/* Copyright (c) Edgeless Systems GmbH SPDX-License-Identifier: AGPL-3.0-only */ // Package cryptmapper provides a wrapper around libcryptsetup to manage dm-crypt volumes for CSI drivers. package cryptmapper import ( "context" "errors" "fmt" "io/fs" "path/filepath" "strings" "sync" "time" "github.com/edgelesssys/constellation/v2/internal/crypto" ccryptsetup "github.com/edgelesssys/constellation/v2/internal/cryptsetup" cryptsetup "github.com/martinjungblut/go-cryptsetup" mount "k8s.io/mount-utils" utilexec "k8s.io/utils/exec" ) const ( // LUKSHeaderSize is the amount of bytes taken up by the header of a LUKS2 partition. // The header is 16MiB (1048576 Bytes * 16). LUKSHeaderSize = 16777216 cryptPrefix = "/dev/mapper/" integritySuffix = "_dif" integrityFSSuffix = "-integrity" keySizeIntegrity = 96 keySizeCrypt = 64 ) // packageLock is needed to block concurrent use of package functions, since libcryptsetup is not thread safe. // See: https://gitlab.com/cryptsetup/cryptsetup/-/issues/710 // // https://stackoverflow.com/questions/30553386/cryptsetup-backend-safe-with-multithreading var packageLock = sync.Mutex{} func init() { cryptsetup.SetDebugLevel(cryptsetup.CRYPT_LOG_NORMAL) cryptsetup.SetLogCallback(func(_ int, message string) { fmt.Printf("libcryptsetup: %s\n", message) }) } // KeyCreator is an interface to create data encryption keys. type KeyCreator interface { GetDEK(ctx context.Context, dekID string, dekSize int) ([]byte, error) } // DeviceMapper is an interface for device mapper methods. type DeviceMapper interface { // Init initializes a crypt device backed by 'devicePath'. // Sets the deviceMapper to the newly allocated Device or returns any error encountered. Init(devicePath string) error // InitByName initializes a crypt device from provided active device 'name'. // Sets the deviceMapper to the newly allocated Device or returns any error encountered. InitByName(name string) error // ActivateByPassphrase activates a device by using a passphrase from a specific keyslot. // Returns nil on success, or an error otherwise. ActivateByPassphrase(deviceName string, keyslot int, passphrase string, flags int) error // ActivateByVolumeKey activates a device by using a volume key. // Returns nil on success, or an error otherwise. ActivateByVolumeKey(deviceName string, volumeKey string, volumeKeySize int, flags int) error // Deactivate deactivates a device. // Returns nil on success, or an error otherwise. Deactivate(deviceName string) error // Format formats a Device, using a specific device type, and type-independent parameters. // Returns nil on success, or an error otherwise. Format(deviceType cryptsetup.DeviceType, genericParams cryptsetup.GenericParams) error // Free releases crypt device context and used memory. Free() bool // GetDeviceName gets the path to the underlying device. GetDeviceName() string // GetUUID gets the devices UUID GetUUID() string // Load loads crypt device parameters from the on-disk header. // Returns nil on success, or an error otherwise. Load(cryptsetup.DeviceType) error // KeyslotAddByVolumeKey adds a key slot using a volume key to perform the required security check. // Returns nil on success, or an error otherwise. KeyslotAddByVolumeKey(keyslot int, volumeKey string, passphrase string) error // Wipe removes existing data and clears the device for use with dm-integrity. // Returns nil on success, or an error otherwise. Wipe(devicePath string, pattern int, offset, length uint64, wipeBlockSize int, flags int, progress func(size, offset uint64) int) error // Resize the crypt device. // Returns nil on success, or an error otherwise. Resize(name string, newSize uint64) error } // CryptDevice is a wrapper for cryptsetup.Device. type CryptDevice struct { *cryptsetup.Device } // Init initializes a crypt device backed by 'devicePath'. // Sets the cryptDevice's deviceMapper to the newly allocated Device or returns any error encountered. func (c *CryptDevice) Init(devicePath string) error { device, err := cryptsetup.Init(devicePath) if err != nil { return err } c.Device = device return nil } // InitByName initializes a crypt device from provided active device 'name'. // Sets the deviceMapper to the newly allocated Device or returns any error encountered. func (c *CryptDevice) InitByName(name string) error { device, err := cryptsetup.InitByName(name) if err != nil { return err } c.Device = device return nil } // Free releases crypt device context and used memory. func (c *CryptDevice) Free() bool { res := c.Device.Free() c.Device = nil return res } // CryptMapper manages dm-crypt volumes. type CryptMapper struct { mapper DeviceMapper kms KeyCreator } // New initializes a new CryptMapper with the given kms client and key-encryption-key ID. // kms is used to fetch data encryption keys for the dm-crypt volumes. func New(kms KeyCreator, mapper DeviceMapper) *CryptMapper { return &CryptMapper{ mapper: mapper, kms: kms, } } // CloseCryptDevice closes the crypt device mapped for volumeID. // Returns nil if the volume does not exist. func (c *CryptMapper) CloseCryptDevice(volumeID string) error { source, err := filepath.EvalSymlinks(cryptPrefix + volumeID) if err != nil { var pathErr *fs.PathError if errors.As(err, &pathErr) { return nil } return fmt.Errorf("getting device path for disk %q: %w", cryptPrefix+volumeID, err) } if err := closeCryptDevice(c.mapper, source, volumeID, "crypt"); err != nil { return fmt.Errorf("closing crypt device: %w", err) } integrity, err := filepath.EvalSymlinks(cryptPrefix + volumeID + integritySuffix) if err == nil { // If device was created with integrity, we need to also close the integrity device integrityErr := closeCryptDevice(c.mapper, integrity, volumeID+integritySuffix, "integrity") if integrityErr != nil { return integrityErr } } if err != nil { var pathErr *fs.PathError if errors.As(err, &pathErr) { // integrity device does not exist return nil } return fmt.Errorf("getting device path for disk %q: %w", cryptPrefix+volumeID, err) } return nil } // OpenCryptDevice maps the volume at source to the crypt device identified by volumeID. // The key used to encrypt the volume is fetched using CryptMapper's kms client. func (c *CryptMapper) OpenCryptDevice(ctx context.Context, source, volumeID string, integrity bool) (string, error) { m := &mount.SafeFormatAndMount{Exec: utilexec.New()} return openCryptDevice(ctx, c.mapper, source, volumeID, integrity, c.kms.GetDEK, m.GetDiskFormat) } // ResizeCryptDevice resizes the underlying crypt device and returns the mapped device path. func (c *CryptMapper) ResizeCryptDevice(ctx context.Context, volumeID string) (string, error) { if err := resizeCryptDevice(ctx, c.mapper, volumeID, c.kms.GetDEK); err != nil { return "", err } return cryptPrefix + volumeID, nil } // GetDevicePath returns the device path of a mapped crypt device. func (c *CryptMapper) GetDevicePath(volumeID string) (string, error) { return getDevicePath(c.mapper, strings.TrimPrefix(volumeID, cryptPrefix)) } // closeCryptDevice closes the crypt device mapped for volumeID. func closeCryptDevice(device DeviceMapper, source, volumeID, deviceType string) error { packageLock.Lock() defer packageLock.Unlock() if err := device.InitByName(volumeID); err != nil { return fmt.Errorf("initializing dm-%s to unmap device %q: %w", deviceType, source, err) } defer device.Free() if err := device.Deactivate(volumeID); err != nil { return fmt.Errorf("deactivating dm-%s volume %q for device %q: %w", deviceType, cryptPrefix+volumeID, source, err) } return nil } // openCryptDevice maps the volume at source to the crypt device identified by volumeID. func openCryptDevice(ctx context.Context, device DeviceMapper, source, volumeID string, integrity bool, getKey func(ctx context.Context, keyID string, keySize int) ([]byte, error), diskInfo func(disk string) (string, error), ) (string, error) { packageLock.Lock() defer packageLock.Unlock() var integrityType string keySize := keySizeCrypt if integrity { integrityType = "hmac(sha256)" keySize = keySizeIntegrity } // Initialize the block device if err := device.Init(source); err != nil { return "", fmt.Errorf("initializing dm-crypt to map device %q: %w", source, err) } defer device.Free() var passphrase []byte // Try to load LUKS headers // If this fails, the device is either not formatted at all, or already formatted with a different FS if err := device.Load(cryptsetup.LUKS2{}); err != nil { format, err := diskInfo(source) if err != nil { return "", fmt.Errorf("determining if disk is formatted: %w", err) } if format != "" { return "", fmt.Errorf("disk %q is already formatted as: %s", source, format) } // Device is not formatted, so we can safely create a new LUKS2 partition if err := device.Format( cryptsetup.LUKS2{ SectorSize: 4096, Integrity: integrityType, PBKDFType: &cryptsetup.PbkdfType{ // Use low memory recommendation from https://datatracker.ietf.org/doc/html/rfc9106#section-7 Type: "argon2id", TimeMs: 2000, Iterations: 3, ParallelThreads: 4, MaxMemoryKb: 65536, // ~64MiB }, }, cryptsetup.GenericParams{ Cipher: "aes", CipherMode: "xts-plain64", VolumeKeySize: keySize, }); err != nil { return "", fmt.Errorf("formatting device %q: %w", source, err) } uuid := device.GetUUID() passphrase, err = getKey(ctx, uuid, crypto.StateDiskKeyLength) if err != nil { return "", err } if len(passphrase) != crypto.StateDiskKeyLength { return "", fmt.Errorf("expected key length to be [%d] but got [%d]", crypto.StateDiskKeyLength, len(passphrase)) } // Add a new keyslot using the internal volume key if err := device.KeyslotAddByVolumeKey(0, "", string(passphrase)); err != nil { return "", fmt.Errorf("adding keyslot: %w", err) } if integrity { if err := performWipe(device, volumeID); err != nil { return "", fmt.Errorf("wiping device: %w", err) } } } else { uuid := device.GetUUID() passphrase, err = getKey(ctx, uuid, crypto.StateDiskKeyLength) if err != nil { return "", err } if len(passphrase) != crypto.StateDiskKeyLength { return "", fmt.Errorf("expected key length to be [%d] but got [%d]", crypto.StateDiskKeyLength, len(passphrase)) } } if err := device.ActivateByPassphrase(volumeID, 0, string(passphrase), ccryptsetup.ReadWriteQueueBypass); err != nil { return "", fmt.Errorf("trying to activate dm-crypt volume: %w", err) } return cryptPrefix + volumeID, nil } // performWipe handles setting up parameters and clearing the device for dm-integrity. func performWipe(device DeviceMapper, volumeID string) error { tmpDevice := "temporary-cryptsetup-" + volumeID // Active as temporary device if err := device.ActivateByVolumeKey(tmpDevice, "", 0, (cryptsetup.CRYPT_ACTIVATE_PRIVATE | cryptsetup.CRYPT_ACTIVATE_NO_JOURNAL)); err != nil { return fmt.Errorf("trying to activate temporary dm-crypt volume: %w", err) } // No terminal available, limit callbacks to once every 30 seconds to not fill up logs with large amount of progress updates ticker := time.NewTicker(30 * time.Second) firstReq := make(chan struct{}, 1) firstReq <- struct{}{} defer ticker.Stop() logProgress := func(size, offset uint64) { prog := (float64(offset) / float64(size)) * 100 fmt.Printf("Wipe in progress: %.2f%%\n", prog) } progressCallback := func(size, offset uint64) int { select { case <-firstReq: logProgress(size, offset) case <-ticker.C: logProgress(size, offset) default: } return 0 } // Wipe the device using the same options as used in cryptsetup: https://gitlab.com/cryptsetup/cryptsetup/-/blob/v2.4.3/src/cryptsetup.c#L1345 if err := device.Wipe(cryptPrefix+tmpDevice, cryptsetup.CRYPT_WIPE_ZERO, 0, 0, 1024*1024, 0, progressCallback); err != nil { return err } // Deactivate the temporary device if err := device.Deactivate(tmpDevice); err != nil { return fmt.Errorf("deactivating temporary volume: %w", err) } return nil } func resizeCryptDevice(ctx context.Context, device DeviceMapper, name string, getKey func(ctx context.Context, keyID string, keySize int) ([]byte, error), ) error { packageLock.Lock() defer packageLock.Unlock() if err := device.InitByName(name); err != nil { return fmt.Errorf("initializing device: %w", err) } defer device.Free() if err := device.Load(cryptsetup.LUKS2{}); err != nil { return fmt.Errorf("loading device: %w", err) } passphrase, err := getKey(ctx, device.GetUUID(), crypto.StateDiskKeyLength) if err != nil { return fmt.Errorf("getting key: %w", err) } if err := device.ActivateByPassphrase("", 0, string(passphrase), cryptsetup.CRYPT_ACTIVATE_KEYRING_KEY|ccryptsetup.ReadWriteQueueBypass); err != nil { return fmt.Errorf("activating keyring for crypt device %q with passphrase: %w", name, err) } if err := device.Resize(name, 0); err != nil { return fmt.Errorf("resizing device: %w", err) } return nil } func getDevicePath(device DeviceMapper, name string) (string, error) { packageLock.Lock() defer packageLock.Unlock() if err := device.InitByName(name); err != nil { return "", fmt.Errorf("initializing device: %w", err) } defer device.Free() deviceName := device.GetDeviceName() if deviceName == "" { return "", errors.New("unable to determine device name") } return deviceName, nil } // IsIntegrityFS checks if the fstype string contains an integrity suffix. // If yes, returns the trimmed fstype and true, fstype and false otherwise. func IsIntegrityFS(fstype string) (string, bool) { if strings.HasSuffix(fstype, integrityFSSuffix) { return strings.TrimSuffix(fstype, integrityFSSuffix), true } return fstype, false }