metropolis/test/launch/launch.go - monogon - Gitiles

 // Copyright 2020 The Monogon Project Authors.
 //
 // SPDX-License-Identifier: Apache-2.0
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //     http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 package launch

 import (
 	"bytes"
 	"context"
 	"crypto/rand"
 	"errors"
 	"fmt"
 	"io"
 	"io/ioutil"
 	"log"
 	"net"
 	"os"
 	"os/exec"
 	"path/filepath"
 	"strconv"
 	"strings"
 	"syscall"
 	"time"

 	"github.com/golang/protobuf/proto"
 	grpcretry "github.com/grpc-ecosystem/go-grpc-middleware/retry"
 	"golang.org/x/sys/unix"
 	"google.golang.org/grpc"

 	"source.monogon.dev/metropolis/node"
 	"source.monogon.dev/metropolis/pkg/freeport"
 	apb "source.monogon.dev/metropolis/proto/api"
 )

 type qemuValue map[string][]string

 // toOption encodes structured data into a QEMU option. Example: "test", {"key1":
 // {"val1"}, "key2": {"val2", "val3"}} returns "test,key1=val1,key2=val2,key2=val3"
 func (value qemuValue) toOption(name string) string {
 	var optionValues []string
 	if name != "" {
 		optionValues = append(optionValues, name)
 	}
 	for name, values := range value {
 		if len(values) == 0 {
 			optionValues = append(optionValues, name)
 		}
 		for _, val := range values {
 			optionValues = append(optionValues, fmt.Sprintf("%v=%v", name, val))
 		}
 	}
 	return strings.Join(optionValues, ",")
 }

 func copyFile(src, dst string) error {
 	in, err := os.Open(src)
 	if err != nil {
 		return fmt.Errorf("when opening source: %w", err)
 	}
 	defer in.Close()

 	out, err := os.Create(dst)
 	if err != nil {
 		return fmt.Errorf("when creating destination: %w", err)
 	}
 	defer out.Close()

 	_, err = io.Copy(out, in)
 	if err != nil {
 		return fmt.Errorf("when copying file: %w", err)
 	}
 	return out.Close()
 }

 // PortMap represents where VM ports are mapped to on the host. It maps from the VM
 // port number to the host port number.
 type PortMap map[uint16]uint16

 // toQemuForwards generates QEMU hostfwd values (https://qemu.weilnetz.de/doc/qemu-
 // doc.html#:~:text=hostfwd=) for all mapped ports.
 func (p PortMap) toQemuForwards() []string {
 	var hostfwdOptions []string
 	for vmPort, hostPort := range p {
 		hostfwdOptions = append(hostfwdOptions, fmt.Sprintf("tcp::%v-:%v", hostPort, vmPort))
 	}
 	return hostfwdOptions
 }

 // DialGRPC creates a gRPC client for a VM port that's forwarded/mapped to the
 // host. The given port is automatically resolved to the host-mapped port.
 func (p PortMap) DialGRPC(port uint16, opts ...grpc.DialOption) (*grpc.ClientConn, error) {
 	mappedPort, ok := p[port]
 	if !ok {
 		return nil, fmt.Errorf("cannot dial port: port %v is not mapped/forwarded", port)
 	}
 	grpcClient, err := grpc.Dial(fmt.Sprintf("localhost:%v", mappedPort), opts...)
 	if err != nil {
 		return nil, fmt.Errorf("failed to dial port %v: %w", port, err)
 	}
 	return grpcClient, nil
 }

 // Options contains all options that can be passed to Launch()
 type Options struct {
 	// Ports contains the port mapping where to expose the internal ports of the VM to
 	// the host. See IdentityPortMap() and ConflictFreePortMap(). Ignored when
 	// ConnectToSocket is set.
 	Ports PortMap

 	// If set to true, reboots are honored. Otherwise all reboots exit the Launch()
 	// command. Metropolis nodes generally restarts on almost all errors, so unless you
 	// want to test reboot behavior this should be false.
 	AllowReboot bool

 	// By default the VM is connected to the Host via SLIRP. If ConnectToSocket is set,
 	// it is instead connected to the given file descriptor/socket. If this is set, all
 	// port maps from the Ports option are ignored. Intended for networking this
 	// instance together with others for running  more complex network configurations.
 	ConnectToSocket *os.File

 	// SerialPort is a io.ReadWriter over which you can communicate with the serial
 	// port of the machine It can be set to an existing file descriptor (like
 	// os.Stdout/os.Stderr) or any Go structure implementing this interface.
 	SerialPort io.ReadWriter

 	// NodeParameters is passed into the VM and subsequently used for bootstrapping or
 	// registering into a cluster.
 	NodeParameters *apb.NodeParameters
 }

 // NodePorts is the list of ports a fully operational Metropolis node listens on
 var NodePorts = []uint16{node.ConsensusPort, node.NodeServicePort, node.MasterServicePort,
 	node.ExternalServicePort, node.DebugServicePort, node.KubernetesAPIPort, node.DebuggerPort}

 // IdentityPortMap returns a port map where each given port is mapped onto itself
 // on the host. This is mainly useful for development against Metropolis. The dbg
 // command requires this mapping.
 func IdentityPortMap(ports []uint16) PortMap {
 	portMap := make(PortMap)
 	for _, port := range ports {
 		portMap[port] = port
 	}
 	return portMap
 }

 // ConflictFreePortMap returns a port map where each given port is mapped onto a
 // random free port on the host. This is intended for automated testing where
 // multiple instances of Metropolis nodes might be running. Please call this
 // function for each Launch command separately and as close to it as possible since
 // it cannot guarantee that the ports will remain free.
 func ConflictFreePortMap(ports []uint16) (PortMap, error) {
 	portMap := make(PortMap)
 	for _, port := range ports {
 		mappedPort, listenCloser, err := freeport.AllocateTCPPort()
 		if err != nil {
 			return portMap, fmt.Errorf("failed to get free host port: %w", err)
 		}
 		// Defer closing of the listening port until the function is done and all ports are
 		// allocated
 		defer listenCloser.Close()
 		portMap[port] = mappedPort
 	}
 	return portMap, nil
 }

 // Gets a random EUI-48 Ethernet MAC address
 func generateRandomEthernetMAC() (*net.HardwareAddr, error) {
 	macBuf := make([]byte, 6)
 	_, err := rand.Read(macBuf)
 	if err != nil {
 		return nil, fmt.Errorf("failed to read randomness for MAC: %v", err)
 	}

 	// Set U/L bit and clear I/G bit (locally administered individual MAC)
 	// Ref IEEE 802-2014 Section 8.2.2
 	macBuf[0] = (macBuf[0] | 2) & 0xfe
 	mac := net.HardwareAddr(macBuf)
 	return &mac, nil
 }

 // Launch launches a Metropolis node instance with the given options. The instance
 // runs mostly paravirtualized but with some emulated hardware similar to how a
 // cloud provider might set up its VMs. The disk is fully writable but is run in
 // snapshot mode meaning that changes are not kept beyond a single invocation.
 func Launch(ctx context.Context, options Options) error {
 	// Pin temp directory to /tmp until we can use abstract socket namespace in QEMU
 	// (next release after 5.0,
 	// https://github.com/qemu/qemu/commit/776b97d3605ed0fc94443048fdf988c7725e38a9).
 	// swtpm accepts already-open FDs so we can pass in an abstract socket namespace FD
 	// that we open and pass the name of it to QEMU. Not pinning this crashes both
 	// swtpm and qemu because we run into UNIX socket length limitations (for legacy
 	// reasons 108 chars).
 	tempDir, err := ioutil.TempDir("/tmp", "launch*")
 	if err != nil {
 		return fmt.Errorf("failed to create temporary directory: %w", err)
 	}
 	defer os.RemoveAll(tempDir)

 	// Copy TPM state into a temporary directory since it's being modified by the
 	// emulator
 	tpmTargetDir := filepath.Join(tempDir, "tpm")
 	tpmSrcDir := "metropolis/node/tpm"
 	if err := os.Mkdir(tpmTargetDir, 0755); err != nil {
 		return fmt.Errorf("failed to create TPM state directory: %w", err)
 	}
 	tpmFiles, err := ioutil.ReadDir(tpmSrcDir)
 	if err != nil {
 		return fmt.Errorf("failed to read TPM directory: %w", err)
 	}
 	for _, file := range tpmFiles {
 		name := file.Name()
 		src := filepath.Join(tpmSrcDir, name)
 		target := filepath.Join(tpmTargetDir, name)
 		if err := copyFile(src, target); err != nil {
 			return fmt.Errorf("failed to copy TPM directory: file %q to %q: %w", src, target, err)
 		}
 	}

 	var qemuNetType string
 	var qemuNetConfig qemuValue
 	if options.ConnectToSocket != nil {
 		qemuNetType = "socket"
 		qemuNetConfig = qemuValue{
 			"id": {"net0"},
 			"fd": {"3"},
 		}
 	} else {
 		qemuNetType = "user"
 		qemuNetConfig = qemuValue{
 			"id":        {"net0"},
 			"net":       {"10.42.0.0/24"},
 			"dhcpstart": {"10.42.0.10"},
 			"hostfwd":   options.Ports.toQemuForwards(),
 		}
 	}

 	tpmSocketPath := filepath.Join(tempDir, "tpm-socket")

 	mac, err := generateRandomEthernetMAC()
 	if err != nil {
 		return err
 	}

 	qemuArgs := []string{"-machine", "q35", "-accel", "kvm", "-nographic", "-nodefaults", "-m", "4096",
 		"-cpu", "host", "-smp", "sockets=1,cpus=1,cores=2,threads=2,maxcpus=4",
 		"-drive", "if=pflash,format=raw,readonly,file=external/edk2/OVMF_CODE.fd",
 		"-drive", "if=pflash,format=raw,snapshot=on,file=external/edk2/OVMF_VARS.fd",
 		"-drive", "if=virtio,format=raw,snapshot=on,cache=unsafe,file=metropolis/node/node.img",
 		"-netdev", qemuNetConfig.toOption(qemuNetType),
 		"-device", "virtio-net-pci,netdev=net0,mac=" + mac.String(),
 		"-chardev", "socket,id=chrtpm,path=" + tpmSocketPath,
 		"-tpmdev", "emulator,id=tpm0,chardev=chrtpm",
 		"-device", "tpm-tis,tpmdev=tpm0",
 		"-device", "virtio-rng-pci",
 		"-serial", "stdio"}

 	if !options.AllowReboot {
 		qemuArgs = append(qemuArgs, "-no-reboot")
 	}

 	if options.NodeParameters != nil {
 		parametersPath := filepath.Join(tempDir, "parameters.pb")
 		parametersRaw, err := proto.Marshal(options.NodeParameters)
 		if err != nil {
 			return fmt.Errorf("failed to encode node paraeters: %w", err)
 		}
 		if err := ioutil.WriteFile(parametersPath, parametersRaw, 0644); err != nil {
 			return fmt.Errorf("failed to write node parameters: %w", err)
 		}
 		qemuArgs = append(qemuArgs, "-fw_cfg", "name=dev.monogon.metropolis/parameters.pb,file="+parametersPath)
 	}

 	// Start TPM emulator as a subprocess
 	tpmCtx, tpmCancel := context.WithCancel(ctx)
 	defer tpmCancel()

 	tpmEmuCmd := exec.CommandContext(tpmCtx, "swtpm", "socket", "--tpm2", "--tpmstate", "dir="+tpmTargetDir, "--ctrl", "type=unixio,path="+tpmSocketPath)
 	tpmEmuCmd.Stderr = os.Stderr
 	tpmEmuCmd.Stdout = os.Stdout

 	err = tpmEmuCmd.Start()
 	if err != nil {
 		return fmt.Errorf("failed to start TPM emulator: %w", err)
 	}

 	// Start the main qemu binary
 	systemCmd := exec.CommandContext(ctx, "qemu-system-x86_64", qemuArgs...)
 	if options.ConnectToSocket != nil {
 		systemCmd.ExtraFiles = []*os.File{options.ConnectToSocket}
 	}

 	var stdErrBuf bytes.Buffer
 	systemCmd.Stderr = &stdErrBuf
 	systemCmd.Stdout = options.SerialPort

 	err = systemCmd.Run()

 	// Stop TPM emulator and wait for it to exit to properly reap the child process
 	tpmCancel()
 	log.Print("Waiting for TPM emulator to exit")
 	// Wait returns a SIGKILL error because we just cancelled its context.
 	// We still need to call it to avoid creating zombies.
 	_ = tpmEmuCmd.Wait()

 	var exerr *exec.ExitError
 	if err != nil && errors.As(err, &exerr) {
 		status := exerr.ProcessState.Sys().(syscall.WaitStatus)
 		if status.Signaled() && status.Signal() == syscall.SIGKILL {
 			// Process was killed externally (most likely by our context being canceled).
 			// This is a normal exit for us, so return nil
 			return nil
 		}
 		exerr.Stderr = stdErrBuf.Bytes()
 		newErr := QEMUError(*exerr)
 		return &newErr
 	}
 	return err
 }

 // NewSocketPair creates a new socket pair. By connecting both ends to different
 // instances you can connect them with a virtual "network cable". The ends can be
 // passed into the ConnectToSocket option.
 func NewSocketPair() (*os.File, *os.File, error) {
 	fds, err := unix.Socketpair(unix.AF_UNIX, syscall.SOCK_STREAM, 0)
 	if err != nil {
 		return nil, nil, fmt.Errorf("failed to call socketpair: %w", err)
 	}

 	fd1 := os.NewFile(uintptr(fds[0]), "network0")
 	fd2 := os.NewFile(uintptr(fds[1]), "network1")
 	return fd1, fd2, nil
 }

 // HostInterfaceMAC is the MAC address the host SLIRP network interface has if it
 // is not disabled (see DisableHostNetworkInterface in MicroVMOptions)
 var HostInterfaceMAC = net.HardwareAddr{0x02, 0x72, 0x82, 0xbf, 0xc3, 0x56}

 // MicroVMOptions contains all options to start a MicroVM
 type MicroVMOptions struct {
 	// Path to the ELF kernel binary
 	KernelPath string

 	// Path to the Initramfs
 	InitramfsPath string

 	// Cmdline contains additional kernel commandline options
 	Cmdline string

 	// SerialPort is a File(descriptor) over which you can communicate with the serial
 	// port of the machine It can be set to an existing file descriptor (like
 	// os.Stdout/os.Stderr) or you can use NewSocketPair() to get one end to talk to
 	// from Go.
 	SerialPort *os.File

 	// ExtraChardevs can be used similar to SerialPort, but can contain an arbitrary
 	// number of additional serial ports
 	ExtraChardevs []*os.File

 	// ExtraNetworkInterfaces can contain an arbitrary number of file descriptors which
 	// are mapped into the VM as virtio network interfaces. The first interface is
 	// always a SLIRP-backed interface for communicating with the host.
 	ExtraNetworkInterfaces []*os.File

 	// PortMap contains ports that are mapped to the host through the built-in SLIRP
 	// network interface.
 	PortMap PortMap

 	// DisableHostNetworkInterface disables the SLIRP-backed host network interface
 	// that is normally the first network interface. If this is set PortMap is ignored.
 	// Mostly useful for speeding up QEMU's startup time for tests.
 	DisableHostNetworkInterface bool
 }

 // RunMicroVM launches a tiny VM mostly intended for testing. Very quick to boot
 // (<40ms).
 func RunMicroVM(ctx context.Context, opts *MicroVMOptions) error {
 	// Generate options for all the file descriptors we'll be passing as virtio "serial
 	// ports"
 	var extraArgs []string
 	for idx, _ := range opts.ExtraChardevs {
 		idxStr := strconv.Itoa(idx)
 		id := "extra" + idxStr
 		// That this works is pretty much a hack, but upstream QEMU doesn't have a
 		// bidirectional chardev backend not based around files/sockets on the disk which
 		// are a giant pain to work with. We're using QEMU's fdset functionality to make
 		// FDs available as pseudo-files and then "ab"using the pipe backend's fallback
 		// functionality to get a single bidirectional chardev backend backed by a passed-
 		// down RDWR fd. Ref https://lists.gnu.org/archive/html/qemu-devel/2015-
 		// 12/msg01256.html
 		addFdConf := qemuValue{
 			"set": {idxStr},
 			"fd":  {strconv.Itoa(idx + 3)},
 		}
 		chardevConf := qemuValue{
 			"id":   {id},
 			"path": {"/dev/fdset/" + idxStr},
 		}
 		deviceConf := qemuValue{
 			"chardev": {id},
 		}
 		extraArgs = append(extraArgs, "-add-fd", addFdConf.toOption(""),
 			"-chardev", chardevConf.toOption("pipe"), "-device", deviceConf.toOption("virtserialport"))
 	}

 	for idx, _ := range opts.ExtraNetworkInterfaces {
 		id := fmt.Sprintf("net%v", idx)
 		netdevConf := qemuValue{
 			"id": {id},
 			"fd": {strconv.Itoa(idx + 3 + len(opts.ExtraChardevs))},
 		}
 		extraArgs = append(extraArgs, "-netdev", netdevConf.toOption("socket"), "-device", "virtio-net-device,netdev="+id)
 	}

 	// This sets up a minimum viable environment for our Linux kernel. It clears all
 	// standard QEMU configuration and sets up a MicroVM machine
 	// (https://github.com/qemu/qemu/blob/master/docs/microvm.rst) with all legacy
 	// emulation turned off. This means the only "hardware" the Linux kernel inside can
 	// communicate with is a single virtio-mmio region. Over that MMIO interface we run
 	// a paravirtualized RNG (since the kernel in there has nothing to gather that from
 	// and it delays booting), a single paravirtualized console and an arbitrary number
 	// of extra serial ports for talking to various things that might run inside. The
 	// kernel, initramfs and command line are mapped into VM memory at boot time and
 	// not loaded from any sort of disk. Booting and shutting off one of these VMs
 	// takes <100ms.
 	baseArgs := []string{"-nodefaults", "-no-user-config", "-nographic", "-no-reboot",
 		"-accel", "kvm", "-cpu", "host",
 		// Needed until QEMU updates their bundled qboot version (needs
 		// https://github.com/bonzini/qboot/pull/28)
 		"-bios", "external/com_github_bonzini_qboot/bios.bin",
 		"-M", "microvm,x-option-roms=off,pic=off,pit=off,rtc=off,isa-serial=off",
 		"-kernel", opts.KernelPath,
 		// We force using a triple-fault reboot strategy since otherwise the kernel first
 		// tries others (like ACPI) which are not available in this very restricted
 		// environment. Similarly we need to override the boot console since there's
 		// nothing on the ISA bus that the kernel could talk to. We also force quiet for
 		// performance reasons.
 		"-append", "reboot=t console=hvc0 quiet " + opts.Cmdline,
 		"-initrd", opts.InitramfsPath,
 		"-device", "virtio-rng-device,max-bytes=1024,period=1000",
 		"-device", "virtio-serial-device,max_ports=16",
 		"-chardev", "stdio,id=con0", "-device", "virtconsole,chardev=con0",
 	}

 	if !opts.DisableHostNetworkInterface {
 		qemuNetType := "user"
 		qemuNetConfig := qemuValue{
 			"id":        {"usernet0"},
 			"net":       {"10.42.0.0/24"},
 			"dhcpstart": {"10.42.0.10"},
 		}
 		if opts.PortMap != nil {
 			qemuNetConfig["hostfwd"] = opts.PortMap.toQemuForwards()
 		}

 		baseArgs = append(baseArgs, "-netdev", qemuNetConfig.toOption(qemuNetType),
 			"-device", "virtio-net-device,netdev=usernet0,mac="+HostInterfaceMAC.String())
 	}

 	var stdErrBuf bytes.Buffer
 	cmd := exec.CommandContext(ctx, "qemu-system-x86_64", append(baseArgs, extraArgs...)...)
 	cmd.Stdout = opts.SerialPort
 	cmd.Stderr = &stdErrBuf

 	cmd.ExtraFiles = append(cmd.ExtraFiles, opts.ExtraChardevs...)
 	cmd.ExtraFiles = append(cmd.ExtraFiles, opts.ExtraNetworkInterfaces...)

 	err := cmd.Run()
 	var exerr *exec.ExitError
 	if err != nil && errors.As(err, &exerr) {
 		exerr.Stderr = stdErrBuf.Bytes()
 		newErr := QEMUError(*exerr)
 		return &newErr
 	}
 	return err
 }

 // QEMUError is a special type of ExitError used when QEMU fails. In addition to
 // normal ExitError features it prints stderr for debugging.
 type QEMUError exec.ExitError

 func (e *QEMUError) Error() string {
 	return fmt.Sprintf("%v: %v", e.String(), string(e.Stderr))
 }

 // NanoswitchPorts contains all ports forwarded by Nanoswitch to the first VM
 var NanoswitchPorts = []uint16{
 	node.ExternalServicePort,
 	node.DebugServicePort,
 	node.KubernetesAPIPort,
 }

 // ClusterOptions contains all options for launching a Metropolis cluster
 type ClusterOptions struct {
 	// The number of nodes this cluster should be started with initially
 	NumNodes int
 }

 // LaunchCluster launches a cluster of Metropolis node VMs together with a
 // Nanoswitch instance to network them all together.
 func LaunchCluster(ctx context.Context, opts ClusterOptions) (apb.NodeDebugServiceClient, PortMap, error) {
 	var switchPorts []*os.File
 	var vmPorts []*os.File
 	for i := 0; i < opts.NumNodes; i++ {
 		switchPort, vmPort, err := NewSocketPair()
 		if err != nil {
 			return nil, nil, fmt.Errorf("failed to get socketpair: %w", err)
 		}
 		switchPorts = append(switchPorts, switchPort)
 		vmPorts = append(vmPorts, vmPort)
 	}

 	if opts.NumNodes == 0 {
 		return nil, nil, errors.New("refusing to start cluster with zero nodes")
 	}

 	if opts.NumNodes > 2 {
 		return nil, nil, errors.New("launching more than 2 nodes is unsupported pending replacement of golden tickets")
 	}

 	go func() {
 		if err := Launch(ctx, Options{
 			ConnectToSocket: vmPorts[0],
 			NodeParameters: &apb.NodeParameters{
 				Cluster: &apb.NodeParameters_ClusterBootstrap_{
 					ClusterBootstrap: &apb.NodeParameters_ClusterBootstrap{},
 				},
 			},
 		}); err != nil {

 			// Launch() only terminates when QEMU has terminated. At that point our function
 			// probably doesn't run anymore so we have no way of communicating the error back
 			// up, so let's just log it. Also a failure in launching VMs should be very visible
 			// by the unavailability of the clients we return.
 			log.Printf("Failed to launch vm0: %v", err)
 		}
 	}()

 	portMap, err := ConflictFreePortMap(NanoswitchPorts)
 	if err != nil {
 		return nil, nil, fmt.Errorf("failed to allocate ephemeral ports: %w", err)
 	}

 	go func() {
 		if err := RunMicroVM(ctx, &MicroVMOptions{
 			KernelPath:             "metropolis/test/ktest/vmlinux",
 			InitramfsPath:          "metropolis/test/nanoswitch/initramfs.lz4",
 			ExtraNetworkInterfaces: switchPorts,
 			PortMap:                portMap,
 		}); err != nil {
 			log.Printf("Failed to launch nanoswitch: %v", err)
 		}
 	}()
 	copts := []grpcretry.CallOption{
 		grpcretry.WithBackoff(grpcretry.BackoffExponential(100 * time.Millisecond)),
 	}
 	conn, err := portMap.DialGRPC(node.DebugServicePort, grpc.WithInsecure(),
 		grpc.WithUnaryInterceptor(grpcretry.UnaryClientInterceptor(copts...)))
 	if err != nil {
 		return nil, nil, fmt.Errorf("failed to dial debug service: %w", err)
 	}
 	debug := apb.NewNodeDebugServiceClient(conn)

 	if opts.NumNodes == 2 {
 		return nil, nil, fmt.Errorf("multinode unimplemented")
 	}

 	return debug, portMap, nil
 }
	// Copyright 2020 The Monogon Project Authors.
	//
	// SPDX-License-Identifier: Apache-2.0
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	package launch

	import (
	"bytes"
	"context"
	"crypto/rand"
	"errors"
	"fmt"
	"io"
	"io/ioutil"
	"log"
	"net"
	"os"
	"os/exec"
	"path/filepath"
	"strconv"
	"strings"
	"syscall"
	"time"

	"github.com/golang/protobuf/proto"
	grpcretry "github.com/grpc-ecosystem/go-grpc-middleware/retry"
	"golang.org/x/sys/unix"
	"google.golang.org/grpc"

	"source.monogon.dev/metropolis/node"
	"source.monogon.dev/metropolis/pkg/freeport"
	apb "source.monogon.dev/metropolis/proto/api"
	)

	type qemuValue map[string][]string

	// toOption encodes structured data into a QEMU option. Example: "test", {"key1":
	// {"val1"}, "key2": {"val2", "val3"}} returns "test,key1=val1,key2=val2,key2=val3"
	func (value qemuValue) toOption(name string) string {
	var optionValues []string
	if name != "" {
	optionValues = append(optionValues, name)
	}
	for name, values := range value {
	if len(values) == 0 {
	optionValues = append(optionValues, name)
	}
	for _, val := range values {
	optionValues = append(optionValues, fmt.Sprintf("%v=%v", name, val))
	}
	}
	return strings.Join(optionValues, ",")
	}

	func copyFile(src, dst string) error {
	in, err := os.Open(src)
	if err != nil {
	return fmt.Errorf("when opening source: %w", err)
	}
	defer in.Close()

	out, err := os.Create(dst)
	if err != nil {
	return fmt.Errorf("when creating destination: %w", err)
	}
	defer out.Close()

	_, err = io.Copy(out, in)
	if err != nil {
	return fmt.Errorf("when copying file: %w", err)
	}
	return out.Close()
	}

	// PortMap represents where VM ports are mapped to on the host. It maps from the VM
	// port number to the host port number.
	type PortMap map[uint16]uint16

	// toQemuForwards generates QEMU hostfwd values (https://qemu.weilnetz.de/doc/qemu-
	// doc.html#:~:text=hostfwd=) for all mapped ports.
	func (p PortMap) toQemuForwards() []string {
	var hostfwdOptions []string
	for vmPort, hostPort := range p {
	hostfwdOptions = append(hostfwdOptions, fmt.Sprintf("tcp::%v-:%v", hostPort, vmPort))
	}
	return hostfwdOptions
	}

	// DialGRPC creates a gRPC client for a VM port that's forwarded/mapped to the
	// host. The given port is automatically resolved to the host-mapped port.
	func (p PortMap) DialGRPC(port uint16, opts ...grpc.DialOption) (*grpc.ClientConn, error) {
	mappedPort, ok := p[port]
	if !ok {
	return nil, fmt.Errorf("cannot dial port: port %v is not mapped/forwarded", port)
	}
	grpcClient, err := grpc.Dial(fmt.Sprintf("localhost:%v", mappedPort), opts...)
	if err != nil {
	return nil, fmt.Errorf("failed to dial port %v: %w", port, err)
	}
	return grpcClient, nil
	}

	// Options contains all options that can be passed to Launch()
	type Options struct {
	// Ports contains the port mapping where to expose the internal ports of the VM to
	// the host. See IdentityPortMap() and ConflictFreePortMap(). Ignored when
	// ConnectToSocket is set.
	Ports PortMap

	// If set to true, reboots are honored. Otherwise all reboots exit the Launch()
	// command. Metropolis nodes generally restarts on almost all errors, so unless you
	// want to test reboot behavior this should be false.
	AllowReboot bool

	// By default the VM is connected to the Host via SLIRP. If ConnectToSocket is set,
	// it is instead connected to the given file descriptor/socket. If this is set, all
	// port maps from the Ports option are ignored. Intended for networking this
	// instance together with others for running more complex network configurations.
	ConnectToSocket *os.File

	// SerialPort is a io.ReadWriter over which you can communicate with the serial
	// port of the machine It can be set to an existing file descriptor (like
	// os.Stdout/os.Stderr) or any Go structure implementing this interface.
	SerialPort io.ReadWriter

	// NodeParameters is passed into the VM and subsequently used for bootstrapping or
	// registering into a cluster.
	NodeParameters *apb.NodeParameters
	}

	// NodePorts is the list of ports a fully operational Metropolis node listens on
	var NodePorts = []uint16{node.ConsensusPort, node.NodeServicePort, node.MasterServicePort,
	node.ExternalServicePort, node.DebugServicePort, node.KubernetesAPIPort, node.DebuggerPort}

	// IdentityPortMap returns a port map where each given port is mapped onto itself
	// on the host. This is mainly useful for development against Metropolis. The dbg
	// command requires this mapping.
	func IdentityPortMap(ports []uint16) PortMap {
	portMap := make(PortMap)
	for _, port := range ports {
	portMap[port] = port
	}
	return portMap
	}

	// ConflictFreePortMap returns a port map where each given port is mapped onto a
	// random free port on the host. This is intended for automated testing where
	// multiple instances of Metropolis nodes might be running. Please call this
	// function for each Launch command separately and as close to it as possible since
	// it cannot guarantee that the ports will remain free.
	func ConflictFreePortMap(ports []uint16) (PortMap, error) {
	portMap := make(PortMap)
	for _, port := range ports {
	mappedPort, listenCloser, err := freeport.AllocateTCPPort()
	if err != nil {
	return portMap, fmt.Errorf("failed to get free host port: %w", err)
	}
	// Defer closing of the listening port until the function is done and all ports are
	// allocated
	defer listenCloser.Close()
	portMap[port] = mappedPort
	}
	return portMap, nil
	}

	// Gets a random EUI-48 Ethernet MAC address
	func generateRandomEthernetMAC() (*net.HardwareAddr, error) {
	macBuf := make([]byte, 6)
	_, err := rand.Read(macBuf)
	if err != nil {
	return nil, fmt.Errorf("failed to read randomness for MAC: %v", err)
	}

	// Set U/L bit and clear I/G bit (locally administered individual MAC)
	// Ref IEEE 802-2014 Section 8.2.2
	macBuf[0] = (macBuf[0] \| 2) & 0xfe
	mac := net.HardwareAddr(macBuf)
	return &mac, nil
	}

	// Launch launches a Metropolis node instance with the given options. The instance
	// runs mostly paravirtualized but with some emulated hardware similar to how a
	// cloud provider might set up its VMs. The disk is fully writable but is run in
	// snapshot mode meaning that changes are not kept beyond a single invocation.
	func Launch(ctx context.Context, options Options) error {
	// Pin temp directory to /tmp until we can use abstract socket namespace in QEMU
	// (next release after 5.0,
	// https://github.com/qemu/qemu/commit/776b97d3605ed0fc94443048fdf988c7725e38a9).
	// swtpm accepts already-open FDs so we can pass in an abstract socket namespace FD
	// that we open and pass the name of it to QEMU. Not pinning this crashes both
	// swtpm and qemu because we run into UNIX socket length limitations (for legacy
	// reasons 108 chars).
	tempDir, err := ioutil.TempDir("/tmp", "launch*")
	if err != nil {
	return fmt.Errorf("failed to create temporary directory: %w", err)
	}
	defer os.RemoveAll(tempDir)

	// Copy TPM state into a temporary directory since it's being modified by the
	// emulator
	tpmTargetDir := filepath.Join(tempDir, "tpm")
	tpmSrcDir := "metropolis/node/tpm"
	if err := os.Mkdir(tpmTargetDir, 0755); err != nil {
	return fmt.Errorf("failed to create TPM state directory: %w", err)
	}
	tpmFiles, err := ioutil.ReadDir(tpmSrcDir)
	if err != nil {
	return fmt.Errorf("failed to read TPM directory: %w", err)
	}
	for _, file := range tpmFiles {
	name := file.Name()
	src := filepath.Join(tpmSrcDir, name)
	target := filepath.Join(tpmTargetDir, name)
	if err := copyFile(src, target); err != nil {
	return fmt.Errorf("failed to copy TPM directory: file %q to %q: %w", src, target, err)
	}
	}

	var qemuNetType string
	var qemuNetConfig qemuValue
	if options.ConnectToSocket != nil {
	qemuNetType = "socket"
	qemuNetConfig = qemuValue{
	"id": {"net0"},
	"fd": {"3"},
	}
	} else {
	qemuNetType = "user"
	qemuNetConfig = qemuValue{
	"id": {"net0"},
	"net": {"10.42.0.0/24"},
	"dhcpstart": {"10.42.0.10"},
	"hostfwd": options.Ports.toQemuForwards(),
	}
	}

	tpmSocketPath := filepath.Join(tempDir, "tpm-socket")

	mac, err := generateRandomEthernetMAC()
	if err != nil {
	return err
	}

	qemuArgs := []string{"-machine", "q35", "-accel", "kvm", "-nographic", "-nodefaults", "-m", "4096",
	"-cpu", "host", "-smp", "sockets=1,cpus=1,cores=2,threads=2,maxcpus=4",
	"-drive", "if=pflash,format=raw,readonly,file=external/edk2/OVMF_CODE.fd",
	"-drive", "if=pflash,format=raw,snapshot=on,file=external/edk2/OVMF_VARS.fd",
	"-drive", "if=virtio,format=raw,snapshot=on,cache=unsafe,file=metropolis/node/node.img",
	"-netdev", qemuNetConfig.toOption(qemuNetType),
	"-device", "virtio-net-pci,netdev=net0,mac=" + mac.String(),
	"-chardev", "socket,id=chrtpm,path=" + tpmSocketPath,
	"-tpmdev", "emulator,id=tpm0,chardev=chrtpm",
	"-device", "tpm-tis,tpmdev=tpm0",
	"-device", "virtio-rng-pci",
	"-serial", "stdio"}

	if !options.AllowReboot {
	qemuArgs = append(qemuArgs, "-no-reboot")
	}

	if options.NodeParameters != nil {
	parametersPath := filepath.Join(tempDir, "parameters.pb")
	parametersRaw, err := proto.Marshal(options.NodeParameters)
	if err != nil {
	return fmt.Errorf("failed to encode node paraeters: %w", err)
	}
	if err := ioutil.WriteFile(parametersPath, parametersRaw, 0644); err != nil {
	return fmt.Errorf("failed to write node parameters: %w", err)
	}
	qemuArgs = append(qemuArgs, "-fw_cfg", "name=dev.monogon.metropolis/parameters.pb,file="+parametersPath)
	}

	// Start TPM emulator as a subprocess
	tpmCtx, tpmCancel := context.WithCancel(ctx)
	defer tpmCancel()

	tpmEmuCmd := exec.CommandContext(tpmCtx, "swtpm", "socket", "--tpm2", "--tpmstate", "dir="+tpmTargetDir, "--ctrl", "type=unixio,path="+tpmSocketPath)
	tpmEmuCmd.Stderr = os.Stderr
	tpmEmuCmd.Stdout = os.Stdout

	err = tpmEmuCmd.Start()
	if err != nil {
	return fmt.Errorf("failed to start TPM emulator: %w", err)
	}

	// Start the main qemu binary
	systemCmd := exec.CommandContext(ctx, "qemu-system-x86_64", qemuArgs...)
	if options.ConnectToSocket != nil {
	systemCmd.ExtraFiles = []*os.File{options.ConnectToSocket}
	}

	var stdErrBuf bytes.Buffer
	systemCmd.Stderr = &stdErrBuf
	systemCmd.Stdout = options.SerialPort

	err = systemCmd.Run()

	// Stop TPM emulator and wait for it to exit to properly reap the child process
	tpmCancel()
	log.Print("Waiting for TPM emulator to exit")
	// Wait returns a SIGKILL error because we just cancelled its context.
	// We still need to call it to avoid creating zombies.
	_ = tpmEmuCmd.Wait()

	var exerr *exec.ExitError
	if err != nil && errors.As(err, &exerr) {
	status := exerr.ProcessState.Sys().(syscall.WaitStatus)
	if status.Signaled() && status.Signal() == syscall.SIGKILL {
	// Process was killed externally (most likely by our context being canceled).
	// This is a normal exit for us, so return nil
	return nil
	}
	exerr.Stderr = stdErrBuf.Bytes()
	newErr := QEMUError(*exerr)
	return &newErr
	}
	return err
	}

	// NewSocketPair creates a new socket pair. By connecting both ends to different
	// instances you can connect them with a virtual "network cable". The ends can be
	// passed into the ConnectToSocket option.
	func NewSocketPair() (os.File, os.File, error) {
	fds, err := unix.Socketpair(unix.AF_UNIX, syscall.SOCK_STREAM, 0)
	if err != nil {
	return nil, nil, fmt.Errorf("failed to call socketpair: %w", err)
	}

	fd1 := os.NewFile(uintptr(fds[0]), "network0")
	fd2 := os.NewFile(uintptr(fds[1]), "network1")
	return fd1, fd2, nil
	}

	// HostInterfaceMAC is the MAC address the host SLIRP network interface has if it
	// is not disabled (see DisableHostNetworkInterface in MicroVMOptions)
	var HostInterfaceMAC = net.HardwareAddr{0x02, 0x72, 0x82, 0xbf, 0xc3, 0x56}

	// MicroVMOptions contains all options to start a MicroVM
	type MicroVMOptions struct {
	// Path to the ELF kernel binary
	KernelPath string

	// Path to the Initramfs
	InitramfsPath string

	// Cmdline contains additional kernel commandline options
	Cmdline string

	// SerialPort is a File(descriptor) over which you can communicate with the serial
	// port of the machine It can be set to an existing file descriptor (like
	// os.Stdout/os.Stderr) or you can use NewSocketPair() to get one end to talk to
	// from Go.
	SerialPort *os.File

	// ExtraChardevs can be used similar to SerialPort, but can contain an arbitrary
	// number of additional serial ports
	ExtraChardevs []*os.File

	// ExtraNetworkInterfaces can contain an arbitrary number of file descriptors which
	// are mapped into the VM as virtio network interfaces. The first interface is
	// always a SLIRP-backed interface for communicating with the host.
	ExtraNetworkInterfaces []*os.File

	// PortMap contains ports that are mapped to the host through the built-in SLIRP
	// network interface.
	PortMap PortMap

	// DisableHostNetworkInterface disables the SLIRP-backed host network interface
	// that is normally the first network interface. If this is set PortMap is ignored.
	// Mostly useful for speeding up QEMU's startup time for tests.
	DisableHostNetworkInterface bool
	}

	// RunMicroVM launches a tiny VM mostly intended for testing. Very quick to boot
	// (<40ms).
	func RunMicroVM(ctx context.Context, opts *MicroVMOptions) error {
	// Generate options for all the file descriptors we'll be passing as virtio "serial
	// ports"
	var extraArgs []string
	for idx, _ := range opts.ExtraChardevs {
	idxStr := strconv.Itoa(idx)
	id := "extra" + idxStr
	// That this works is pretty much a hack, but upstream QEMU doesn't have a
	// bidirectional chardev backend not based around files/sockets on the disk which
	// are a giant pain to work with. We're using QEMU's fdset functionality to make
	// FDs available as pseudo-files and then "ab"using the pipe backend's fallback
	// functionality to get a single bidirectional chardev backend backed by a passed-
	// down RDWR fd. Ref https://lists.gnu.org/archive/html/qemu-devel/2015-
	// 12/msg01256.html
	addFdConf := qemuValue{
	"set": {idxStr},
	"fd": {strconv.Itoa(idx + 3)},
	}
	chardevConf := qemuValue{
	"id": {id},
	"path": {"/dev/fdset/" + idxStr},
	}
	deviceConf := qemuValue{
	"chardev": {id},
	}
	extraArgs = append(extraArgs, "-add-fd", addFdConf.toOption(""),
	"-chardev", chardevConf.toOption("pipe"), "-device", deviceConf.toOption("virtserialport"))
	}

	for idx, _ := range opts.ExtraNetworkInterfaces {
	id := fmt.Sprintf("net%v", idx)
	netdevConf := qemuValue{
	"id": {id},
	"fd": {strconv.Itoa(idx + 3 + len(opts.ExtraChardevs))},
	}
	extraArgs = append(extraArgs, "-netdev", netdevConf.toOption("socket"), "-device", "virtio-net-device,netdev="+id)
	}

	// This sets up a minimum viable environment for our Linux kernel. It clears all
	// standard QEMU configuration and sets up a MicroVM machine
	// (https://github.com/qemu/qemu/blob/master/docs/microvm.rst) with all legacy
	// emulation turned off. This means the only "hardware" the Linux kernel inside can
	// communicate with is a single virtio-mmio region. Over that MMIO interface we run
	// a paravirtualized RNG (since the kernel in there has nothing to gather that from
	// and it delays booting), a single paravirtualized console and an arbitrary number
	// of extra serial ports for talking to various things that might run inside. The
	// kernel, initramfs and command line are mapped into VM memory at boot time and
	// not loaded from any sort of disk. Booting and shutting off one of these VMs
	// takes <100ms.
	baseArgs := []string{"-nodefaults", "-no-user-config", "-nographic", "-no-reboot",
	"-accel", "kvm", "-cpu", "host",
	// Needed until QEMU updates their bundled qboot version (needs
	// https://github.com/bonzini/qboot/pull/28)
	"-bios", "external/com_github_bonzini_qboot/bios.bin",
	"-M", "microvm,x-option-roms=off,pic=off,pit=off,rtc=off,isa-serial=off",
	"-kernel", opts.KernelPath,
	// We force using a triple-fault reboot strategy since otherwise the kernel first
	// tries others (like ACPI) which are not available in this very restricted
	// environment. Similarly we need to override the boot console since there's
	// nothing on the ISA bus that the kernel could talk to. We also force quiet for
	// performance reasons.
	"-append", "reboot=t console=hvc0 quiet " + opts.Cmdline,
	"-initrd", opts.InitramfsPath,
	"-device", "virtio-rng-device,max-bytes=1024,period=1000",
	"-device", "virtio-serial-device,max_ports=16",
	"-chardev", "stdio,id=con0", "-device", "virtconsole,chardev=con0",
	}

	if !opts.DisableHostNetworkInterface {
	qemuNetType := "user"
	qemuNetConfig := qemuValue{
	"id": {"usernet0"},
	"net": {"10.42.0.0/24"},
	"dhcpstart": {"10.42.0.10"},
	}
	if opts.PortMap != nil {
	qemuNetConfig["hostfwd"] = opts.PortMap.toQemuForwards()
	}

	baseArgs = append(baseArgs, "-netdev", qemuNetConfig.toOption(qemuNetType),
	"-device", "virtio-net-device,netdev=usernet0,mac="+HostInterfaceMAC.String())
	}

	var stdErrBuf bytes.Buffer
	cmd := exec.CommandContext(ctx, "qemu-system-x86_64", append(baseArgs, extraArgs...)...)
	cmd.Stdout = opts.SerialPort
	cmd.Stderr = &stdErrBuf

	cmd.ExtraFiles = append(cmd.ExtraFiles, opts.ExtraChardevs...)
	cmd.ExtraFiles = append(cmd.ExtraFiles, opts.ExtraNetworkInterfaces...)

	err := cmd.Run()
	var exerr *exec.ExitError
	if err != nil && errors.As(err, &exerr) {
	exerr.Stderr = stdErrBuf.Bytes()
	newErr := QEMUError(*exerr)
	return &newErr
	}
	return err
	}

	// QEMUError is a special type of ExitError used when QEMU fails. In addition to
	// normal ExitError features it prints stderr for debugging.
	type QEMUError exec.ExitError

	func (e *QEMUError) Error() string {
	return fmt.Sprintf("%v: %v", e.String(), string(e.Stderr))
	}

	// NanoswitchPorts contains all ports forwarded by Nanoswitch to the first VM
	var NanoswitchPorts = []uint16{
	node.ExternalServicePort,
	node.DebugServicePort,
	node.KubernetesAPIPort,
	}

	// ClusterOptions contains all options for launching a Metropolis cluster
	type ClusterOptions struct {
	// The number of nodes this cluster should be started with initially
	NumNodes int
	}

	// LaunchCluster launches a cluster of Metropolis node VMs together with a
	// Nanoswitch instance to network them all together.
	func LaunchCluster(ctx context.Context, opts ClusterOptions) (apb.NodeDebugServiceClient, PortMap, error) {
	var switchPorts []*os.File
	var vmPorts []*os.File
	for i := 0; i < opts.NumNodes; i++ {
	switchPort, vmPort, err := NewSocketPair()
	if err != nil {
	return nil, nil, fmt.Errorf("failed to get socketpair: %w", err)
	}
	switchPorts = append(switchPorts, switchPort)
	vmPorts = append(vmPorts, vmPort)
	}

	if opts.NumNodes == 0 {
	return nil, nil, errors.New("refusing to start cluster with zero nodes")
	}

	if opts.NumNodes > 2 {
	return nil, nil, errors.New("launching more than 2 nodes is unsupported pending replacement of golden tickets")
	}

	go func() {
	if err := Launch(ctx, Options{
	ConnectToSocket: vmPorts[0],
	NodeParameters: &apb.NodeParameters{
	Cluster: &apb.NodeParameters_ClusterBootstrap_{
	ClusterBootstrap: &apb.NodeParameters_ClusterBootstrap{},
	},
	},
	}); err != nil {

	// Launch() only terminates when QEMU has terminated. At that point our function
	// probably doesn't run anymore so we have no way of communicating the error back
	// up, so let's just log it. Also a failure in launching VMs should be very visible
	// by the unavailability of the clients we return.
	log.Printf("Failed to launch vm0: %v", err)
	}
	}()

	portMap, err := ConflictFreePortMap(NanoswitchPorts)
	if err != nil {
	return nil, nil, fmt.Errorf("failed to allocate ephemeral ports: %w", err)
	}

	go func() {
	if err := RunMicroVM(ctx, &MicroVMOptions{
	KernelPath: "metropolis/test/ktest/vmlinux",
	InitramfsPath: "metropolis/test/nanoswitch/initramfs.lz4",
	ExtraNetworkInterfaces: switchPorts,
	PortMap: portMap,
	}); err != nil {
	log.Printf("Failed to launch nanoswitch: %v", err)
	}
	}()
	copts := []grpcretry.CallOption{
	grpcretry.WithBackoff(grpcretry.BackoffExponential(100 * time.Millisecond)),
	}
	conn, err := portMap.DialGRPC(node.DebugServicePort, grpc.WithInsecure(),
	grpc.WithUnaryInterceptor(grpcretry.UnaryClientInterceptor(copts...)))
	if err != nil {
	return nil, nil, fmt.Errorf("failed to dial debug service: %w", err)
	}
	debug := apb.NewNodeDebugServiceClient(conn)

	if opts.NumNodes == 2 {
	return nil, nil, fmt.Errorf("multinode unimplemented")
	}

	return debug, portMap, nil
	}