass plain function to fasthttp fasthttp.ListenAndServe(":8081", fastHTTPHandler)
-
The RequestHandler accepts only one argument - RequestCtx. It contains all the functionality required for http request processing and response writing. Below is an example of a simple request handler conversion from net/http to fasthttp.
// net/http request handler requestHandler := func(w http.ResponseWriter, r *http.Request) { switch r.URL.Path { case "/foo": fooHandler(w, r) case "/bar": barHandler(w, r) default: http.Error(w, "Unsupported path", http.StatusNotFound) } }
// the corresponding fasthttp request handler requestHandler := func(ctx *fasthttp.RequestCtx) { switch string(ctx.Path()) { case "/foo": fooHandler(ctx) case "/bar": barHandler(ctx) default: ctx.Error("Unsupported path", fasthttp.StatusNotFound) } }
-
Fasthttp allows setting response headers and writing response body in an arbitrary order. There is no 'headers first, then body' restriction like in net/http. The following code is valid for fasthttp:
requestHandler := func(ctx *fasthttp.RequestCtx) { // set some headers and status code first ctx.SetContentType("foo/bar") ctx.SetStatusCode(fasthttp.StatusOK) // then write the first part of body fmt.Fprintf(ctx, "this is the first part of body\n") // then set more headers ctx.Response.Header.Set("Foo-Bar", "baz") // then write more body fmt.Fprintf(ctx, "this is the second part of body\n") // then override already written body ctx.SetBody([]byte("this is completely new body contents")) // then update status code ctx.SetStatusCode(fasthttp.StatusNotFound) // basically, anything may be updated many times before // returning from RequestHandler. // // Unlike net/http fasthttp doesn't put response to the wire until // returning from RequestHandler. }
-
Fasthttp doesn't provide ServeMux, but there are more powerful third-party routers and web frameworks with fasthttp support:
Net/http code with simple ServeMux is trivially converted to fasthttp code:
// net/http code m := &http.ServeMux{} m.HandleFunc("/foo", fooHandlerFunc) m.HandleFunc("/bar", barHandlerFunc) m.Handle("/baz", bazHandler) http.ListenAndServe(":80", m)
// the corresponding fasthttp code m := func(ctx *fasthttp.RequestCtx) { switch string(ctx.Path()) { case "/foo": fooHandlerFunc(ctx) case "/bar": barHandlerFunc(ctx) case "/baz": bazHandler.HandlerFunc(ctx) default: ctx.Error("not found", fasthttp.StatusNotFound) } } fasthttp.ListenAndServe(":80", m)
-
net/http -> fasthttp conversion table:
- All the pseudocode below assumes w, r and ctx have these types:
var ( w http.ResponseWriter r *http.Request ctx *fasthttp.RequestCtx )
- r.Body -> ctx.PostBody()
- r.URL.Path -> ctx.Path()
- r.URL -> ctx.URI()
- r.Method -> ctx.Method()
- r.Header -> ctx.Request.Header
- r.Header.Get() -> ctx.Request.Header.Peek()
- r.Host -> ctx.Host()
- r.Form -> ctx.QueryArgs() + ctx.PostArgs()
- r.PostForm -> ctx.PostArgs()
- r.FormValue() -> ctx.FormValue()
- r.FormFile() -> ctx.FormFile()
- r.MultipartForm -> ctx.MultipartForm()
- r.RemoteAddr -> ctx.RemoteAddr()
- r.RequestURI -> ctx.RequestURI()
- r.TLS -> ctx.IsTLS()
- r.Cookie() -> ctx.Request.Header.Cookie()
- r.Referer() -> ctx.Referer()
- r.UserAgent() -> ctx.UserAgent()
- w.Header() -> ctx.Response.Header
- w.Header().Set() -> ctx.Response.Header.Set()
- w.Header().Set("Content-Type") -> ctx.SetContentType()
- w.Header().Set("Set-Cookie") -> ctx.Response.Header.SetCookie()
- w.Write() -> ctx.Write(), ctx.SetBody(), ctx.SetBodyStream(), ctx.SetBodyStreamWriter()
- w.WriteHeader() -> ctx.SetStatusCode()
- w.(http.Hijacker).Hijack() -> ctx.Hijack()
- http.Error() -> ctx.Error()
- http.FileServer() -> fasthttp.FSHandler(), fasthttp.FS
- http.ServeFile() -> fasthttp.ServeFile()
- http.Redirect() -> ctx.Redirect()
- http.NotFound() -> ctx.NotFound()
- http.StripPrefix() -> fasthttp.PathRewriteFunc
-
VERY IMPORTANT! Fasthttp disallows holding references to RequestCtx or to its' members after returning from RequestHandler. Otherwise data races are inevitable. Carefully inspect all the net/http request handlers converted to fasthttp whether they retain references to RequestCtx or to its' members after returning. RequestCtx provides the following band aids for this case:
- Wrap RequestHandler into TimeoutHandler.
- Call TimeoutError before returning from RequestHandler if there are references to RequestCtx or to its' members. See the example for more details.
Use this brilliant tool - race detector - for detecting and eliminating data races in your program. If you detected data race related to fasthttp in your program, then there is high probability you forgot calling TimeoutError before returning from RequestHandler.
-
Blind switching from net/http to fasthttp won't give you performance boost. While fasthttp is optimized for speed, its' performance may be easily saturated by slow RequestHandler. So profile and optimize your code after switching to fasthttp. For instance, use quicktemplate instead of html/template.
-
See also fasthttputil, fasthttpadaptor and expvarhandler.
Performance optimization tips for multi-core systems
- Use reuseport listener.
- Run a separate server instance per CPU core with GOMAXPROCS=1.
- Pin each server instance to a separate CPU core using taskset.
- Ensure the interrupts of multiqueue network card are evenly distributed between CPU cores. See this article for details.
- Use Go 1.6 as it provides some considerable performance improvements.
Fasthttp best practices
- Do not allocate objects and
[]byte
buffers - just reuse them as much as possible. Fasthttp API design encourages this. - sync.Pool is your best friend.
- Profile your program
in production.
go tool pprof --alloc_objects your-program mem.pprof
usually gives better insights for optimization opportunities thango tool pprof your-program cpu.pprof
. - Write tests and benchmarks for hot paths.
- Avoid conversion between
[]byte
andstring
, since this may result in memory allocation+copy. Fasthttp API provides functions for both[]byte
andstring
- use these functions instead of converting manually between[]byte
andstring
. There are some exceptions - see this wiki page for more details. - Verify your tests and production code under race detector on a regular basis.
- Prefer quicktemplate instead of html/template in your webserver.
Tricks with []byte
buffers
The following tricks are used by fasthttp. Use them in your code too.
- Standard Go functions accept nil buffers
var (
// both buffers are uninitialized
dst []byte
src []byte
)
dst = append(dst, src...) // is legal if dst is nil and/or src is nil
copy(dst, src) // is legal if dst is nil and/or src is nil
(string(src) == "") // is true if src is nil
(len(src) == 0) // is true if src is nil
src = src[:0] // works like a charm with nil src
// this for loop doesn't panic if src is nil
for i, ch := range src {
doSomething(i, ch)
}
So throw away nil checks for []byte
buffers from you code. For example,
srcLen := 0
if src != nil {
srcLen = len(src)
}
becomes
srcLen := len(src)
- String may be appended to
[]byte
buffer withappend
dst = append(dst, "foobar"...)
[]byte
buffer may be extended to its' capacity.
buf := make([]byte, 100)
a := buf[:10] // len(a) == 10, cap(a) == 100.
b := a[:100] // is valid, since cap(a) == 100.
- All fasthttp functions accept nil
[]byte
buffer
statusCode, body, err := fasthttp.Get(nil, "http://google.com/")
uintBuf := fasthttp.AppendUint(nil, 1234)
Related projects
- fasthttp-contrib - various useful helpers for projects based on fasthttp.
- iris - web application framework built on top of fasthttp. Features speed and functionality.
- fasthttp-routing - fast and powerful routing package for fasthttp servers.
- fasthttprouter - a high performance fasthttp request router that scales well.
- lu - a high performance go middleware web framework which is based on fasthttp.
- websocket - Gorilla-based websocket implementation for fasthttp.
FAQ
-
Why creating yet another http package instead of optimizing net/http?
Because net/http API limits many optimization opportunities. For example:
- net/http Request object lifetime isn't limited by request handler execution time. So the server must create a new request object per each request instead of reusing existing objects like fasthttp does.
- net/http headers are stored in a
map[string][]string
. So the server must parse all the headers, convert them from[]byte
tostring
and put them into the map before calling user-provided request handler. This all requires unnecessary memory allocations avoided by fasthttp. - net/http client API requires creating a new response object per each request.
-
Why fasthttp API is incompatible with net/http?
Because net/http API limits many optimization opportunities. See the answer above for more details. Also certain net/http API parts are suboptimal for use:
-
Why fasthttp doesn't support HTTP/2.0 and WebSockets?
There are plans for adding HTTP/2.0 and WebSockets support in the future. In the mean time, third parties may use RequestCtx.Hijack for implementing these goodies. See the first third-party websocket implementation on the top of fasthttp.
-
Are there known net/http advantages comparing to fasthttp?
Yes:
- net/http supports HTTP/2.0 starting from go1.6.
- net/http API is stable, while fasthttp API constantly evolves.
- net/http handles more HTTP corner cases.
- net/http should contain less bugs, since it is used and tested by much wider audience.
- net/http works on Go older than 1.5.
-
Why fasthttp API prefers returning
[]byte
instead ofstring
?Because
[]byte
tostring
conversion isn't free - it requires memory allocation and copy. Feel free wrapping returned[]byte
result intostring()
if you prefer working with strings instead of byte slices. But be aware that this has non-zero overhead. -
Which GO versions are supported by fasthttp?
Go1.5+. Older versions won't be supported, since their standard package miss useful functions.
-
Please provide real benchmark data and sever information
See this issue.
-
Are there plans to add request routing to fasthttp?
There are no plans to add request routing into fasthttp. Use third-party routers and web frameworks with fasthttp support:
See also this issue for more info.
-
I detected data race in fasthttp!
Cool! File a bug. But before doing this check the following in your code:
- Make sure there are no references to RequestCtx or to its' members after returning from RequestHandler.
- Make sure you call TimeoutError before returning from RequestHandler if there are references to RequestCtx or to its' members, which may be accessed by other goroutines.
-
I didn't find an answer for my question here
Try exploring these questions.