package qemu import ( "context" "crypto/rand" "fmt" "net" "os" "os/exec" "runtime" "strconv" "strings" "github.com/google/uuid" log "github.com/sirupsen/logrus" ) const ( NetworkingNone = "none" NetworkingUser = "user" NetworkingTap = "tap" NetworkingBridge = "bridge" NetworkingDefault = NetworkingUser ) var ( defaultArch string defaultAccel string ) func init() { switch runtime.GOARCH { case "arm64": defaultArch = "aarch64" case "amd64": defaultArch = "x86_64" case "s390x": defaultArch = "s390x" } switch { case runtime.GOARCH == "s390x": defaultAccel = "kvm" case haveKVM(): defaultAccel = "kvm:tcg" case runtime.GOOS == "darwin": defaultAccel = "hvf:tcg" } } func Run(ctx context.Context, path string, opts ...Option) error { config := &config{} for _, o := range opts { o(config) } config.path = path // Generate UUID, so that /sys/class/dmi/id/product_uuid is populated config.uuid = uuid.New() // These envvars override the corresponding command line // options. So this must remain after the `flags.Parse` above. // accel = GetStringValue("LINUXKIT_QEMU_ACCEL", accel, "") if config.arch == "" { config.arch = defaultArch } if config.accel == "" { config.accel = defaultAccel } if _, err := os.Stat(config.path); err != nil { return err } if config.cpus == 0 { config.cpus = 1 } if config.memory == 0 { config.memory = 1024 } for i, d := range config.disks { id := "" if i != 0 { id = strconv.Itoa(i) } if d.Size != 0 && d.Format == "" { d.Format = "qcow2" } if d.Size != 0 && d.Path == "" { d.Path = "disk" + id + ".img" } if d.Path == "" { return fmt.Errorf("disk specified with no size or name") } config.disks[i] = d } config.disks = append([]Disk{{Path: config.path}}, config.disks...) if config.networking == "" || config.networking == "default" { dflt := NetworkingDefault config.networking = dflt } netMode := strings.SplitN(config.networking, ",", 2) switch netMode[0] { case NetworkingUser: config.netdevConfig = "user,id=t0" case NetworkingTap: if len(netMode) != 2 { return fmt.Errorf("Not enough arguments for %q networking mode", NetworkingTap) } if len(config.publishedPorts) != 0 { return fmt.Errorf("Port publishing requires %q networking mode", NetworkingUser) } config.netdevConfig = fmt.Sprintf("tap,id=t0,ifname=%s,script=no,downscript=no", netMode[1]) case NetworkingBridge: if len(netMode) != 2 { return fmt.Errorf("Not enough arguments for %q networking mode", NetworkingBridge) } if len(config.publishedPorts) != 0 { return fmt.Errorf("Port publishing requires %q networking mode", NetworkingUser) } config.netdevConfig = fmt.Sprintf("bridge,id=t0,br=%s", netMode[1]) case NetworkingNone: if len(config.publishedPorts) != 0 { return fmt.Errorf("Port publishing requires %q networking mode", NetworkingUser) } config.netdevConfig = "" default: return fmt.Errorf("Invalid networking mode: %s", netMode[0]) } if err := config.discoverBinaries(); err != nil { log.Fatal(err) } return config.runQemuLocal(ctx) } func (c *config) runQemuLocal(ctx context.Context) (err error) { var args []string args, err = c.buildQemuCmdline() if err != nil { return err } for _, d := range c.disks { // If disk doesn't exist then create one if _, err := os.Stat(d.Path); err != nil { if os.IsNotExist(err) { log.Debugf("Creating new qemu disk [%s] format %s", d.Path, d.Format) qemuImgCmd := exec.Command(c.qemuImgPath, "create", "-f", d.Format, d.Path, fmt.Sprintf("%dM", d.Size)) log.Debugf("%v", qemuImgCmd.Args) if err := qemuImgCmd.Run(); err != nil { return fmt.Errorf("Error creating disk [%s] format %s: %s", d.Path, d.Format, err.Error()) } } else { return err } } else { log.Infof("Using existing disk [%s] format %s", d.Path, d.Format) } } // Detached mode is only supported in a container. if c.detached == true { return fmt.Errorf("Detached mode is only supported when running in a container, not locally") } qemuCmd := exec.CommandContext(ctx, c.qemuBinPath, args...) // If verbosity is enabled print out the full path/arguments log.Debugf("%v", qemuCmd.Args) // If we're not using a separate window then link the execution to stdin/out if c.gui == true { qemuCmd.Stdin = nil qemuCmd.Stdout = nil qemuCmd.Stderr = nil } else { qemuCmd.Stdin = c.stdin qemuCmd.Stdout = c.stdout qemuCmd.Stderr = c.stderr } return qemuCmd.Run() } func (c *config) buildQemuCmdline() ([]string, error) { // Iterate through the flags and build arguments var qemuArgs []string qemuArgs = append(qemuArgs, "-smp", fmt.Sprintf("%d", c.cpus)) qemuArgs = append(qemuArgs, "-m", fmt.Sprintf("%d", c.memory)) qemuArgs = append(qemuArgs, "-uuid", c.uuid.String()) // Need to specify the vcpu type when running qemu on arm64 platform, for security reason, // the vcpu should be "host" instead of other names such as "cortex-a53"... if c.arch == "aarch64" { if runtime.GOARCH == "arm64" { qemuArgs = append(qemuArgs, "-cpu", "host") } else { qemuArgs = append(qemuArgs, "-cpu", "cortex-a57") } } // goArch is the GOARCH equivalent of config.Arch var goArch string switch c.arch { case "s390x": goArch = "s390x" case "aarch64": goArch = "arm64" case "x86_64": goArch = "amd64" default: return nil, fmt.Errorf("%s is an unsupported architecture.", c.arch) } if goArch != runtime.GOARCH { log.Infof("Disable acceleration as %s != %s", c.arch, runtime.GOARCH) c.accel = "" } if c.accel != "" { switch c.arch { case "s390x": qemuArgs = append(qemuArgs, "-machine", fmt.Sprintf("s390-ccw-virtio,accel=%s", c.accel)) case "aarch64": gic := "" // VCPU supports less PA bits (36) than requested by the memory map (40) highmem := "highmem=off," if runtime.GOOS == "linux" { // gic-version=host requires KVM, which implies Linux gic = "gic_version=host," highmem = "" } qemuArgs = append(qemuArgs, "-machine", fmt.Sprintf("virt,%s%saccel=%s", gic, highmem, c.accel)) default: qemuArgs = append(qemuArgs, "-machine", fmt.Sprintf("q35,accel=%s", c.accel)) } } else { switch c.arch { case "s390x": qemuArgs = append(qemuArgs, "-machine", "s390-ccw-virtio") case "aarch64": qemuArgs = append(qemuArgs, "-machine", "virt") default: qemuArgs = append(qemuArgs, "-machine", "q35") } } // rng-random does not work on macOS // Temporarily disable it until fixed upstream. if runtime.GOOS != "darwin" { rng := "rng-random,id=rng0" if runtime.GOOS == "linux" { rng = rng + ",filename=/dev/urandom" } if c.arch == "s390x" { qemuArgs = append(qemuArgs, "-object", rng, "-device", "virtio-rng-ccw,rng=rng0") } else { qemuArgs = append(qemuArgs, "-object", rng, "-device", "virtio-rng-pci,rng=rng0") } } var lastDisk int for i, d := range c.disks { index := i if d.Format != "" { qemuArgs = append(qemuArgs, "-drive", "file="+d.Path+",format="+d.Format+",index="+strconv.Itoa(index)+",media=disk") } else { qemuArgs = append(qemuArgs, "-drive", "file="+d.Path+",index="+strconv.Itoa(index)+",media=disk") } lastDisk = index } // Ensure CDROMs start from at least hdc if lastDisk < 2 { lastDisk = 2 } if c.netdevConfig != "" { mac := generateMAC() if c.arch == "s390x" { qemuArgs = append(qemuArgs, "-device", "virtio-net-ccw,netdev=t0,mac="+mac.String()) } else { qemuArgs = append(qemuArgs, "-device", "virtio-net-pci,netdev=t0,mac="+mac.String()) } forwardings, err := buildQemuForwardings(c.publishedPorts) if err != nil { log.Error(err) } qemuArgs = append(qemuArgs, "-netdev", c.netdevConfig+forwardings) } else { qemuArgs = append(qemuArgs, "-net", "none") } if c.gui != true { qemuArgs = append(qemuArgs, "-nographic") } return qemuArgs, nil } func (c *config) discoverBinaries() error { if c.qemuImgPath != "" { return nil } qemuBinPath := "qemu-system-" + c.arch qemuImgPath := "qemu-img" var err error c.qemuBinPath, err = exec.LookPath(qemuBinPath) if err != nil { return fmt.Errorf("Unable to find %s within the $PATH", qemuBinPath) } c.qemuImgPath, err = exec.LookPath(qemuImgPath) if err != nil { return fmt.Errorf("Unable to find %s within the $PATH", qemuImgPath) } return nil } func buildQemuForwardings(publishedPorts []PublishedPort) (string, error) { if len(publishedPorts) == 0 { return "", nil } var forwardings string for _, p := range publishedPorts { hostPort := p.Host guestPort := p.Guest forwardings = fmt.Sprintf("%s,hostfwd=%s::%d-:%d", forwardings, p.Protocol, hostPort, guestPort) } return forwardings, nil } func haveKVM() bool { _, err := os.Stat("/dev/kvm") return !os.IsNotExist(err) } func generateMAC() net.HardwareAddr { mac := make([]byte, 6) n, err := rand.Read(mac) if err != nil { log.WithError(err).Fatal("failed to generate random mac address") } if n != 6 { log.WithError(err).Fatalf("generated %d bytes for random mac address", n) } mac[0] &^= 0x01 // Clear multicast bit mac[0] |= 0x2 // Set locally administered bit return mac }