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backend_uml.go
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backend_uml.go
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//go:build linux
// +build linux
package fakemachine
import (
"errors"
"fmt"
"io/ioutil"
"os"
"os/exec"
"path"
"golang.org/x/sys/unix"
)
type umlBackend struct {
machine *Machine
}
func newUmlBackend(m *Machine) umlBackend {
return umlBackend{machine: m}
}
func (b umlBackend) Name() string {
return "uml"
}
func (b umlBackend) Supported() (bool, error) {
// only support amd64
if b.machine.arch != Amd64 {
return false, fmt.Errorf("unsupported arch: %s", b.machine.arch)
}
// check the kernel exists
if _, err := b.KernelPath(); err != nil {
return false, err
}
// check the modules exist
if _, err := b.ModulePath(); err != nil {
return false, err
}
// check the slirp helper exists exec.LookPath
if _, err := b.SlirpHelperPath(); err != nil {
return false, fmt.Errorf("libslirp-helper not installed")
}
return true, nil
}
func (b umlBackend) KernelRelease() (string, error) {
return "", errors.New("not implemented")
}
func (b umlBackend) KernelPath() (string, error) {
// find the UML binary
kernelPath, err := exec.LookPath("linux.uml")
if err != nil {
return "", fmt.Errorf("user-mode-linux not installed")
}
return kernelPath, nil
}
func (b umlBackend) ModulePath() (string, error) {
// make sure the UML modules exist
// on non-merged usr systems the modules still reside under /usr/lib/uml
moddir := "/usr/lib/uml/modules"
if _, err := os.Stat(moddir); err != nil {
return "", fmt.Errorf("user-mode-linux modules not installed")
}
// find the subdirectory containing the modules for the UML release
modSubdirs, err := ioutil.ReadDir(moddir)
if err != nil {
return "", err
}
if len(modSubdirs) != 1 {
return "", fmt.Errorf("could not determine which user-mode-linux modules to use")
}
moddir = path.Join(moddir, modSubdirs[0].Name())
return moddir, nil
}
func (b umlBackend) SlirpHelperPath() (string, error) {
return exec.LookPath("libslirp-helper")
}
func (b umlBackend) UdevRules() []string {
udevRules := []string{}
// create symlink under /dev/disk/by-fakemachine-label/ for each virtual image
for i, img := range b.machine.images {
driveLetter := 'a' + i
udevRules = append(udevRules,
fmt.Sprintf(`KERNEL=="ubd%c", SYMLINK+="disk/by-fakemachine-label/%s"`, driveLetter, img.label),
fmt.Sprintf(`KERNEL=="ubd%c[0-9]", SYMLINK+="disk/by-fakemachine-label/%s-part%%n"`, driveLetter, img.label))
}
return udevRules
}
func (b umlBackend) JobOutputTTY() string {
// Send the fakemachine job output to the right console
if b.machine.showBoot {
return "/dev/tty0"
}
return "/dev/tty1"
}
func (b umlBackend) MountParameters(mount mountPoint) (fstype string, options []string) {
fstype = "hostfs"
options = []string{mount.hostDirectory}
return
}
func (b umlBackend) InitModules() []string {
return []string{}
}
func (b umlBackend) InitStaticVolumes() []mountPoint {
// mount the UML modules over the top of /lib/modules
// which currently contains the modules from the base system
moddir, _ := b.ModulePath()
moddir = path.Join(moddir, "../")
machineDir := "/lib/modules"
if mergedUsrSystem() {
machineDir = "/usr/lib/modules"
}
moduleVolume := mountPoint{moddir, machineDir, "modules", true}
return []mountPoint{moduleVolume}
}
func (b umlBackend) Start() (bool, error) {
m := b.machine
kernelPath, err := b.KernelPath()
if err != nil {
return false, err
}
slirpHelperPath, err := b.SlirpHelperPath()
if err != nil {
return false, err
}
/* for networking we use the UML vector transport alongside the
* libslirp-helper on the host. This works by creating a pair of
* connected sockets on the host using the socketpair syscall, which
* returns two file descriptors. One of the sockets is attached to the
* UML process and the other socket is attached to the libslirp-helper
* process allowing communication between the two processes.
* It doesn't matter the order in which the sockets are connected to
* the processes.
*/
netSocketpair, err := unix.Socketpair(unix.AF_UNIX, unix.SOCK_DGRAM, 0)
if err != nil {
return false, err
}
// one of the sockets will be attached to the slirp-helper
slirpHelperSocket := os.NewFile(uintptr(netSocketpair[0]), "")
if slirpHelperSocket == nil {
return false, fmt.Errorf("creation of slirpHelperSocket failed")
}
defer slirpHelperSocket.Close()
// while the other socket will be attached to the uml guest
umlVectorTransportSocket := os.NewFile(uintptr(netSocketpair[1]), "")
if umlVectorTransportSocket == nil {
return false, fmt.Errorf("creation of umlVectorTransportSocket failed")
}
defer umlVectorTransportSocket.Close()
// launch libslirp-helper
slirpHelperArgs := []string{"libslirp-helper",
"--exit-with-parent"}
/* attach the slirpHelperSocket as an additional fd to the process,
* after std*. The helper then bridges the host network to the attached
* file descriptor using the --fd argument. Since the standard std*
* file descriptors are passed to the libslirp-helper --fd should
* always be set to 3.
*/
slirpHelperAttr := &os.ProcAttr{
Files: []*os.File{os.Stdin, os.Stdout, os.Stderr, slirpHelperSocket},
}
slirpHelperArgs = append(slirpHelperArgs, "--fd=3")
slirpHelper, err := os.StartProcess(slirpHelperPath, slirpHelperArgs, slirpHelperAttr)
if err != nil {
return false, err
}
defer func() { _ = slirpHelper.Kill() }()
// launch uml guest
memory := fmt.Sprintf("%d", m.memory)
umlargs := []string{"linux",
"mem=" + memory + "M",
"initrd=" + m.initrdpath,
"panic=-1",
"plymouth.enable=0",
"systemd.unit=fakemachine.service",
"console=tty0",
}
/* umlVectorTransportSocket is attached as an additional fd to the process,
* after the std* file descriptors. Setup a vector device inside the guest
* which uses fd transport with the 3rd file descriptor attached to the
* UML process.
*/
umlAttr := &os.ProcAttr{
Files: []*os.File{os.Stdin, os.Stdout, os.Stderr, umlVectorTransportSocket},
}
umlargs = append(umlargs, "vec0:transport=fd,fd=3,vec=0")
if m.showBoot {
// Create a character device representing our stdio
// file descriptors, and connect the emulated serial
// port (which is the console device for the BIOS,
// Linux and systemd, and is also connected to the
// fakemachine script) to that device
umlargs = append(umlargs,
"con0=fd:0,fd:1", // tty0 to stdin/stdout when showing boot
"con=none") // no other consoles
} else {
// don't show the UML message output by default
umlargs = append(umlargs, "quiet")
umlargs = append(umlargs,
"con1=fd:0,fd:1",
"con0=null",
"con=none") // no other consoles
}
for i, img := range m.images {
umlargs = append(umlargs,
fmt.Sprintf("ubd%d=%s", i, img.path))
}
p, err := os.StartProcess(kernelPath, umlargs, umlAttr)
if err != nil {
return false, err
}
// wait for uml process to exit
ustate, err := p.Wait()
if err != nil {
return false, err
}
return ustate.Success(), nil
}