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GO-URING

Linux io_uring for GO.

A series of articles about this library and io_uring (RU):

About

This project contains:

  1. uring package - low-level io_uring API. This API is similar to liburing API. In other words - this is a port of liburing.
  2. reactor package - high-level API - implementation of event loop pattern with io_uring.
  3. net package - this is an implementation of net.Listener and net.Conn interfaces with io_uring.
  4. Examples and benchmarks:

URING package

Package uring is a port of liburing. It provides low-level functionality for working with io_uring. Example of usage:

  • read file:
package main

import (
   "fmt"
   "github.com/godzie44/go-uring/uring"
   "os"
)

func main() {
   ring, err := uring.New(8)
   noErr(err)
   defer ring.Close()

   // open file and init read buffers
   file, err := os.Open("./go.mod")
   noErr(err)
   stat, _ := file.Stat()
   buff := make([]byte, stat.Size())

   // add Read operation to SQ queue
   err = ring.QueueSQE(uring.Read(file.Fd(), buff, 0), 0, 0)
   noErr(err)

   // submit all SQ new entries
   _, err = ring.Submit()
   noErr(err)

   // wait until data is reading into buffer
   cqe, err := ring.WaitCQEvents(1)
   noErr(err)

   noErr(cqe.Error()) //check read error

   fmt.Printf("read %d bytes, read result: \n%s", cqe.Res, string(buff))

   // dequeue CQ
   ring.SeenCQE(cqe)
}
  • accept incoming connections:
package main

import (
   "fmt"
   "github.com/godzie44/go-uring/uring"
   "syscall"
)

func main() {
   // create io_uring instance
   ring, err := uring.New(8)
   noErr(err)
   defer ring.Close()

   // create server socket
   socketFd, err := syscall.Socket(syscall.AF_INET, syscall.SOCK_STREAM, 0)
   noErr(err)
   defer syscall.Close(socketFd)

   addr := syscall.SockaddrInet4{Port: 8081}
   noErr(syscall.Bind(socketFd, &addr))
   noErr(syscall.Listen(socketFd, syscall.SOMAXCONN))

   for {
      // add Accept operation to SQ queue
      err = ring.QueueSQE(uring.Accept(uintptr(socketFd), 0), 0, 0)
      noErr(err)

      // submit all SQ new entries
      _, err = ring.Submit()
      noErr(err)

      // wait until new client connection is accepted
      cqe, err := ring.WaitCQEvents(1)
      noErr(err)

      //check accept error
      noErr(cqe.Error())

      // handle client socket, socket descriptor now in cqe.Res field
      fmt.Printf("socket %d connected\n", cqe.Res)

      // dequeue CQ
      ring.SeenCQE(cqe)
   }
}
  • Look more examples in uring package tests

Release/Acquire semantic

Model of GO atomic is more strict than atomics using in liburing. Currently, there is no public description of memory model for GO atomics, but with these articles (1, 2), we know that the implementation of GO atomics is the same as default (seq_cst) atomics in C/C++. But liburing use less strict semantic (explained here) - similar memory_order_acquire/memory_order_release semantic in C/C++ memory model. Certainly, we can use GO atomics as is (because of strict semantic), but this entails some overhead costs.

This lib provides experimental and totally unsafe realization of memory_order_acquire/memory_order_release atomics for amd64 arch, you can enable it by adding build tag amd64_atomic. It is based on the fact that MOV instructions are enough to implement memory_order_acquire/memory_order_release on the amd64 architecture (link). For example:

  go test -v -tags amd64_atomic ./...

This can give about 1%-3% performance gain.

REACTOR package

Reactor - is event loop implemented with io_uring. Currently, there are two reactors in this package:

  1. Reactor - generic event loop, give a possibility to work with all io_uring operations.
  2. NetReactor - event loop optimized for work with network operations on sockets.

Example of usage:

  • read file:
package main

import (
	"context"
	"fmt"
	"github.com/godzie44/go-uring/reactor"
	"github.com/godzie44/go-uring/uring"
	"os"
	"os/signal"
)

func main() {
	ring, err := uring.New(8)
	noErr(err)

	// create and start reactor
	rea, err := reactor.New([]*uring.Ring{ring})
	noErr(err)
	ctx, cancel := signal.NotifyContext(context.Background(), os.Interrupt)
	go func() {
		rea.Run(ctx)
	}()

	// open file and init read buffers
	file, err := os.Open("./go.mod")
	noErr(err)
	stat, _ := file.Stat()
	buff := make([]byte, stat.Size())

	// queue read operation, result CQE will be handled by callback func
	op := uring.Read(file.Fd(), buff, 0)
	rea.Queue(op, func(event uring.CQEvent) {
		noErr(event.Error()) //check read error
		fmt.Printf("read %d bytes, read result: \n%s", event.Res, string(buff))
		cancel()
	})

	<-ctx.Done()
}
  • accept incoming connections:
package main

import (
	"context"
	"fmt"
	"github.com/godzie44/go-uring/reactor"
	"github.com/godzie44/go-uring/uring"
	"syscall"
)

func main() {
	ring, err := uring.New(8)
	noErr(err)

	// create and start net-reactor
	rea, err := reactor.NewNet([]*uring.Ring{ring})
	noErr(err)
	go func() {
		rea.Run(context.Background())
	}()

	// create server socket
	socketFd, err := syscall.Socket(syscall.AF_INET, syscall.SOCK_STREAM, 0)
	noErr(err)
	defer syscall.Close(socketFd)
	addr := syscall.SockaddrInet4{Port: 8081}
	noErr(syscall.Bind(socketFd, &addr))
	noErr(syscall.Listen(socketFd, syscall.SOMAXCONN))

	acceptChan := make(chan int32)
	for {
		// queue accept operation, result CQE will be handled by callback func
		op := uring.Accept(uintptr(socketFd), 0)
		rea.Queue(op, func(event uring.CQEvent) {
			noErr(event.Error()) //check accept error
			acceptChan <- event.Res
		})

		fmt.Printf("socket %d connected\n", <-acceptChan)
	}
}
  • Look more examples in reactor package tests

NET package

This is the implementation of net.Listener and net.Conn interfaces. Uses NetReactor inside. Please check the example of HTTP server and multi thread TCP echo-server to familiarize yourself with it.

Examples and benchmarks

Plain TCP echo-server

Single thread echo-server (listens on a specific TCP port and as soon as any data arrives at this port, it immediately forwards it back to the sender) implemented with go-uring. Useful for compare GO go-uring lib realization with liburing realization. See source code and benchmarks for familiarization.

GO-style TCP echo-server

Echo-server (listens on a specific TCP port and as soon as any data arrives at this port, it immediately forwards it back to the sender) implemented with go-uring and reactor packages. Realization similar with realization of echo-server with net/http package (benchmarks attached). See source code and benchmarks for familiarization.

HTTP server

Example of HTTP-server implemented with io_uring. Sources.