//go:build linux
// +build linux

/*
Copyright 2014 The Kubernetes Authors.

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 mount

import (
	"fmt"
	"os"
	"os/exec"
	"path/filepath"
	"strconv"
	"strings"
	"syscall"

	"k8s.io/klog/v2"
	utilexec "k8s.io/utils/exec"
	utilio "k8s.io/utils/io"
)

const (
	// Number of fields per line in /proc/mounts as per the fstab man page.
	expectedNumFieldsPerLine = 6
	// Location of the mount file to use
	procMountsPath = "/proc/mounts"
	// Location of the mountinfo file
	procMountInfoPath = "/proc/self/mountinfo"
	// 'fsck' found errors and corrected them
	fsckErrorsCorrected = 1
	// 'fsck' found errors but exited without correcting them
	fsckErrorsUncorrected = 4
)

// Mounter provides the default implementation of mount.Interface
// for the linux platform.  This implementation assumes that the
// kubelet is running in the host's root mount namespace.
type Mounter struct {
	mounterPath string
	withSystemd bool
}

// New returns a mount.Interface for the current system.
// It provides options to override the default mounter behavior.
// mounterPath allows using an alternative to `/bin/mount` for mounting.
func New(mounterPath string) Interface {
	return &Mounter{
		mounterPath: mounterPath,
		withSystemd: detectSystemd(),
	}
}

// Mount mounts source to target as fstype with given options. 'source' and 'fstype' must
// be an empty string in case it's not required, e.g. for remount, or for auto filesystem
// type, where kernel handles fstype for you. The mount 'options' is a list of options,
// currently come from mount(8), e.g. "ro", "remount", "bind", etc. If no more option is
// required, call Mount with an empty string list or nil.
func (mounter *Mounter) Mount(source string, target string, fstype string, options []string) error {
	return mounter.MountSensitive(source, target, fstype, options, nil)
}

// MountSensitive is the same as Mount() but this method allows
// sensitiveOptions to be passed in a separate parameter from the normal
// mount options and ensures the sensitiveOptions are never logged. This
// method should be used by callers that pass sensitive material (like
// passwords) as mount options.
func (mounter *Mounter) MountSensitive(source string, target string, fstype string, options []string, sensitiveOptions []string) error {
	// Path to mounter binary if containerized mounter is needed. Otherwise, it is set to empty.
	// All Linux distros are expected to be shipped with a mount utility that a support bind mounts.
	mounterPath := ""
	bind, bindOpts, bindRemountOpts, bindRemountOptsSensitive := MakeBindOptsSensitive(options, sensitiveOptions)
	if bind {
		err := mounter.doMount(mounterPath, defaultMountCommand, source, target, fstype, bindOpts, bindRemountOptsSensitive)
		if err != nil {
			return err
		}
		return mounter.doMount(mounterPath, defaultMountCommand, source, target, fstype, bindRemountOpts, bindRemountOptsSensitive)
	}
	// The list of filesystems that require containerized mounter on GCI image cluster
	fsTypesNeedMounter := map[string]struct{}{
		"nfs":       {},
		"glusterfs": {},
		"ceph":      {},
		"cifs":      {},
	}
	if _, ok := fsTypesNeedMounter[fstype]; ok {
		mounterPath = mounter.mounterPath
	}
	return mounter.doMount(mounterPath, defaultMountCommand, source, target, fstype, options, sensitiveOptions)
}

// doMount runs the mount command. mounterPath is the path to mounter binary if containerized mounter is used.
// sensitiveOptions is an extension of options except they will not be logged (because they may contain sensitive material)
func (mounter *Mounter) doMount(mounterPath string, mountCmd string, source string, target string, fstype string, options []string, sensitiveOptions []string) error {
	mountArgs, mountArgsLogStr := MakeMountArgsSensitive(source, target, fstype, options, sensitiveOptions)
	if len(mounterPath) > 0 {
		mountArgs = append([]string{mountCmd}, mountArgs...)
		mountArgsLogStr = mountCmd + " " + mountArgsLogStr
		mountCmd = mounterPath
	}

	if mounter.withSystemd {
		// Try to run mount via systemd-run --scope. This will escape the
		// service where kubelet runs and any fuse daemons will be started in a
		// specific scope. kubelet service than can be restarted without killing
		// these fuse daemons.
		//
		// Complete command line (when mounterPath is not used):
		// systemd-run --description=... --scope -- mount -t <type> <what> <where>
		//
		// Expected flow:
		// * systemd-run creates a transient scope (=~ cgroup) and executes its
		//   argument (/bin/mount) there.
		// * mount does its job, forks a fuse daemon if necessary and finishes.
		//   (systemd-run --scope finishes at this point, returning mount's exit
		//   code and stdout/stderr - thats one of --scope benefits).
		// * systemd keeps the fuse daemon running in the scope (i.e. in its own
		//   cgroup) until the fuse daemon dies (another --scope benefit).
		//   Kubelet service can be restarted and the fuse daemon survives.
		// * When the fuse daemon dies (e.g. during unmount) systemd removes the
		//   scope automatically.
		//
		// systemd-mount is not used because it's too new for older distros
		// (CentOS 7, Debian Jessie).
		mountCmd, mountArgs, mountArgsLogStr = AddSystemdScopeSensitive("systemd-run", target, mountCmd, mountArgs, mountArgsLogStr)
	} else {
		// No systemd-run on the host (or we failed to check it), assume kubelet
		// does not run as a systemd service.
		// No code here, mountCmd and mountArgs are already populated.
	}

	// Logging with sensitive mount options removed.
	klog.V(4).Infof("Mounting cmd (%s) with arguments (%s)", mountCmd, mountArgsLogStr)
	command := exec.Command(mountCmd, mountArgs...)
	output, err := command.CombinedOutput()
	if err != nil {
		klog.Errorf("Mount failed: %v\nMounting command: %s\nMounting arguments: %s\nOutput: %s\n", err, mountCmd, mountArgsLogStr, string(output))
		return fmt.Errorf("mount failed: %v\nMounting command: %s\nMounting arguments: %s\nOutput: %s",
			err, mountCmd, mountArgsLogStr, string(output))
	}
	return err
}

// detectSystemd returns true if OS runs with systemd as init. When not sure
// (permission errors, ...), it returns false.
// There may be different ways how to detect systemd, this one makes sure that
// systemd-runs (needed by Mount()) works.
func detectSystemd() bool {
	if _, err := exec.LookPath("systemd-run"); err != nil {
		klog.V(2).Infof("Detected OS without systemd")
		return false
	}
	// Try to run systemd-run --scope /bin/true, that should be enough
	// to make sure that systemd is really running and not just installed,
	// which happens when running in a container with a systemd-based image
	// but with different pid 1.
	cmd := exec.Command("systemd-run", "--description=Kubernetes systemd probe", "--scope", "true")
	output, err := cmd.CombinedOutput()
	if err != nil {
		klog.V(2).Infof("Cannot run systemd-run, assuming non-systemd OS")
		klog.V(4).Infof("systemd-run failed with: %v", err)
		klog.V(4).Infof("systemd-run output: %s", string(output))
		return false
	}
	klog.V(2).Infof("Detected OS with systemd")
	return true
}

// MakeMountArgs makes the arguments to the mount(8) command.
// options MUST not contain sensitive material (like passwords).
func MakeMountArgs(source, target, fstype string, options []string) (mountArgs []string) {
	mountArgs, _ = MakeMountArgsSensitive(source, target, fstype, options, nil /* sensitiveOptions */)
	return mountArgs
}

// MakeMountArgsSensitive makes the arguments to the mount(8) command.
// sensitiveOptions is an extension of options except they will not be logged (because they may contain sensitive material)
func MakeMountArgsSensitive(source, target, fstype string, options []string, sensitiveOptions []string) (mountArgs []string, mountArgsLogStr string) {
	// Build mount command as follows:
	//   mount [-t $fstype] [-o $options] [$source] $target
	mountArgs = []string{}
	mountArgsLogStr = ""
	if len(fstype) > 0 {
		mountArgs = append(mountArgs, "-t", fstype)
		mountArgsLogStr += strings.Join(mountArgs, " ")
	}
	if len(options) > 0 || len(sensitiveOptions) > 0 {
		combinedOptions := []string{}
		combinedOptions = append(combinedOptions, options...)
		combinedOptions = append(combinedOptions, sensitiveOptions...)
		mountArgs = append(mountArgs, "-o", strings.Join(combinedOptions, ","))
		// exclude sensitiveOptions from log string
		mountArgsLogStr += " -o " + sanitizedOptionsForLogging(options, sensitiveOptions)
	}
	if len(source) > 0 {
		mountArgs = append(mountArgs, source)
		mountArgsLogStr += " " + source
	}
	mountArgs = append(mountArgs, target)
	mountArgsLogStr += " " + target

	return mountArgs, mountArgsLogStr
}

// AddSystemdScope adds "system-run --scope" to given command line
// If args contains sensitive material, use AddSystemdScopeSensitive to construct
// a safe to log string.
func AddSystemdScope(systemdRunPath, mountName, command string, args []string) (string, []string) {
	descriptionArg := fmt.Sprintf("--description=Kubernetes transient mount for %s", mountName)
	systemdRunArgs := []string{descriptionArg, "--scope", "--", command}
	return systemdRunPath, append(systemdRunArgs, args...)
}

// AddSystemdScopeSensitive adds "system-run --scope" to given command line
// It also accepts takes a sanitized string containing mount arguments, mountArgsLogStr,
// and returns the string appended to the systemd command for logging.
func AddSystemdScopeSensitive(systemdRunPath, mountName, command string, args []string, mountArgsLogStr string) (string, []string, string) {
	descriptionArg := fmt.Sprintf("--description=Kubernetes transient mount for %s", mountName)
	systemdRunArgs := []string{descriptionArg, "--scope", "--", command}
	return systemdRunPath, append(systemdRunArgs, args...), strings.Join(systemdRunArgs, " ") + " " + mountArgsLogStr
}

// Unmount unmounts the target.
func (mounter *Mounter) Unmount(target string) error {
	klog.V(4).Infof("Unmounting %s", target)
	command := exec.Command("umount", target)
	output, err := command.CombinedOutput()
	if err != nil {
		return fmt.Errorf("unmount failed: %v\nUnmounting arguments: %s\nOutput: %s", err, target, string(output))
	}
	return nil
}

// List returns a list of all mounted filesystems.
func (*Mounter) List() ([]MountPoint, error) {
	return ListProcMounts(procMountsPath)
}

// IsLikelyNotMountPoint determines if a directory is not a mountpoint.
// It is fast but not necessarily ALWAYS correct. If the path is in fact
// a bind mount from one part of a mount to another it will not be detected.
// It also can not distinguish between mountpoints and symbolic links.
// mkdir /tmp/a /tmp/b; mount --bind /tmp/a /tmp/b; IsLikelyNotMountPoint("/tmp/b")
// will return true. When in fact /tmp/b is a mount point. If this situation
// is of interest to you, don't use this function...
func (mounter *Mounter) IsLikelyNotMountPoint(file string) (bool, error) {
	stat, err := os.Stat(file)
	if err != nil {
		return true, err
	}
	rootStat, err := os.Stat(filepath.Dir(strings.TrimSuffix(file, "/")))
	if err != nil {
		return true, err
	}
	// If the directory has a different device as parent, then it is a mountpoint.
	if stat.Sys().(*syscall.Stat_t).Dev != rootStat.Sys().(*syscall.Stat_t).Dev {
		return false, nil
	}

	return true, nil
}

// GetMountRefs finds all mount references to pathname, returns a
// list of paths. Path could be a mountpoint or a normal
// directory (for bind mount).
func (mounter *Mounter) GetMountRefs(pathname string) ([]string, error) {
	pathExists, pathErr := PathExists(pathname)
	if !pathExists {
		return []string{}, nil
	} else if IsCorruptedMnt(pathErr) {
		klog.Warningf("GetMountRefs found corrupted mount at %s, treating as unmounted path", pathname)
		return []string{}, nil
	} else if pathErr != nil {
		return nil, fmt.Errorf("error checking path %s: %v", pathname, pathErr)
	}
	realpath, err := filepath.EvalSymlinks(pathname)
	if err != nil {
		return nil, err
	}
	return SearchMountPoints(realpath, procMountInfoPath)
}

// checkAndRepairFileSystem checks and repairs filesystems using command fsck.
func (mounter *SafeFormatAndMount) checkAndRepairFilesystem(source string) error {
	klog.V(4).Infof("Checking for issues with fsck on disk: %s", source)
	args := []string{"-a", source}
	out, err := mounter.Exec.Command("fsck", args...).CombinedOutput()
	if err != nil {
		ee, isExitError := err.(utilexec.ExitError)
		switch {
		case err == utilexec.ErrExecutableNotFound:
			klog.Warningf("'fsck' not found on system; continuing mount without running 'fsck'.")
		case isExitError && ee.ExitStatus() == fsckErrorsCorrected:
			klog.Infof("Device %s has errors which were corrected by fsck.", source)
		case isExitError && ee.ExitStatus() == fsckErrorsUncorrected:
			return NewMountError(HasFilesystemErrors, "'fsck' found errors on device %s but could not correct them: %s", source, string(out))
		case isExitError && ee.ExitStatus() > fsckErrorsUncorrected:
			klog.Infof("`fsck` error %s", string(out))
		}
	}
	return nil
}

// formatAndMount uses unix utils to format and mount the given disk
func (mounter *SafeFormatAndMount) formatAndMountSensitive(source string, target string, fstype string, options []string, sensitiveOptions []string) error {
	readOnly := false
	for _, option := range options {
		if option == "ro" {
			readOnly = true
			break
		}
	}
	if !readOnly {
		// Check sensitiveOptions for ro
		for _, option := range sensitiveOptions {
			if option == "ro" {
				readOnly = true
				break
			}
		}
	}

	options = append(options, "defaults")
	mountErrorValue := UnknownMountError

	// Check if the disk is already formatted
	existingFormat, err := mounter.GetDiskFormat(source)
	if err != nil {
		return NewMountError(GetDiskFormatFailed, "failed to get disk format of disk %s: %v", source, err)
	}

	// Use 'ext4' as the default
	if len(fstype) == 0 {
		fstype = "ext4"
	}

	if existingFormat == "" {
		// Do not attempt to format the disk if mounting as readonly, return an error to reflect this.
		if readOnly {
			return NewMountError(UnformattedReadOnly, "cannot mount unformatted disk %s as we are manipulating it in read-only mode", source)
		}

		// Disk is unformatted so format it.
		args := []string{source}
		if fstype == "ext4" || fstype == "ext3" {
			args = []string{
				"-F",  // Force flag
				"-m0", // Zero blocks reserved for super-user
				source,
			}
		}

		klog.Infof("Disk %q appears to be unformatted, attempting to format as type: %q with options: %v", source, fstype, args)
		output, err := mounter.Exec.Command("mkfs."+fstype, args...).CombinedOutput()
		if err != nil {
			// Do not log sensitiveOptions only options
			sensitiveOptionsLog := sanitizedOptionsForLogging(options, sensitiveOptions)
			detailedErr := fmt.Sprintf("format of disk %q failed: type:(%q) target:(%q) options:(%q) errcode:(%v) output:(%v) ", source, fstype, target, sensitiveOptionsLog, err, string(output))
			klog.Error(detailedErr)
			return NewMountError(FormatFailed, detailedErr)
		}

		klog.Infof("Disk successfully formatted (mkfs): %s - %s %s", fstype, source, target)
	} else {
		if fstype != existingFormat {
			// Verify that the disk is formatted with filesystem type we are expecting
			mountErrorValue = FilesystemMismatch
			klog.Warningf("Configured to mount disk %s as %s but current format is %s, things might break", source, existingFormat, fstype)
		}

		if !readOnly {
			// Run check tools on the disk to fix repairable issues, only do this for formatted volumes requested as rw.
			err := mounter.checkAndRepairFilesystem(source)
			if err != nil {
				return err
			}
		}
	}

	// Mount the disk
	klog.V(4).Infof("Attempting to mount disk %s in %s format at %s", source, fstype, target)
	if err := mounter.MountSensitive(source, target, fstype, options, sensitiveOptions); err != nil {
		return NewMountError(mountErrorValue, err.Error())
	}

	return nil
}

// GetDiskFormat uses 'blkid' to see if the given disk is unformatted
func (mounter *SafeFormatAndMount) GetDiskFormat(disk string) (string, error) {
	args := []string{"-p", "-s", "TYPE", "-s", "PTTYPE", "-o", "export", disk}
	klog.V(4).Infof("Attempting to determine if disk %q is formatted using blkid with args: (%v)", disk, args)
	dataOut, err := mounter.Exec.Command("blkid", args...).CombinedOutput()
	output := string(dataOut)
	klog.V(4).Infof("Output: %q, err: %v", output, err)

	if err != nil {
		if exit, ok := err.(utilexec.ExitError); ok {
			if exit.ExitStatus() == 2 {
				// Disk device is unformatted.
				// For `blkid`, if the specified token (TYPE/PTTYPE, etc) was
				// not found, or no (specified) devices could be identified, an
				// exit code of 2 is returned.
				return "", nil
			}
		}
		klog.Errorf("Could not determine if disk %q is formatted (%v)", disk, err)
		return "", err
	}

	var fstype, pttype string

	lines := strings.Split(output, "\n")
	for _, l := range lines {
		if len(l) <= 0 {
			// Ignore empty line.
			continue
		}
		cs := strings.Split(l, "=")
		if len(cs) != 2 {
			return "", fmt.Errorf("blkid returns invalid output: %s", output)
		}
		// TYPE is filesystem type, and PTTYPE is partition table type, according
		// to https://www.kernel.org/pub/linux/utils/util-linux/v2.21/libblkid-docs/.
		if cs[0] == "TYPE" {
			fstype = cs[1]
		} else if cs[0] == "PTTYPE" {
			pttype = cs[1]
		}
	}

	if len(pttype) > 0 {
		klog.V(4).Infof("Disk %s detected partition table type: %s", disk, pttype)
		// Returns a special non-empty string as filesystem type, then kubelet
		// will not format it.
		return "unknown data, probably partitions", nil
	}

	return fstype, nil
}

// ListProcMounts is shared with NsEnterMounter
func ListProcMounts(mountFilePath string) ([]MountPoint, error) {
	content, err := utilio.ConsistentRead(mountFilePath, maxListTries)
	if err != nil {
		return nil, err
	}
	return parseProcMounts(content)
}

func parseProcMounts(content []byte) ([]MountPoint, error) {
	out := []MountPoint{}
	lines := strings.Split(string(content), "\n")
	for _, line := range lines {
		if line == "" {
			// the last split() item is empty string following the last \n
			continue
		}
		fields := strings.Fields(line)
		if len(fields) != expectedNumFieldsPerLine {
			// Do not log line in case it contains sensitive Mount options
			return nil, fmt.Errorf("wrong number of fields (expected %d, got %d)", expectedNumFieldsPerLine, len(fields))
		}

		mp := MountPoint{
			Device: fields[0],
			Path:   fields[1],
			Type:   fields[2],
			Opts:   strings.Split(fields[3], ","),
		}

		freq, err := strconv.Atoi(fields[4])
		if err != nil {
			return nil, err
		}
		mp.Freq = freq

		pass, err := strconv.Atoi(fields[5])
		if err != nil {
			return nil, err
		}
		mp.Pass = pass

		out = append(out, mp)
	}
	return out, nil
}

// SearchMountPoints finds all mount references to the source, returns a list of
// mountpoints.
// The source can be a mount point or a normal directory (bind mount). We
// didn't support device because there is no use case by now.
// Some filesystems may share a source name, e.g. tmpfs. And for bind mounting,
// it's possible to mount a non-root path of a filesystem, so we need to use
// root path and major:minor to represent mount source uniquely.
// This implementation is shared between Linux and NsEnterMounter
func SearchMountPoints(hostSource, mountInfoPath string) ([]string, error) {
	mis, err := ParseMountInfo(mountInfoPath)
	if err != nil {
		return nil, err
	}

	mountID := 0
	rootPath := ""
	major := -1
	minor := -1

	// Finding the underlying root path and major:minor if possible.
	// We need search in backward order because it's possible for later mounts
	// to overlap earlier mounts.
	for i := len(mis) - 1; i >= 0; i-- {
		if hostSource == mis[i].MountPoint || PathWithinBase(hostSource, mis[i].MountPoint) {
			// If it's a mount point or path under a mount point.
			mountID = mis[i].ID
			rootPath = filepath.Join(mis[i].Root, strings.TrimPrefix(hostSource, mis[i].MountPoint))
			major = mis[i].Major
			minor = mis[i].Minor
			break
		}
	}

	if rootPath == "" || major == -1 || minor == -1 {
		return nil, fmt.Errorf("failed to get root path and major:minor for %s", hostSource)
	}

	var refs []string
	for i := range mis {
		if mis[i].ID == mountID {
			// Ignore mount entry for mount source itself.
			continue
		}
		if mis[i].Root == rootPath && mis[i].Major == major && mis[i].Minor == minor {
			refs = append(refs, mis[i].MountPoint)
		}
	}

	return refs, nil
}