gpxe/src/net/80211/wpa_ccmp.c - platform/external/syslinux - Git at Google

 /*
  * Copyright (c) 2009 Joshua Oreman <oremanj@rwcr.net>.
  *
  * This program 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 2 of the
  * License, or any later version.
  *
  * This program 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 this program; if not, write to the Free Software
  * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
  */

 FILE_LICENCE ( GPL2_OR_LATER );

 #include <gpxe/net80211.h>
 #include <gpxe/crypto.h>
 #include <gpxe/hmac.h>
 #include <gpxe/sha1.h>
 #include <gpxe/aes.h>
 #include <gpxe/wpa.h>
 #include <byteswap.h>
 #include <errno.h>

 /** @file
  *
  * Backend for WPA using the CCMP encryption method
  */

 /** Context for CCMP encryption and decryption */
 struct ccmp_ctx
 {
 	/** AES context - only ever used for encryption */
 	u8 aes_ctx[AES_CTX_SIZE];

 	/** Most recently sent packet number */
 	u64 tx_seq;

 	/** Most recently received packet number */
 	u64 rx_seq;
 };

 /** Header structure at the beginning of CCMP frame data */
 struct ccmp_head
 {
 	u8 pn_lo[2];		/**< Bytes 0 and 1 of packet number */
 	u8 _rsvd;		/**< Reserved byte */
 	u8 kid;			/**< Key ID and ExtIV byte */
 	u8 pn_hi[4];		/**< Bytes 2-5 (2 first) of packet number */
 } __attribute__ (( packed ));


 /** CCMP header overhead */
 #define CCMP_HEAD_LEN	8

 /** CCMP MIC trailer overhead */
 #define CCMP_MIC_LEN	8

 /** CCMP nonce length */
 #define CCMP_NONCE_LEN	13

 /** CCMP nonce structure */
 struct ccmp_nonce
 {
 	u8 prio;		/**< Packet priority, 0 for non-QoS */
 	u8 a2[ETH_ALEN];	/**< Address 2 from packet header (sender) */
 	u8 pn[6];		/**< Packet number */
 } __attribute__ (( packed ));

 /** CCMP additional authentication data length (for non-QoS, non-WDS frames) */
 #define CCMP_AAD_LEN	22

 /** CCMP additional authentication data structure */
 struct ccmp_aad
 {
 	u16 fc;			/**< Frame Control field */
 	u8 a1[6];		/**< Address 1 */
 	u8 a2[6];		/**< Address 2 */
 	u8 a3[6];		/**< Address 3 */
 	u16 seq;		/**< Sequence Control field */
 	/* Address 4 and QoS Control are included if present */
 } __attribute__ (( packed ));

 /** Mask for Frame Control field in AAD */
 #define CCMP_AAD_FC_MASK	0xC38F

 /** Mask for Sequence Control field in AAD */
 #define CCMP_AAD_SEQ_MASK	0x000F


 /**
  * Convert 6-byte LSB packet number to 64-bit integer
  *
  * @v pn	Pointer to 6-byte packet number
  * @ret v	64-bit integer value of @a pn
  */
 static u64 pn_to_u64 ( const u8 *pn )
 {
 	int i;
 	u64 ret = 0;

 	for ( i = 5; i >= 0; i-- ) {
 		ret <<= 8;
 		ret |= pn[i];
 	}

 	return ret;
 }

 /**
  * Convert 64-bit integer to 6-byte packet number
  *
  * @v v		64-bit integer
  * @v msb	If TRUE, reverse the output PN to be in MSB order
  * @ret pn	6-byte packet number
  *
  * The PN is stored in LSB order in the packet header and in MSB order
  * in the nonce. WHYYYYY?
  */
 static void u64_to_pn ( u64 v, u8 *pn, int msb )
 {
 	int i;
 	u8 *pnp = pn + ( msb ? 5 : 0 );
 	int delta = ( msb ? -1 : +1 );

 	for ( i = 0; i < 6; i++ ) {
 		*pnp = v & 0xFF;
 		pnp += delta;
 		v >>= 8;
 	}
 }

 /** Value for @a msb argument of u64_to_pn() for MSB output */
 #define PN_MSB	1

 /** Value for @a msb argument of u64_to_pn() for LSB output */
 #define PN_LSB	0


 /**
  * Initialise CCMP state and install key
  *
  * @v crypto	CCMP cryptosystem structure
  * @v key	Pointer to 16-byte temporal key to install
  * @v keylen	Length of key (16 bytes)
  * @v rsc	Initial receive sequence counter
  */
 static int ccmp_init ( struct net80211_crypto *crypto, const void *key,
 		       int keylen, const void *rsc )
 {
 	struct ccmp_ctx *ctx = crypto->priv;

 	if ( keylen != 16 )
 		return -EINVAL;

 	if ( rsc )
 		ctx->rx_seq = pn_to_u64 ( rsc );

 	cipher_setkey ( &aes_algorithm, ctx->aes_ctx, key, keylen );

 	return 0;
 }


 /**
  * Encrypt or decrypt data stream using AES in Counter mode
  *
  * @v ctx	CCMP cryptosystem context
  * @v nonce	Nonce value, 13 bytes
  * @v srcv	Data to encrypt or decrypt
  * @v len	Number of bytes pointed to by @a src
  * @v msrcv	MIC value to encrypt or decrypt (may be NULL)
  * @ret destv	Encrypted or decrypted data
  * @ret mdestv	Encrypted or decrypted MIC value
  *
  * This assumes CCMP parameters of L=2 and M=8. The algorithm is
  * defined in RFC 3610.
  */
 static void ccmp_ctr_xor ( struct ccmp_ctx *ctx, const void *nonce,
 			   const void *srcv, void *destv, int len,
 			   const void *msrcv, void *mdestv )
 {
 	u8 A[16], S[16];
 	u16 ctr;
 	int i;
 	const u8 *src = srcv, *msrc = msrcv;
 	u8 *dest = destv, *mdest = mdestv;

 	A[0] = 0x01;		/* flags, L' = L - 1 = 1, other bits rsvd */
 	memcpy ( A + 1, nonce, CCMP_NONCE_LEN );

 	if ( msrcv ) {
 		A[14] = A[15] = 0;

 		cipher_encrypt ( &aes_algorithm, ctx->aes_ctx, A, S, 16 );

 		for ( i = 0; i < 8; i++ ) {
 			*mdest++ = *msrc++ ^ S[i];
 		}
 	}

 	for ( ctr = 1 ;; ctr++ ) {
 		A[14] = ctr >> 8;
 		A[15] = ctr & 0xFF;

 		cipher_encrypt ( &aes_algorithm, ctx->aes_ctx, A, S, 16 );

 		for ( i = 0; i < len && i < 16; i++ )
 			*dest++ = *src++ ^ S[i];

 		if ( len <= 16 )
 			break;	/* we're done */

 		len -= 16;
 	}
 }


 /**
  * Advance one block in CBC-MAC calculation
  *
  * @v aes_ctx	AES encryption context with key set
  * @v B		Cleartext block to incorporate (16 bytes)
  * @v X		Previous ciphertext block (16 bytes)
  * @ret B	Clobbered
  * @ret X	New ciphertext block (16 bytes)
  *
  * This function does X := E[key] ( X ^ B ).
  */
 static void ccmp_feed_cbc_mac ( void *aes_ctx, u8 *B, u8 *X )
 {
 	int i;
 	for ( i = 0; i < 16; i++ )
 		B[i] ^= X[i];
 	cipher_encrypt ( &aes_algorithm, aes_ctx, B, X, 16 );
 }


 /**
  * Calculate MIC on plaintext data using CBC-MAC
  *
  * @v ctx	CCMP cryptosystem context
  * @v nonce	Nonce value, 13 bytes
  * @v data	Data to calculate MIC over
  * @v datalen	Length of @a data
  * @v aad	Additional authentication data, for MIC but not encryption
  * @ret mic	MIC value (unencrypted), 8 bytes
  *
  * @a aadlen is assumed to be 22 bytes long, as it always is for
  * 802.11 use when transmitting non-QoS, not-between-APs frames (the
  * only type we deal with).
  */
 static void ccmp_cbc_mac ( struct ccmp_ctx *ctx, const void *nonce,
 			   const void *data, u16 datalen,
 			   const void *aad, void *mic )
 {
 	u8 X[16], B[16];

 	/* Zeroth block: flags, nonce, length */

 	/* Rsv AAD - M'-  - L'-
 	 *  0   1  0 1 1  0 0 1   for an 8-byte MAC and 2-byte message length
 	 */
 	B[0] = 0x59;
 	memcpy ( B + 1, nonce, CCMP_NONCE_LEN );
 	B[14] = datalen >> 8;
 	B[15] = datalen & 0xFF;

 	cipher_encrypt ( &aes_algorithm, ctx->aes_ctx, B, X, 16 );

 	/* First block: AAD length field and 14 bytes of AAD */
 	B[0] = 0;
 	B[1] = CCMP_AAD_LEN;
 	memcpy ( B + 2, aad, 14 );

 	ccmp_feed_cbc_mac ( ctx->aes_ctx, B, X );

 	/* Second block: Remaining 8 bytes of AAD, 8 bytes zero pad */
 	memcpy ( B, aad + 14, 8 );
 	memset ( B + 8, 0, 8 );

 	ccmp_feed_cbc_mac ( ctx->aes_ctx, B, X );

 	/* Message blocks */
 	while ( datalen ) {
 		if ( datalen >= 16 ) {
 			memcpy ( B, data, 16 );
 			datalen -= 16;
 		} else {
 			memcpy ( B, data, datalen );
 			memset ( B + datalen, 0, 16 - datalen );
 			datalen = 0;
 		}

 		ccmp_feed_cbc_mac ( ctx->aes_ctx, B, X );

 		data += 16;
 	}

 	/* Get MIC from final value of X */
 	memcpy ( mic, X, 8 );
 }


 /**
  * Encapsulate and encrypt a packet using CCMP
  *
  * @v crypto	CCMP cryptosystem
  * @v iob	I/O buffer containing cleartext packet
  * @ret eiob	I/O buffer containing encrypted packet
  */
 struct io_buffer * ccmp_encrypt ( struct net80211_crypto *crypto,
 				  struct io_buffer *iob )
 {
 	struct ccmp_ctx *ctx = crypto->priv;
 	struct ieee80211_frame *hdr = iob->data;
 	struct io_buffer *eiob;
 	const int hdrlen = IEEE80211_TYP_FRAME_HEADER_LEN;
 	int datalen = iob_len ( iob ) - hdrlen;
 	struct ccmp_head head;
 	struct ccmp_nonce nonce;
 	struct ccmp_aad aad;
 	u8 mic[8], tx_pn[6];
 	void *edata, *emic;

 	ctx->tx_seq++;
 	u64_to_pn ( ctx->tx_seq, tx_pn, PN_LSB );

 	/* Allocate memory */
 	eiob = alloc_iob ( iob_len ( iob ) + CCMP_HEAD_LEN + CCMP_MIC_LEN );
 	if ( ! eiob )
 		return NULL;

 	/* Copy frame header */
 	memcpy ( iob_put ( eiob, hdrlen ), iob->data, hdrlen );
 	hdr = eiob->data;
 	hdr->fc |= IEEE80211_FC_PROTECTED;

 	/* Fill in packet number and extended IV */
 	memcpy ( head.pn_lo, tx_pn, 2 );
 	memcpy ( head.pn_hi, tx_pn + 2, 4 );
 	head.kid = 0x20;	/* have Extended IV, key ID 0 */
 	head._rsvd = 0;
 	memcpy ( iob_put ( eiob, sizeof ( head ) ), &head, sizeof ( head ) );

 	/* Form nonce */
 	nonce.prio = 0;
 	memcpy ( nonce.a2, hdr->addr2, ETH_ALEN );
 	u64_to_pn ( ctx->tx_seq, nonce.pn, PN_MSB );

 	/* Form additional authentication data */
 	aad.fc = hdr->fc & CCMP_AAD_FC_MASK;
 	memcpy ( aad.a1, hdr->addr1, 3 * ETH_ALEN ); /* all 3 at once */
 	aad.seq = hdr->seq & CCMP_AAD_SEQ_MASK;

 	/* Calculate MIC over the data */
 	ccmp_cbc_mac ( ctx, &nonce, iob->data + hdrlen, datalen, &aad, mic );

 	/* Copy and encrypt data and MIC */
 	edata = iob_put ( eiob, datalen );
 	emic = iob_put ( eiob, CCMP_MIC_LEN );
 	ccmp_ctr_xor ( ctx, &nonce,
 		       iob->data + hdrlen, edata, datalen,
 		       mic, emic );

 	/* Done! */
 	DBGC2 ( ctx, "WPA-CCMP %p: encrypted packet %p -> %p\n", ctx,
 		iob, eiob );

 	return eiob;
 }

 /**
  * Decrypt a packet using CCMP
  *
  * @v crypto	CCMP cryptosystem
  * @v eiob	I/O buffer containing encrypted packet
  * @ret iob	I/O buffer containing cleartext packet
  */
 static struct io_buffer * ccmp_decrypt ( struct net80211_crypto *crypto,
 					 struct io_buffer *eiob )
 {
 	struct ccmp_ctx *ctx = crypto->priv;
 	struct ieee80211_frame *hdr;
 	struct io_buffer *iob;
 	const int hdrlen = IEEE80211_TYP_FRAME_HEADER_LEN;
 	int datalen = iob_len ( eiob ) - hdrlen - CCMP_HEAD_LEN - CCMP_MIC_LEN;
 	struct ccmp_head *head;
 	struct ccmp_nonce nonce;
 	struct ccmp_aad aad;
 	u8 rx_pn[6], their_mic[8], our_mic[8];

 	iob = alloc_iob ( hdrlen + datalen );
 	if ( ! iob )
 		return NULL;

 	/* Copy frame header */
 	memcpy ( iob_put ( iob, hdrlen ), eiob->data, hdrlen );
 	hdr = iob->data;
 	hdr->fc &= ~IEEE80211_FC_PROTECTED;

 	/* Check and update RX packet number */
 	head = eiob->data + hdrlen;
 	memcpy ( rx_pn, head->pn_lo, 2 );
 	memcpy ( rx_pn + 2, head->pn_hi, 4 );

 	if ( pn_to_u64 ( rx_pn ) <= ctx->rx_seq ) {
 		DBGC ( ctx, "WPA-CCMP %p: packet received out of order "
 		       "(%012llx <= %012llx)\n", ctx, pn_to_u64 ( rx_pn ),
 		       ctx->rx_seq );
 		free_iob ( iob );
 		return NULL;
 	}

 	ctx->rx_seq = pn_to_u64 ( rx_pn );
 	DBGC2 ( ctx, "WPA-CCMP %p: RX packet number %012llx\n", ctx, ctx->rx_seq );

 	/* Form nonce */
 	nonce.prio = 0;
 	memcpy ( nonce.a2, hdr->addr2, ETH_ALEN );
 	u64_to_pn ( ctx->rx_seq, nonce.pn, PN_MSB );

 	/* Form additional authentication data */
 	aad.fc = ( hdr->fc & CCMP_AAD_FC_MASK ) | IEEE80211_FC_PROTECTED;
 	memcpy ( aad.a1, hdr->addr1, 3 * ETH_ALEN ); /* all 3 at once */
 	aad.seq = hdr->seq & CCMP_AAD_SEQ_MASK;

 	/* Copy-decrypt data and MIC */
 	ccmp_ctr_xor ( ctx, &nonce, eiob->data + hdrlen + sizeof ( *head ),
 		       iob_put ( iob, datalen ), datalen,
 		       eiob->tail - CCMP_MIC_LEN, their_mic );

 	/* Check MIC */
 	ccmp_cbc_mac ( ctx, &nonce, iob->data + hdrlen, datalen, &aad,
 		       our_mic );

 	if ( memcmp ( their_mic, our_mic, CCMP_MIC_LEN ) != 0 ) {
 		DBGC2 ( ctx, "WPA-CCMP %p: MIC failure\n", ctx );
 		free_iob ( iob );
 		return NULL;
 	}

 	DBGC2 ( ctx, "WPA-CCMP %p: decrypted packet %p -> %p\n", ctx,
 		eiob, iob );

 	return iob;
 }


 /** CCMP cryptosystem */
 struct net80211_crypto ccmp_crypto __net80211_crypto = {
 	.algorithm = NET80211_CRYPT_CCMP,
 	.init = ccmp_init,
 	.encrypt = ccmp_encrypt,
 	.decrypt = ccmp_decrypt,
 	.priv_len = sizeof ( struct ccmp_ctx ),
 };


 /**
  * Calculate HMAC-SHA1 MIC for EAPOL-Key frame
  *
  * @v kck	Key Confirmation Key, 16 bytes
  * @v msg	Message to calculate MIC over
  * @v len	Number of bytes to calculate MIC over
  * @ret mic	Calculated MIC, 16 bytes long
  */
 static void ccmp_kie_mic ( const void *kck, const void *msg, size_t len,
 			   void *mic )
 {
 	u8 sha1_ctx[SHA1_CTX_SIZE];
 	u8 kckb[16];
 	u8 hash[SHA1_SIZE];
 	size_t kck_len = 16;

 	memcpy ( kckb, kck, kck_len );

 	hmac_init ( &sha1_algorithm, sha1_ctx, kckb, &kck_len );
 	hmac_update ( &sha1_algorithm, sha1_ctx, msg, len );
 	hmac_final ( &sha1_algorithm, sha1_ctx, kckb, &kck_len, hash );

 	memcpy ( mic, hash, 16 );
 }

 /**
  * Decrypt key data in EAPOL-Key frame
  *
  * @v kek	Key Encryption Key, 16 bytes
  * @v iv	Initialisation vector, 16 bytes (unused)
  * @v msg	Message to decrypt
  * @v len	Length of message
  * @ret msg	Decrypted message in place of original
  * @ret len	Adjusted downward for 8 bytes of overhead
  * @ret rc	Return status code
  *
  * The returned message may still contain padding of 0xDD followed by
  * zero or more 0x00 octets. It is impossible to remove the padding
  * without parsing the IEs in the packet (another design decision that
  * tends to make one question the 802.11i committee's intelligence...)
  */
 static int ccmp_kie_decrypt ( const void *kek, const void *iv __unused,
 			      void *msg, u16 *len )
 {
 	if ( *len % 8 != 0 )
 		return -EINVAL;

 	if ( aes_unwrap ( kek, msg, msg, *len / 8 - 1 ) != 0 )
 		return -EINVAL;

 	*len -= 8;

 	return 0;
 }

 /** CCMP-style key integrity and encryption handler */
 struct wpa_kie ccmp_kie __wpa_kie = {
 	.version = EAPOL_KEY_VERSION_WPA2,
 	.mic = ccmp_kie_mic,
 	.decrypt = ccmp_kie_decrypt,
 };
	/*
	* Copyright (c) 2009 Joshua Oreman <oremanj@rwcr.net>.
	*
	* This program 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 2 of the
	* License, or any later version.
	*
	* This program 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 this program; if not, write to the Free Software
	* Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
	*/

	FILE_LICENCE ( GPL2_OR_LATER );

	#include <gpxe/net80211.h>
	#include <gpxe/crypto.h>
	#include <gpxe/hmac.h>
	#include <gpxe/sha1.h>
	#include <gpxe/aes.h>
	#include <gpxe/wpa.h>
	#include <byteswap.h>
	#include <errno.h>

	/** @file
	*
	* Backend for WPA using the CCMP encryption method
	*/

	/** Context for CCMP encryption and decryption */
	struct ccmp_ctx
	{
	/** AES context - only ever used for encryption */
	u8 aes_ctx[AES_CTX_SIZE];

	/** Most recently sent packet number */
	u64 tx_seq;

	/** Most recently received packet number */
	u64 rx_seq;
	};

	/** Header structure at the beginning of CCMP frame data */
	struct ccmp_head
	{
	u8 pn_lo[2]; /*< Bytes 0 and 1 of packet number /
	u8 _rsvd; /*< Reserved byte /
	u8 kid; /*< Key ID and ExtIV byte /
	u8 pn_hi[4]; /*< Bytes 2-5 (2 first) of packet number /
	} __attribute__ (( packed ));


	/** CCMP header overhead */
	#define CCMP_HEAD_LEN 8

	/** CCMP MIC trailer overhead */
	#define CCMP_MIC_LEN 8

	/** CCMP nonce length */
	#define CCMP_NONCE_LEN 13

	/** CCMP nonce structure */
	struct ccmp_nonce
	{
	u8 prio; /*< Packet priority, 0 for non-QoS /
	u8 a2[ETH_ALEN]; /*< Address 2 from packet header (sender) /
	u8 pn[6]; /*< Packet number /
	} __attribute__ (( packed ));

	/** CCMP additional authentication data length (for non-QoS, non-WDS frames) */
	#define CCMP_AAD_LEN 22

	/** CCMP additional authentication data structure */
	struct ccmp_aad
	{
	u16 fc; /*< Frame Control field /
	u8 a1[6]; /*< Address 1 /
	u8 a2[6]; /*< Address 2 /
	u8 a3[6]; /*< Address 3 /
	u16 seq; /*< Sequence Control field /
	/* Address 4 and QoS Control are included if present */
	} __attribute__ (( packed ));

	/** Mask for Frame Control field in AAD */
	#define CCMP_AAD_FC_MASK 0xC38F

	/** Mask for Sequence Control field in AAD */
	#define CCMP_AAD_SEQ_MASK 0x000F


	/**
	* Convert 6-byte LSB packet number to 64-bit integer
	*
	* @v pn Pointer to 6-byte packet number
	* @ret v 64-bit integer value of @a pn
	*/
	static u64 pn_to_u64 ( const u8 *pn )
	{
	int i;
	u64 ret = 0;

	for ( i = 5; i >= 0; i-- ) {
	ret <<= 8;
	ret \|= pn[i];
	}

	return ret;
	}

	/**
	* Convert 64-bit integer to 6-byte packet number
	*
	* @v v 64-bit integer
	* @v msb If TRUE, reverse the output PN to be in MSB order
	* @ret pn 6-byte packet number
	*
	* The PN is stored in LSB order in the packet header and in MSB order
	* in the nonce. WHYYYYY?
	*/
	static void u64_to_pn ( u64 v, u8 *pn, int msb )
	{
	int i;
	u8 *pnp = pn + ( msb ? 5 : 0 );
	int delta = ( msb ? -1 : +1 );

	for ( i = 0; i < 6; i++ ) {
	*pnp = v & 0xFF;
	pnp += delta;
	v >>= 8;
	}
	}

	/** Value for @a msb argument of u64_to_pn() for MSB output */
	#define PN_MSB 1

	/** Value for @a msb argument of u64_to_pn() for LSB output */
	#define PN_LSB 0



	/**
	* Initialise CCMP state and install key
	*
	* @v crypto CCMP cryptosystem structure
	* @v key Pointer to 16-byte temporal key to install
	* @v keylen Length of key (16 bytes)
	* @v rsc Initial receive sequence counter
	*/
	static int ccmp_init ( struct net80211_crypto crypto, const void key,
	int keylen, const void *rsc )
	{
	struct ccmp_ctx *ctx = crypto->priv;

	if ( keylen != 16 )
	return -EINVAL;

	if ( rsc )
	ctx->rx_seq = pn_to_u64 ( rsc );

	cipher_setkey ( &aes_algorithm, ctx->aes_ctx, key, keylen );

	return 0;
	}


	/**
	* Encrypt or decrypt data stream using AES in Counter mode
	*
	* @v ctx CCMP cryptosystem context
	* @v nonce Nonce value, 13 bytes
	* @v srcv Data to encrypt or decrypt
	* @v len Number of bytes pointed to by @a src
	* @v msrcv MIC value to encrypt or decrypt (may be NULL)
	* @ret destv Encrypted or decrypted data
	* @ret mdestv Encrypted or decrypted MIC value
	*
	* This assumes CCMP parameters of L=2 and M=8. The algorithm is
	* defined in RFC 3610.
	*/
	static void ccmp_ctr_xor ( struct ccmp_ctx ctx, const void nonce,
	const void srcv, void destv, int len,
	const void msrcv, void mdestv )
	{
	u8 A[16], S[16];
	u16 ctr;
	int i;
	const u8 src = srcv, msrc = msrcv;
	u8 dest = destv, mdest = mdestv;

	A[0] = 0x01; /* flags, L' = L - 1 = 1, other bits rsvd */
	memcpy ( A + 1, nonce, CCMP_NONCE_LEN );

	if ( msrcv ) {
	A[14] = A[15] = 0;

	cipher_encrypt ( &aes_algorithm, ctx->aes_ctx, A, S, 16 );

	for ( i = 0; i < 8; i++ ) {
	mdest++ = msrc++ ^ S[i];
	}
	}

	for ( ctr = 1 ;; ctr++ ) {
	A[14] = ctr >> 8;
	A[15] = ctr & 0xFF;

	cipher_encrypt ( &aes_algorithm, ctx->aes_ctx, A, S, 16 );

	for ( i = 0; i < len && i < 16; i++ )
	dest++ = src++ ^ S[i];

	if ( len <= 16 )
	break; /* we're done */

	len -= 16;
	}
	}


	/**
	* Advance one block in CBC-MAC calculation
	*
	* @v aes_ctx AES encryption context with key set
	* @v B Cleartext block to incorporate (16 bytes)
	* @v X Previous ciphertext block (16 bytes)
	* @ret B Clobbered
	* @ret X New ciphertext block (16 bytes)
	*
	* This function does X := E[key] ( X ^ B ).
	*/
	static void ccmp_feed_cbc_mac ( void aes_ctx, u8 B, u8 *X )
	{
	int i;
	for ( i = 0; i < 16; i++ )
	B[i] ^= X[i];
	cipher_encrypt ( &aes_algorithm, aes_ctx, B, X, 16 );
	}


	/**
	* Calculate MIC on plaintext data using CBC-MAC
	*
	* @v ctx CCMP cryptosystem context
	* @v nonce Nonce value, 13 bytes
	* @v data Data to calculate MIC over
	* @v datalen Length of @a data
	* @v aad Additional authentication data, for MIC but not encryption
	* @ret mic MIC value (unencrypted), 8 bytes
	*
	* @a aadlen is assumed to be 22 bytes long, as it always is for
	* 802.11 use when transmitting non-QoS, not-between-APs frames (the
	* only type we deal with).
	*/
	static void ccmp_cbc_mac ( struct ccmp_ctx ctx, const void nonce,
	const void *data, u16 datalen,
	const void aad, void mic )
	{
	u8 X[16], B[16];

	/* Zeroth block: flags, nonce, length */

	/* Rsv AAD - M'- - L'-
	* 0 1 0 1 1 0 0 1 for an 8-byte MAC and 2-byte message length
	*/
	B[0] = 0x59;
	memcpy ( B + 1, nonce, CCMP_NONCE_LEN );
	B[14] = datalen >> 8;
	B[15] = datalen & 0xFF;

	cipher_encrypt ( &aes_algorithm, ctx->aes_ctx, B, X, 16 );

	/* First block: AAD length field and 14 bytes of AAD */
	B[0] = 0;
	B[1] = CCMP_AAD_LEN;
	memcpy ( B + 2, aad, 14 );

	ccmp_feed_cbc_mac ( ctx->aes_ctx, B, X );

	/* Second block: Remaining 8 bytes of AAD, 8 bytes zero pad */
	memcpy ( B, aad + 14, 8 );
	memset ( B + 8, 0, 8 );

	ccmp_feed_cbc_mac ( ctx->aes_ctx, B, X );

	/* Message blocks */
	while ( datalen ) {
	if ( datalen >= 16 ) {
	memcpy ( B, data, 16 );
	datalen -= 16;
	} else {
	memcpy ( B, data, datalen );
	memset ( B + datalen, 0, 16 - datalen );
	datalen = 0;
	}

	ccmp_feed_cbc_mac ( ctx->aes_ctx, B, X );

	data += 16;
	}

	/* Get MIC from final value of X */
	memcpy ( mic, X, 8 );
	}


	/**
	* Encapsulate and encrypt a packet using CCMP
	*
	* @v crypto CCMP cryptosystem
	* @v iob I/O buffer containing cleartext packet
	* @ret eiob I/O buffer containing encrypted packet
	*/
	struct io_buffer * ccmp_encrypt ( struct net80211_crypto *crypto,
	struct io_buffer *iob )
	{
	struct ccmp_ctx *ctx = crypto->priv;
	struct ieee80211_frame *hdr = iob->data;
	struct io_buffer *eiob;
	const int hdrlen = IEEE80211_TYP_FRAME_HEADER_LEN;
	int datalen = iob_len ( iob ) - hdrlen;
	struct ccmp_head head;
	struct ccmp_nonce nonce;
	struct ccmp_aad aad;
	u8 mic[8], tx_pn[6];
	void edata, emic;

	ctx->tx_seq++;
	u64_to_pn ( ctx->tx_seq, tx_pn, PN_LSB );

	/* Allocate memory */
	eiob = alloc_iob ( iob_len ( iob ) + CCMP_HEAD_LEN + CCMP_MIC_LEN );
	if ( ! eiob )
	return NULL;

	/* Copy frame header */
	memcpy ( iob_put ( eiob, hdrlen ), iob->data, hdrlen );
	hdr = eiob->data;
	hdr->fc \|= IEEE80211_FC_PROTECTED;

	/* Fill in packet number and extended IV */
	memcpy ( head.pn_lo, tx_pn, 2 );
	memcpy ( head.pn_hi, tx_pn + 2, 4 );
	head.kid = 0x20; /* have Extended IV, key ID 0 */
	head._rsvd = 0;
	memcpy ( iob_put ( eiob, sizeof ( head ) ), &head, sizeof ( head ) );

	/* Form nonce */
	nonce.prio = 0;
	memcpy ( nonce.a2, hdr->addr2, ETH_ALEN );
	u64_to_pn ( ctx->tx_seq, nonce.pn, PN_MSB );

	/* Form additional authentication data */
	aad.fc = hdr->fc & CCMP_AAD_FC_MASK;
	memcpy ( aad.a1, hdr->addr1, 3 * ETH_ALEN ); /* all 3 at once */
	aad.seq = hdr->seq & CCMP_AAD_SEQ_MASK;

	/* Calculate MIC over the data */
	ccmp_cbc_mac ( ctx, &nonce, iob->data + hdrlen, datalen, &aad, mic );

	/* Copy and encrypt data and MIC */
	edata = iob_put ( eiob, datalen );
	emic = iob_put ( eiob, CCMP_MIC_LEN );
	ccmp_ctr_xor ( ctx, &nonce,
	iob->data + hdrlen, edata, datalen,
	mic, emic );

	/* Done! */
	DBGC2 ( ctx, "WPA-CCMP %p: encrypted packet %p -> %p\n", ctx,
	iob, eiob );

	return eiob;
	}

	/**
	* Decrypt a packet using CCMP
	*
	* @v crypto CCMP cryptosystem
	* @v eiob I/O buffer containing encrypted packet
	* @ret iob I/O buffer containing cleartext packet
	*/
	static struct io_buffer * ccmp_decrypt ( struct net80211_crypto *crypto,
	struct io_buffer *eiob )
	{
	struct ccmp_ctx *ctx = crypto->priv;
	struct ieee80211_frame *hdr;
	struct io_buffer *iob;
	const int hdrlen = IEEE80211_TYP_FRAME_HEADER_LEN;
	int datalen = iob_len ( eiob ) - hdrlen - CCMP_HEAD_LEN - CCMP_MIC_LEN;
	struct ccmp_head *head;
	struct ccmp_nonce nonce;
	struct ccmp_aad aad;
	u8 rx_pn[6], their_mic[8], our_mic[8];

	iob = alloc_iob ( hdrlen + datalen );
	if ( ! iob )
	return NULL;

	/* Copy frame header */
	memcpy ( iob_put ( iob, hdrlen ), eiob->data, hdrlen );
	hdr = iob->data;
	hdr->fc &= ~IEEE80211_FC_PROTECTED;

	/* Check and update RX packet number */
	head = eiob->data + hdrlen;
	memcpy ( rx_pn, head->pn_lo, 2 );
	memcpy ( rx_pn + 2, head->pn_hi, 4 );

	if ( pn_to_u64 ( rx_pn ) <= ctx->rx_seq ) {
	DBGC ( ctx, "WPA-CCMP %p: packet received out of order "
	"(%012llx <= %012llx)\n", ctx, pn_to_u64 ( rx_pn ),
	ctx->rx_seq );
	free_iob ( iob );
	return NULL;
	}

	ctx->rx_seq = pn_to_u64 ( rx_pn );
	DBGC2 ( ctx, "WPA-CCMP %p: RX packet number %012llx\n", ctx, ctx->rx_seq );

	/* Form nonce */
	nonce.prio = 0;
	memcpy ( nonce.a2, hdr->addr2, ETH_ALEN );
	u64_to_pn ( ctx->rx_seq, nonce.pn, PN_MSB );

	/* Form additional authentication data */
	aad.fc = ( hdr->fc & CCMP_AAD_FC_MASK ) \| IEEE80211_FC_PROTECTED;
	memcpy ( aad.a1, hdr->addr1, 3 * ETH_ALEN ); /* all 3 at once */
	aad.seq = hdr->seq & CCMP_AAD_SEQ_MASK;

	/* Copy-decrypt data and MIC */
	ccmp_ctr_xor ( ctx, &nonce, eiob->data + hdrlen + sizeof ( *head ),
	iob_put ( iob, datalen ), datalen,
	eiob->tail - CCMP_MIC_LEN, their_mic );

	/* Check MIC */
	ccmp_cbc_mac ( ctx, &nonce, iob->data + hdrlen, datalen, &aad,
	our_mic );

	if ( memcmp ( their_mic, our_mic, CCMP_MIC_LEN ) != 0 ) {
	DBGC2 ( ctx, "WPA-CCMP %p: MIC failure\n", ctx );
	free_iob ( iob );
	return NULL;
	}

	DBGC2 ( ctx, "WPA-CCMP %p: decrypted packet %p -> %p\n", ctx,
	eiob, iob );

	return iob;
	}


	/** CCMP cryptosystem */
	struct net80211_crypto ccmp_crypto __net80211_crypto = {
	.algorithm = NET80211_CRYPT_CCMP,
	.init = ccmp_init,
	.encrypt = ccmp_encrypt,
	.decrypt = ccmp_decrypt,
	.priv_len = sizeof ( struct ccmp_ctx ),
	};




	/**
	* Calculate HMAC-SHA1 MIC for EAPOL-Key frame
	*
	* @v kck Key Confirmation Key, 16 bytes
	* @v msg Message to calculate MIC over
	* @v len Number of bytes to calculate MIC over
	* @ret mic Calculated MIC, 16 bytes long
	*/
	static void ccmp_kie_mic ( const void kck, const void msg, size_t len,
	void *mic )
	{
	u8 sha1_ctx[SHA1_CTX_SIZE];
	u8 kckb[16];
	u8 hash[SHA1_SIZE];
	size_t kck_len = 16;

	memcpy ( kckb, kck, kck_len );

	hmac_init ( &sha1_algorithm, sha1_ctx, kckb, &kck_len );
	hmac_update ( &sha1_algorithm, sha1_ctx, msg, len );
	hmac_final ( &sha1_algorithm, sha1_ctx, kckb, &kck_len, hash );

	memcpy ( mic, hash, 16 );
	}

	/**
	* Decrypt key data in EAPOL-Key frame
	*
	* @v kek Key Encryption Key, 16 bytes
	* @v iv Initialisation vector, 16 bytes (unused)
	* @v msg Message to decrypt
	* @v len Length of message
	* @ret msg Decrypted message in place of original
	* @ret len Adjusted downward for 8 bytes of overhead
	* @ret rc Return status code
	*
	* The returned message may still contain padding of 0xDD followed by
	* zero or more 0x00 octets. It is impossible to remove the padding
	* without parsing the IEs in the packet (another design decision that
	* tends to make one question the 802.11i committee's intelligence...)
	*/
	static int ccmp_kie_decrypt ( const void kek, const void iv __unused,
	void msg, u16 len )
	{
	if ( *len % 8 != 0 )
	return -EINVAL;

	if ( aes_unwrap ( kek, msg, msg, *len / 8 - 1 ) != 0 )
	return -EINVAL;

	*len -= 8;

	return 0;
	}

	/** CCMP-style key integrity and encryption handler */
	struct wpa_kie ccmp_kie __wpa_kie = {
	.version = EAPOL_KEY_VERSION_WPA2,
	.mic = ccmp_kie_mic,
	.decrypt = ccmp_kie_decrypt,
	};