grub-lakitu/grub-core/disk/luks.c - cos/cobble - Git at Google

 /*
  *  GRUB  --  GRand Unified Bootloader
  *  Copyright (C) 2003,2007,2010,2011  Free Software Foundation, Inc.
  *
  *  GRUB is free software: you can redistribute it and/or modify
  *  it under the terms of the GNU General Public License as published by
  *  the Free Software Foundation, either version 3 of the License, or
  *  (at your option) any later version.
  *
  *  GRUB is distributed in the hope that it will be useful,
  *  but WITHOUT ANY WARRANTY; without even the implied warranty of
  *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  *  GNU General Public License for more details.
  *
  *  You should have received a copy of the GNU General Public License
  *  along with GRUB.  If not, see <http://www.gnu.org/licenses/>.
  */

 #include <grub/cryptodisk.h>
 #include <grub/types.h>
 #include <grub/misc.h>
 #include <grub/mm.h>
 #include <grub/dl.h>
 #include <grub/err.h>
 #include <grub/disk.h>
 #include <grub/crypto.h>
 #include <grub/partition.h>
 #include <grub/i18n.h>

 GRUB_MOD_LICENSE ("GPLv3+");

 #define MAX_PASSPHRASE 256

 #define LUKS_KEY_ENABLED  0x00AC71F3

 /* On disk LUKS header */
 struct grub_luks_phdr
 {
   grub_uint8_t magic[6];
 #define LUKS_MAGIC        "LUKS\xBA\xBE"
   grub_uint16_t version;
   char cipherName[32];
   char cipherMode[32];
   char hashSpec[32];
   grub_uint32_t payloadOffset;
   grub_uint32_t keyBytes;
   grub_uint8_t mkDigest[20];
   grub_uint8_t mkDigestSalt[32];
   grub_uint32_t mkDigestIterations;
   char uuid[40];
   struct
   {
     grub_uint32_t active;
     grub_uint32_t passwordIterations;
     grub_uint8_t passwordSalt[32];
     grub_uint32_t keyMaterialOffset;
     grub_uint32_t stripes;
   } keyblock[8];
 } GRUB_PACKED;

 typedef struct grub_luks_phdr *grub_luks_phdr_t;

 gcry_err_code_t AF_merge (const gcry_md_spec_t * hash, grub_uint8_t * src,
 			  grub_uint8_t * dst, grub_size_t blocksize,
 			  grub_size_t blocknumbers);

 static grub_cryptodisk_t
 configure_ciphers (grub_disk_t disk, const char *check_uuid,
 		   int check_boot)
 {
   grub_cryptodisk_t newdev;
   const char *iptr;
   struct grub_luks_phdr header;
   char *optr;
   char uuid[sizeof (header.uuid) + 1];
   char ciphername[sizeof (header.cipherName) + 1];
   char ciphermode[sizeof (header.cipherMode) + 1];
   char *cipheriv = NULL;
   char hashspec[sizeof (header.hashSpec) + 1];
   grub_crypto_cipher_handle_t cipher = NULL, secondary_cipher = NULL;
   grub_crypto_cipher_handle_t essiv_cipher = NULL;
   const gcry_md_spec_t *hash = NULL, *essiv_hash = NULL;
   const struct gcry_cipher_spec *ciph;
   grub_cryptodisk_mode_t mode;
   grub_cryptodisk_mode_iv_t mode_iv = GRUB_CRYPTODISK_MODE_IV_PLAIN64;
   int benbi_log = 0;
   grub_err_t err;

   if (check_boot)
     return NULL;

   /* Read the LUKS header.  */
   err = grub_disk_read (disk, 0, 0, sizeof (header), &header);
   if (err)
     {
       if (err == GRUB_ERR_OUT_OF_RANGE)
 	grub_errno = GRUB_ERR_NONE;
       return NULL;
     }

   /* Look for LUKS magic sequence.  */
   if (grub_memcmp (header.magic, LUKS_MAGIC, sizeof (header.magic))
       || grub_be_to_cpu16 (header.version) != 1)
     return NULL;

   optr = uuid;
   for (iptr = header.uuid; iptr < &header.uuid[ARRAY_SIZE (header.uuid)];
        iptr++)
     {
       if (*iptr != '-')
 	*optr++ = *iptr;
     }
   *optr = 0;

   if (check_uuid && grub_strcasecmp (check_uuid, uuid) != 0)
     {
       grub_dprintf ("luks", "%s != %s\n", uuid, check_uuid);
       return NULL;
     }

   /* Make sure that strings are null terminated.  */
   grub_memcpy (ciphername, header.cipherName, sizeof (header.cipherName));
   ciphername[sizeof (header.cipherName)] = 0;
   grub_memcpy (ciphermode, header.cipherMode, sizeof (header.cipherMode));
   ciphermode[sizeof (header.cipherMode)] = 0;
   grub_memcpy (hashspec, header.hashSpec, sizeof (header.hashSpec));
   hashspec[sizeof (header.hashSpec)] = 0;

   ciph = grub_crypto_lookup_cipher_by_name (ciphername);
   if (!ciph)
     {
       grub_error (GRUB_ERR_FILE_NOT_FOUND, "Cipher %s isn't available",
 		  ciphername);
       return NULL;
     }

   /* Configure the cipher used for the bulk data.  */
   cipher = grub_crypto_cipher_open (ciph);
   if (!cipher)
     return NULL;

   if (grub_be_to_cpu32 (header.keyBytes) > 1024)
     {
       grub_error (GRUB_ERR_BAD_ARGUMENT, "invalid keysize %d",
 		  grub_be_to_cpu32 (header.keyBytes));
       grub_crypto_cipher_close (cipher);
       return NULL;
     }

   /* Configure the cipher mode.  */
   if (grub_strcmp (ciphermode, "ecb") == 0)
     {
       mode = GRUB_CRYPTODISK_MODE_ECB;
       mode_iv = GRUB_CRYPTODISK_MODE_IV_PLAIN;
       cipheriv = NULL;
     }
   else if (grub_strcmp (ciphermode, "plain") == 0)
     {
       mode = GRUB_CRYPTODISK_MODE_CBC;
       mode_iv = GRUB_CRYPTODISK_MODE_IV_PLAIN;
       cipheriv = NULL;
     }
   else if (grub_memcmp (ciphermode, "cbc-", sizeof ("cbc-") - 1) == 0)
     {
       mode = GRUB_CRYPTODISK_MODE_CBC;
       cipheriv = ciphermode + sizeof ("cbc-") - 1;
     }
   else if (grub_memcmp (ciphermode, "pcbc-", sizeof ("pcbc-") - 1) == 0)
     {
       mode = GRUB_CRYPTODISK_MODE_PCBC;
       cipheriv = ciphermode + sizeof ("pcbc-") - 1;
     }
   else if (grub_memcmp (ciphermode, "xts-", sizeof ("xts-") - 1) == 0)
     {
       mode = GRUB_CRYPTODISK_MODE_XTS;
       cipheriv = ciphermode + sizeof ("xts-") - 1;
       secondary_cipher = grub_crypto_cipher_open (ciph);
       if (!secondary_cipher)
 	{
 	  grub_crypto_cipher_close (cipher);
 	  return NULL;
 	}
       if (cipher->cipher->blocksize != GRUB_CRYPTODISK_GF_BYTES)
 	{
 	  grub_error (GRUB_ERR_BAD_ARGUMENT, "Unsupported XTS block size: %d",
 		      cipher->cipher->blocksize);
 	  grub_crypto_cipher_close (cipher);
 	  grub_crypto_cipher_close (secondary_cipher);
 	  return NULL;
 	}
       if (secondary_cipher->cipher->blocksize != GRUB_CRYPTODISK_GF_BYTES)
 	{
 	  grub_crypto_cipher_close (cipher);
 	  grub_error (GRUB_ERR_BAD_ARGUMENT, "Unsupported XTS block size: %d",
 		      secondary_cipher->cipher->blocksize);
 	  grub_crypto_cipher_close (secondary_cipher);
 	  return NULL;
 	}
     }
   else if (grub_memcmp (ciphermode, "lrw-", sizeof ("lrw-") - 1) == 0)
     {
       mode = GRUB_CRYPTODISK_MODE_LRW;
       cipheriv = ciphermode + sizeof ("lrw-") - 1;
       if (cipher->cipher->blocksize != GRUB_CRYPTODISK_GF_BYTES)
 	{
 	  grub_error (GRUB_ERR_BAD_ARGUMENT, "Unsupported LRW block size: %d",
 		      cipher->cipher->blocksize);
 	  grub_crypto_cipher_close (cipher);
 	  return NULL;
 	}
     }
   else
     {
       grub_crypto_cipher_close (cipher);
       grub_error (GRUB_ERR_BAD_ARGUMENT, "Unknown cipher mode: %s",
 		  ciphermode);
       return NULL;
     }

   if (cipheriv == NULL);
   else if (grub_memcmp (cipheriv, "plain", sizeof ("plain") - 1) == 0)
       mode_iv = GRUB_CRYPTODISK_MODE_IV_PLAIN;
   else if (grub_memcmp (cipheriv, "plain64", sizeof ("plain64") - 1) == 0)
       mode_iv = GRUB_CRYPTODISK_MODE_IV_PLAIN64;
   else if (grub_memcmp (cipheriv, "benbi", sizeof ("benbi") - 1) == 0)
     {
       if (cipher->cipher->blocksize & (cipher->cipher->blocksize - 1)
 	  || cipher->cipher->blocksize == 0)
 	grub_error (GRUB_ERR_BAD_ARGUMENT, "Unsupported benbi blocksize: %d",
 		    cipher->cipher->blocksize);
 	/* FIXME should we return an error here? */
       for (benbi_log = 0;
 	   (cipher->cipher->blocksize << benbi_log) < GRUB_DISK_SECTOR_SIZE;
 	   benbi_log++);
       mode_iv = GRUB_CRYPTODISK_MODE_IV_BENBI;
     }
   else if (grub_memcmp (cipheriv, "null", sizeof ("null") - 1) == 0)
       mode_iv = GRUB_CRYPTODISK_MODE_IV_NULL;
   else if (grub_memcmp (cipheriv, "essiv:", sizeof ("essiv:") - 1) == 0)
     {
       char *hash_str = cipheriv + 6;

       mode_iv = GRUB_CRYPTODISK_MODE_IV_ESSIV;

       /* Configure the hash and cipher used for ESSIV.  */
       essiv_hash = grub_crypto_lookup_md_by_name (hash_str);
       if (!essiv_hash)
 	{
 	  grub_crypto_cipher_close (cipher);
 	  grub_crypto_cipher_close (secondary_cipher);
 	  grub_error (GRUB_ERR_FILE_NOT_FOUND,
 		      "Couldn't load %s hash", hash_str);
 	  return NULL;
 	}
       essiv_cipher = grub_crypto_cipher_open (ciph);
       if (!essiv_cipher)
 	{
 	  grub_crypto_cipher_close (cipher);
 	  grub_crypto_cipher_close (secondary_cipher);
 	  return NULL;
 	}
     }
   else
     {
       grub_crypto_cipher_close (cipher);
       grub_crypto_cipher_close (secondary_cipher);
       grub_error (GRUB_ERR_BAD_ARGUMENT, "Unknown IV mode: %s",
 		  cipheriv);
       return NULL;
     }

   /* Configure the hash used for the AF splitter and HMAC.  */
   hash = grub_crypto_lookup_md_by_name (hashspec);
   if (!hash)
     {
       grub_crypto_cipher_close (cipher);
       grub_crypto_cipher_close (essiv_cipher);
       grub_crypto_cipher_close (secondary_cipher);
       grub_error (GRUB_ERR_FILE_NOT_FOUND, "Couldn't load %s hash",
 		  hashspec);
       return NULL;
     }

   newdev = grub_zalloc (sizeof (struct grub_cryptodisk));
   if (!newdev)
     {
       grub_crypto_cipher_close (cipher);
       grub_crypto_cipher_close (essiv_cipher);
       grub_crypto_cipher_close (secondary_cipher);
       return NULL;
     }
   newdev->cipher = cipher;
   newdev->offset = grub_be_to_cpu32 (header.payloadOffset);
   newdev->source_disk = NULL;
   newdev->benbi_log = benbi_log;
   newdev->mode = mode;
   newdev->mode_iv = mode_iv;
   newdev->secondary_cipher = secondary_cipher;
   newdev->essiv_cipher = essiv_cipher;
   newdev->essiv_hash = essiv_hash;
   newdev->hash = hash;
   newdev->log_sector_size = 9;
   newdev->total_length = grub_disk_get_size (disk) - newdev->offset;
   grub_memcpy (newdev->uuid, uuid, sizeof (newdev->uuid));
   newdev->modname = "luks";
   COMPILE_TIME_ASSERT (sizeof (newdev->uuid) >= sizeof (uuid));
   return newdev;
 }

 static grub_err_t
 luks_recover_key (grub_disk_t source,
 		  grub_cryptodisk_t dev)
 {
   struct grub_luks_phdr header;
   grub_size_t keysize;
   grub_uint8_t *split_key = NULL;
   char passphrase[MAX_PASSPHRASE] = "";
   grub_uint8_t candidate_digest[sizeof (header.mkDigest)];
   unsigned i;
   grub_size_t length;
   grub_err_t err;
   grub_size_t max_stripes = 1;
   char *tmp;

   err = grub_disk_read (source, 0, 0, sizeof (header), &header);
   if (err)
     return err;

   grub_puts_ (N_("Attempting to decrypt master key..."));
   keysize = grub_be_to_cpu32 (header.keyBytes);
   if (keysize > GRUB_CRYPTODISK_MAX_KEYLEN)
     return grub_error (GRUB_ERR_BAD_FS, "key is too long");

   for (i = 0; i < ARRAY_SIZE (header.keyblock); i++)
     if (grub_be_to_cpu32 (header.keyblock[i].active) == LUKS_KEY_ENABLED
 	&& grub_be_to_cpu32 (header.keyblock[i].stripes) > max_stripes)
       max_stripes = grub_be_to_cpu32 (header.keyblock[i].stripes);

   split_key = grub_malloc (keysize * max_stripes);
   if (!split_key)
     return grub_errno;

   /* Get the passphrase from the user.  */
   tmp = NULL;
   if (source->partition)
     tmp = grub_partition_get_name (source->partition);
   grub_printf_ (N_("Enter passphrase for %s%s%s (%s): "), source->name,
 	       source->partition ? "," : "", tmp ? : "",
 	       dev->uuid);
   grub_free (tmp);
   if (!grub_password_get (passphrase, MAX_PASSPHRASE))
     {
       grub_free (split_key);
       return grub_error (GRUB_ERR_BAD_ARGUMENT, "Passphrase not supplied");
     }

   /* Try to recover master key from each active keyslot.  */
   for (i = 0; i < ARRAY_SIZE (header.keyblock); i++)
     {
       gcry_err_code_t gcry_err;
       grub_uint8_t candidate_key[GRUB_CRYPTODISK_MAX_KEYLEN];
       grub_uint8_t digest[GRUB_CRYPTODISK_MAX_KEYLEN];

       /* Check if keyslot is enabled.  */
       if (grub_be_to_cpu32 (header.keyblock[i].active) != LUKS_KEY_ENABLED)
 	continue;

       grub_dprintf ("luks", "Trying keyslot %d\n", i);

       /* Calculate the PBKDF2 of the user supplied passphrase.  */
       gcry_err = grub_crypto_pbkdf2 (dev->hash, (grub_uint8_t *) passphrase,
 				     grub_strlen (passphrase),
 				     header.keyblock[i].passwordSalt,
 				     sizeof (header.keyblock[i].passwordSalt),
 				     grub_be_to_cpu32 (header.keyblock[i].
 						       passwordIterations),
 				     digest, keysize);

       if (gcry_err)
 	{
 	  grub_free (split_key);
 	  return grub_crypto_gcry_error (gcry_err);
 	}

       grub_dprintf ("luks", "PBKDF2 done\n");

       gcry_err = grub_cryptodisk_setkey (dev, digest, keysize);
       if (gcry_err)
 	{
 	  grub_free (split_key);
 	  return grub_crypto_gcry_error (gcry_err);
 	}

       length = (keysize * grub_be_to_cpu32 (header.keyblock[i].stripes));

       /* Read and decrypt the key material from the disk.  */
       err = grub_disk_read (source,
 			    grub_be_to_cpu32 (header.keyblock
 					      [i].keyMaterialOffset), 0,
 			    length, split_key);
       if (err)
 	{
 	  grub_free (split_key);
 	  return err;
 	}

       gcry_err = grub_cryptodisk_decrypt (dev, split_key, length, 0);
       if (gcry_err)
 	{
 	  grub_free (split_key);
 	  return grub_crypto_gcry_error (gcry_err);
 	}

       /* Merge the decrypted key material to get the candidate master key.  */
       gcry_err = AF_merge (dev->hash, split_key, candidate_key, keysize,
 			   grub_be_to_cpu32 (header.keyblock[i].stripes));
       if (gcry_err)
 	{
 	  grub_free (split_key);
 	  return grub_crypto_gcry_error (gcry_err);
 	}

       grub_dprintf ("luks", "candidate key recovered\n");

       /* Calculate the PBKDF2 of the candidate master key.  */
       gcry_err = grub_crypto_pbkdf2 (dev->hash, candidate_key,
 				     grub_be_to_cpu32 (header.keyBytes),
 				     header.mkDigestSalt,
 				     sizeof (header.mkDigestSalt),
 				     grub_be_to_cpu32
 				     (header.mkDigestIterations),
 				     candidate_digest,
 				     sizeof (candidate_digest));
       if (gcry_err)
 	{
 	  grub_free (split_key);
 	  return grub_crypto_gcry_error (gcry_err);
 	}

       /* Compare the calculated PBKDF2 to the digest stored
          in the header to see if it's correct.  */
       if (grub_memcmp (candidate_digest, header.mkDigest,
 		       sizeof (header.mkDigest)) != 0)
 	{
 	  grub_dprintf ("luks", "bad digest\n");
 	  continue;
 	}

       /* TRANSLATORS: It's a cryptographic key slot: one element of an array
 	 where each element is either empty or holds a key.  */
       grub_printf_ (N_("Slot %d opened\n"), i);

       /* Set the master key.  */
       gcry_err = grub_cryptodisk_setkey (dev, candidate_key, keysize);
       if (gcry_err)
 	{
 	  grub_free (split_key);
 	  return grub_crypto_gcry_error (gcry_err);
 	}

       grub_free (split_key);

       return GRUB_ERR_NONE;
     }

   grub_free (split_key);
   return GRUB_ACCESS_DENIED;
 }

 struct grub_cryptodisk_dev luks_crypto = {
   .scan = configure_ciphers,
   .recover_key = luks_recover_key
 };

 GRUB_MOD_INIT (luks)
 {
   COMPILE_TIME_ASSERT (sizeof (((struct grub_luks_phdr *) 0)->uuid)
 		       < GRUB_CRYPTODISK_MAX_UUID_LENGTH);
   grub_cryptodisk_dev_register (&luks_crypto);
 }

 GRUB_MOD_FINI (luks)
 {
   grub_cryptodisk_dev_unregister (&luks_crypto);
 }
	/*
	* GRUB -- GRand Unified Bootloader
	* Copyright (C) 2003,2007,2010,2011 Free Software Foundation, Inc.
	*
	* GRUB is free software: you can redistribute it and/or modify
	* it under the terms of the GNU General Public License as published by
	* the Free Software Foundation, either version 3 of the License, or
	* (at your option) any later version.
	*
	* GRUB is distributed in the hope that it will be useful,
	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	* GNU General Public License for more details.
	*
	* You should have received a copy of the GNU General Public License
	* along with GRUB. If not, see <http://www.gnu.org/licenses/>.
	*/

	#include <grub/cryptodisk.h>
	#include <grub/types.h>
	#include <grub/misc.h>
	#include <grub/mm.h>
	#include <grub/dl.h>
	#include <grub/err.h>
	#include <grub/disk.h>
	#include <grub/crypto.h>
	#include <grub/partition.h>
	#include <grub/i18n.h>

	GRUB_MOD_LICENSE ("GPLv3+");

	#define MAX_PASSPHRASE 256

	#define LUKS_KEY_ENABLED 0x00AC71F3

	/* On disk LUKS header */
	struct grub_luks_phdr
	{
	grub_uint8_t magic[6];
	#define LUKS_MAGIC "LUKS\xBA\xBE"
	grub_uint16_t version;
	char cipherName[32];
	char cipherMode[32];
	char hashSpec[32];
	grub_uint32_t payloadOffset;
	grub_uint32_t keyBytes;
	grub_uint8_t mkDigest[20];
	grub_uint8_t mkDigestSalt[32];
	grub_uint32_t mkDigestIterations;
	char uuid[40];
	struct
	{
	grub_uint32_t active;
	grub_uint32_t passwordIterations;
	grub_uint8_t passwordSalt[32];
	grub_uint32_t keyMaterialOffset;
	grub_uint32_t stripes;
	} keyblock[8];
	} GRUB_PACKED;

	typedef struct grub_luks_phdr *grub_luks_phdr_t;

	gcry_err_code_t AF_merge (const gcry_md_spec_t * hash, grub_uint8_t * src,
	grub_uint8_t * dst, grub_size_t blocksize,
	grub_size_t blocknumbers);

	static grub_cryptodisk_t
	configure_ciphers (grub_disk_t disk, const char *check_uuid,
	int check_boot)
	{
	grub_cryptodisk_t newdev;
	const char *iptr;
	struct grub_luks_phdr header;
	char *optr;
	char uuid[sizeof (header.uuid) + 1];
	char ciphername[sizeof (header.cipherName) + 1];
	char ciphermode[sizeof (header.cipherMode) + 1];
	char *cipheriv = NULL;
	char hashspec[sizeof (header.hashSpec) + 1];
	grub_crypto_cipher_handle_t cipher = NULL, secondary_cipher = NULL;
	grub_crypto_cipher_handle_t essiv_cipher = NULL;
	const gcry_md_spec_t hash = NULL, essiv_hash = NULL;
	const struct gcry_cipher_spec *ciph;
	grub_cryptodisk_mode_t mode;
	grub_cryptodisk_mode_iv_t mode_iv = GRUB_CRYPTODISK_MODE_IV_PLAIN64;
	int benbi_log = 0;
	grub_err_t err;

	if (check_boot)
	return NULL;

	/* Read the LUKS header. */
	err = grub_disk_read (disk, 0, 0, sizeof (header), &header);
	if (err)
	{
	if (err == GRUB_ERR_OUT_OF_RANGE)
	grub_errno = GRUB_ERR_NONE;
	return NULL;
	}

	/* Look for LUKS magic sequence. */
	if (grub_memcmp (header.magic, LUKS_MAGIC, sizeof (header.magic))
	\|\| grub_be_to_cpu16 (header.version) != 1)
	return NULL;

	optr = uuid;
	for (iptr = header.uuid; iptr < &header.uuid[ARRAY_SIZE (header.uuid)];
	iptr++)
	{
	if (*iptr != '-')
	optr++ = iptr;
	}
	*optr = 0;

	if (check_uuid && grub_strcasecmp (check_uuid, uuid) != 0)
	{
	grub_dprintf ("luks", "%s != %s\n", uuid, check_uuid);
	return NULL;
	}

	/* Make sure that strings are null terminated. */
	grub_memcpy (ciphername, header.cipherName, sizeof (header.cipherName));
	ciphername[sizeof (header.cipherName)] = 0;
	grub_memcpy (ciphermode, header.cipherMode, sizeof (header.cipherMode));
	ciphermode[sizeof (header.cipherMode)] = 0;
	grub_memcpy (hashspec, header.hashSpec, sizeof (header.hashSpec));
	hashspec[sizeof (header.hashSpec)] = 0;

	ciph = grub_crypto_lookup_cipher_by_name (ciphername);
	if (!ciph)
	{
	grub_error (GRUB_ERR_FILE_NOT_FOUND, "Cipher %s isn't available",
	ciphername);
	return NULL;
	}

	/* Configure the cipher used for the bulk data. */
	cipher = grub_crypto_cipher_open (ciph);
	if (!cipher)
	return NULL;

	if (grub_be_to_cpu32 (header.keyBytes) > 1024)
	{
	grub_error (GRUB_ERR_BAD_ARGUMENT, "invalid keysize %d",
	grub_be_to_cpu32 (header.keyBytes));
	grub_crypto_cipher_close (cipher);
	return NULL;
	}

	/* Configure the cipher mode. */
	if (grub_strcmp (ciphermode, "ecb") == 0)
	{
	mode = GRUB_CRYPTODISK_MODE_ECB;
	mode_iv = GRUB_CRYPTODISK_MODE_IV_PLAIN;
	cipheriv = NULL;
	}
	else if (grub_strcmp (ciphermode, "plain") == 0)
	{
	mode = GRUB_CRYPTODISK_MODE_CBC;
	mode_iv = GRUB_CRYPTODISK_MODE_IV_PLAIN;
	cipheriv = NULL;
	}
	else if (grub_memcmp (ciphermode, "cbc-", sizeof ("cbc-") - 1) == 0)
	{
	mode = GRUB_CRYPTODISK_MODE_CBC;
	cipheriv = ciphermode + sizeof ("cbc-") - 1;
	}
	else if (grub_memcmp (ciphermode, "pcbc-", sizeof ("pcbc-") - 1) == 0)
	{
	mode = GRUB_CRYPTODISK_MODE_PCBC;
	cipheriv = ciphermode + sizeof ("pcbc-") - 1;
	}
	else if (grub_memcmp (ciphermode, "xts-", sizeof ("xts-") - 1) == 0)
	{
	mode = GRUB_CRYPTODISK_MODE_XTS;
	cipheriv = ciphermode + sizeof ("xts-") - 1;
	secondary_cipher = grub_crypto_cipher_open (ciph);
	if (!secondary_cipher)
	{
	grub_crypto_cipher_close (cipher);
	return NULL;
	}
	if (cipher->cipher->blocksize != GRUB_CRYPTODISK_GF_BYTES)
	{
	grub_error (GRUB_ERR_BAD_ARGUMENT, "Unsupported XTS block size: %d",
	cipher->cipher->blocksize);
	grub_crypto_cipher_close (cipher);
	grub_crypto_cipher_close (secondary_cipher);
	return NULL;
	}
	if (secondary_cipher->cipher->blocksize != GRUB_CRYPTODISK_GF_BYTES)
	{
	grub_crypto_cipher_close (cipher);
	grub_error (GRUB_ERR_BAD_ARGUMENT, "Unsupported XTS block size: %d",
	secondary_cipher->cipher->blocksize);
	grub_crypto_cipher_close (secondary_cipher);
	return NULL;
	}
	}
	else if (grub_memcmp (ciphermode, "lrw-", sizeof ("lrw-") - 1) == 0)
	{
	mode = GRUB_CRYPTODISK_MODE_LRW;
	cipheriv = ciphermode + sizeof ("lrw-") - 1;
	if (cipher->cipher->blocksize != GRUB_CRYPTODISK_GF_BYTES)
	{
	grub_error (GRUB_ERR_BAD_ARGUMENT, "Unsupported LRW block size: %d",
	cipher->cipher->blocksize);
	grub_crypto_cipher_close (cipher);
	return NULL;
	}
	}
	else
	{
	grub_crypto_cipher_close (cipher);
	grub_error (GRUB_ERR_BAD_ARGUMENT, "Unknown cipher mode: %s",
	ciphermode);
	return NULL;
	}

	if (cipheriv == NULL);
	else if (grub_memcmp (cipheriv, "plain", sizeof ("plain") - 1) == 0)
	mode_iv = GRUB_CRYPTODISK_MODE_IV_PLAIN;
	else if (grub_memcmp (cipheriv, "plain64", sizeof ("plain64") - 1) == 0)
	mode_iv = GRUB_CRYPTODISK_MODE_IV_PLAIN64;
	else if (grub_memcmp (cipheriv, "benbi", sizeof ("benbi") - 1) == 0)
	{
	if (cipher->cipher->blocksize & (cipher->cipher->blocksize - 1)
	\|\| cipher->cipher->blocksize == 0)
	grub_error (GRUB_ERR_BAD_ARGUMENT, "Unsupported benbi blocksize: %d",
	cipher->cipher->blocksize);
	/* FIXME should we return an error here? */
	for (benbi_log = 0;
	(cipher->cipher->blocksize << benbi_log) < GRUB_DISK_SECTOR_SIZE;
	benbi_log++);
	mode_iv = GRUB_CRYPTODISK_MODE_IV_BENBI;
	}
	else if (grub_memcmp (cipheriv, "null", sizeof ("null") - 1) == 0)
	mode_iv = GRUB_CRYPTODISK_MODE_IV_NULL;
	else if (grub_memcmp (cipheriv, "essiv:", sizeof ("essiv:") - 1) == 0)
	{
	char *hash_str = cipheriv + 6;

	mode_iv = GRUB_CRYPTODISK_MODE_IV_ESSIV;

	/* Configure the hash and cipher used for ESSIV. */
	essiv_hash = grub_crypto_lookup_md_by_name (hash_str);
	if (!essiv_hash)
	{
	grub_crypto_cipher_close (cipher);
	grub_crypto_cipher_close (secondary_cipher);
	grub_error (GRUB_ERR_FILE_NOT_FOUND,
	"Couldn't load %s hash", hash_str);
	return NULL;
	}
	essiv_cipher = grub_crypto_cipher_open (ciph);
	if (!essiv_cipher)
	{
	grub_crypto_cipher_close (cipher);
	grub_crypto_cipher_close (secondary_cipher);
	return NULL;
	}
	}
	else
	{
	grub_crypto_cipher_close (cipher);
	grub_crypto_cipher_close (secondary_cipher);
	grub_error (GRUB_ERR_BAD_ARGUMENT, "Unknown IV mode: %s",
	cipheriv);
	return NULL;
	}

	/* Configure the hash used for the AF splitter and HMAC. */
	hash = grub_crypto_lookup_md_by_name (hashspec);
	if (!hash)
	{
	grub_crypto_cipher_close (cipher);
	grub_crypto_cipher_close (essiv_cipher);
	grub_crypto_cipher_close (secondary_cipher);
	grub_error (GRUB_ERR_FILE_NOT_FOUND, "Couldn't load %s hash",
	hashspec);
	return NULL;
	}

	newdev = grub_zalloc (sizeof (struct grub_cryptodisk));
	if (!newdev)
	{
	grub_crypto_cipher_close (cipher);
	grub_crypto_cipher_close (essiv_cipher);
	grub_crypto_cipher_close (secondary_cipher);
	return NULL;
	}
	newdev->cipher = cipher;
	newdev->offset = grub_be_to_cpu32 (header.payloadOffset);
	newdev->source_disk = NULL;
	newdev->benbi_log = benbi_log;
	newdev->mode = mode;
	newdev->mode_iv = mode_iv;
	newdev->secondary_cipher = secondary_cipher;
	newdev->essiv_cipher = essiv_cipher;
	newdev->essiv_hash = essiv_hash;
	newdev->hash = hash;
	newdev->log_sector_size = 9;
	newdev->total_length = grub_disk_get_size (disk) - newdev->offset;
	grub_memcpy (newdev->uuid, uuid, sizeof (newdev->uuid));
	newdev->modname = "luks";
	COMPILE_TIME_ASSERT (sizeof (newdev->uuid) >= sizeof (uuid));
	return newdev;
	}

	static grub_err_t
	luks_recover_key (grub_disk_t source,
	grub_cryptodisk_t dev)
	{
	struct grub_luks_phdr header;
	grub_size_t keysize;
	grub_uint8_t *split_key = NULL;
	char passphrase[MAX_PASSPHRASE] = "";
	grub_uint8_t candidate_digest[sizeof (header.mkDigest)];
	unsigned i;
	grub_size_t length;
	grub_err_t err;
	grub_size_t max_stripes = 1;
	char *tmp;

	err = grub_disk_read (source, 0, 0, sizeof (header), &header);
	if (err)
	return err;

	grub_puts_ (N_("Attempting to decrypt master key..."));
	keysize = grub_be_to_cpu32 (header.keyBytes);
	if (keysize > GRUB_CRYPTODISK_MAX_KEYLEN)
	return grub_error (GRUB_ERR_BAD_FS, "key is too long");

	for (i = 0; i < ARRAY_SIZE (header.keyblock); i++)
	if (grub_be_to_cpu32 (header.keyblock[i].active) == LUKS_KEY_ENABLED
	&& grub_be_to_cpu32 (header.keyblock[i].stripes) > max_stripes)
	max_stripes = grub_be_to_cpu32 (header.keyblock[i].stripes);

	split_key = grub_malloc (keysize * max_stripes);
	if (!split_key)
	return grub_errno;

	/* Get the passphrase from the user. */
	tmp = NULL;
	if (source->partition)
	tmp = grub_partition_get_name (source->partition);
	grub_printf_ (N_("Enter passphrase for %s%s%s (%s): "), source->name,
	source->partition ? "," : "", tmp ? : "",
	dev->uuid);
	grub_free (tmp);
	if (!grub_password_get (passphrase, MAX_PASSPHRASE))
	{
	grub_free (split_key);
	return grub_error (GRUB_ERR_BAD_ARGUMENT, "Passphrase not supplied");
	}

	/* Try to recover master key from each active keyslot. */
	for (i = 0; i < ARRAY_SIZE (header.keyblock); i++)
	{
	gcry_err_code_t gcry_err;
	grub_uint8_t candidate_key[GRUB_CRYPTODISK_MAX_KEYLEN];
	grub_uint8_t digest[GRUB_CRYPTODISK_MAX_KEYLEN];

	/* Check if keyslot is enabled. */
	if (grub_be_to_cpu32 (header.keyblock[i].active) != LUKS_KEY_ENABLED)
	continue;

	grub_dprintf ("luks", "Trying keyslot %d\n", i);

	/* Calculate the PBKDF2 of the user supplied passphrase. */
	gcry_err = grub_crypto_pbkdf2 (dev->hash, (grub_uint8_t *) passphrase,
	grub_strlen (passphrase),
	header.keyblock[i].passwordSalt,
	sizeof (header.keyblock[i].passwordSalt),
	grub_be_to_cpu32 (header.keyblock[i].
	passwordIterations),
	digest, keysize);

	if (gcry_err)
	{
	grub_free (split_key);
	return grub_crypto_gcry_error (gcry_err);
	}

	grub_dprintf ("luks", "PBKDF2 done\n");

	gcry_err = grub_cryptodisk_setkey (dev, digest, keysize);
	if (gcry_err)
	{
	grub_free (split_key);
	return grub_crypto_gcry_error (gcry_err);
	}

	length = (keysize * grub_be_to_cpu32 (header.keyblock[i].stripes));

	/* Read and decrypt the key material from the disk. */
	err = grub_disk_read (source,
	grub_be_to_cpu32 (header.keyblock
	[i].keyMaterialOffset), 0,
	length, split_key);
	if (err)
	{
	grub_free (split_key);
	return err;
	}

	gcry_err = grub_cryptodisk_decrypt (dev, split_key, length, 0);
	if (gcry_err)
	{
	grub_free (split_key);
	return grub_crypto_gcry_error (gcry_err);
	}

	/* Merge the decrypted key material to get the candidate master key. */
	gcry_err = AF_merge (dev->hash, split_key, candidate_key, keysize,
	grub_be_to_cpu32 (header.keyblock[i].stripes));
	if (gcry_err)
	{
	grub_free (split_key);
	return grub_crypto_gcry_error (gcry_err);
	}

	grub_dprintf ("luks", "candidate key recovered\n");

	/* Calculate the PBKDF2 of the candidate master key. */
	gcry_err = grub_crypto_pbkdf2 (dev->hash, candidate_key,
	grub_be_to_cpu32 (header.keyBytes),
	header.mkDigestSalt,
	sizeof (header.mkDigestSalt),
	grub_be_to_cpu32
	(header.mkDigestIterations),
	candidate_digest,
	sizeof (candidate_digest));
	if (gcry_err)
	{
	grub_free (split_key);
	return grub_crypto_gcry_error (gcry_err);
	}

	/* Compare the calculated PBKDF2 to the digest stored
	in the header to see if it's correct. */
	if (grub_memcmp (candidate_digest, header.mkDigest,
	sizeof (header.mkDigest)) != 0)
	{
	grub_dprintf ("luks", "bad digest\n");
	continue;
	}

	/* TRANSLATORS: It's a cryptographic key slot: one element of an array
	where each element is either empty or holds a key. */
	grub_printf_ (N_("Slot %d opened\n"), i);

	/* Set the master key. */
	gcry_err = grub_cryptodisk_setkey (dev, candidate_key, keysize);
	if (gcry_err)
	{
	grub_free (split_key);
	return grub_crypto_gcry_error (gcry_err);
	}

	grub_free (split_key);

	return GRUB_ERR_NONE;
	}

	grub_free (split_key);
	return GRUB_ACCESS_DENIED;
	}

	struct grub_cryptodisk_dev luks_crypto = {
	.scan = configure_ciphers,
	.recover_key = luks_recover_key
	};

	GRUB_MOD_INIT (luks)
	{
	COMPILE_TIME_ASSERT (sizeof (((struct grub_luks_phdr *) 0)->uuid)
	< GRUB_CRYPTODISK_MAX_UUID_LENGTH);
	grub_cryptodisk_dev_register (&luks_crypto);
	}

	GRUB_MOD_FINI (luks)
	{
	grub_cryptodisk_dev_unregister (&luks_crypto);
	}